ISSN 1713-7845

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JOURNAL

;

of the iy
ENTOMOLOGICAL — -

SOCIETY

OF
ONTARIO

Volume

One Hundred and Forty Three
2012

Published December 2012

ISSN 1713-7845

JOURNAL

of the

ENTOMOLOGICAL SOCIETY

ONTARIO
Volume One Hundred and Forty Three

2012

THE ENTOMOLOGICAL SOCIETY OF ONTARIO
OFFICERS AND GOVERNORS
2011-2012

President: B. GILL
Entomology Unit, Ontario Plant Laboratories,

Canadian Food Inspection Agency. Building 18 C.E.F.

960 Carling Ave., Ottawa, ON K1A 0C6
bruce.gill@inspection.ge.ca
President-Elect: J. SKEVINGTON
Agriculture and Agri-Food Canada,

K.W. Neatby Building

960 Carling Avenue, Ottawa, ON K1A 0C6
jskevington@gmail.com

Past-President: H. FRASER

Ontario Ministry of Agriculture, Food and Rural Affairs

4890 Victoria Ave. North, P.O. Box 8000
Vineland, ON LOR 2E0

hannah. fraser@ontario.ca

Secretary: N. MCKENZIE

Vista Centre, 1830 Bank Street, P.O. Box 83025
Ottawa, ON K1V 1A3
nicole_mekenzie@he-sc.ge.ca

Treasurer: S. LI

Pest Management Centre, Building 57
Agriculture and Agri-Food Canada

960 Carling Ave., Ottawa, ON KIA 0C6
Dr.Shiyou.Li@nrcan.ge.ca
Directors:

C. BAHLAI

School of Environmental Science
University of Guelph

Guelph, ON NIG 2W1
cbahlai@uoguelph.ca

R. BUITENHUIS (2011-2013)
Vineland Research and Innovation Centre

4890 Victoria Ave. North, P.O. Box 4000
Vineland, ON LOR 2E0
rose.buitenhuis@vinelandresearch.com
J. GIBSON

Department of Integrative Biology
University of Guelph

Guelph,ON N1G 2W1
jfgibson@uoguelph.ca

S. LACHANCE (2010-2012)
Université de Guelph - Campus d’ Alfred

31 St. Paul Street, Alfred, ON KOB 1A0
Slachance@alfredc.uoguelph.ca

J. MCNEIL

Department of Biology, BGS 3066
University of Western Ontario,
London, ON N6A 5B7
jmeneil2@uwo.ca

(2012-2014)

(2012-2014)

(2011-2013)

I. SCOTT

Agriculture and Agri-Food Canada
1391 Sandford Street, London, ON NSV 4T3
lan.Scott@agr.ge.ca

ESO Regional Rep to ESC: H. DOUGLAS
Canadian Food Inspection Agency

960 Carling Ave., Ottawa ON KIA 06C
douglash@inspection.ge.ca

Librarian: J. BRETT

Library, University of Guelph

Guelph, ON NIG 2W1
jimbrett@uoguelph.ca

Newsletter Editor: A. GRADISH

School of Environmental Science

University of Guelph, Guelph ON N1G 4Y2
agradish@uoguelph.ca

Student Representative: K. MARSHALL
Department of Biology

University of Western Ontario

Room 2035, Biological and Geological Sciences
London, ON N6A 5B7

kmarsh32@uwo.ca

Website: M. JACKSON

School of Environmental Science

University of Guelph, Guelph, ON N1G 2W1
jackson@uoguelph.ca

(2010-2012)

JESO Editor: J. HUBER

Canadian National Collection of Insects
Agriculture and Agri-Food Canada

960 Carling Ave. Ottawa, ON,K1A 0C6
John. Huber@agr.gce.ca

Technical Editor: J. VICKRUCK
Dept. of Biological Sciences, Brock University
St. Catharines, ON L2S 3A1
jess.vickruck@pbrocku.ca

Associate Editors:

A. BENNETT

Agriculture and Agri-Food Canada

960 Carling Ave., Ottawa ON KIA 06C
N. CARTER

Engage Agro Corporation

1030 Gordon St., Guelph, ON, NIG 4X5
neilcarter@engageagro.com

J. SKEVINGTON

Agriculture and Agri-Food Canada
Eastern Cereal and Oilseed Research Centre
960 Carling Ave., Ottawa, ON K1A 0C6

FELLOWS OF THE ENTOMOLOGICAL SOCIETY OF ONTARIO

W. W. BILL JUDD

C. RON HARRIS
GLENN WIGGINS
BERNARD PHILOGENE
FREEMAN MCEWEN

2002
2003
2006
2010
2010

JESO Volume 143, 2012

JOURNAL
of the
ENTOMOLOGICAL SOCIETY OF ONTARIO

VOLUME 143 ZOIZ

I thank all the reviewers and Associate Editors — Andy Bennett, Neil Carter, and
Jeff Skevington — for their careful reviews and seeing acceptable mss through the review
process. In this day and age it is not always easy to find those willing to take time from their
own busy schedules to provide careful and thoughtful reviews that improve the quality of
articles submitted to JESO. For many years Martin Damus has provided a cover illustration
that reflects an insect treated in one of the articles. This year it is the Oriental Chestnut Gall
Wasp. It finally arrived in Canada in 2012 and is reported here—38 years after it was first
found in the US. Jess Vickruck has again done an excellent job as Technical Editor. These
dedicated people have greatly improved the quality of articles published in JESO. It is a
pleasure to work with them.

The Entomological Society of Ontario celebrates its 150" annual meeting next
year. Please consider JESO milestone volume 144 as a good venue to publish your research,
especially if you plan to present a talk about it at the special anniversary meeting in Guelph.
If you do want to publish in JESO, please consult the recently updated “Instructions to
Authors” on the website.

Many of the new electronic journals aimed at biologists and promoted almost
weekly in emails received by all and sundry advertise a quick turn around time from ms
submission to publication. Their editors perhaps forget that if their journal articles are to
be of high quality referees must be given sufficient time to review submissions properly,
(assuming that willing referees who know the subject can even be found). If turn around
time is too short many potential referees will simply refuse to provide reviews. Despite
the electronic competition I like to think, and certainly hope, that JESO will continue to
receive interesting and diverse articles for decades to come, having stood the test of time as
a worthwhile entomological journal for publishing on insects in Ontario. Although JESO
might be considered as not having enough impact or prestige it has a long and solid pedigree,
thanks especially to the conscientious efforts of past Editors, Associate Editors and referees.
Quality and reliability count for a lot, no matter how short the article or how limited in scope
it may be. So choose JESO in which to publish your work.

Happy reading.

John T. Huber
Editor

Optimization of synthetic pheromone blend for C. rosaceana _ JESO Volume 143, 2012

OPTIMIZATION OF SYNTHETIC PHEROMONE BLEND
FOR USE IN MONITORING CHORISTONEURA ROSACEANA
(LEPIDOPTERA: TORTRICIDAE) IN NIAGARA PENINSULA,

ONTARIO, APPLE ORCHARDS

R. M. TRIMBLE
Southern Crop Protection and Food Research Centre
Agriculture & Agri-Food Canada
Vineland Station, ON LOR 2E0
e-mail: trimbler@agr.gc.ca

Abstract went “Soc. “Ont “Y43°" 3-14

Trapping experiments were carried out in Niagara peninsula, Ontario apple
orchards to determine the optimum ratios of synthetic pheromone compounds
for use in monitoring the obliquebanded leafroller, Choristoneura rosaceana
(Harris) (Leptidoptera: Tortricidae). The mean total number of moths
captured in traps baited with rubber stopper lures impregnated with 0.97 mg
of the major compound (Z)-11-tetradecenyl acetate (71 1-14:OAc) increased
3—4-fold with the addition of 2% of the minor compound (£)-11-tetradecenyl
acetate (E11-14:OAc) and increases to 4 and 8% did not change average
catch. The addition of 1-8% of the minor compound (Z)-11-tetradecenol
(Z11-14:OH) to lures containing 0.97 mg Z11-14:0Ac + 2% E11-14:0Ac
did not affect average catch. There was a 3.5—3.8-fold increase in catch when
0.97 mg Z11-14:0Ac + 2% E11-14:OAc + 1.5% Z11-14:0H was combined
with 1% of the minor compound (Z)-11-tetradecenal (711-14:Ald). Mean trap
catch declined when the relative amount of Z11-14:Ald was >4%. There was
a 2.3—-3.7-fold increase mean trap catch when 0.97 mg Z11-14:OAc + 1.5%
mg Z11-14:0H + 1% Z11-14:Ald was combined with 1% £11-14:OAc. There
was no increase in catch with additional increases in the relative amount of
E\1-14:0Ac. There was a 1.8—2.3-fold decrease in catch when 2% Z11-
14:0H was combined with 0.97 mg Z11-14:0Ac + 2% E11-14:0Ac + 1%
Z\1-14:Ald. There was no change in mean trap catch with the addition of
greater relative amounts of Z11-14:OH. The results suggest that the optimum
blend of synthetic pheromone compounds for use in monitoring C. rosaceana
in the Niagara peninsula of Ontario is a blend of the main compound Z11-
14:0Ac plus the minor compounds in relative amounts of 1% E11-14:OAc,
0-1% Z11-14:0OH and 1% Z11-14:Ald.

Published December 2012

Trimble JESO Volume 143, 2012

Introduction

The obliquebanded leafroller, Choristoneura rosaceana (Harris) (Lepidoptera:
Tortricidae), is native to North America where it is distributed throughout southern Canada
and most areas of the continental United States, except the arid southwest (Chapman and
Lienk 1971). The larvae of C. rosaceana are polyphagous, feeding on the foliage and fruit
of many deciduous plants, although its primary hosts typically belong to the Rosaceae
(Weires and Ried! 1991). There are one or two generations per year, depending on climate,
and second- or third-instar larvae overwinter in a hibernaculum (Chapman and Lienk 1971).
Choristoneura rosaceana is a key pest of commercial apple, Malus domestica (Borkh)
(Rosaceae) in Ontario where sprays of insecticide are applied to control the larvae of its two
annual generations (Anonymous 2009, 2010).

The sex pheromone of C. rosaceana consists of the major compound (Z)-11-
tetradecenyl acetate (Z11-14:OAc) (Roelofs and Tette 1970) and three minor compounds,
(£)-11-tetradecenyl acetate (E11-14:OAc), (Z)-11-tetradecenol (Z11-14:OH) and (Z)-
11-tetradecenal (Z11-14:Ald) (Cardé et al. 1977; Hill and Roelofs 1979; Vakenti et al.
1988; El-Sayed et al. 2001a). It was initially believed that Z11-14:Ald was present only
in populations from western North America (Vakenti et al. 1988; Thomson et al. 1991),
but further investigation revealed that this compound was also an important component of
the pheromone of some eastern North American populations of this species in Ontario and
Quebec (El-Sayed et al. 2001a, 2003). The pheromone gland and effluvium of an Ontario
population of C. rosaceana contained approximately 96% Z11-14:O0Ac, 2% E11-14:0Ac,
1.5% Z11-14:0OH and 0.5% Z11-14:Ald (El-Sayed et al. 2001ab).

Traps baited with synthetic sex pheromone are used to accurately time insecticide
sprays for the control of C. rosaceana in Ontario apple orchards (Anonymous 2009).
Sex pheromone-baited traps have also been used in Ontario to indirectly measure the
effectiveness of pheromone treatments applied to control C. rosaceana by sex pheromone-
mediated mating disruption (Trimble and Appleby 2004). Field trapping studies carried out
in the Niagara peninsula of Ontario have demonstrated the behavioral activity of the minor
pheromone compounds when combined with the main compound in relative amounts of
2% (E11-14:O0Ac), 1.5% (Z11-14:OH) and 1% (Z11-14:Ald) (El-Sayed et al. 2001a, 2003;
Trimble and Marshall 2008), but it is not known if this is the optimal blend of compounds
for use in this location. This paper reports the results of field trapping experiments designed
to determine if the previously used blend is optimal for use in apple orchards in the Niagara
peninsula of Ontario.

Materials and Methods

Synthetic pheromone

Pheromone compounds were acquired from the Pherobank, Plant Research
International, Wageningen, The Netherlands. The Z11-14:OAc was 99.2% chemically pure
and contained 0.4% E11-14:OAc. It did not contain the known C. rosaceana attraction
inhibitors (Z)-9-tetradecenyl acetate (Z9-14:OAc) or (£)-9-tetradecenyl acetate (£9-

Optimization of synthetic pheromone blend for C. rosaceana — JESO Volume 143, 2012

14:0Ac) (Trimble and El-Sayed 2006). The £11-14:O0Ac had a chemical and isomeric
purity of 99.5%, The Z11-14:0OH and Z11-14:Ald had a chemical purity of 99 and 91.5%,
respectively.

Field trapping experiments

A stepwise approach was used to determine the effect on trap catch of combining
increasing relative amounts of minor compounds with the main pheromone compound. In
the first experiment, Z11-14:0Ac was combined with 0, 1, 2, 4 or 8% E£11-14:OAc. In the
second experiment Z11-14OAc + 2% E11-14:0Ac was combined with 0-8% Z11-14:0OH.
In the third experiment Z11-14OAc + 2% E11-14:O0Ac + 1.5% Z11-14:0H was combined
with 0-8% Z11-14:Ald. In a second set of experiments, Z711-140Ac + 1.5% Z11-14:0OH
+ 1% Z11-14:Ald was combined with 0-8% £11-14:OAc, and Z11-140Ac + 2% E11-
14:0Ac + 1% Z11-14:Ald was combined with 0-8% Z11-14:OH. Trap lures were prepared
by applying 200 ul of pheromone in hexane, or hexane (i.e. control), to the large “well” of
9 mm diameter, natural rubber sleeve stoppers (Chromatographic Specialties, Brockville,
Ontario). The solvent was allowed to evaporate in a fume hood and the stoppers were stored
at —20°C until use. Stoppers were attached to 8 mm-diameter corks using an insect pin. The
corks were positioned in the middle of the insect adhesive-coated surface of 21 cm-long x
20 cm-wide x 12 cm-high white plastic delta traps (Cooper Mill Ltd., Madoc, Ontario) and
the traps were positioned |.5—2.0 m above the ground within the tree canopy.

Experiments were carried out in 0.2—2.2 ha plots of cv. Empire, McIntosh or Red
Delicious insecticide-free apple trees at the Agriculture and Agri-Food Canada (AAFC)
Experimental Farm at Jordan Station, Ontario (43°10°N 79°24’W) during the first and
second annual C. rosaceana flights of 2004—2008, and during each of the two annual flights
of 2010. A randomized complete block (RCB) or split-plot experimental design (Snedecor
and Cochran 1989) was used to test the effect of varying the relative amounts of F11-
14:0Ac and Z11-14:0H (2004-2008). The location of treatments within blocks (RCB) or
subplots (split-plot) was not changed during a flight period. There was +10 m between
traps. A completely randomized design (Snedecor and Cochran 1989) was used to test the
effect of varying the relative amount of Z11-14:Ald (2010). There was ~20 m between traps
in this experiment and the location of treatments was re-randomized at 14 d intervals. In
all experiments moths were counted and removed from the traps twice each week and the
rubber stopper lures were renewed at 2-wk intervals.

Analysis of data

Statistical analyses were performed using JMP® 7.0 (SAS Institute, Cary, North
Carolina). The significance of the effect of the relative amount of a minor compound on the
mean number of moths captured during a flight was tested using a randomized complete
block, split-plot, or completely randomized analysis of variance model after transforming the
data using V(x + 0.5). The significance of differences between means was first tested using
the Tukey Honestly Significant Difference (HSD) test. If there were no differences using
this test the Fisher Least Significant Difference (LSD) test was used to identify differences
(Dallal 2001). Means were back-transformed for presentation in tables (Snedecor and
Cochran 1989).

Trimble JESO Volume 143, 2012

Results

The attractiveness of lures baited with Z11-14:OAc was increased by the addition
of F£11-14:OAc (Table 1). There was a 3- and 4-fold increase in the mean total number of
moths captured during the spring and summer flights of 2004, respectively, when 0.97 mg
of Z11-14:0Ac was combined with 0.02 mg E11-14:0Ac (2%). There was no statistically
detectable increase in trap catch when the relative amount of £11-14:0Ac was 1%, and
increases above 2% did not significantly change average catch (Table 1). The addition of
Z11-14:0H to lures containing a blend of 0.97 mg Z11-14:OAc + 0.02 mg £11-14:0Ac
2%) did not affect the mean total number of moths captured during the spring and summer
flights of 2005 (Table 2). There was a 3.5- and 3.8-fold increase in the mean total number

TABLE 1. Mean + SD total number Choristoneura rosaceana captured in traps baited
with lures containing a constant amount of Z11-14:OAc and increasing amounts of E11-
14:0Ac.

Ari te Amount of compound, mg/lure Total number captured
Z11-14:0Ac El1-14:0Ac First flight Second Flight
l 0.97 0.0 5.4+3.4b (29) 8.5+8.7b (50)
2 0.97 0.01 10.6+11.6ab (64) — 22.04+30.6ab (134)
3 Om 0.02 14.6+17.3a (89) 32.8+51.8a (211)
4 0.97 0.04 8.7+7.2ab (48) 22.3+18.1ab (123)
5 0.97 0.08 6.9+7.4ab (40) —24.5+23.2ab (147)
6 0.0 0.0 0.0+0.0c (0) 0.0+0.0¢ (0)

Total number trapped in parenthesis. First flight, 11 June — 9 July 2004 (n = 270), RCB ANOVA, F = 6.21, df=
5,20, P = 0.0013; Second flight, 4 August — 16 September 2004 (n = 665), RCB ANOVA, F = 6.47, df = 5,20,
P = 0.001. Means within each flight followed by the same letter not significantly different (Fisher LSD test, P >
0.05).

TABLE 2. Mean + SD total number Choristoneura rosaceana captured in traps baited with
lures containing constant amounts of Z11-14:OAc and E11-14:OAc and increasing amounts
of Z11-14:0OH.

eee Amount of compound, mg/lure Total moths captured
Z\1-14:0Ac Ell-14:0Ac Z11-14:0H _ First flight | Second flight
ay unOoa 0.02 0.0 11.2+8.2a (61) 13.0£23.3a (374)
2 0.97 0.02 0.01 10.3+7.3a (56) 10.7+26.4a (348)
8 0.97 0.02 0.02 8.9+10.6a (52) 5.4+17.0a (193)
4 O97 0.02 0.04 13.9417.2a (82) 11.0+35.6a (355)
5 0.97 0.02 0.08 11.6+8.9a (63) 8.6+27.1a (283)
6 0.0 0.0 0.0 0.0£0.0b(0) ———_:0.0£0.0b (0) _

Total number trapped in parenthesis. First flight, 13 June — 11 July 2005 (n = 314), RCB ANOVA, F = 12.92,
df = 5,20, P < 0.0001); Second flight, 29 July — 21 September 2005 (n = 1554), Split-plot ANOVA, F = 4.78, df
= 5,60, P < 0.008. Means in a column within each flight followed by the same letter not significantly different
(Fisher LSD test, P > 0.05).

Optimization of synthetic pheromone blend for C. rosaceana — JESO Volume 143, 2012

of moths captured during the spring and summer | mo
flights of 2010, respectively, when a blend of 2 lege | 9
’ ; 5 |L,le naar alss
0.97 mg Z11-14:0Ac + 0.02 mg £11-14:0Ac 2 Him cee eu Ve
(2%) + 0.015 mg Z11-14:0H (1.5%) was = ee ereoree S a=
combined with 0.01 mg (1%) of Z11-14:Ald gin 2e Sh Pisee
* = ley | SB) H OO = 1 ARO Pep | 2"
(Table 3). Mean trap catch declined when the ONS) sieve ect et eas sil ese
3 < . | lw . é A | A
relative amount of Z11-14:Ald was increased to S BA) 6 6 fm 5s
4% during the spring flight and to 8% during 5 = PD 3
the summer flight. There was a 2.3- and 3.7- ‘= S| Ss
fold increase in the mean total number of moths = = = E
captured during the spring and summer flights § I's aoeeseea.s
of 2006, respectively, when a blend of 097mg g |/G\S\2E KAS a oes
Z11-14:0Ac + 0.015 mg Zl1-14:0H (1.5%) 3 | jelgaegg3c"8
+ 0.01 mg ZI1-14:Ald (1%) was combined + Blo Pau A Hes
: = {56 12 Gay IN We) aI
with 0.01 mg (1%) of E1l-14:0Ac (Table 4). 2 Fe) A a 4 a Em gz
There was no increase in mean trap catch with 3 [RS tee Bean eect Rres
additional increases in the relative amount of ‘3 wt, seh Nas
E\1-14:0Ac. There was no change inthe mean w . <5
‘ ; ; ag SS
total number of moths captured during the spring & z asi iS is
and summer flights of 2007 when 0.01 mg Z11- <¢ + ay sazeoci< 5
. . Chon bee) | =~
14:0H (1%) was combined with a blend of 0.97 sche | ae BSS hil $ =
mg Z11-14:0Ac + 0.02 mg £11-14:0Ac (2%) 3 N N 2 <
+ 0.01 mg Z11-14:Ald (1%). There was a 1.8- 2S) | ee
é an |
and 2.3-fold decrease in the mean total number x = a c 2
of moths captured during these flights, however, S 2 3) in =
when 0.02 mg Z11-14:OH (2%) was used in this S = y cae Aes ol=s
blend (Table 5). There was no change in mean § §) WJ~ SSSSS SlSy
: Sis , ae In cn ee S NT ee,
trap catch with the addition of greater relative 5 3) §) < | 2 os
amounts of Z11-14:OH. = 3| Sle m| aye
See i
S a
3 El 8! | ee
§ S/s\s 23
Discussion So Blslaaaaacli?
wel oi—ie Cec CPSs a
9m e|ajoooonso =
The results of this study suggest that r= i | Fs | res
the optimum blend of synthetic pheromone 2 = | zz
compounds for use in monitoring C. rosaceana 3 § . |-2 >
in the Niagara peninsula of Ontario is a blend © 2 S FE is
of the main compound Z11-14:OAc plus the a e) SARARS =) BS =
minor compounds in relative amounts of 4 = DS SCR ae
1% E\1-14:0Ac, 0-1% Z11-14:0H and 1% § =|} |R Bil A
Z11-14:Ald. Traps baited only with the main 22 \BS 2
5 ies Ss) |\5= 6
compound required the addition of 2% Ell- ..<) € 5 Sis
14:0Ac to effect a significant increase in the .y e = e5 ee
; RPS ts}! (AY Ga Sr Ya) NS) Se
capture of moths, but when traps were baited RT = § ~s2
with the main compound and each of the three 4 RS os s oe Ec

JESO Volume 143, 2012

Trimble

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Optimization of synthetic pheromone blend for C. rosaceana —_ JESO Volume 143, 2012

minor compounds, the inclusion of £11-14:OAc at 1% was sufficient to effect a significant
increase in the capture of C. rosaceana. There was no increase in the number of moths
captured with the use of greater relative amounts of £11-14:OAc in the complete, four-
compound blend.

The results suggest that it may not be necessary to include 71 1-14:OH in synthetic
C. rosaceana pheromone for use in the Niagara peninsula because there was no change in
the number of moths captured in traps baited with Z11-14:OAc plus 2% £11-14:0Ac when
Z\1-14:OH was included at 1, 2, 4 or 8% relative to the main compound. In addition, there
was no change in the number of moths captured when 1% Z11-14:OH was added to a blend
of Z11-14:OAc plus relative amounts of 2% £11-14:OAc and 1% Z11-14:Ald; the addition
of greater relative amounts of Z11-14:OH to this blend significantly reduced the number of
moths captured compared to the numbers captured in traps baited with a lure that did not
contain the alcohol. In another field trapping study conducted in Niagara peninsula apple
orchards, Trimble and Marshall (2008) were unable to detect any increase in trap catch
during three of four C. rosaceana flight periods when 1.5% Z11-14:OH was added to a
blend of Z11-14:OAc plus 2% E11-14:Ac; however, during a fourth flight period there was
a 2.2-fold increase in trap catch with the addition of the alcohol.

The pheromone gland of female C. rosaceana from the Niagara peninsula
contained Z11-14:OH in amounts ranging from 1|.16—2.20% relative to the main pheromone
compound Z11-14:OAc (El-Sayed et al. 2001ab, 2003; El-Sayed and Trimble 2002) and the
pheromone gland effluvium contained 1.75% Z11-14:OH relative to the main pheromone
compound (El-Sayed et al. 20014). In addition, the electroantennogram (EAG) response—
pheromone dose relationships measured in the antennae of male C. rosaceana from the
Niagara peninsula was similar for Z11-14:OAc and Z11-14:OH (El-Sayed et al. 20015).
The production and emission of Z11-14:OH by female C. rosaceana, and the ability of male
antennae to detect this compound suggests that it has a role in the pheromone-mediated
sexual communication of Niagara populations of this species. In a flight tunnel experiment
using male C. rosaceana from the Niagara peninsula, there was a trend of increase in
the proportion of individuals initiating the take-off, lock-on, close-in, and touchdown
phases of upwind flight to Z11-14:0Ac when E11-14:OAc, Z11-14:OH and Z11-14:Ald
were successively added in relative amounts of 2, 1.5 and 1%, respectively (Trimble and
Marshall 2008). This observation suggests that Z11-14:OH is important in the chemical
communication of C. rosaceana and should be included in a blend of synthetic pheromone
compounds for use in monitoring the presence and activity of this species in the Niagara
peninsula.

The results of the present study confirm the behavioural activity of the minor
pheromone compound Z11-14:Ald. There was an approximately 4-fold increase in the
capture of C. rosaceana in traps baited with Z11-14:OAc plus relative amounts of 2% £11-
14:0Ac and 1.5% Z11-14:0H when 1% Z11-14:Ald is added to the blend. In previous
trapping studies in Niagara peninsula apple orchards 2—3-fold increases in trap catch were
observed after the addition of 1% of the aldehyde compound (El-Sayed et al. 2001a, 2003;
Trimble and Marshall 2008).

The significance of differences between the mean numbers of C. rosaceana
captured in traps baited with different blends of pheromone was tested using both the Tukey
HSD test and the Fisher LSD test. The Tukey HSD test is very conservative, i.e. it has a low

Trimble JESO Volume 143, 2012

likelihood of declaring differences when none exist, whereas the Fisher LSD test is liberal,
i.e. it has a higher likelihood of declaring differences when none exist (Chew 1976). The
approach recommended by Dallal (2001) was used to test for the significance of differences
between the mean numbers of C. rosaceana captured in traps baited with difference blends
of synthetic pheromone compounds. The Tukey HSD was first applied and significant
differences were accepted. If no differences were found using the Tukey HSD test, the
significance of differences between means was then tested using the Fisher LSD test. Dallal
(2001) advised that differences judged significant by the Fisher LSD test but not by the
Tukey HSD test should be considered open to further investigation. In the present study,
the Tukey HSD test identified differences between means only in the experiment where the
relative amount of Z11-14:Ald was varied in a blend of Z11-14:OAc plus 2% E11-14:0Ac
and 1.5% Z11-14:OH. This suggests that additional experimentation should be undertaken
to confirm the results of the other experiments carried out in this study. The use of a flight
tunnel for these studies would eliminate the need to control for possible trap position
effects and would permit between-experiment uniformity of sample size. Flight tunnel
experiments, however, might not yield pheromone-blend differences that are detectable
using a conservative multiple comparison test like the Tukey HSD. For example, Trimble
and Marshall (2008) did not detect an increase in the number of C. rosaceana males landing
at a pheromone source in a flight tunnel when 2% Z11-14:Ald was added to a blend of Z11-
14:0Ac plus 2% E11-14:0Ac and 1.5% Z11-14:0OH, whereas in the currently reported field
trapping study, a 2.4—3.7-fold increase in the capture of C. rosaceana was detected with the
addition of 2% of the aldehyde to this blend of compounds.

There is evidence of geographic variation in the optimum ratio of the main
pheromone compound and its £-isomer. For example, in New York apple orchards, Hill
and Roelofs (1979) found that traps baited with the main compound required the addition
of at least 3% E11-14:OAc to significantly increase the capture of C. rosaceana. They also
found no difference in the number of moths captured when using relative amounts of E11-
14:0Ac ranging from 3—12%); in their study the number of trapped moths declined when
the relative amount of £11-14:O0Ac exceeded 12%. In a Quebec woodlot, Delisle (1992)
found that during the first annual flight of C. rosaceana traps baited with Z11-14:OAc plus
10% E11-14:OAc captured more C. rosaceana than traps baited with Z11-14:OAc plus
3% E11-14:OAc; these blends captured similar numbers of moths during the second flight
of the year. In Michigan apple orchards, traps baited with the main pheromone compound
plus 5% Z11-14:OH and 2% Z11-14:Ald captured more C. rosaceana when E11-14:O0Ac
was included at 4% compared to when this compound was included at | or 10%, whereas
in Oregon apple orchards, the addition of E11-14:OAc at 1% resulted in the capture of a
greater number of C. rosaceana than when this compound was added at 4 or 10% (Stelinski
et al. 2007).

There is also evidence of geographic variation in the behavioural activity of Z11-
14:OH when used as a component of synthetic pheromone for monitoring C. rosaceana. For
example, in New York apple orchards, Hill and Roelofs (1979) found statistically similar
increases of 1.5—2.2-fold in the capture of C. rosaceana when 0.5—5% Z11-14:0H was
added to a two compound blend of Z11-14:0Ac plus 3% £11-14:OAc. In Quebec, Delisle
(1992) found that the capture of C. rosaceana increased in traps baited with Z11-14:O0Ac
plus 2% E11-14:0Ac when Z11-14:0OH was added at 1.5% relative to Z11-14:O0Ac, and

10

Optimization of synthetic pheromone blend for C. rosaceana — JESO Volume 143, 2012

as well in traps baited with Z11-14:OAc plus 5.6 % E11-14:0Ac when Z11-14:0H was
added at 5.6% relative to Z11-14:OAc. In Michigan apple orchards, traps baited with the
main pheromone compound plus 4% E11-14:0Ac and 2% Z11-14:Ald captured similar
numbers of C. rosaceana when Z11-14:OH was included at 1, 4 and 10% relative to the
main compound (Stelinski et al. 2007). In Oregon apple orchards during the first annual
flight, the addition of Z11-14:OH to the three compound blend used in Michigan at 1%
and 4% resulted in similar trap catches of C. rosaceana, but trap catch was reduced when
the alcohol compound was included at 10% relative to the main compound; trap catch was
greatest using 1% Z11-14:OH during the second flight period in Oregon (Stelinski et al.
2007).

Geographic variation in the behavioural activity of 71 1-14:Ald has been previously
reported for C. rosaceana. The pheromone gland of populations from British Columbia,
Michigan, Ontario, Quebec, New York (El-Sayed et al. 2003) and from Oregon (Stelinski
et al. 2007) contained Z11-14:Ald, and the inclusion of this compound in traps baited with
Z\1-14:0Ac, E11-14:0Ac and Z11-14:0OH resulted in significant increases in the capture
of moths in all of these locations except Michigan (El-Sayed et al. 2003; Stelinski et al.
2007) and New York (El-Sayed et al. 2003). The addition of Z11-14:Ald to traps baited
with Z11-14:0Ac, E11-14:O0Ac and Z11-14:OH also significantly increased trap catch of
C. rosaceana in Minnesota apple orchards (Fadamiro 2004). The current study provides
additional information on geographic variation in the behavioural activity of Z11-14:Ald
in C. rosaceana. In Niagara apple orchards, there was no change in the number of moths
trapped when the relative amount of Z11-14:Ald was increased from | % to 2%, but trap
catch declined when the amount was increase to 4% during the first flight, and to 8% in the
second annual flight. In a previous trapping study in Niagara peninsula apple orchards, the
capture of C. rosaceana declined when the relative amount of Z11-14:Ald was increased
from 4 to 8% (El-Sayed et al. 2003). By contrast, in British Columbia apple orchards,
Vakenti et al. (1988) found no change in the number of C. rosaceana captured in traps baited
with Z11-14:O0Ac plus 2% E11-14:O0Ac and 1.5% Z11-14:0H when Z11-14:Ald was added
at 2, 4 and 8% relative to Z11:14:OAc. Similarly, in Oregon apple orchards, traps baited
with the main pheromone compound plus 4% £11-14:OAc and 5% Z11-14:OH captured
similar numbers of C. rosaceana when Z11-14:Ald was included at 4 and 10% (Stelinski et
al. 2007).

In addition to the relative amounts of minor compounds in synthetic pheromone,
pheromone dose and formulation can also affect the performance of a synthetic sex-
pheromone lure (Wall 1989). In the present study, rubber stoppers were loaded with 1
mg of pheromone but it is not known if this resulted in optimal attractiveness under the
conditions in which the effectiveness of different pheromone blends was compared. In
British Columbia, Vakenti et al. (1988) found that traps baited with lures loaded with 3 mg
of an optimally attractive blend captured 13x more C. rosaceana than traps baited with 0.3
mg of the same blend of compounds. The use of the optimally attractive pheromone load in
a lure could be important when monitoring small populations of C. rosaceana, and therefore
additional research should be carried out to determine the relationship between pheromone
load and trap catch for this pest in Niagara peninsula apple orchards.

The amount of pheromone loaded into a stopper could also affect its longevity.
In the present study the rubber stopper lures were renewed every two weeks during the

1]

Trimble JESO Volume 143, 2012

4-6 week flight period of C. rosaceana in to an attempt to compensate for a change in
their attractiveness due to the loss of pheromone, or to a change in the ratio of pheromone
compounds. Additional research should also be undertaken to determine the rate of decline
in attractiveness of lures to insure that reductions in trap catch are the result of declines in
population density and not lure attractiveness.

Sex-pheromone lures can be formulated using rubber, polyethylene or polyvinyl
chloride, and the material used to control the release of pheromone will also affect the
longevity of a lure (Wall 1989). In addition, the formulation material can also affect the
stability of pheromone compounds. For example, McDonough (1991) found that aldehyde
pheromone compounds were susceptible to oxidation when formulated on rubber substrates.
In British Columbia however, Vakenti et al. (1988) found that the addition of an antioxidant
compound to natural rubber lures loaded with Z11-14:OAc plus 2% E11-14:OAc, 1.5% Z11-
14:0H and 1% Z11-14:Ald had no effect on the number of C. rosaceana captured after 10
weeks of field use. This suggests that oxidation of Z11-12:Ald should not be a contributing
factor to a decline in lure attractiveness when C. rosaceana synthetic pheromone is loaded
into natural rubber sleeve stoppers.

Acknowledgements

I thank Donald Marshall, Iris Roman, Jocelyn Fedyczko and Natasha McDonald for
technical assistance.

References

Anonymous. 2009. Integrated Pest Management for Apples. Publication 310. Ontario
Ministry of Agriculture, Food and Rural Affairs.

Anonymous. 2010. Fruit Production Recommendations 2010-2011. Publication 360.
Ontario Ministry of Agriculture, Food and Rural Affairs.

Cardé, R. T., Cardé, A. M., Hill, A. S. and Roelofs, W. L. 1977. Sex pheromone specificity as
a reproductive isolating mechanism among the sibling species Archips argyrospilus
and A. ortuanus and other sympatric Tortricine moths (Lepidoptera: Tortricidae).
Journal of Chemical Ecology 3: 7\—84.

Chapman P. J. and Lienk, S. E. 1971. Tortricid Fauna of Apple in New York (Lepidoptera;
Tortricidae). New York State Agricultural Experiment Station, Geneva, NY.

Chew, V. 1976. Comparing treatment means: a compendium. HortScience 11: 348-357.

Dallal, G. E. 2001. The little handbook of statistical practice {online}. Available from: http://
www.jerrydallal.com/LHSP/HTM [accessed 12 October 2011].

Delisle, J. 1992. Monitoring the seasonal male flight activity of Choristoneura rosaceana
(Lepidoptera: Tortricidae) in eastern Canada using virgin females and several
different pheromone blends. Environmental Entomology 21: 1007-1012.

Optimization of synthetic pheromone blend for C. rosaceana — JESO Volume 143, 2012

El-Sayed, H .M., Fraser, H. M. and Trimble, R. M. 2001a. Chemical identification and
behavioral activity of (Z)-11-tetradecenal in an eastern North American population
of the obliquebanded leafroller. The Canadian Entomologist 133: 365-374.

El-Sayed, H. M., Fraser, H. M. and Trimble, R. M. 20015. Modification of the sex-
pheromone communication system associated with organophosphorus-insecticide
resistance in the obliquebanded leafroller (Lepidoptera: Tortricidae). The Canadian
Entomologist 133: 867-881.

El-Sayed, A. M. and Trimble, R. M. 2002. Pheromone content of azinphosmethy|-susceptible
and -resistant obliquebanded leafrollers (Lepidoptera: Tortricidae) as a function of
time of day and female age. The Canadian Entomologist 134: 331-341.

El-Sayed, A. M., Delisle, J., DeLury, N., Gut, L. J., Judd, G. J. R., Legrand, S., Reissig, W.
H., Roelofs, W. L., Unelius, C. R. and Trimble, R. M. 2003. Geographic variation
in pheromone chemistry, antennal electrophysiology and pheromone-mediated
trap catch of North American populations of the obliquebanded leafroller.
Environmental Entomology 32: 470-476.

Fadamiro, H. Y. 2004. Pest phenology and evaluation of traps and pheromone lures for
monitoring flight activity of obliquebanded leafroller (Lepidoptera: Tortricidae) in
Minnesota apple orchards. Journal of Economic Entomology 97: 530-538.

Hill, A. S. and Roelofs, W. L. 1979. Sex pheromone components of the obliquebanded
leafroller moth, Choristoneura rosaceana. Journal of Chemical Ecology 5: 3-11.

McDonough, L.M. 1991. Controlled release of insect sex pheromones from a natural rubber
substrate. Pp. 106—124 in P. A. Hedin (ed.), Naturally Occurring Pest Bioregulators,
American Chemical Society, Washington, D.C.

Roelofs, W. L. and Tette, J. P. 1970. Sex pheromone of the oblique-banded leafroller moth.
Nature 226: 1172.

SAS Institute. 2007. JMP® version 7. SAS Institute, Cary, NC.

Snedecor, G. W. and Cochran, W. G. 1989. Statistical Methods, 8" Edition. Blackwell,
Ames, Iowa.

Stelinski, L. L., McKenzie, D., Gut, L. J., Isaacs, L J. R. and Brunner, J. 2007. Comparison
of female attractiveness and male response among populations of Choristoneura
rosaceana (Harris) in western and eastern U.S. apple orchards. Environmental
Entomology 36: 1032-1039.

Thomson, D. R., Angerilli, N. P. D., Vincent, C. and Gaunce, A. P. 1991. Evidence for
regional differences in the response of obliquebanded leafroller (Lepidoptera:
Tortricidae) to sex pheromone blends. Environmental Entomology 20: 935-938.

Trimble, R. M. and Appleby, M. E. 2004. Comparison of efficacy of programs using
insecticide and insecticide plus mating disruption for controlling the obliquebanded
leafroller in apple (Lepidoptera: Tortricidae). Journal of Economic Entomology 97:
518-524.

Trimble, R. M. and El-Sayed, A. M. 2006. Effect of certain monounsaturated dodecene and
tetradecene acetates and alcohols on electroantennogram response and pheromone-
mediated trap catch of the obliquebanded leafroller, Choristoneura rosaceana
(Harris) (Lepidoptera: Tortricidae). The Canadian Entomologist 138: 218-227.

Trimble, R. M. and Marshall, D. B. 2008. Relative attractiveness of incomplete and complete
blends of synthetic pheromone to male obliquebanded leafroller (Lepidoptera:

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Tortricidae) moths in a flight tunnel and in apple orchards: implications for sex
pheromone-mediated mating disruption of this species. Environmental Entomology
37: 366-373.

Vakenti, J. M., Gaunce, A. P., Slessor, K. N., King, G. G. S., Allan, S. A., Madsen, H. F. and
Borden, J. H. 1988. Sex pheromone components of the oblique-banded leafroller,
Choristoneura rosaceana in the Okanagan Valley of British Columbia. Journal of
Chemical Ecology 14: 605-662.

Wall, C. 1989. Monitoring and spray timing. Pp. 39—66 in Jutsum, A. R. and Gordon, R. F.
S. (eds.), /nsect Pheromones in Plant Protection, John Wiley and Sons, London.

Weires, R. and Riedl, H. 1991. Other tortricids on pome and stone fruits. Pp. 413-434 in
van der Geest, L. P. S. and Evenhuis, H. H. (eds.), Zortricid Pests. Their Biology,
Natural Enemies and Control. Elsevier Science Publishing Company, New York,
NY.

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

REVISION OF OOCTONUS (HYMENOPTERA: MYMARIDAE) IN
THE NEARCTIC REGION

J.T. HUBER
Canadian Forest Service c/o AAFC,
960 Carling Ave., Ottawa, ON, Canada K1A 0C6
email: john.huber@agr.gc.ca

Abstract J. ent. Soc. Ont. 143: 15-105

The genus Ooctonus Haliday (Hymenoptera: Mymaridae) includes 14 species
in the Nearctic Region north of Mexico. The known species are redescribed
and five new species are described: O. arizonensis Huber, sp. n., O. boltei
Huber, sp. n., O. ongipetiolus Huber sp. n., O. readae Huber, sp. n., and O.
triapitsyni Huber, sp. n. One new synonym is proposed: O. auripes Whittaker,
syn. n., under O. vu/gatus Haliday. A key to females is given. Known hosts
in North America are Cercopoidea (one species of Aphrophora Germar and
one of Philaenus Stal) and, in the Old World, Cicadellidae (one species of
Nephotettix Matsumura and one of Cicadella Latreille).

Published December 2012

Introduction

Ooctonus Haliday (Hymenoptera: Mymaridae) is predominantly a Northern
Hemisphere genus. Twelve species are recorded in the Palaearctic Region and five in the
Oriental Region (Triapitsyn 2010). Burks (1979) catalogued eight species in the Nearctic
region. Triapitsyn (2010) synonymized two Nearctic names under European names
(americanus Girault under vulgatus Haliday, and auripes Whittaker under notatus Walker)
and recorded three other European species (hemipterus Haliday, insignis Haliday, and
sublaevis Foerster) in the Nearctic region, the latter two mistakenly, as discussed below.
Three native and one introduced species (O. vulgatus) are known from the Southern
Hemisphere (Huber et al. 2010).

The Nearctic species are revised here. They are classified into 14 species, 5 of them
new. Although no species have been described from south of the USA, a few specimens have
been collected from high elevations in Mexico and from Costa Rica, and will be treated
separately.

Huber JESO Volume 143, 2012

Materials and Methods

About 2040 specimens (about 1050 females and 990 males from Canada and
USA) and an additional 210 European specimens identified by Triapitsyn (2010) and
160 specimens identified by the author using the key in Triapitsyn (2010) were seen. The
specimens were borrowed from the following institutions (curators in parentheses), or if not
borrowed (some types) the depository is given without a curator name.

AEIC — American Entomological Institute, Gainesville, Florida (D. Wahl).

BMNH — Natural History Museum, London, UK (G. Broad).

CAS — California Academy of Sciences, San Francisco, California (R. Zuparko).

CFS-Great Lakes — Canadian Forest Service, Sault Ste. Marie, Ontario (1. Ochoa).

CFS-Pacific — Canadian Forest Service, Victoria, British Columbia (L. Humble).

CLEV — Cleveland Museum of Natural History, Cleveland, Ohio (T. Pucci).

CNC — Canadian National Collection of Insects, Ottawa, Ontario (A. Bennett).

ICCM — Carnegie Museum of Natural History, Insects and Spiders Section, Pittsburg,
Pennsylvania (J. Rawlins).

NMID — National Museum of Ireland, Dublin, Ireland.

NMPC ~— Bouéek collection, National Museum (Natural History), Prague, Czech Republic
(P. JanSta).

ROM — Royal Ontario Museum, Toronto, Ontario (C. Darling).

UCFC — University of Central Florida, Orlando, Florida (S. Fullerton).

UCRC — University of California, Riverside, California (S. Triapitsyn).

USNM ~— National Museum of Natural History, Washington, District of Columbia (M.

Gates).

Within America north of Mexico some species appear to be fairly uniform
throughout their range; others appear to be more variable, making it difficult to describe
them and find stable features to distinguish them from other species. A conservative view of
species is therefore used to avoid subdividing the genus into numerous ‘species’ that cannot
be defined meaningfully, as was unfortunately done by W. Soyka (1941) for the European
Ooctonus. Two or more species may be obtained from the same collecting event, so care
must be taken to examine all specimens from a locality in case the series is mixed.

Photographs were taken with a digital CCD camera attached to a compound
microscope, and the resulting layers combined electronically using Auto-Montage”™ and
retouched as needed with Adobe” Photoshop. Micrographs were taken with a scanning
electron microscope after gold coating specimens mounted on stubs with carbon tape or, on
occasion, from uncoated specimens on their card or point mounts.

Measurements are given in micrometers (um). Body length was measured from
the transverse trabecula to the gastral apex for critical point dried specimens; the remaining
measurements were from cleared and slide mounted specimens. Triapitsyn (2010) should
be consulted for most references to species described from Europe and reliably reported in
North America, 1.e., O. hemipterus, O. notatus, and O. vulgatus. A few references to these
species that he missed are given below; the numerous others are not duplicated here.

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Structures are labelled mostly on Figs. 6-10 and 193-199, and abbreviations
are explained Table 1. Terms are according to Gibson (1997), Krogmann and Vilhelmsen
(2006) for the body, Ronquist and Nordlander (1989) and Gibson (2004) for some wing
structures. Terms in Viggiani (1970; 1988), and Chiappini and Mazzoni (2000) are used for
male genitalia; the basal ring is absent in Mymaridae, so their labeling of it is incorrect.

Two structural characters not previously used in taxonomy of Mymaridae are named
here because they are useful to help to define genera or groups of genera within Mymaridae
though they may not help distinguish species within a given genus. Both characters are
internal and can only be observed in properly cleared and slide mounted specimens. The
first character occurs inside the compound eye, seen in lateral view. The eye is rimmed
internally by a narrow ocular ridge that becomes more or less widened anteriorly (Takaie
1999, fig. 5B) and often continues well into the eye as a long, slender ocular apophysis. In
Ooctonus species the apophyses are wide and blunt apically (Fig. 62). The second character,
named here the scutellar fenestra, is a lighter area of varying shape usually between and
posterior to the placoid sensilla on the anterior scutellum seen in dorsal view, but in many
genera it may occupy much of the anterior scutellum. In Ooctonus, the scutellar fenestra
(Fig. 140) is a triangle with rounded corners, a narrower apex anteriorly, and wider base
posteriorly at the level of the frenal line. Internally, it seems to be defined by a thinning on
the underside of the cuticle, hence the lighter colour compared to the surrounding cuticle.
The area of thinning partly lines up with the fenestra, a hole through the thin, transverse
internal septum across the scutellar-axillar complex present in some genera (Fig. 139, and
Krogmann and Vilhelmsen 2006, fig. 10D). A fan-shaped muscle (t,t,) that appears to
originate on the posterior ridge of the frenum (its origin is in the metasctellum) fans out
anteriorly past the apex of the fenestra. It lies along the inner surface of the frenum for its
entire length and can be seen from the outside though the cuticle (Fig. 140) or from the
inside (Fig. 139) against the inner surface of the frenum. The shape of the scutellar fenestra
differs somewhat among Ooctonus species.

Sixty-four Ooctonus specimens were submitted for barcoding to the Biodiversity
Institute, Guelph, Ontario. Specimens were removed from their cards, DNA was extracted
using non-destructive methods (Ivanova et al. 2006; Porco et al. 2010), and returned in
ethanol to the CNC where they were critical point dried for a second time and remounted
on pins with their tracking numbers and original locality labels, and their identities
corrected, where necessary. A 658-bp region near the 5’ terminus of the CO! gene was
amplified using standard primers (LepFl-LepR1). If the internal 658 bp amplification
was not successful composite sequences were generated using internal primers. Primer
information for individual sequences can be retrieved from the Barcode of Life System
(BOLD) (Ratnasingham and Hebert 2007). Collection data for all barcoded specimens are
in the Material examined sections. Successful barcodes and the corresponding Genbank
sequences are listed in Table 2.

Taxonomy

Ooctonus Haliday, 1833: 269, 343. Type species: O. insignis Haliday, designated by
Westwood 1839: 78.

Huber JESO Volume 143, 2012

Sphecomicrus Haliday in Walker, 1846: 50 (and errata). Type species: O. insignis Haliday,
designated by Peck, 1951: 410.

Ooctonus Haliday: Triapitsyn 2010: 11 (literature, diagnosis, classification, distribution,
hosts, keys to Palaearctic, European, and Oriental species); Huber et al., 2010: 222
(African species).

Diagnosis. Ooctfonus is distinguished from all other genera of Mymaridae by the combination
of tarsi 5-segmented, propodeum with diamond-shaped pattern of carinae (Figs. 7, 8, 97—
138), fore wing venation about one-third the wing length, and parastigma with hypochaeta
next to proximal macrochaeta (Fig. 10). Boudiennyia is the most similar genus, differing by
the propodeum with an H-shaped pattern of carinae and fore wing venation about half the
wing length.

Description. Female. Colour. Dark brown to black, usually with base of antenna, legs
and petiole yellow or brown. Sculpture. Head, mesoscutum, mesoscutellum, anterior
half of axilla, and sometimes metanotum, propodeum and petiole with fairly conspicuous,
usually engraved, reticulate microsculpture, the reticulations largest on the frenum. Head.
Face without subantennal sulci and without a small pit medially next to each torulus (Figs.
26-39). Antenna. Funicle 8-segmented; clava entire (Figs. 63-76), with 8 mps (7 in a
few extralimital species) (Fig. 76). Mesosoma. Pronotum (Fig. 7) entire, with transverse
carina posteriorly separating short, curved collar with strongly angular anterolateral corners
from anteriorly tapering neck; notauli complete, deep but thin; propleura broadly abutting
anteriorly (Fig. 197), thus separating prosternum from head [prosternum ‘closed’ |; prosternal
discrimen complete; prepectus strap-like, about as wide dorsally and ventrally (Figs. 6,
197); frenum more than half length of mesoscutellum and separated from mesoscutellum
by curved row of shallow fovea (Fig. 7); metanotum with distinct, usually smooth
metascutellum (Fig. 8); propodeum (Fig. 8) with plicae (sublateral carinae of Triapitsyn
2010) extending from posterior margin near outer margin of coxae almost to anterior margin
at about level of lateral margins of metascutellum, with submedian carinae arranged in a
rhomboid (diamond) shape, and usually with a short transverse carina (costula) extending
between submedian carina and plica (the median area of propodeum thus consists of five
large, usually complete, pentagonal areoles); anterior margin of propodeum often with a
short posteriorly-directed and strongly sclerotized spur almost opposite anterior apex of
plica; propodeal nucha short, separated anteriorly from pentagonal areoles by a transverse
carina; Legs. Tarsi 5-segmented. Metasoma. Petiole narrow, much longer than wide (Fig.
195), with posterior half divided by a ventrolongitudinal suture (as in Fig. 198); gaster
(Fig. 195) smooth except for slight reticulation around apex of petiole (at junction of gs, );
gt, the largest tergum, apparently 3-lobed in dorsal view, the two lateral lobes extending
posteriorly and, in lateral view (Fig. 195), with their strongly rounded margins covering
anterior sterna and part of gt,, especially ventrally; gt, with a tuft of 3 appressed, posteriorly
directed setae next to a deep pit at junction between median and lateral lobes and midway
between anterior and posterior margins of tergum; gt, almost as long as gt,; remaining terga
short; gt, with spiracle; gt, with cerci, in dorsal view, separated from each other by more
than a cercus width.

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Male. Similar to female except antenna, sometimes ocelli and shape of gaster (Fig.
196). Flagellum 11-segmented, each with several mps extending almost entire length of
segment. Ocelli usually slightly larger than in female, e.g., Figs. 46 vs 47 and Figs. 54 vs
55. Metasoma without spiracle. Gaster with gs, the longest segment (Fig. 199), but it and
following sterna often hidden by terga (Fig. 198). Genitalia (Figs. 178-186, 191-194) usually
at least half length of gaster, with a long, tubular phallobase, aedeagal apodemes apparently
not articulated but continuous with base of aedeagus, digiti with 3 teeth and‘parameres’
slender and fairly long.

Males usually have darker legs than females. This is most noticeable in species with
uniformly yellow legs in females. In one species, O. hemipterus, male fore wing shape is
different from wing shape in macropterous females (micropterous males are not known).

Species characters. The species within almost any genus of Mymaridae are often
very similar, difficult to characterize and distinguish from one another. Usually, several
qualitative features and quantitative features (measurements, ratios, numbers of sensilla,
structural features) taken together are needed to distinguish a species. In Ooctonus, the most
important feature for all species is the pattern of propodeal carinae, and mps distribution
on and proportions of female flagellar segments. Other qualitative characters that help
define some species are: leg, antenna, and petiole colour, relative size of compound eye,
ocellar diameter relative to LOL, presence of a stemmaticum (Fig. 43—white lines in
cleared specimens from mid to lateral ocelli), mesosomal seta length, and wing shape.
Microsculpture, of the mesonotal midlobe in particular, varies subtly among species and, if
present (occasionally it is absent medially on frenum) is best described using two features:
the mesh surrounding each cell, its shape and whether it is above or below the cell, and the
cell itself (sculpticell, Goulet 1996: 23) (whether it is higher or lower relative to the mesh).
It is best seen in scanning electon micrographs (Figs. 100-102, 106—108, 112—114, 118-120
123-138). Other characters that are sometimes useful are fore and hind wing proportions,
presence or absence of a hair line/wing fold, fore wing marginal vein length, female gaster
shape, and ovipositor/metatibia ratio.

Males are difficult or impossible to identify to species (as is usual for Mymaridae)
unless they can be clearly associated with the corresponding females. Male antennae vary
in length, with length/width of fl, varying from 2.85—5.03 and total flagellum length varying
from 918—2027, depending on the specimen and the species. Because male antennal length
and flagellomere proportions can vary considerably within a species and there is often
substantial overlap in these measurements they are often not useful for species identification.
Flagellomere shape may sometimes be useful, varying from evenly cylindrical to slightly
swollen basally. Overall length of the genitalia, shape and length/width proportions of the
phallobase, and length of aedeagal apodemes compared to the aedeagus vary among the
species.

Type material. Whittaker (1931) described four species of Ooctonus. In his brief
introduction he stated that a paratype of each species was placed in the USNM but gave no
other depositories for the remaining specimens. They were found in the BMNH. He also
did not specifically state under each species description that one specimen was the holotype.
A red label with “paratype” typed on it is pinned under each specimen in the USNM and a

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Huber JESO Volume 143, 2012

second red paratype label with a USNM number was later added. A red label with “type”
written in black ink on it is pinned under one specimen of each of the Whittaker species
in BMNH and a lectotype label (white circle with purple border) is the top label on one
specimen of each of them but this was clearly added later and the lectotype designation
was not published. Despite the red ‘type’ or ‘paratype’ labels on the specimens, | formally
designate below the specimens bearing lectotype labels in the BMNH as lectotypes because
no holotypes were specified in the original descriptions.

Biology. The few host records available indicate that Ooctonus species parasitize eggs
of Cercopoidea and, less often, Cicadellidae. Members of both host families cause direct
feeding damage and may also transmit plant pathogens (Hamilton 1982; Nault 1989; Dupo
and Barrion 2009). Triapitsyn (2010) summarized the few host records for the Palaearctic
region—O. orientalis Doutt parasitizes Nephotettix cincticeps (Uhler) (cited in Doutt 1961)
and Cicadella viridis L. (Doutt 1961) (Cicadellidae). An unidentified species, questionably
of Ooctonus, parasitizes Nephotettix virescens (Distant) on rice (Dupo and Barrion 2009).
The only previously published hosts for Ooctonus in North America are O. aphrophorae
Milliron on Aphrophora saratogensis (Fitch) (Milliron 1947) and O. vulgatus (as O.
americanus) on Philaenus spumarius (L.) (Weaver and King 1954). The white pine weevil,
Pissodes strobi Peck (Curculionidae), is recorded below as a host of O. quadricarinatus.
This record is doubtful and needs confirmation before it can be accepted as reliable.

Key to Nearctic Ooctonus species in America North of Mexico. Females.

l Micropterous or brachypterous, the wings not extending beyond apex of gaster
(Fig. 1) and venation length at least half wing length (Figs. 147, 148)..............
1iten vadon hd eb eda asst SOREL REL RRR I IIE hemipterus Haliday (part)

- Macropterous, the wings extending well beyond gastral apex (Figs. 2-5) and
venation length much less than half wing length (Figs. 141-146, 149—158)...2

2(1) Ovipositor at least 1.7 as long as metatibia and exserted considerably beyond
apex of gaster (Figs. 3, 159, 187, 189); legs black or dark brown, coxae almost
Same colour aS mnesosomia (Hig. pS) ieee etter cttee eee eee eee 3
— Ovipositor at most 1.4* as long as metatibia and at most only slightly exserted
beyond apex of gaster (e.g., Figs. 2, 160); legs yellow or brown, coxae usually
different in colour from mesosoma, yellow or light brown (Figs. 1, 2, 4, 5) but
sometimes '(O’ fuscipes)| dark: Brows: Merits eeseeeeea einen eens 4

3(2) Gaster unusual in shape (Figs. 159, 187), in lateral view with dorsal margin
of gt, concave posteriorly and gaster projecting anteriorly under mesosoma;
petiole attached about 0.25* gaster length from anterior apex of gaster; funicle
withoutimps on flyomile(Mige6S)s vein santos econo aphrophorae Milliron

~ Gaster normal in shape (Figs. 160-177, 188-190), in lateral view with dorsal
margin of gt, more or less straight; petiole attached almost at anterior apex of
gaster; funicle with | (rarely 0) mps on fl, and | on fl, (Fig. 72)...
Lk Ae, AE ene Ae, SOREN, SAA, BATE ENR, ORT Sa: quadricarinatus Girault

Revision of the genus Oocfonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

S(4)

6(5)

7(6)

8(4)

Vertex with stemmaticum [on cleared specimens seen as white lines extending
from supraorbital trabecula along eye margin to mid ocellus and from mid
ocellus to lateral ocelli (Figs. 41, 43, 45); on dry specimens seen as lines or
slightiyrarsedmnidges (EVs: S2YS 3556) NA. ei tk Piaierectccsncittscatsssossssonscsetoased
Vertex without stemmaticum (Figs. 40, 42, 44, 54, 55, 57-61)... eee 8

Mesosoma laterally and propodeum between major carinae entirely covered
with reticulate sculpture (Figs. 105, 108, 130); fore wing apex rounded and
with distinct brown basal band (Fig. 146)................ hemipterus Haliday (part)
Mesosoma laterally and propodeum between major carinae entirely smooth
(Figs. 90, 91, 93, 94, 96, 126-129, 131-138); fore wing apex truncate and
without brown band (Figs. 141—145, 1S0—158)........ ce ccceecccteesecsecceeesonccceeeens 6

Propodeal spur absent (Figs. 111, 114, 133) [also absent in hemipterus, Figs.
92, 105, 108, 130]; mesoscutum without median longitudinal groove (Fig.
AIAN) El eww. © us GrenaigISM( ei eee Aly) saecemenetae cnet cna cen-coreckreesec aces nese ones oc? occidentalis
Propodeal spur present (Figs. 125-129, 131, 132, 134-136); mesoscutum with
median longitudinal groove (Figs. 103, 106, 109, 112); fl, with at least 1 mps
CEI SAGGNOD) OS AES RIOR IE, SIAMESE SIAL, cccabecececndoctce 7

Petiole shorter than combined lengths of metacoxa and metatrochanter (Fig.
162); clava short, at most 0.18* funicle length; entire funicle longer, e.g.,
length/width ratio of fl, at least about 5.8 (Fig. 66).......... canadensis Whittaker
Petiole longer than combined lengths of metacoxa and metatrochanter (Fig.
165); clava longer, at least 0.26* funicle length; entire funicle shorter, e.g.,
length/width ratio of fl, at most about 3.8 (Fig. 69)........cccccccceeseeeseseseseseseees

Frenum smooth medially (Figs. 116, 117, 119, 120, 122, 124), rarely reticulate

OMLYeilipPOSteLl Or third SEAR Hea Ie Eee SS a ek 3)
Frenum entirely reticulate (Figs. 97-115, 118, 121, 123), sometimes only
ative SO teete neta tA hes Nea, PSR Oe Maha A hoc doa Heed dasa 11
Pimandsiswathoutsnpss(Pigsarasi6) wic0e. 22a Ss 10

Fl. with 1 mps and fl, with | (rarely without) mps (Fig. 73).........cccccceeeeseeee
Ui: EOI ES ed Ee APN OAS LIU Ns ce ati let. readae Huber, sp. n.

Propodeum without a median carina, the pentagonal areole joined to anterior
margin of propodeum by converging dorsolateral carinae (Figs. 122, 124, 138);
marginal + stigmal vein short (Fig. 158); funicle with fl—fl, relatively long,
e.g., fl, length/width at least about 2.7 (Fig. 76); ocelli small (16 wm), LOL
about 4.0x mid ocellar diameter (Fig. 61)............c:cccssceeseeees vulgatus Haliday
Propodeum with a short median carina, the pentagonal areole thus separated
from anterior margin of propodeum (Figs. 117, 120, 136); marginal + stigmal

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Huber JESO Volume 143, 2012

vein longer (Fig. 156); funicle with fl, — fl, relatively short, e.g., fl, length/
width at most 2.3 (Fig. 74); ocelli larger (24 um), LOL about 2.0 mid ocellar

diameter (Big. 59) s.r ee ee es silvensis Girault
11(8) Fl. without mps (Fig. 67), rarely with 1 mps on one antenna................::0ccee
sav Raa ROR HG RR SBT: as na ge ered As Jfuscipes Whittaker
~ Flawithel<or 2ampsiom bothiantenmacstatats...te.. 0:5 ievescceeee- cee 12
12(11) Propodeum without a median carina, the pentagonal areole joined to anterior

margin by converging dorsolateral carinae (Figs. 110, 113, 132); fl, without
mps (Fig. 70); smaller species, with body at most 930 um long and fore wing
length atdnost,9S0) pin longusei eee eee ee notatus Walker
- Propodeum with a median carina, the pentagonal areole distinctly separated
from anterior margin; fl, with at least | mps, rarely without; larger species, with
body at least 1075 um long and fore wing length at least 1100 um long........ 13

13(12) Ovipositor shorter, at most 0.80* metatibia length.............. boltei Huber, sp. n.
~ Ovipositor longer; at least'0:97>metatibia length: 322.. 222s eee eee ee 14

14(13) Legs uniformly yellow; apical funicle segments shorter and wider, e.g., fl,, fl,,
fl, length/width ratios at most 2.19, 2.07, and 1.81, respectively; body slightly
shorter,atanostdl 330, uma aes eee triapitsyni Huber, sp. n.

- Legs mainly brown; apical funicle segments longer and narrower, e.g., fl,, fl, fl,
length/width ratios at least 2.40, 2.33, 1.99, respectively; body slightly longer,
at least.1350 pumyncs rhe eae Se ees dees arizonensis Huber, sp. n.

Ooctonus aphrophorae Milliron
(Figs: 26; 46,4763, 77489; 97, 100,125, 141,159) 7 S87)

Ooctonus aphrophorae Milliron, 1947: 219; Peck, 1951: 410 (catalogue); Ewan, 1961:
43 (host); Peck, 1963: 18 (catalogue); Herting, 1972: 10 (host); Wilson, 1978: 3
(percent parasitism); Burks, 1979: 1027 (catalogue, Ohio record).

Type material. Holotype 2 in USNM (examined), on triangular card point labelled 1.
“USA: Wisc. Lakewood, 18 Sept. ‘46”. 2. “Ex egg of Aphrophora saratogensis (Fitch)”. 3.
“Ooctonus 9 aphrophorae Milliron ’46 Holotype”. 3. “Type No. 58267 U.S.N.M.”.

Paratypes. 759, 42¢ (USNM, examined). USA. Wisconsin. Oconto Co.:
Lakewood, 18, 20, 21 and 26 ix.1946, ex Aphrophora saratogensis. The paratype numbers
are lower than reported by Milliron (1947) because several card triangles examined no
longer had specimens on them.

Diagnosis. Ooctonus aphrophorae is distinguished from other Nearctic species by the
unusual gaster that projects anteriorly under the mesosoma and is very narrow anteriorly
(Fig. 159), with the petiole attached quite far from the anterior apex of the gaster and the
dorsal surface of gt, concave posteriorly (Fig. 187).

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

In colour O. aphrophorae is most similar to O. quadricarinatus (both have black
coxae) but the body is smaller, antennal segments are shorter and without mps on fl,
and fl, (Fig. 63) (O. quadricarinatus with mps on fl, and f1,), and the metascutellum and
anterolateral areole have some reticulate sculpture (Fig. 125) (O. quadricarinatus without
sculpture).

Description. Female. Body length 1152-1357 (critical point dried, Constance Bay, Ontario,
n=5) or 1126-1280 (air dried, Lakewood, Wisconsin, n=5), all in natural position. Head
and mesosoma black, metasoma dark brown; antenna brown except sometimes radicle and
pedicel laterally, and sometimes flagellum light brown; legs brown, except base and apex
of tibiae, and tarsomeres 1—4 yellowish. Head. Head (Fig. 26) width (n=4) 323-334. Vertex
without stemmaticum (Fig. 46). Mid ocellus diameter 26-29. Antenna. Flagellum (Fig.
63) with 2 mps on fl,, 2 on fl,, and 7 on clava. Fl, usually slightly the longest funicle
segment. Fl —fl, loner hay dath alles (n=5): fl, 2.86— 3% DSeeiil 233.353.0241 1235-3. 3 1) fl
2.29-3.03, fl 2 '06- 2.78, fl, 1.69—2.29; clava 3. 62-4.10* as long as wide, and almost as
long as fl. fl, together. Measurements (length/width, n=5): scape 199—231/39-44, pedicel
68-71/33- a6) ft S6[69/19 215 wee 5 0=60/20=25; Ties5—72/22—24,) 5 1=66/21—24; fi,
54-67/24-27, fl, 47-59/25—28, fi, -59-67/3 1-34, fi 58 64/34-37, ean 178—216/48— 54.
Total flagellum length 608-749. Mesasome! Sion (Figs. 97, 100) with collar wide,
moderately long and clearly visible in dorsal view, with well defined carina. Mesonotum
(Fig. 97, 100-male) wide; midlobe of mesoscutum with meshes engraved; scutellar seta long,
extending posterior to straight or medially slightly concave frenal line; frenum about 0.75
mesoscutellum length and entirely reticulate, with a few short carinae extending posteriorly
from anterior margin. Metanotum with metascutellum long, with several irregular and
incomplete carinae extending towards each other from anterior and posterior margins, and
lateral lobes smooth except for about 2 longitudinal carinae (Fig. 89-male). Propodeum
(Figs. 97, 100-male, 125) smooth between carinae, except anterolateral areole with some
reticulate sculpture, and anterior margin of propodeum with a stub slightly lateral to lateral
margin of metascutellum; median areole separated from metascutellum by at most a very
short median carina (appearing double in slide mounts); plica almost straight, its anterior
apex in line with apex of stub, with medial branch of anterior bifurcation extending almost
to anterior margin of propodeum and lateral branch short and curved. Wings. Fore wing
(Fig. 141) length 1207-1323, width 463-534, length/width 2.48—2.70, longest marginal
setae 56—92, about 0.15 as long as greatest wing width (n=6). Hind wing (Fig.141) length
(n=5) 969-1046, width 60—75, longest marginal setae 90-115. Metasoma. Petiole shorter
than metacoxa + macrotrochanter. Gaster (Fig. 159) with ovipositor length 977—1237 (n=6),
1.99-2.44~ as long as metatibia length (480-528) and distinctly projecting beyond gastral
apex (Figs. 159, 187).

Male. Body length. 1178—1306 (n=10). Antenna (Fig. 77). Measurements, length
(n=2): scape 158-164, pedicel 56-66, fi, 116-129, fl, 135-137, fi, 129-131, fl, 129-130,
eal ih 29-13 0s 127130, 125129. fi, 25107 AIO 55 fl, 124-138.
Beseadenm ae 100) as in female. Tol qeecien length 1386-1436. Fl leneihi a taih
3.38-3.52, with about 9 mps. Mid ocellus (Fig. 47) diameter 29-36. Gasier (Gig w91):
Genitalia fairly wide (dorsal view) for most of length (Figs. 178, 191).

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Huber JESO Volume 143, 2012

Hosts and Habitat. The host is Aphrophora saratogensis (Fitch). Specimens were obtained
by rearing host eggs and sweeping Jack pine; one male emerged from old host eggs in
dead red maple twigs (Milliron 1947). The species is solitary—only one wasp emerges
from a host egg. The rearing record from Rhyacionia (as Evetria) buoliana |(Denis and
Schiffermiiller)] (Tortricidae) is almost certainly incorrect, as are any of the very few
records of Mymaridae from Lepidoptera. However, it possibly represents an opportunistic
and evidently successful parasitism of an unusual host egg in the same microhabitat (pine
shoots) in which the normal host would be found.

Material examined. 449 and 32 in addition to type material. CANADA. Ontario.
Constance Bay [near Ottawa], 12-19.x.1973, G. Gibson, YPT (19°, CNC), 21 .viil-7.1x.1983,
M. Sanborne (2, 1, CNC). Quebee. Luskville falls [near Gatineau], 300m, 17-22.ix.1986,
J. Denis, L. Dumouchel, YPT (19, CNC). USA. New York. Nassau Co.: Nassau Boulevard,
18.ix.1915, L.C. Griffith, ex Evetria buoliana (12, 143, USNM). Wisconsin. Oconto Co.:
Lakewood, 5, 9, 13, 17, 18, 20, 22, and 23.ix.1946 ex A. saratogensis eggs (199, 14¢,
USNM), 11, 12, 13, 14, 15, 18, 19, 20, and 21.ix.1946, sweeping Jack pine (199, 156,
USNM), ex egg of A. saratogensis coll. 5.ix and emerged 7.ix.1946 (14, USNM), ex eggs
of A. saratogensis coll. 18.ix and emerged 25.ix.1946 (3 empty eggs, 1% still stuck to an
egg, USNM).

Ooctonus arizonensis Huber, sp. n.
(Figs. 19, 27, 40, 48, 64, 78, 90, 98, 101, 126, 142, 160)

Type material. Holotype ° in CNC, on slide (Fig. 19) labelled 1. “USA: AZ, Cochise Co.
Chiricahua Mts. Rustler Park, 6000’, 15.vil.1982, G. Gibson”. 2. “Ooctonus arizonensis
Huber Holotype © dorsal”.

Paratypes. 12 and 49¢. USA. Arizona. Cochise Co.: same data as holotype
(14, CNC); Chiricahua Mountains, Barfoot Park, ca. 8600’, 26.viii.1982, J. LaSalle (12,
CNC), Rustler Park, 8200’, 26.viii.1982, J. LaSalle, sweeping (22, 13, CNC), 8300’,
23.vili, 21.ix.1987, H. & M. Townes (19, 3¢, AEIC); Carr Canyon, summit camp, 8000’,
18.viii.1993, M. Sharkey (12, 14, CNC); Huachuca Mountains, Miller Canyon, 1600m,
11.viil.1982, G. Gibson (29, CNC); Portal, 5000’, 19.x.1978, L. Masner, C. Yoshimoto
(12, CNC); Portal, 2, 4, 6, 18, 21.ix.1987, H.K. Townes (12, 114, AEIC); Portal, Southern
Research Station, 11.1x.1978, G. Gordh (1 2, UCRC); 12 mi. S. Sierra Vista, Ramsey Canyon,
1700m, 17.v, 6-13.vii CNCHYMO07510 [barcode failed], 24.vii, 4-22.1x CNCHYMO07511,
27.ix, 11.x, 26.xi-5.xii.1986, B.V. Brown, oak/juniper, MT (19, 294, AEIC, CNC). Pima
Co.: Santa Catalina Mountains, Molino Basin, 4200 and 4300’, 2-4.vilit.1982, G. Gibson
(QOz2SGxCNE):

Derivation of specific epithet. The species is named after the state in which all the
specimens were collected.

Diagnosis. Ooctonus arizonensis is distinguished from other Nearctic species by the

combination of body length greater than about 1350 tm, brown legs, and usually | mps on
fl_and fl, (Fig. 64) and ovipositor at most scarcely exserted.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Ooctonus arizonensis is similar O. quadricarinatus in size but the latter has a
distinctly exserted ovipositor. O. arizonensis is most similar to O. fuscipes but the latter
lacks mps on fl, and fl,. Barcoding suggest that the latter two are closely related. Because
of differences in number of mps on fl, and fl, and different ranges (Arizona mountains vs
Pacific coast forests) I treat them as separate species.

Description. Female. Body length 1357-1510 (n=5). Head and mesosoma very dark
brown, metasoma brown; scape and pedicel yellowish to light brown laterally, remainder
of flagellum dark brown; petiole and legs, light brown. Head. Head (Fig. 27) width (n=4)
347-372. Vertex without stemmaticum (Fig. 40, 48-male). Mid ocellus diameter 25-31.
Antenna. Flagellum (Fig. 64) with | (exceptionally 2) mps on fl,, | or 0 mps on fl,, 2 mps
on fi, and fl,,and 7 mps on clava. FI, slightly the longest funicle segment. Fl —fl, ‘length/
orn ratios: fi, 2. 95=3- 39 MT 2ST 3.02, fl, 2.56—2.83, fl, 2.40—2.67, fi, 238% 2.47, and
He L99—2 23; clave 3.07-3.91* as long as wide, and sieht longer than fl fl, together.
Measurements, length/width (n=5): scape 239-255/38-45, pedicel 69— 758 39, fh 162—
20-23 Al63=70/225 245" i 63=71/24=26» fy S7—63/23—25, fi 64—72/27-30; fl, 53-
62/26-29, fl, 65—75/29-35, fl, @u 68/3240, ena 205—230/56— 6% Total flagellum feneti
695-780. Mesisontal Brotiotnn (Figs. 98, 101) with collar wide, moderately long and
clearly visible in dorsal view, with well defined carina. Mesonotum (Figs. 98, 101) wide;
midlobe of mesoscutum with meshes engraved; scutellar seta short, extending to medially
slightly curved frenal line; frenum 0.62—72* mesoscutellum length and entirely reticulate.
Metanotum with metascutellum smooth. Propodeum (Fig. 126) smooth between carinae
and its anterior margin with stub, the latter just lateral to lateral margin of metascutellum;
median areole separated from metascutellum by median carina; plica curved, extending
almost to anterior margin of propodeum just medial to stub, without an anterior bifurcation
but with a slight curved thickening posterior to the stub. Wings. Fore wing (Fig. 142) length
1457-1568, width 513-553, length/width 2.83—2.95, longest marginal setae 84—99, about
0.17x as long as greatest wing width (n=5). Marginal vein length about 173. Hind wing
(Fig. 142) length 1138-1264, width 61—76, longest marginal setae 128-141. Metasoma.
Petiole shorter than metacoxa + mesotrochanter. Gaster (Fig. 160) with ovipositor length
546-569 (n=5), 0.97—1.18* as long as metatibia (507-561).

Male. Body length 1331—1587 (n=10). Legs darker than in female. Antenna (Fig.
78). Measurements, length (n=5): scape 185-220, pedicel 64—73, fl, 105-134, fl, 115-141,
Me WNO=1355 0107-135, fo 110-114, fl) 106=132, fly 105=134) fy 102- 128s 105127 fit,
95. PANS i 94 126. Total flagellar iene 1163= 1446. BI leneth/widiha: 1] 25) 89, with 7 or
8 mps. Bye small (Fig. 90). Mid ocellus (Fig. 48) diameten 28-30.

Barcoding. Five specimens were submitted for barcoding, all of them males,
and one (CNCHYMO07511) yielded a barcode. Because males are usually unidentifiable
it is difficult to be sure what species they represented prior to barcoding but the only two
possibilities based on locality data are O. arizonensis (CNCHYMO07511) and O. triapitsyni.
Based on their larger size, two of the specimens (CNCHYM07510 and CNCHYMO07511)
are O. arizonensis and have the same data as some females of that species. The remaining
three specimens are listed under O. triapitsvni. CNCHYMO07511 is almost identical to that
of O. fuscipes specimens (1 base pair difference), suggesting that O. arizonensis and O.

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Huber _ JESO Volume 143, 2012

fuscipes are the same species. They are kept separate because of slight differences in the
proportions of fl, and fl,, different distribution of mps (mps present on fl, and usually fl, in
arizonensis, absent in fuscipes), and different geographic ranges.

Hosts and habitat. Hosts are unknown. Specimens have been collected in an oak/juniper
habitat.

Ooctonus boltei Huber, sp. n.
(Figs. 20, 28, 49, 65, 99, 102, 127, 143, 161)

Type material. Holotype Y in CNC, on slide (Fig. 20) labelled 1. “Canada: MB, Riding
Mt. Nat. Park, 3 km E. Clear Lake, 29. VIII.1979 S.J. Miller, pitfall trap, beaver meadow”.
2. “Ooctonus boltei Huber Y dorsal”.

Paratypes. 89 and 3¢. CANADA. Manitoba. Same data as_ holotype,
CNCHYM07481 [barcode failed] (22, CNC); Aweme, Criddle Homestead, 49°42'34’"N
99°34'58"W, 24.vii1.2007, H. Goulet, mixed grass prairie, CNCH YM07479 [barcode failed]
(14, CNC); Riding Mountain National Park, 1 km E. Clear Lake, 16.viii.1979, S.J. Miller,
small meadow, Malaise trap (12, CNC), near refuse pit, 29.vii.1979, S.J. Miller, aspen
stand, pan trap, CNCHYM07483 [barcode failed] (12, 14, CNC), Wishing Well road,
20.viii.1979, D.B. Lyons, CNCHYM07482 [barcode failed) (22, 1¢, CNC); 0.1 km N.
Onanole, 29.viii.1979, S.J. Miller, field-forest edge (19, CNC). New Brunswick. Fundy
National Park, Wolfe Point campground, 27.vili.1984, M. Kaulbars (192, CNC).

Derivation of specific epithet. The species is named after Klaus Bolte, an outstanding
technician at the CNC for almost four decades, who worked for the author from 1988 until
his retirement.

Diagnosis. Ooctonus boltei is distinguished from other Nearctic species by the combination
of fl, without mps (exceptionally one antenna with 1 mps), uniform yellow legs, entirely
reticulate mesoscutellum, ovipositor at most 0.78% as long as metatibia, and body length at
least 1300um.

Ooctonus boltei is similar to O. triapitsyni, which also has uniform yellow legs, but differs
by the absence of mps on fl. (mps present in O. triapitsyni) and ovipositor shorter than
metatibia (longer than metatibia in O. triapitsyni). It is also similar to O. notatus but has the
ovipositor shorter than metatibia (longer in O. notatus).

Description. Female. Body length 1331—1434 (n=5). Head and mesosoma dark brown,
metasoma brown; fl,—fl, light brown to brown, remainder of flagellum dark brown; petiole,
legs, scape and pedicel uniformly yellow, though sometimes scape and pedicel light brown
and fl —fl, honey yellow. Head. Head (Fig. 28) width (n=3) 375-390. Vertex without
stemmaticum. Mid ocellus diameter 26 (Fig. 49). Antenna. Flagellum (Fig. 65) with 1|
(exceptionally 2) mps on fl., | or 0 mps on fl,, 2 mps on fl, and fl,, and 7 mps on clava. FI,
slightly the longest funicle segment. FI fl, length/width ratios: fl, 3.61—3.98, fl, 2.85—3.55,
fl, 2.69-3.09, fl, 2.43—2.88, fl, 2.44-2.97, fl, 2.27-2.55; clava 3.96 4.38% as long as wide
and shorter than fifi, together. Measurements (length/width, n=3): scape 240-270/41-42,
pedicel 68—73/34—39, fl, 7683/21, fl, 65-83/22—23, fl, 69-79/26, fl, 59-70/24—26, fl, 66—

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

74/25-27, fl, 59-66/24-27, fl, 72—78/30—36, fl, 68—75/32-39, clava 238-249/54-63. Total
flagellum length 772-857. Mesosoma. Pronotum (Figs. 99, 102) with collar moderately
wide, long and clearly visible in dorsal view, with well defined carina. Mesonotum (Figs. 99,
102) wide; midlobe of mesoscutum with meshes raised; scutellar seta fairly short, extending
to almost straight frenal line; frenum 0.64—0.69* mesoscutellum length and entirely
reticulate. Metanotum with metascutellum smooth. Propodeum (Fig. 127) smooth between
carinae and its anterior margin with a stub just lateral to lateral margin of metascutellum;
median areole separated from metascutellum by short median carina; plica almost straight,
extending almost to anterior margin, not bifurcate anteriorly. Wings. Fore wing (Fig. 143-
male) length 1433-1515, width 494-505, length/width 2.90-3.00, longest marginal setae
66-72, about 0.14 as long as greatest wing width (n=3). Marginal vein length 168—180.
Hind wing (Fig. 143-male) length 1102-1160, width 58-59, longest marginal setae 104—
135. Metasoma. Petiole shorter than metacoxa + mesotrochanter. Gaster (Fig. 161) with
ovipositor length 43 1-476 (n=3), 0.74—0.78* as long as metatibia (560-611).

Male. Body length 1357 (n=1). Colour as in female except pedicel dorsally and
entire flagellum brown. Antennal measurements, length (n=1) scape 213, pedicel 71, fl,
i675 13758; 129,134) fl 13, A 128, fi 131, fi, 126515125, fl, 113; fl, ca 107. Total
flagellar length 1387. Fl, length/width 3.64, with about 6 mps. Mid ocellus diameter 30.

Hosts and habitat. Hosts are unknown. Specimens have been collected in a small meadow,
aspen stand, and field/forest edge.

Barcoding. Four specimens (CNCHYM07479, CNCHYM07481, CNCHYM07482, and
CNCHYM07483) were submitted but no barcodes were obtained.

Ooctonus canadensis Whittaker
(Figs. 12, 29, 41, 50, 66, 79, 103, 106, 128, 144, 162, 183)

Ooctonus canadensis Whittaker, 1931: 190; Peck, 1951: 410 (catalogue); Peck, 1963: 18
(catalogue); Burks, 1979: 1027 (catalogue).

Ooctonus sublaevis Foerster: Triapitsyn, 2010: 47 (misidentification). The male specimen
from Alaska, listed below, bears a 2009 identification label by Triapitsyn reading
“Ooctonus sp. insignis-type” but was incorrectly published as O. sublaevis.

Type material. Lectotype 2 in BMNH (examined), here designated to avoid ambiguity
about the status of the type specimens of this species, on card (Fig. 12) labelled 1.” Lectotype
[purple edged circle]”. 2. “Type [red rectangular label]”. 3. “Holyburn, B.C. 7.1X.30 Coll.
O.W.”. 4. Canada: O. Whittaker Coll. per W.H. Storey. B.M. 1947 - 212.”. 5. Ooctonus
canadensis Whitt. 2 Det. O. Whittaker’. 6. “B.M. Type Hym. 5.2320”. The lectotype is
mounted dorsal side up on a card with wings, legs, and antennae (dorsal view) spread out.
Paralectotype. One 9 in USNM (examined), mounted in same way as lectotype and
labelled 1. “Paratype”. 2. “Paratype No. 43551 U.S.N.M.” 3. “Hollyburn, B.C. 31.VIII.30
Coll. O.W.”. 4. “Ooctonus canadensis Whitt. 2 Det. O. Whittaker”.
Diagnosis. Ooctonus canadensis females are distinguished from other Nearctic species by

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Huber JESO Volume 143, 2012

the combination of vertex with stemmaticum (Figs. 41, 50), relatively short clava (Fig. 66),
midlobe of mesoscutum with long median groove, and propodeum with plicae straight but
diverging and bifurcating anteriorly, with the medial arm long, curved and almost touching
anterior margin of propodeum and the lateral arm almost straight and extending as far as
level of spiracle (Figs. 103, 106, 128).

Ooctonus canadensis is most similar to O. /ongipetiolus, sp. n., which has most of
the above features but in O. canadensis the plica diverge more (less in O. longipetiolus), the
petiole is not much longer than the metacoxa (distinctly longer in O. /ongipetiolus), and the
ovipositor is as long as the metatibia (0.7* as long in O. longipetiolus).

Description. Female. Body length 1382—1664 (n=5). Head and mesosoma dark brown,
metasoma and flagellum brown; scape, pedicel, and legs except metacoxa dark yellow,
metacoxa brownish yellow. Head. Head (Fig. 29) width 351-356 (n=2). Vertex (Fig. 41-
male, 50-male) with stemmaticum. Mid ocellus diameter about 45. Antenna. Flagellum
(Fig. 66) with 2 mps on fl,—fl, (one specimen with only | mps on fl, of one antenna) and 7
mps on clava. FI, the jenees! fanicle segment. Fl —fl, length/width cree fl, 4.86-5.60, fl,
Seid 6192 tik 5.04-5.98, fl, 4.07-4.82, fi, 2.76— 3211 fl, 2.76-3.42; clava 3. 17-4 93> alone
as wide, slightly longer than fl, and fl _together. Measurements (length/width, n=2): scape
241—254/42-50, pedicel 71/39_Al, fi) 113=130/22—23, fl, 130=143/23 il 129-189 26224,
Ap IlG=122/29=32 tielO3=O982— 35, fl, 87-98/28-34, fl, 81-93/30-3 1 i 18/3328
cle 167—-184/44— 53. Total flagellum length 997-1096. Mesosoma: Pronotum (Figs. 103,
106-male) with collar narrow, long and clearly visible in dorsal view, with well defined
carina. Mesonotum (Figs. 103, 106-male) moderately wide; midlobe of mesoscutum with
meshes engraved and with longitudinal median groove; scutellar seta long, extending
posterior to medially concave frenal line; frenum about 0.6 mesoscutellum length and
entirely reticulate. Metanotum with metascutellum smooth. Propodeum (Fig. 128-male)
smooth between carinae and its anterior margin with stub slightly lateral to lateral margin of
metascutellum; dorsolateral areole with a thin, wavy or broken carina close to and parallel
with anterior margin; median areole well separated from metascutellum by long median
carina not extending to metascutellum; dorsolateral areole much larger than ventrolateral
areole; plica straight, not extending to metascutellum (if it did, it would meet metascutellum
lateral to its lateral margin) and bifurcate anteriorly with a long lateral and shorter medial
arm. Wings. Fore wing (Fig. 144) length 1676-1800, width 598-640, length/width 2.80—
2.81, longest marginal setae 92—104, about 0.33 as long as greatest wing width. Hind wing
(Fig. 144) length 1293-1344, width 60—65, longest marginal setae 130 (n=2). Metasoma.
Petiole shorter than metacoxa + metatrochanter. Gaster (Fig. 162) with ovipositor length
(n=2) 555-617, 0.96—1.08x as long as metatibia (579-590).

Male. Body length. 1485—1587 (n=4). Antenna (Fig. 79). Measurements, length
(n=1): scape 195, pedicel 62,,fl) 163, fl, 19257, 19251, 1940 9197) tL 193; siaS Seat:
1808 1735. He 148) tl els (last two flagellomeres ewan from critical Bova ned
specimen). Total fiapelles length 1820. Each flagellomere bottle-shaped, distinctly wider
towards base. FI, length/width 4.56, with about 7 mps. Mid ocellus diameter 41 (Figs. 41,
50). Genitalia fairly narrow for anterior half of length (Fig. 183, 193).

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Hosts and habitat. Hosts are unknown. Specimens have been collected during two of the
same collecting events as O. occidentalis but O. canadensis is evidently much less common.
Specimens of both species from California were swept from under story vegetation (ferns)
in a redwood forest (L. Masner, personal communication) and both species were collected
at Dredge Lake, Alaska.

Barcoding. One of two specimens yielded a DNA barcode (CNCHY M07506) but the other
did not (CNCHYM07505) so nothing can be said about intraspecific variation based on
DNA. I had incorrectly assigned CNCHYM07506 to O. occidentalis prior to barcoding.
The relatively large difference in barcodes (ca. 3.5%) between it and the other specimen
made me re-examine it and I realized it was actually O. canadensis.

Material examined. 89 and 6<. CANADA. British Columbia. Terrace, | 1.viii.1960, W.R.
Richards (14, CNC); Vancouver I., Lake Cowichan, 1.7 km N. of town, 24 and 31.vii.1979,
I.M. Smith, sweeping (12, 1¢, CNC). USA. Alaska. 14 km N. Juneau, Mendenhall
Valley, Dredge Lake, 17-25.vili.1999, M. Schutz, MT (12, UCRC); Valdez, Valdez Glacier
Campground, 2.viii.1978, P.H. Arnaud (1¢, CAS). California. De/ Norte Co.: Crescent
City, 3.viii.1940, H. & M. Townes (12, AEIC); Klamath, coastal trail, 3.viii.1985, L.
Masner, sweeping, CNCHYM07505 [barcode failed], CNCHYM07506 (42, 24, CNC).
Washington. Clallam Co.: Lake Ozette, north shore, 24.vi.1990, J.D. Pinto (3%, CNC).

Comment. A specimen from North Carolina, Yancey Co., Mt. Mitchell, 6800’, 12.viii.1957,
J.G. Chillcott (192, CNC) is puzzling. It has no mps on fl,. Because O. canadensis is
morphologically close to O. longipetiolus | thought perhaps the specimen belonged to the
latter species but it does not. More material is needed from North Carolina to determine its
status.

Ooctonus fuscipes Whittaker
(Figs. 13, 30, 42, 51, 67, 80, 91, 104, 107, 129, 145, 163, 179)

Ooctonus fuscipes Whittaker, 1931: 189; Peck, 1951: 411 (catalogue); Peck, 1963: 18
(catalogue); Burks, 1979: 1027 (catalogue).

Odéctonus |sic] fuscipes; Britton, 1938: 146 (catalogue, misidentification).

Type material. Lectotype ° in BMNH (examined), here designated to avoid ambiguity
about the status of the type specimens of this species, on card (Fig. 13) labeled: 1.““Lectotype
[purple edged circle]”. 2. “Type [red rectangular label]. 3. “Hollyburn, B.C. 7.1X.28 Coll.
O.W.”. 4. Canada: O. Whittaker Coll. Per W.H. Storey. B.M. 1947 - 212.”. 5. Ooctonus
fuscipes Whitt. 9 Det. O. Whittaker”. 6. “B.M. Type Hym. 5.2318”. Type in good condition,
mounted in dorsal view on card with wings, legs, and antennae spread out.

Paralectotypes. Whittaker stated that he had four specimens of O. fuscipes. Two
paralectotypes are supposed to be in BMNH but only one of them could be found there.
It was examined but is covered in mould; it has the same data as the lectotype but was
collected on 4.i1x.1929. Its colour, antennal proportions, and as much structure that could

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Huber JESO Volume 143, 2012

be seen clearly match the lectotype. The paralectotype female in USNM (examined) is
mounted in same way as the lectotype and labelled 1. “Paratype”. 2. “Paratype No. 43552
U.S.N.M..” 3. “Hollyburn, B.C. 27.VIII.30 Coll. O.W.”. 4. “Ooctonus fuscipes Whitt. 2
Det. O. Whittaker”. It is in good condition and also matches the lectotype.

Diagnosis. Ooctonus fuscipes females are distinguished from other Nearctic species by the
body length more than about 1200 «um, brown legs (Fig. 13), no mps on fl, and fl, (Fig. 67)
and ovipositor not or scarcely exserted.

Ooctonus fuscipes is similar in size and leg colour to O. arizonensis and O.
quadricarinatus but differs by the distribution of mps on the funicle segments (at least 1
mps on fl, and fl, in the latter two species).

Description. Female. Body length 1230-1382 (n=5). Head, antenna except radicle,
sometimes scape laterally, and apex of pedicel, mesosoma, and gaster dark brown/orange
brown; radicle, apex of pedicel, petiole, and taromeres 1-4, dark yellow. Legs vary from
mostly dark brown to mostly yellowish brown, except yellowish joints and tarsomeres I-4.
Head. Head (Fig. 30) width 326—365 (n=4). Vertex (Fig. 42-male, 51) without stemmaticum;
mid ocellus diameter 33. Antenna. Flagellum (Fig. 67) with 2 mps on fl, and fl,, and 7
mps on clava. FL, slightly the longest segment. Fl,—fl, length/width ratios fl 2.87— 3. 29 itis
2.15=3:06; tie 2.83- 3.44, fl, 2.41-3.23, fl, 2.64— 3.22, fl) 2225=3:68: lava sle2s 3.87 as
long as wide, ‘slightly ences than fl —fl, _together. MMe sourcments (length/width, n=4): scape
221—248/36-41, pedicel 67—72/34— 39, ‘fl 60—73/19—26, fl, 57—-63/20—24, fl, 64—74/21—26,
fl, 57-68/20—24, fl, 65—74/23—26, fi, 53— 63/24- 277, the 69 75/29-36, fl, 60— 68/34— 38, clava
202- 234/52-65. Total flagellum length 687-791. Meccan Bromann (Figs. 104, 107)
with collar wide, moderately long and clearly visible in dorsal view, with well defined
carina. Mesonotum (Figs. 104, 107) wide; midlobe of mesoscutum with meshes engraved;
scutellar seta long, extending well posterior to medially almost straight frenal line; frenum
0.62—0.66* mesoscutellum length and entirely reticulate. Metanotum with metascutellum
faintly reticulate posteriorly. Propodeum (Fig. 129) smooth between carinae and its anterior
margin with stub, the latter just lateral to lateral margin of metascutellum; median areole
separated from metascutellum by short median carina; plica (Fig. 91-male) straight except
anteriorly where curved medially and extending as a short arm to metascutellum just medial
to stub but lateral to lateral margin of metascutellum. Wings. Fore wing (Fig. 145) length
1345-1561, width 505—610, length/width 2.56—2.77, longest marginal setae 73—91, about
0.15 as long as greatest wing width (n=4). Marginal vein length 150—156. Hind wing (Fig.
145) length 1033-1203, width 171—80, longest marginal setae 115-134. Metasoma. Petiole
slightly shorter than metacoxa + metatrochanter. Gaster (Fig. 163) with ovipositor length
466-515 (n=4), 0.80—1.00% as long as metatibia.

Male. Body length. 1331-1434 (n=2). Antenna (Fig. 80). Measurements, length
(n=2): scape 214-218, pedicel 67—-69, fl, 111-116, fl, 138-141, fl, 141-132, fi, 130-131;
fi. 128=132, fi, 127-128, fly 122-1245 fi, 121123) fly, 120-125, fie ae yaa epee Gs
Total flagellar length 1364-1372. Fl, length/width 3.74—3.83, with about 8 mps. Mid ocellus
diameter 33. Genitalia short (Fig. 179).

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Hosts and habitat. Hosts are unknown. Specimens have been collected 31—39m in height
in the canopy of ancient (up to 700 years old) Sitka spruce trees or on the forest floor
ground cover of Salmonberry, Devil’s Club, Alaskan Blueberry and False Azalea in the
upper Carmanah Valley.

A few specimens were collected elsewhere in boreal forest, and on ocean side vegetation.
The Upper Carmanah Valley sample consisted of several Malaise traps at 30-49 m height in
Sitka spruce trees, and at ground level on ancient forest floor, transition zone, and a 4 ha clear
cut. The largest number (362 specimens) of a single species of Ooctonus from one area that
I have seen was collected there. The sex ratio was heavily biased towards males, with only
28.4% females, unlike the situation for most populations of most species of Mymaridae,
where females predominate. Interesting location within habitat differences occur between
males (n=257) and females (n=97). For females, none (0%) were collected in the canopy,
16 (16.5%) in the transition zone, 10 (10.3%) in the clear cut and 71 (73.2%) on the forest
floor. For males, the respective numbers were 176 (68.5%), 36 (14.0%), 10 (3.8%), and 36
(13.6%). Presumably, females remain on the forest floor searching for suitable host eggs,
whereas males move into the canopy to disperse. Neither sex was common in clear cut or
transitional zone areas. Unfortunately, the hosts and therefore the location of egg deposition
are unknown. The other two Ooctonus species, O. notatus (n=S0) and O. vulgatus (n=11),
collected in Upper Carmanah valley were found almost entirely in the clear cut (55 of 61
specimens or 90.2%). Three males of O. notatus (6.0%) were collected in the canopy and
four females of O. vulgatus (36.4%) were collected in the transition zone. Both these species
are found mainly in open habitats, and are almost certainly European introductions. Their
presence in a small clear cut area surrounded by ancient forest shows that they (and their
hosts) are very capable of dispersing widely, and perhaps quickly, into suitable habitats.

Barcoding. Four specimens yielded barcodes (CNCHYM07499, CNCHYM0O7501,
CNCHY MO07502, and CNCHYM07503), showing slight variation between the Oregon and
British Columbia specimens.

Material examined. 1089 and 261¢. CANADA. British Columbia. Upper Carmanah
Valley, 18.viii-9.ix, 10-29.ix CNCHYM07499, 30.ix-16.x.1991, 31-39m [1 ¢ at 42m
on 21.ix] up in tree canopy, N. Winchester, MT (1039, 2594, CFS-Victoria, CNC);
Cassiar hwy. Boyar Lake to Stikine River, 6.viii.1988, S. & J. Peck, boreal forest, car net,
CNCHYM07525 [barcode failed] (22, 1¢, CNC). USA. California. Monterey Co.: Pfeiffer
Big Sur State Park, |.iv.1985, J.T. Huber, sweeping grasses and vegetation, CNCH YM07500
[barcode failed] (1¢, CNC). Oregon. Benton Co.: Corvallis, 8.x.1980, H.K. Townes
(1d, AEIC). Lincoln Co.: 2 mi. W. Newport, South Beach State Park, 23.viii.1984, M.E.
Schauff, P. Hanson, ocean side vegetation, sweeping, CNCHYM07501, CNCHYM07502,
CNCHYM07503 (32, USNM).

An additional 6 females from South Beach State Park are doubtfully assigned to
O. fuscipes because they have 2 mps on each of fl, and fl,; four males from this locality and
date are also doubtfully assigned to this species.

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Huber JESO Volume 143, 2012

Ooctonus hemipterus Haliday
(Figs. 1, 31, 43, 52, 62, 68, 81, 92, 105, 108, 130, 146-149, 164, 172, 188)

Ooctonus hemipterus Haliday, 1833: 344; Schmiedeknecht, 1909: 490 (catalogue); Kloet and
Hincks, 1945: 305 (checklist, Britain); Kryger, 1950: 78 (list); Bouéek and Graham,
1978: 109 (checklist, Britain); Kalina 1989: 127 (checklist, Czechoslovakia);
Triapitsyn 2010: 15 (redescription, literature), 18 (records from Canada and USA).

Ooctonus atroclavus Kieffer, 1913: 2; Bouéek and Graham, 1978: 109 (checklist, under
hemipterus).

Ooctonus soykai Hincks, 1952: 154 (key), 160 (description); Bouéek, 1977: 122 (list,
Yugoslavia); Kalina, 1989: 127 (checklist, Czechoslovakia).

Type material. Lectotype ° of O. hemipterus in NMID (not examined), designated by
Hincks 1952: 158. Synonyms and their types treated by Triapitsyn (2010).

Diagnosis. Ooctonus hemipterus is distinguished from other Nearctic species by the entire
head and mesosoma (including mesopleuron, prepectus, and all propodeal areoles) covered
with reticulate sculpture, thus appearing matte (Figs. 92, 105, 108, 130). Other unusual
features are the toruli well separated from the transverse trabecula (Fig. 31), large eye (Fig.
92) (also large in O. silvensis, O. hemipterus, and O. occidentalis), very low (almost absent)
transverse carina dorsally on pronotum, weakly defined femoral depression (mesopleural
and transepimeral sutures almost absent) and absence of propodeal stub (also absent in O.
occidentalis). All other Nearctic Ooctonus species have the sides of the mesosoma and the
propodeal areoles smooth or almost so, thus appearing quite shiny, and the other features
are mostly different. Ooctonus hemipterus is most similar to O. capensis Huber from South
Africa (Huber et al. 2010) but the latter has the propodeum with a stub and the plica is
bifurcate at the propodeum, with a long median and short lateral arm (stub absent and plica
usually not bifurcate in O. hemipterus).

Ooctonus hemipterus is clearly unrelated to the Nearctic species, as might be
expected from an Old World introduction. It is also the only Ooctonus species whose females
may be macropterous, brachypterous or micropterous (Figs. 1, 146—148). Macropterous
specimens have a relatively narrow fore wing, in females with the apex slightly truncated
apically (Fig. 146) and in males definitely rounded apically (Fig. 149). Both sexes of other
species have the forewing relatively wider and more clearly truncated apically.

Description. Female. Body length 922-1075 (n=10). Head and mesosoma dark brown,
matte, entirely covered with reticulate sculpture; scape except radicle, and pedicel light
brown, flagellum brown, petiole, and legs yellow. Forewing with faint brown band just
beyond venation and sometimes a faint brown suffusion in apical half of wing beyond
venation (Fig. 146). Head. Head (Fig. 31) width 287-320 (n=5). Vertex with stemmaticum
(Figs. 43, 52). Mid ocellus diameter at most 17. Antenna. Flagellum (Fig. 68) with 2 mps on
fl, 2 on fl,, and 7 on clava. Fl,—fl, length/width ratios: fl, 1.78—2.33, fl, 1.76-1.90, fi, 1.82—
2.05, fl, | ee 2.03; Met S532 04, fl, 1.52—1.73; clava 2. 75 —3.02x as long as wide, alae as

32

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

long as fl_—fl, together. Measurements (length/width, n=5): scape 183—195/31—35, pedicel
56— 61/29- 32, fi v30>35/15 17, 2729/1 5=17) tL, 5 1=34/ 16-18) 41, °30—32/15—19} fi, 30
37/18—20, fi, 34- 37/21—22, fe 44-47/27-31, fl, 47-50/34—36, clava 154 161/53—56. Total
flagellum length 423-454. Mesosonia. Pronotum (Figs. 105, 108) with collar moderately
wide, short but visible in dorsal view, without carina. Mesonotum (Figs. 105, 108) wide;
midlobe of mesoscutum with meshes strongly raised; scutellar seta short, extending to
medially almost straight frenal line; frenum about 0.66 mesoscutellum length and entirely
reticulate. Metanotum with metascutellum and lateral lobes reticulate. Propodeum (Fig.
130) entirely covered with reticulate sculpture and its anterior margin without a stub; median
areole separated from metascutellum by a median carina (carina sometimes almost absent);
plica straight, extending to anterior margin of propodeum, occasionally bifurcate with a
short median arm. Wings. Fore wing in macropterous form (Fig. 146) fairly narrow, slightly
truncate apically, and with a transverse brown band just beyond venation, in brachypterous
or micropterous forms with narrow fore wing rounded apically and with venation greater
than half wing length (Figs. 147, 148). Length (macropterous form) 926—1004 (n=4), width
279-313, length/width 3.21—3.38, longest marginal setae 68-83, about 0.25 as long as
greatest wing width. Hind wing length 752-849, width 32-38, longest marginal setae 93—
113. Marginal vein length 123-129. Metasoma. Petiole (Fig. 188) reticulate dorsally, about
as long as metacoxa. Gaster (Fig. 164, 172, 188) with ovipositor length 406-434 (n=5)
1.12—1.14~ as long as metatibia (350-374).

Male. Body length 896-1178 (n=5). Antenna (Fig. 81). Measurements, length
(n=5): scape 153-184, pedicel 26—36, fl, 65-75, fl, 62-83, fl, 62-86, fl, 69-89, fl, 75-87,
iP 89 fi 81=93; fi, 78—89, fl, 81-97, fl yes 89, fi, 74— 86. Total aaecllan feneth 1049—
1067. Bip length/width 3.384. 27, with 4 (25) mps. Borewine (Fig. 149) narrower, length/
width 3.864. 10, and with more rounded apex. Mid ocellus diameter 24-26.

Hosts and habitat. Hosts are unknown. Habitats vary widely. Specimens were collected
near water, in water with 7ypha or Carex, agricultural areas such as blueberry, onion, alfalfa,
clover, and potato fields, apple orchards, prairie remnants, fields, forests, bush, meadows,
bogs, sandy areas, urban gardens, cedar swamps, and beach. Several specimens were sifted
from duff or litter, including two males (Oxford Mills) in early December, suggesting that
they overwinter as adults.

Barcoding. Three of four specimens yielded barcodes (CNCH Y M07476, CNCHY M07477,
and CNCHYM07478) and one did not (CNCHYM07475). There was slight variation in
DNA between the two specimens from Ontario but none between the Quebec specimen and
one of the Ontario specimens.

Distribution. Ooctonus hemipterus occurs across the Palaearctic region from Ireland to the
Kuril Islands (Triapitsyn 2010). In the Nearctic region its presence in Alaska and northern
Canada and and apparent absence from southern USA suggests it may be a naturally
occurring Holarctic species though it could also have been introduced from Europe into
eastern North America by human activity.

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Huber JESO Volume 143, 2012

Material examined. 1839 and 330¢. CANADA. British Columbia. Abbotsford, Aquilini
off Ladner road, Pitt Meadows, 49°17.996'N 122°37.865'W, 2.vii.2001, M. Robertson,
blueberry field, YPT (49, CNC), Vye road, 49° 00.847'N 122° 15.479'W, 7.viii, 4.ix.2001,
M. Robertson, blueberry field, YPT (29, CNC); Richmond, No. 6 road, 49° 09.481'N 123°
04.188'W, 2.vii.2001, blueberry field, YPT (12, CNC). Manitoba. Elma, 2 mi. E. on hwy
11, 31.vii.2000, M. Iranpour, pond, YPT (1¢, CNC). New Brunswick. Albert Co.: Fundy
National Park, Chignecto campsite, 45.6032°N 64.9877°W, 12.viii.2009, J. Fernandez, (2,
CNC). Kent Co.: Kouchibouguac National Park, 18.v.1977, G.A.P. Gibson (14, CNC), 29
and 30.viii, and 12.ix.1977, G.A. Calderwood (3 microp.2, 12, 24, CNC), 20 and 21.
ix.1977, S.J. Miller (59, 123, CNC). Queen’ Co.: 25 km W. Canaan Forks, hwy. 112,
19.viii. 1984, M. Kaulbars (2¢, CNC). Northwest Territories. Kovaluk River, 69°11'N
131°W, 6-10.vii.1971, W.R.M. Mason (2¢, CNC). Nova Scotia. Kings Co.: Kentville, 6.
x1.1953, C.J.S. Fox, Berlese, apple orchard duff (1 microp. 2, CNC); Sheffield Mills,
orchard, 31.viii.1998, 20.viii.1999, M. Trombley, YPT (3 microp. 2, 64, CNC), Lunenburg
Co.: North Sawler, 31.viii.1951, K.H. Sanford (1¢, CNC). Victoria Co.: 5 km S. Ingonish,
Smoke Mt., 275m, 23.viii.1984, M. Kaulbars (1, CNC). Ontario. Alfred Bog, 13.vii.1981,
L. LeSage (12, CNC); 3 km N. Almonte, 12-19.vili-1986, J. Denis, L. Dumouchel, YPT
(146, CNC); 3 km N. Almonte, 12-19. viii, 17-24.ix.1986, J. Denis, L. Dumouchel, YPT (4<,
CNC), 5 km NW. Almonte, 22-29.vii.1986, H. Goulet (34, CNC); Ancaster, 3-15.x.1994,
H. Goulet, prairie remnant (3, CNC); near Ancaster, 43°15’N 80°00'W, 2.vi-1.vii, 7-28.
vii.1995, B. DeJonge, bush/prairie, MT (12, 14, CNC); Buckham’s Bay, 45.4985°N
76.1108°W, v-x.2010, J. Read, CNCHYMO07478 (1, CNC); 7 mi. SW. Carleton Place, S.
Miller’s farm, 27.v-2.vi.1980 (2¢, CNC), viii-ix, 1-30.x.1991, YPT in pond with Carex
(34, CNC); Chatterton, 13 mi. N. Belleville, 27.x.1969, C.D. Dondale, meadow (1 microp.@,
CNC); near Clayton, 12.viii.1981, L. Masner, H. Goulet, forest, sweeping (12, CNC);
Crieff Bog, 3 km W. Puslinch, 28.v-4.vi.1987, D. Blades, mid-forest pool, YPT (2 microp.°,
CNC); Constance Bay, 12-19.x.1973, G. Gibson, YPT (34, CNC), 26.viii-7.ix.1983, M.
Sanborne (12, CNC); Elmira, Salem Creek, 1-31.viii.1977, L. LeSage (24, CNC); near
Embro, 43°12.362’N 80°55.713'W, 7-21.ix.2006, B. Broadbent, pitfall under spruce
hedgerow near alfalfa field (2 microp.Y, CNC); Flint Hill, near Kemptville, 30.viii-6.
ix.1983, L. Dumouchel (1 microp.2, CNC); Gananoque, 24.vili-12.x.1977 (7 microp.,
5¢, CNC); 18 km E. Gananoque, 12.v-9.vi.1977, C. Dondale, J. Redner, pitfall in old field
(10 microp.2, CNC); Gloucester, 4-17.x.1984, M. Sanborne (34, CNC); Guelph, 1-20.
vii.1982, K.N. Barber (24, CNC); Hamilton, 6 and 18.viii.1980, 2-7.viii, 14-22.viii, 28.
vii-1.viii, 31 .viii-7.ix, 25.x-8.xi, 30.ix-11.x.1981, M. Sanborne (1 microp.2, 42,93, CNC);
Innisville, 29.vii.1963, (1¢, CNC); Leitrim, 16-23.ix, 13-20.x.1985, R.E. Skidmore, MT
(3¢, CNC); London, 1-17.ix.1982, A. Tomlin, pine hedgerow (12, CNC), Fanshawe
Experimental Farm, 10-31.vil, 5.1x-2.x.1981, 4-25.viii, 31.1x., 8-12.x, 5.x1.1982, A. Tomlin,
onion field (22, 6¢, CNC), 5-30.vii.1982, L. Masner (12, CNC); Marmora, Crow Lake,
20.viii.1975, L. Masner, R. Longair (24, CNC); Milton, 8-13.viii.1981, M. Sanborne (19,
14, CNC); Nepean, Pine Glen, 3-10, 12-14 and 22-26.x.1991, 16.viii-7.ix.1992, 24-
30.x.1994, 27-30.vii.1999, L. Masner (4 microp.2, 22, 3d, CNC), Slack Road, 2.x,
4-5.x.2007, 1 and 6-9.xi.1999, L. Masner, YPT, sandy area (54, CNC); Ottawa, 23-30.
ix.1985, H. Goulet, garden (14, CNC), 20-27.ix.2008, L. Masner, MT, CNCHYM07476
(12, CNC), 30.x.1988, 1-3.i1x.1989, 10 and 27.x.1992, 20.x.1995, J.R. Vockeroth, Zypha on

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

pond/YPT among 7ypha (14 microp.2, 44, CNC), airport, 20-27.ix.1985, L. Dumouchel,
YPT (34, CNC), airport road, 1-8.xi.1985, L. Masner, (1, CNC); airport sands, 11-18.
ix.1985, J. Denis (24, CNC), 23-30.ix, 1-16.x, 17.x-7.xi.1985, 20.vii-10.viii, 26.viii-7.
ix.1986, 20-31.vii, 14-21.viii, 19.1x-8.xi, 20-27.1x, 27-30.x.1987, 17-20.vii, 5-8.x, 10-
13.x.2008, H. Goulet, city/urban garden, 45°21.365'N 75°42.416'W, YPT and MT (11
microp.°, 19, 534, CNC), Jock River, 4-5.x.2007, L. Masner (44, CNC), Mer Bleue, 16-
23.viii. 1982, H. Goulet (19, CNC), 2.x.2000, L. Masner, sweep (1 microp.9, 2, CNC),
along Ottawa River shoreline, 19-20.1x.2007, L. Masner (12, CNC), Riverfront Park, 13.
ix.2000, L. Masner, YPT (1, CNC); Rockland Park, 9.xi.2005, YPT under Erigeron, J.R.
Vockeroth (1 microp.2, 44, CNC), Tanglewood road, 14.ix-2.x.1978, L. Masner, YPT (1,
CNC); Oxford Mills, edge of Little Rideau River, 17.vii.1971, 3-10, 10-17 and 17-24.viii,
J-21.ix, 21-28.ix, 28.ix-12.x.1973, L. Masner, YPT (22 microp.?, 22, 174, CNC), 4.
xii.1973, sifted from litter, L. Masner (24, CNC), 17 and 21.viii.1978, N. Tulsiram (3
microp.?, 73, CNC), 31.viii, 22.ix-3.x.1978, G. Gibson, YPT (4 microp.2, 6¢, CNC);
Point Pelee, 22.viii.1984, A. Borkent (19°, CNC); Saugeen Bluffs Conservation Area, near
Paisley, 19.v-16.vi.1988, C. Dondale, J. Redner, pitfall trap in cedar swamp (1 microp.’,
CNC); Shaw Forest, 10 km N. Eganville, edge of beaver pond, 6-13.vili.1992, M.J. Sharkey
(12, 14, CNC); 5 km E. Eganville, 30.vi.1992, H. Goulet (12, CNC), 1-8.x.1992, M.
Sharkey, MT (1, CNC); Shirley’s Bay, 15 km W. Ottawa, 16-31.vii.1984, M. Kaulbars (1
microp.2, 14, CNC), 12-19.viii, 29.vii-5.viii.1985, M. Sanborne, L. Leblanc (49, 2¢,
CNC), 7-14.viii.1985, M. Sanborne, L. Dumouchel, (42, CNC), 3-10.x.1985, J. Denis (1
microp. 2, 12, CNC), Innes Point [Shirley’s Bay], 25.x-5.xi.1986, J. Denis, MT (12, CNC);
Spencerville, 14-21.viii.1979, L. Masner (12, CNC); St. Lawrence Islands National Park,
summer, 1975 (34, CNC), Grenadier Island, 16-30.viii.1994, CNC Hym. team, Carya
grove, YPT (1 microp.2, CNC), Grenadier Island Centre, 30.vii, 7.viii.1975, E. Sigler (4,
CNC); McDonald Island, 9 and 11.ix, 1, 4, and 6.x.1976, W. Reid (42¢, CNC), Thwartway
Island, 30.viii.1976, Reid (14, CNC); Stittsville, 24.ix.1976, M. Sanborne (14, CNC), 29-
31.viii.1978, MT (14, CNC); Thunder Bay, Law road, Powells Lakes, 16 and 29.viii.1980,
intercept trap/sweeping, M. Kaulbars, CNCHYM07475 [barcode failed] (1 microp.2, 139,
124, CNC); Toronto, Etobicoke, Etienne Brulé Park, 17-19.vili.1998, S. Libenson, mixed
forest, deadwood (192, CNC); Waterloo, 4.ix.1977, L. LeSage, MT (12, CNC). Quebec. 6
km N. Bouchette, Lac Roddick (= Lac Ronde), 46°15’21.4"N 75°54'44.2"W, 18..ix,
1-3.x.2005, L. Masner, YPT (23, CNC), 27-29.vii.2001, L. Masner, YPT (14, CNC), 24-
25.ix.2007, L. Masner, riverine (14, CNC), 15-17.viii.2009, L. Masner, YPT (19, 12,
CNC); Eardley, junction hwy 148 & Eardley-Masham road, 2-20.viii.1992, CNC Hym.
team (19, CNC); Gatineau Park, 4.x.1976, G. Gibson, L. Masner (54, CNC), 11-20.
vili.1991, K. Yamagishi, YPT (2 microp.2, CNC), 2 km W. chemin Pilon, 23-29.ix, 21-
27.x.1992, CNC Hym. team (1 microp.2, 14, CNC), summit of King Mt., 1150’, 16.x.1968,
J.F. McAlpine (14, CNC), 10.x.1961, J.R. Vockeroth (14, CNC), 23.viii.1981, L. Masner
(13, CNC); Hull (= Gatineau), 23.viii, 19.x.1983, L. Dumouchel, flood forest, flood plain,
YPT (1 microp.2, 12, 14, CNC), boulevard Fournier, 28.viii-4.ix.1984, J. Denis, L.
Dumouchel (1 microp.2, CNC); Luskville Falls, 300m, 22-29. vii, 5-12.viii, 17-25.ix.1986,
J. Denis, L. Dumouchel, MT (49, 3¢, CNC), 25.viii-2.ix.1986, YPT in blueberry field in
oak-conifer forest clearing, J. Denis, L. Dumouchel, YPT (14, CNC); 1 km N. La Corne,
22.v1.2005, 48°24'19.4"N 78°00'11.9"W, H. Goulet, C. Boudreault, fallow field by road,

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Huber JESO Volume 143, 2012

CNCHYM07477 (24, CNC); Old Chelsea, 3.ix.1958, S.M. Clark (14, CNC). Prince
Edward Island. Queens Co.: Brackley Beach near Stanope 17.viii.1988, C.M. Yoshimoto,
sweeping (3, CNC); Harrington, 10-22 and 22-29. viii.1988, 7-21 and 23.vii-28. viii. 1989,
M.E.M. Smith, potato field, YPT (1 microp.2, 62, 84, CNC), 7.ix.2006, pitfall trap in
potato field (1¢, CNC), 22.viii and 5.ix.2006, pitfall trap barley/red clover field and clover
field (2 microp.:, CNC). Saskatchewan. S. of Moosomin Piperstone Creek, 570m, 50°
01.97'N 101°40.61'W, H. Goulet, C. Boudreault, J. Fernandez, prairie (12, CNC). USA.
Alaska. Cantwell, Denali hwy, route 8, mi. 85-130, 24.vi1.1984, S. & J. Peck, taiga-tundra,
car netting (14, CNC); Murphy Dome, 64°57.157'N 148°21.331/W, 892m, 20.vii.2009, H.
Goulet, C. Boudreault, tundra (24, CNC); Tok, 21.vi-15.vii.1984, S. & J. Peck, FIT (14,
CNC). Massachussetts. Barnstable Co.: Cape Cod, 16.vili.1977, W.A. Attwater (192
microp., CNC) Eastham, 23.ix.1992, J.R. Vockeroth (14, CNC). Hampden Co.:Westfield,
30.ix.1992, J.R. Vockeroth, pan traps in Zypha (1¢, CNC). Michigan. Livingston Co.:
Edwin S. George Res., 13.ix.1973, G. Gibson (1¢, CNC). New Hampshire. Coos Co.: 8
km S. Gorham, 30.viii.1984, M. Kaulbars (1¢, CNC); Mt. Washington, 1370m, 9-13.
[month illegible].1983, L. LeSage, E. Rickey, litter (19, CNC). New York. Essex Co.: 10
mi. SE. Lake Placid, Adirondack Park, Heart Lake, 17-18.viii.1987, J. Cumming (19
microp., CNC). Dutchess Co.: Amenia, 7-12.ix.1982, (1¢, CNC). Tompkins Co.: Ithaca, N.
shore of Beebe Lake, 20-26.vii, 24-31.vii, and 2.viii.1977, N.F. Johnson, yellow pan traps
(84, CNC), Ithaca, 14-21.vii.1978, N.F. Johnson (54, CNC). North Carolina. Jackson
Co.: near Highlands, Whiteside Mt., 1600m, 1v,-20.vi1. oak forest, Malaise trap, CNC Hym.
Team (1¢, CNC). Wisconsin. Milwaukee Co.: Milwaukee, Bayside, corner of Brown Deer
& N. Rexleigh roads, 2.ix.1983, J.T. Huber (24, CNC).

Ooctonus longipetiolus Huber, sp. n.
(Figs: 95 21; 323 536982; 93. 109; 112, 1313150653 ISAs)

Type material. Holotype 2 in CNC, on slide (Fig. 21) labelled 1. “Canada: ON,
Nepean, Slack Road, 9.x1.1999, sands, L. Masner, YPT”. 2. “Ooctonus longipetiolus Huber
Holotype & dorsal”.

Paratypes. 5992 and 26¢. CANADA. Ontario. Ancaster, 30.ix-12.x.1991, marsh,
B. DeJonge (1¢, CNC), 4-11.vi, and 25.vi-l.vii, B. DeJonge, prairie remnant (49, 1¢,
CNC); near Ancaster, 43°15’N 80°00'W, 7-28.vii.1995, B. DeJonge, bush/prairie (19,
CNC), 27.v-4.vi.1994, B. DeJonge, prairie, MT (12, CNC); Constance Bay [near Ottawa],
22-28.ix.1973, G. Gibson, PT (12, CNC); Hamilton, 2-7.viii.1980, M. Sanborne, MT
(22, CNC), 14-19.vii.1981, CNCHYM07515 [barcode failed], M. Sanborne (14, CNC);
London, 1-17.ix.1982, A. Tomlin, pine hedgerow (192, CNC); Malacoff, 22-28.vii.1985,
R. Foottit, YPT (19, CNC); Ottawa, same data as holotype (72, 24, CNC), same data as
holotype but 1.xi and 6-9.xi.1999 (79, 1¢, CNC); Shaw Forest near Eganville, 27.viii-3.
ix.1992, M. Sharkey, MT (1¢, CNC); Shirley’s Bay [E. of Ottawa], 27.viii-10.ix.1985, M.
Sanborne, H. Goulet (12, CNC); Thunder Bay, Law Road, Powell Lakes, 16.viii.1980,
M. Kaulbars (2¢, CNC). Quebec. Cap Rouge [near Quebec City], 3.viii.1955, O. Peck
(12, CNC); Luskville Falls top, Gatineau Park, 11.ix.1985, H. Goulet (1¢, CNC); Mont
Pinnacle, near Frelighsburg, 20.vi.1991, M. Sharkey (1¢, CNC). Prince Edward Island.
Millvale, 30.viii.1992, J. Heraty, deciduous forest along river (12, UCRC); 1 km SE.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Stanley Bridge, 30.viii.1992, J. Heraty, scrub/goldenrod/apple (1, CNC). USA. Florida.
Baker Co.: Glen St. Mary, 30°18'00"N 82°00'55"W, 14.xii.2006, 22.111, 3.v, 14.vi.2007, E.
Zoll, S. Fullerton, MT, rural yard/mixed woods (29, 2, UCFC). Highlands Co.: Archbold
Biological Station, 29.v.1991, J.B. Woolley (14, CNC). Marion Co.: Ocala National Forest,
Alexander Spring, 18.ix.1987, L. Masner, hardwood forest, sweep (19, 40, CNC). Orange
Co.: Apopka, Rocksprings, Kelly Park, 7.iii.1975, W.R.M. Mason (29, 14, CNC). Seminole
Co.: Longwood, 4-8.iii.1975, W.R.M. Mason (1, CNC). Maine. Washington Co.: 5 km E.
Wesley, hwy 9 at East Machias road, 29.viii.1984, M. Kaulbars (12, CNC). Maryland.
Montgomery Co.: Potomac River Trail, mouth of Seneca Creek, 16.vi.1985, L. Masner,
undergrowth by old canal (12, CNC). Prince Georges Co.: 2 mi. S. Laurel, 18-30.vi.1986,
M.E. Schauff (12, USNM); Patuxent Wildlife Research Center, 22.vi.1980, G. Gibson (1%,
1¢, CNC). Missouri. Wayne Co.: Williamsville, 21.x-11.xi.1987, J.T. Becker, MT (19,
CNC). North Carolina. Jackson Co.: Whiteside Mountain, near Highlands, 1600m, iv-20.
vi.1987, MT, oak forest, CNC Hymenoptera team (19, CNC). South Carolina. Dorchester
Co.: Francis Beidler Forest near Harleyville, 1-22.ix.1987, L. Masner (392, 14, CNC).
Virginia. Clarke Co.: 2 mi. S. Boyce, University of Virginia, Blandy Experimental Farm,
19-30.vi.1990, D.R. Smith, MT (2¢, USNM). Hardy Co.: 3 mi. NE. Mathias, 38°55'N
78°49'W, 17.iv-3.v, 17.v-3.vi, 4-17.vi, 18.vi-18.vii CNCHYM07516, 22.vii-13.1x, 10-30.
viii.2002, D.R. Smith, MT (112, 24, CNC, UCR). Louisa Co.: 4 mi. S. Cuckoo, 26.vi-5.
vii.1987, 15.ix-7.x.1988, J. Kloke, D.R. Smith, MT (22, USNM). Page Co.: Shenandoah
National Park, Big Meadows, 14.vi.1982, H. Goulet, sweeping various plant communities
in meadow (19, CNC).

Diagnosis. Ooctonus longipetiolus is distinguished from other Nearctic species by the
combination of vertex with stemmaticum (Fig. 53), mesoscutum with median longitudinal
groove usually extending almost length of midlobe (Fig. 109, 112), transepimeral suture
not joining mesopleural suture dorsally, so femoral depression open above (Fig. 93),
propodeum with pentagonal areole separated from metascutellum by a median carina about
as long as areole and plica bifurcate with long arms (Fig. 131), and gastral petiole longer
than metacoxa + metatrochanter (Fig. 165); fl,—fl, each with 2 (rarely | on fl,) mps, clava
relatively long and funicle segments relatively short (Fig. 69).

Ooctonus longipetiolus is similar to O. canadensis in that both share most of the
above features. They differ in antennal proportions: O. canadensis has relatively longer
funicle segments and a relatively shorter clava that O. longipetiolus, and in head shape:
shorter and wider in O. longipetiolus (Fig. 32) compared to O. canadensis (Fig. 29).
Ooctonus longipetiolus is also remarkably similar to O. sublaevis Férster from Europe,
which seems to have all but one of the diagnostic features—the median longitudinal groove
on the mesoscutal midlobe is absent (Triapitsyn 2010), and the body is smaller (the femoral
groove and sutures were not described). Five other Ooctonus species in the Palaearctic and
Oriental regions have a long longitudinal groove on the mesoscutal midlobe (Triapitsyn
2010). Two specimens from Alabama and Florida (UCRC) have a larger pentagonal areole
and shorter gastral petiole so are not included in the type series. Whether they represent
variants of O. /ongipetiolus or a different species is uncertain.

Derivation of specific epithet. The name refers to the unusually long gastral petiole.

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Huber ’ JESO Volume 143, 2012

Description. Female. Body length 1050-1382 (n=20). Head and mesosoma dark brown,
gaster and flagellum except fl, brown, pedicel dorsally and procoxa light brown; scape,
pedicel except dorsally, fl,, and legs except procoxa uniformly bright yellow to mainly brown
(except joints), especially on metafemur and metatibia; petiole even ligher yellow than legs.
Head. Head (Fig. 32) width (n=3) 337-344. Vertex (Fig. 53-male) with stemmaticum. Mid
ocellus diameter 27-31. Antenna. Flagellum (Fig. 69) with 2 (occasionally 1) mps on fl,, 2
mps on each of fl_—fl,, and 7 mps on clava. FI, slightly the longest funicle segment. Fl —fl,

length/width ratios: fl 2.66-4.09, fl, 3.03-3. 81, fl, 2.73=3.24, fi, )2.57=3:30 Misa 3) 06.

fl, 1.82—2.89; clava 3. 75 —5.52x as long as wide, very slightly shore than fl, ny together.

Measurements (length/width, n=5): scape 216—224/31—36, pedicel 61 -65/33- 38, il 62
72/18—24, fl, 68-77/20-24, fl, 67—77/21-25, fl, 72-83/24—29, fl, 70-80/26-34, fl, 66—
79/21—367 i 68=77/29=35 hil: 67-77/29- 38, ceva 197-228/41-52. Total flagellum length
735-850. Mesosoma. pronotum (Figs. 109, 112) with collar wide, long and clearly visible
in dorsal view, with well defined carina. Mesonotum (Figs. 109, 112) wide; midlobe of
mesoscutum with meshes engraved and with longitudinal median groove; scutellar setae long,
extending well beyond medially slightly concave anterior margin of frenum; frenum short,
at most 0.60 mesoscutellum length and entirely reticulate. Metanotum with metascutellum
smooth. Propodeum (Fig. 131-male) smooth between carinae and its anterior margin with
a stub just lateral to lateral margin of metascutellum; median areole short, about as long as
wide, separated from metascutellum by a long median carina extending to metascutellum;
dorsolateral areole with a thin, broken carina close to and parallel with anterior and median
margin; plicae straight, not extending to metascutellum and widely bifurcate anteriorly as
two long lateral arms, the lateral one longer than the median one. Wings. Fore wing (Fig.
150) length 1310-1405, width 461-514, length/width 2.61—2.85, longest marginal setae
67-81, about 0.18 as long as greatest wing width (n=5). Hind wing (Fig. 150) length

935-1011, width 50-67, longest marginal setae 80-94. Metasoma. Petiole long (Fig. 165),

extending distinctly beyond apex of metacoxa + metatrochanter. Gaster (Fig. 165, 173) with
ovipositor length (n=5) 313-343, 0.68—0.72* as long as metatibia (461480).

Male. Body length. 998—1408 (n=5). Entire flagellum brown. Antenna (Fig. 82).
Measurements (n=3): scape 132-172, pedicel 48-54, fl, 90-122, fl, 101-139, fi, 99-135,
fl, 98-1295 fie 97-129) fi 98129 tie 00-130; fi; LO0-128 i IOI 8rene 101- PANE iby
97-121. Total flagellar length 1090-1412. Fl, length/width 2. 85- S22i8 ah 9 or 10 mps.
Mid ocellus diameter 31—33. Genitalia fairly narrow for anterior half of length (Fig. 184).

Barcoding. Two of three specimens yielded barcodes (CNCHYM07514-Ontario,
CNCHYM07516-Virginia); the third did not (CNCHYMO07515-Ontario). Based on the
DNA two species are involved. Upon rechecking the Ontario specimen I realized I had
misidentified the Ontario specimen (it is much smaller than O. /ongipetiolus specimens). It
does not fit the other described species so it is placed under Unassigned species (below).

Hosts and habitat. Hosts are unknown. The habitats are varied: marsh, prairie remnant,

bush/prairie, pine hedgerow, oak forest, undergrowth by old canal, plant communities in
meadow.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Ooctonus notatus Walker
(Figs. 33, 44, 54, 55, 70, 83, 110, 113, 132, 151, 166, 174)

Ooctonus notatus; Walker, 1846: 50; Dalla Torre, 1898: 430 (catalogue); Schmiedeknecht,
1909: 490 (catalogue); Kloet and Hincks, 1945: 305 (checklist, Britain); Triapitsyn
2010: 28 (redescription, literature), 30 (records from USA).

Ooctonus heterotomus Foerster, 1847: 201; Kalina 1989: 127 (checklist, Czechoslovakia).
Synonymy under O. notatus by Graham, 1982: 226.

Ooctonus auripes Whittaker, 1931: 190 (in part); Triapitsyn, 2010: 28 (see also under O.
vulgatus).

Type material. Lectotype 9 of O. notatus Walker in NMID (not examined), designated by
Graham 1982: 226. Synonyms and their types treated by Triapitsyn (2010).

Paralectotype. One ¥ of O. auripes in USNM (examined), on card and mounted in
same manner as lectotype of O. auripes and labelled |. “Paratype”. 2. “Paratype No. 43553
U.S.N.M..” 3. “Chilliwack, B.C. 4.1X.26 Coll. O.W.”. 4. “Ooctonus auripes Whitt. 2 Det.
O. Whittaker”. 5. “= Ooctonus notatus Walker Det. S.V. Triapitsyn 2008”. The paralectotype
is mounted in the same way as the lectotype but the right antenna is missing fl, , and the
left antenna is missing the apical half of the clava. I agree with Triapitsyn (2010) that the
paralectotype is a specimen of O. notatus. However, the lectotype of O. auripes (BMNH)
belongs to O. vulgatus (see below under O. vulgatus).

Diagnosis. Ooctonus notatus is distinguished from other Nearctic species by the combination
of body length less than 1000 um, fi, distinctly shorter and narrower than fl, or fi,, and
without mps, mesoscutellum entirely reticulate, and propodeum with median areole joined
directly to propodeum.

Ooctonus notatus is most similar to O. silvensis and O. vulgatus. All are small
species with a short pronotum and gaster and without mps on fl,— fl,. Ooctonus notatus
is distinguished from these and perhaps other Nearctic species by the presence of 2 mps
on fl,, fl,, and fl, (Fig. 70) (fl, without mps in O. si/vensis and O. vulgatus), the frenum
with reticulation over the entire surface (Fig. 110, 113) (smooth or almost so medially in
O. silvensis and O. vulgatus), and propodeum with a large median areole not separated
from metascutellum (Fig. 132). A median areole joined anteriorly directly to the propodeal
margin also occurs in O. vulgatus but O. vulgatus has a shorter marginal vein.
Description. Female. Body length 742—922 (n=10). Head and mesosoma dark brown,
metasoma brown, sometimes reddish brown; radicle, scape and pedicel laterally and
petiole yellow; legs except apical tarsomere of each leg usually uniform light yellow, rarely
with slight brown infuscation on femora and tibiae. Head. Head (Fig. 33) width 277-287
(n=3). Vertex (Fig. 44, 55-male) without stemmaticum. Mid ocellus diameter about 19.
Antenna. Flagellum (Fig. 70) with 2 mps on fl,, fl, and fl,, and 7 mps on clava. Fl, the
longest segment; Fl—fl, length/width ratios (n= aN ‘i 2.49- DAO 2 232259), wile ig
2.66, fi, 1.84-2.17, fl. I '89- 1.90, fl, 1.58-1.94; clava ) 76-3.52x as long as wide, slightly
shorter ian fi fl _together. MMe gatnentcars (length/width: scape 173—179/31—32, pedicel
56—57/3 1-32, fl, 4446/1618, fi, 043) li Neti 42 47/320) 1 3538/1719). fh
53-56/27-28, fi, '36/19- 23; ii 49> 53/24-30, fl, 46-47732- 35, clava 161-168/47- 59: Total

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Huber JESO Volume 143, 2012

flagellum length 500-534. Mesosoma. Pronotum (Figs. 110, 113) wide, with collar short
and scarcely visible in dorsal view, with well defined carina. Mesonotum (Figs. 110, 113)
very wide; midlobe of mesoscutum with meshes raised anteriorly, engraved posteriorly;
scutellar seta short, extending just posterior to medially slightly concave frenal line; frenum
about 0.79 mesoscutellum length, and entirely reticulate. Metanotum with metascutellum
smooth. Propodeum (Fig. 132) smooth between carinae and its anterior margin with stub
just lateral to lateral margin of metascutellum; median areole joined to metascutellum by
united carinae of dorsolateral areoles; plica straight, not (or scarcely) bifurcate anteriorly,
extending to apex of stub. Wings. Fore wing (Fig. 151) length 911—939, width 329-350,
length/width 2.68—2.80, longest marginal setae 52-60, about 0.17 as long as greatest wing
width (n=3). Hind wing (Fig. 151) length 689-710, width 38-41, longest marginal setae
79-101. Metasoma. Petiole shorter than metacoxa + metatrochanter. Gaster (Fig. 166, 174)
with ovipositor length 376-442 (n=3) 1.15—1.29* as long as metatibia (326-335).

Male. Body length 845-922 (n=2). Legs mainly brown. Antenna (Fig. 83).
Measurements, length (n=2): scape 143-159, pedicel 50—S6, fl, 76-85, fl, 89-91, fl, 89-92,
fi, 90-92, fi; 91=93;fl. 86-89) fl | 75-93, fl, 92-93) fi, 9192) fi 87 95, fi aS SanMotal
flagellar length 959-1007. FI, length/width 3.31—3.33 and with 6 mps. Mid ocellus diameter
24.

Barcoding. Three of five specimens yielded barcodes (CNCH YM07459, CNCHY M07461,
and CNCHYM07462) and two did not (CNCHYM07460 and CNCHYMO07463). There
was little variation among the specimens despite the geographic range covered (Alberta,
Ontario, and Prince Edward Island.)

Hosts and habitat. Hosts are unknown. Specimens have been collected in a fallow field,
old field, turnip [rutabaga] field, potato field, and orchard. Some specimens may have come
from more natural habitats (less disturbed by mankind).

Material examined. 699 and 114. Six specimens reported by Triapitsyn (2010) from
Montana and Washington were also examined, confirming his identifications. Their
collection data are not duplicated here. Specimens from Alaska, California, and Oregon
(Triapitsyn 2010) were not examined but represent additional state records. CANADA.
Alberta. Beaverlodge area, Saskatoon Mt., 962m, 55°13.20'N 119°16.92'W, 2.viii.2007,
J. Otani, natural meadow, sweeping, CNCHYMO07462 (1¢, CNC). British Columbia.
Shushwap Lake, Blind Bay, 15-31.viii.1986, C.A. Elsey, MT, CNCHYM07460 [barcode
failed] (14, CNC); Upper Carmanah Valley, 31-vii-11.viti, 12-27.viti, 28.vii-9.1x, 10-29.1x,
30.ix-16.x, 17-26.x.1991, N. Winchester, MT (159, 33¢, CFS-Victoria). New Brunswick.
Fundy National Park, Chignecto campsite, 45.6032°N 64.9877°W, 12.viii.2009, J. Fernandez,
roadside, MT (22, CNC); Parker Ridge, Forest Insect Survey, 53-18C14, 5.viii.1953 (29,
14, CNC). Nova Scotia. Bridgetown, 7.x.1912, 20.vii, 26.vii, 5.xi, 16.xi, 1.x.1913, G.E.
Saunders (32, 384, USNM). Newfoundland. Cornerbrook, 48°57.355’N 57°54.681°W,
17.vii.2008, H. Goulet, C. Boudreault, fallow field (22, 54, CNC). Nova Scotia. Cape
Breton Highlands National Park, Pleasant Bay, 24.vii.1983, L. Masner (32, CNC). Ontario.
Buckham’s Bay, 45.4985°N 76.1108°W, v-x.2010, J. Read, MT, CNCHYMO07459 (19,
CNC): Hamilton, 28.vii-1.viii.1981,M. Sanborne, MT (32, CNC); Island Falls, 23.viti.1959,

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

S.M. Clark (19, CNC); London, Fanshawe Experimental Farm, 9-12.1982, L. Masner,
turnip field (29, CNC), and 5-30.vii.1982, L. Masner (12, CNC); Ottawa, 45°21.365'N
75°42.416'W, 5-8.x.2008, H. Goulet (19, CNC); Thunder Bay, Powells Lakes, 10.5 km NE.
Lake Superior, Law road, 16.viii.1980. M. Kaulbars, sweeping, CNCH YM07463 [barcode
failed] (1¢, CNC). Waterloo, 4.ix.1977, L. LeSage (19, CNC). Prince Edward Island.
Charlottetown, 4-18.viii.1991, M.E.M. Smith, rutabaga field, YPT, (19, CNC); Harrington,
18-22. vill. 1988, 18-24.vii, 23.vil-8.vill, 7-21.vili.1989, M.E.M. Smith, potato field, YPT
(52, 14, CNC); North Tryon, 7.viii.1991, M.E.M. Smith, potato field, YPT (12, CNC);
near Stanope, Brackley Beach,17.vili.1988, C.M. Yoshimoto, sweeping, CNCHY M07461
(12, CNC). Quebec. Belle-Anse, 48°37.50'N 64°10.70'W, 26.vii.2008, H. Goulet, C.
Boudreault, A. Badiss, fallow field, sweeping (39, 1¢, CNC); Frelighsburg, 8.viii.1995,
N. Bostanian, orchard, YPT (12, CNC); Lac Chicobi, 18.viii.1971, A. Sauvé, MT (39,
CNC). USA. New York. Herkimer Co.: 9 mi. N. Herkimer, no date, N.F. Johnson, old
field, MT (22, 14, CNC). Ohio: Portage Co., Nelson & Kennedy State Res., 9.viii.2003, T.
Pucci (12, CLEV). Virginia. Page Co.: Shenandoah National Park, Big Meadows, 1006m,
19.ix.1980, L. Masner, B. Bowen (22, 194, CNC), 8.vii.1987, G. Gibson (24, CNC),
8.vii.1987, 1300m, J. T. Huber, sweeping (69, 54, CNC). Washington. Clallam Co.:
Olympic National Park, 4 mi. S. Elwha [River], 15.viii.1985, A.T. Finnamore, T. Thormin
(22, CNC). Pacific Co.: 6 mi. N. Raymond, 19.vii.1988, J.D. Pinto (12, CNC). Pierce Co.:
Ashford, 1-14.viii.1985 (12, CNC). Thurston Co.: Kalispell, 30.vii.1988, H.E. Andersen
(63, UCRC).

Ooctonus occidentalis Whittaker
(Figs. 14, 34, 45, 56, 71, 84, 111, 114, 133, 152, 167, 175, 180)

Ooctonus occidentalis Whittaker, 1931: 191; Peck, 1951: 411 (catalogue); Peck, 1963: 19
(catalogue); Burks, 1979: 1027 (catalogue).

Ooctonus insignis Haliday: Triapitsyn, 2010: 23, 47 (misidentifications). The two female
specimens from Alaska in CAS, one of which bears a 2009 identification label by
Triapitsyn reading “Ooctonus ?insignis” and incorrectly published as O. insignis
[without the question mark], are both O. occidentalis.

Type material. Lectotype 2 in BMNH (examined), here designated to avoid ambiguity
about the status of the type specimens of this species, on card (Fig. 14) labelled 1.
“Lectotype [purple edged circle]”. 2. “Type [red rectangular label]”. 3. “Hollyburn, B.C.
31.VHI.30 Coll. O.W.”. 4. Canada: O. Whittaker Coll. Per W.H. Storey. B.M. 1947 - 212.”.
5. “Ooctonus occidentalis Whitt. 9 Det. O. Whittaker’. 6. “B.M. Type Hym. 5.2321”. The
lectoype is mounted face down on the card with wings, legs, and antennae (dorsal view)
spread out.

Paralectotype. One female in USNM (examined), on card and mounted in same
manner as lectotype, and labelled 1. “Paratype”. 2. “Paratype No. 43554 U.S.N.M..”
3. “Hollyburn, B.C. 18.VII.28 Coll. O.W.”. 4. “Ooctonus occidentalis Whitt. 2 Det. O.
Whittaker”.

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Huber JESO Volume 143, 2012

Diagnosis. Ooctonus occidentalis is distinguished from other Nearctic species by the
combination of fl—fl, each with 2 sensory ridges, vertex with stemmaticum, propodeum
without spur, pentagonal areole with anterior median carina gradually and smoothly
bifurcating posteriorly, and plica clearly and uniformly bowed outwards and meeting
propodeal margin well within lateral margins of metascutellum.

Some of the above features (stemmaticum, lack of propodeal spur and shape of
sublateral carina) occur in O. hemipterus but this is a smaller species with shorter antenna
and mps on fl, and fl, only, and the propodeum is reticulate. Oriental and Palaearctic species
that lack a spur are O. himalayus Subba Rao, O. lapen Triapitsyn, and O. spartak Triapitsyn
but they differ in other features.

Description. Female. Body length 1434-1613 (n=10). Head, flagellum except fl, and
sometimes fl, and fl,,and mesosoma dark brown; metasoma brown; scape, pedicel, fl and
sometimes fl, and fl,, petiole, and legs uniform bright yellow. Head. Head (Fig. 34) width
350-407 (n= 25) Vertex (Figs. 45, 56) with stemmaticum; mid ocellus diameter 30-36.
Antenna. Flagellum (Fig. 71) with 2 mps on fl—fl, and 7 mps on clava. FI, the longest
funicle segment. Fl —fl, length/width ratios (n=5): fl, 4, 19-5.76, fl, 3.77-4.59, fl 3.48-4.54,
ASals—-4 47 yile2 90- 3 S, fi,.2:67—3.35: Clavasis0= n 93 as long as wide, slightly shorter
than fi, =i _together, Measurements (length/width, n=5): scape 260—283/36—44, pedicel 67—
7138-41, fl, 93-110/19—23, fl, 88-106/22—23, fl, 86—-108/24—26, fl, 85—-101/23—24, fi, 90-
99/29-31, fl 86—97/29-32) ie 82-92/30-32, fl, i= 83/3742, cla 220—238/57-63. Total
flagellum length 907-1032. Mesosoma. Pronotum (Rigs 111, 114) with collar narrow, long
and clearly visible in dorsal view, with well defined carina (Figs. 111, 114). Mesonotum
(Figs. 111, 114) wide; midlobe of mesoscutum with meshes engraved; scutellar seta long,
extending well posterior to frenal line; frenum about 0.6 mesoscutellum length and entirely
reticulate, frenal line slightly concave medially. Metanotum with metascutellum smooth.
Propodeum (Fig. 133) smooth between carinae and its anterior margin without stub; median
areole well separated from metascutellum by fairly long median carina not extending to
metascutellum; plica uniformly curved, extending to metascutellum medial to its lateral
margin, and not divided anteriorly. Wings. Fore wing (Fig. 152) length 1529-1763, width
570-650, length/width 2.55—2.68, longest marginal setae 68—91, about 0.13 as long as
greatest wing width. Hind wing (Fig. 152) length 1175-1311, width 65—79. Metasoma.
Petiole shorter than metacoxa + metatrochanter. Gaster (Fig. 167, 175) with ovipositor
length 455—5S05 (n=5), 0.81—0.85* as long as metatibia (554—608).

Male. Body length 1210-1469 (n=10). Entire flagellum dark brown. Antenna (Fig.
84). Measurements, length (n=4): scape 188-202, pedicel 61—65, fl, 155-174, fl, 171-198,
fl, 164-198, fl, 165-195, fl, 166-192, fl, 168-188, fl, 166-186, fl, 162- Igoe 161-170, Li
153- 1 7Opti 147- LS: Total flagellar length 1184— 1994, Each faeelionier slightly, bottle-
shaped, distinctly wider towards base (Fig. 84). Fl, length/width 4.27—5.03, with about 8
mps. Mid ocellus diameter 34. Genitalia fairly narrow in anterior half (Fig. 180).

Hosts and habitat. Hosts are unknown. Specimens have been collected mainly in forests,
from old growth rainforest (hemlock and cedar), to deciduous forest (alder and cottonwood)
but also from a meadow. Ooctonus occidentalis has often been collected at the same times
and places as O. canadensis.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Barcoding. Two of three specimens yielded barcodes (CNCH YM07504, CNCH Y M07507),
the third did not (CNCHYM07508). There was no intraspecific variation based on DNA,
not surprisingly because the specimens were from the same collecting event. Two other
specimens were incorrectly assigned to O. occidentalis prior to barcoding. They belong to
O. canadensis.

Variation. The Alaska specimen has both antennae missing beyond fl, (and part of this
segment may also be missing) and the propodeal carinae differ slightly from other specimens.
It is identified O. occidentalis with some doubt.

Material examined. 289 and 29%. CANADA. British Columbia. Near Elk Falls,
49°08.25'N 121°48.16'W, 500m, 9.vili.2001, D. Gillespie, H. Goulet, L. Hoey, old meadow
and old growth rainforest (hemlock and cedar), CNCHYM07508 [barcode failed] (3%,
34, CNC); Manning Provincial Park, 650m, 1-10.vii.1988, S. & J. Peck (12, 1¢, CNC);
Queen Charlotte Is., Charlotte City, 9.viii.1960, W.R. Richards (1¢, CNC), Graham I.,
Masset, 9-13.vii.1983, ILM. Smith (14, CNC), Graham I., Rennel Sound, 15.vii.1983,
I.M. Smith, sweeping grasses and alders (14, CNC), Graham I., Tow Hill, 7-vii.1983, I.M.
Smith (14, CNC); Sooke, 48°23'44.6"N 123°45'55”W, 90m, 27-31.vii.2010, A. Bennett,
MT (14, CNC); Sumas Mountain Provincial Park, 29.vii.1980, G. Gibson, sweeping
(22, USNM); Terrace, 2.viii.1960, W.R. Richards (14, CNC); Tweedsmuir Provincial
Park, Bella Coola Valley, Stuie, 23.vii-4.vili.1983, I.M. Smith, meadow, pitfall trap (1°,
CNC); Vancouver, 10.vii.1988, J.R. Vockeroth (14, CNC), Pacific Spirit Provincial Park,
7.viii.1997, I. Klimaszewski, forest edge (19, CNC); Vancouver I., Lake Cowichan, 1.7
km N. of town, 24.vi1.1979, 19-28.vii.1985, I.M. Smith, at seepage area, sweeping (49,
1¢, CNC), Sayward, 1000’, 14.vi-10.xi.1984, D. Miller, PT, alder/cottonwood (19, 12,
CNC). USA. Alaska. 14 km N. Juneau, Mendenhall Valley, Dredge Lake, 17-25.vili.1999,
M. Schultz, MT (12, 24, UCRC); Sitka, 0-100m, vii.1970, N.L.H. Krauss (1¢, USNM);
Valdez, Valdez Glacier Campground, 2.viii.1978, P.H. Arnaud (2°, CAS). California. De/
Norte Co.: Crescent City, 3.viii.1940, H. & M. Townes (22, 24, AEIC); Klamath, coastal
trail, 3.viii.1985, L. Masner, sweeping, CNCHYM07504, CNCHYMO07507 (119, 112,
CNC, UCRC). Oregon. Curry Co.: Port Oxford, 10.vi1.1985, I.M. Smith, 4.6 km from
101, stream by road to McGribble Campground (32, 2¢, CNC). Washington. Clallam
Co.: Agnew, 25.vi1.1990, J.D. Pinto. Pacific Co.: 23.2 mi. S. South Bend on US 10, 8-11.
ix.1968, D.D. Munroe, MT (12, CNC).

Ooctonus quadricarinatus Girault
(Figs. 3, 6, 7, 17, 22, 35, 57, 72, 85, 95, 115, 118, 134, 140, 153, 181, 189, 192, 195-198)

Ooctonus quadricarinatus Girault, 1916b: 301; Girault, 1929: 21 (key); Peck, 1951: 411
(catalogue); Peck, 1963: 19 (catalogue); Burks, 1979: 1027 (catalogue).

Ooctonus quadrisignatus Blackman, 1915: 56 (nomen nudum).

Type material. Lectotype ¢ (Fig. 17) in USNM (examined), here designated to avoid
confusion about the identity of this species, on slide (Fig. 22) labeled: 1. “Ooctonus

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Huber JESO Volume 143, 2012

ppacaipaceees tus Gir © types.”. 2. “Ooctonus quadricarinatus Lectotype 4 des. Huber
2011”. 3. “19942”. 4. “+14 Polynema (Doriclytus) Det. J. Huber & S. Triapitsyn 2008”.
The cate pe is the most intact specimen of Ooctonus quadricarinatus (only head separated
from rest of body).

Paralectotypes. The two other, broken up males of O. quadricarinatus {and two
males of Polynema (one 1s a head + antennae only)] under one cover slip on the type slide are
designated here as paralectotypes. The types clearly are most of the specimens mentioned
by Blackman (1915), probably using a name supplied to him by Girault who then changed
his mind about the specific epithet when he described the species a year later. Blackman
(1915) incorrectly recorded the sex of the Ooctonus specimens as female but astutely noted
that the host could not be a species of Scolytidae but possibly came from eggs of tree
hoppers or leaf hoppers.

Diagnosis. Ooctonus quadricarinatus is distinguished from other Nearctic species by the
combination of large size, very dark petiole and coxae (Fig. 3), and ovipositor exserted
distinctly beyond the gastral apex.

Description. Female. Body length 1382—1843 (n=10). Head and mesosoma black, metasoma
dark brown, except petiole apically and gaster basally and ovipositor lighter brown; antenna
dark brown except radicle and scape and pedicel laterally usually yellowish; coxae, femora,
and apical tarsomere dark brown, trochanters, tibiae, and tarsomeres 1—4 usually yellowish
(Fig. 3). Mandibles brown. Head. Head width (n=4) 316-352. Vertex without stemmaticum
(Fig. 57-male). Mid ocellus diameter 27—35. eae Flagellum (Fig. 72) with | mps
(rarely 0) on fi,, 1 mps on fl, 2 mps (rarely 1) on fl, 2 mps on fl,, and 7 mps on clava;
fl, slightly the longest funicle segment. Fl —-fl, length/width ratios Ge =5): fl, 4.03-5.00, fi,
4.29- 5.70, fl, 4.08-4.98, fi, 3.94-4.61, fi, 3. 58 3.88, fl 3al0=3525 Clava 401A 7aeceallone
as wide, atl almost as [eng as half of fl, + fl, and fl, together. Total flagellum 708-758.
Measurements (length/width, n=5): scape 230- 260/30-44, pedicel 30-44/32—36, fl, 80—
90/18-22, fl, 93-105/21—25, fl, 98-107/21—24, fl, 90-99/20-24, fi, 93-98/21-27, fl, 78—
91/24—27, fl 89-94/30-32, fi, 16~ 84/3242, ead 208—227/44—SS. “Total flagellum length
905-995. Macuser! Browottinl (Figs. 115, 118) with collar moderately narrow and short
but clearly visible in dorsal view, with well defined carina. Mesonotum (Figs. 6, 7, 95, 115,
118-male) moderately wide; midlobe of mesoscutum with meshes engraved; scutellar setae
short, extending posteriorly at most to medially almost straight frenal line; frenum about
0.66* mesoscutellum length. Metanotum with metascutellum smooth. Propodeum (Fig.
134-male) smooth between carinae, and anterior margin of propodeum with a stub slightly
lateral to lateral margin of metascutellum; median areole separated from metascutellum by
fairly short median carina; plica straight, its anterior apex extending almost to stub, and with
a short bifurcation. Wings. Fore wing (Fig. 153-male) length 1508—1623, width 528-581,
length/width 2.81—2.88, longest marginal setae 63—75, about 0.13% as long as greatest wing
width (n=4). Hind wing (Fig. 153-male) length (n=3) 1156-1194, width 69-71, longest
marginal setae 94-103. Metasoma. Petiole almost as long as metacoxa + metatrochanter.
Gaster (Fig. 189) with ovipositor length 1173—1253 (n=5), 1.77—2.17* as long as metatibia
(580-683), and distinctly projecting beyond gastral apex.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Male. Body length 1152-1638 (n=10). Antenna (Fig. 85). Measurements, length
(n=3): scape 188-199, pedicel 63-69, fl, 159-164, fl, 182-194, fl, 184-200, fl, 188-190,
fl; 171-195, fi; 167—187, fi, 168-185, fi, 163-176; fi, 159-166, fl, 166-171, fl, 153-174.
Total flagellar length 1887-2027. Fl, length/width 3.82—4.73, with 8 or 9 mps. Mid ocellus
diameter 39-41. Gaster (Fig. 192). Genitalia fairly wide (dorsal view) for most of its length
(Figs. 181, 192).

Hosts and habitat. One male (Ontario, Chalk River) was recorded from Pissodes strobi
Say (Curculionidae). Additional rearing records are needed to confirm the weevil host.
Many specimens have been obtained from stumps, logs or forests of Pinus [some infested
with Jomicus piniperda (L.)], others from meadows or openings in forests and two from
grassland and plankton netting. The latter two specimens were evidently collected during
dispersal. Blackman (1915) collected the type series from Pinus strobus L.

Barcoding. Four of five specimens yielded barcodes (CNCH YM07470, CNCHY M07471,
and CNCHYM07472, CNCHYM07473) and one did not (CNCHYM07469). There was
slight variation in DNA among the specimens.

Material examined. 349 and 74¢. CANADA. New Brunswick. Queen’ Co.: 25 km
W. Canaan Forks, hwy. 112, 19.viii.1984, M. Kaulbars (14, CNC). Albert Co.: Fundy
National Park, Chignecto campsite, 6-10.viii.2009, J. Fernandez, YPT (24, CNC). Kent
Co., Kouchibouguac National Park, 18.v.1977, G.A.P. Gibson (3, CNC). Nova Scotia.
Bay of Fundy, 21.viii.1979, A. Locke, from plankton sample (12, CNC); Kejimkujik
National Park, Peter’s Point, 44.36571°N 65.19624°W, 2.vi11.2009, J. Fernandez, mixed
forest, swamp, CNCHYM07469 [barcode failed], CNCHYM07470, CNCHYM07472,
CNCHYM07473, (12 and 5 4, CNC). Ontario. Alfred Bog, 29.vii.1984, M. Sanborne
(1d, CNC); 5 mi. E. Camden East, 44°20’19”"N 76°47°46”W, 1-8.viii.1997, P. Bouchard,
grassland, MT (12, CNC); Chalk River, 18.viii.1951, J.M. Anderson, ex Pissodes strobi
(1g, CNC); near Clayton, 12.viii.1981, C. Babcock, H. Goulet (39 and 24, CNC);
Constance Bay, 6-23.vii, 12-24.viii, and 26.viii-7.ix.1983, M. Sanborne (1 Qand 4°, CNC):
near Flanboro, Lawson Farm, 21-30.ix.1996, alvar, B. DeJonge, MT (12, CNC); Guelph,
ex trap logs of Scots and Jack pines infested with Zomicus piniperda, collected 24.111-29.
vi.1998, em. 21 and 30.vii.1998 in laboratory, K. Ryall (39 and 74, ROM, CNC) and 20 km
S., Reid Property, 23.vii-8.viii.1998, K. Ryall, ex Pinus sylvestris log (692 and 20¢, CNC);
Haliburton Forest and Wildlife Reserve, 45°15’N 78°35’W, 7 and 8.viii.2001, C. Vance,
pine forest, MT (22, CNC); Hamilton, 14-22.viii.1981, M. Sanborne (1°, CNC); London,
1-17.ix.1972, A. Tomlin, pine hedgerow (14, CNC), Fanshawe Experimental Farm, 10-31.
Vii, 5.ix.-2.x.1981, 4-25.viii.1982, A. Tomlin (12 and 34, CNC); Nepean, Bruce Pit, 1-14.
xi.1993, and Merivale Gardens, 1-11.xi.1984, L. Masner, YPT (2°, CNC); Palgrave, SE. Of
Orangeville, 1.viii.1998, K. Ryall, ex Pinus sylvestris log (24, CNC); Rockton, |.viii.1998,
K. Ryall, ex Pinus sylvestris log (1¢, CNC); Rondeau Provincial Park, 13.viii.1980, C.M.
Yoshimoto (12, CNC), near hwy. 16, 44°47712”N 75°30°38”W, 16-22.viii, 27.ix-5.x.1994,
L. Masner, YPT CNCHYM07471 (34, CNC); Woodside, 27.viii.2007, ex Pinus sylvestris
log, P. DeGroot (14, CFS-Great Lakes). Prince Edward Island. Millvale, 46°25'7"N
63°26'22"W, river, 30.viii.1992, J. Heraty. Quebec. Gatineau Park, 26.vili.1987, sweeping,

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Huber JESO Volume 143, 2012

and vil-vili. 1989, L. Masner, emergence trap over pine stump (29, CNC), Luskville Falls,
300m, 12-19.vili, 25.vili-2.i1x.1986, J. Denis, L. Dumouchel, blueberry fields in oak-conifer
clearing, YPT (2¢, CNC), near Luskville Falls, 27.vii-4.viii.1992, CNC Hym team (16,
CNC). USA. Alabama. Baldwin Co.: Tensaw, 31.17°N 87.72°W, 15.xii.2004, E. Benton
(ly, CNC). Arkansas. Johnson Co.: 12 mi. NE. Clarksville White Road Spring, 11.viii-6.
ix.1994, G. Leeds, YPT (14, CNC). New York. Otsego Co.: Oneonta, 1900’, 18.viii.1935,
H.K. Townes, swamp (1¢, AEIC). North Carolina. 14 mi. NW. Highlands, Nantahala
National Forest, 3500’, 27.1x.1980, L. Masner and B. Bowen (19, CNC). South Carolina.
Aiken Co.: no locality given, 3.viii.1998, J.P. Pitts (1¢, CNC). Tennessee. Blount Co.:
Great Smoky Mountains National Park, Top of the World, 35°38’N 83°55'W, 670m, 2-16.
vii. 1998, H. Alley, old growth pine, MT (6¢, CNC). Henderson Co.: Lexington, Natchez
Trace State Park, 11-15.vi.1972, G. Heinrich, MT (14, CNC). Virginia. Essex Co.: 1 mi.
SE. Dunnsville, 37°52'N 76°48'W, 14.111-3.iv, 12-21.vi, 3-20.vili.1996, D.R. Smith, MT
(592, 2¢, USNM). Hardy Co.: 3 mi. NE. Mathias, 38°55'N 78°49'W, 2-16.vii, 17.vii-2.viii,
22.vii-13.ix, and 14.ix-14.x.2002, D.R. Smith, MT (59 and 14, CNC). Louisa Co.: 4 mi.
S. Cuckoo, 15.vi.1985, J. Kloke, D.R. Smith, MT (192, USNM). Montgomery Co.: 8 mi.
N. Blacksburg, 1000m, 24.x-8.xi.1987, MT (1¢, CNC); Page Co.: Shenandoah National
Park, Big Meadow, 1300m, 8.vii-20.viii.1987, CNC Hym. Team, MT (1¢, CNC), Skyline
Parkway S., 610-915m, 20.ix.1980, L. Masner and B. Bowen (12, CNC).

Ooctonus readae Huber, sp. n.
(Figs: 2, 8,10; 23,36; 58; 73; 86,94, 116) 1195135) 154368y 1769190)

Type material. Holotype (CNC), on slide (Fig. 23) labeled: 1. “Canada: ON, Buckham’s
Bay, 45.4985°N 76.1108°W, 15-20.v.2010, J. Read, MT”. 2. “Ooctonus readae Huber
Holotype & dorsal”.

Paratypes. 439 and 20¢. CANADA. Ontario. Buckham’s Bay, 45.4985°N
76.1108°W, 15-20.v CNCHYM07465 [barcode failed], 21-28.v.2010 CNCHYM07466
[barcode failed], J. Read, MT (302, 94, CNC); 5 km NW. Almonte, hwy 49, Burnt Lands
Provincial Park, 45°5.29'N 76°08.39'W, H. Goulet, J. Frenandez, 29.v.2008, alvar, sweep
(42, 84, CNC); North Gower to Smiths Falls, 45°02’N 75°54'W, 14-16, 17-19.v.2004, A.
Bennett, D. Barnes, MT (592, 14, CNC); Ottawa, 45°21.365'N 75°42.426'W, 24-30.v.2007
CNCHYM07464, 1-15.v.2010, H. Goulet, city garden, MT, (49, 24, CNC)

Derivation of specific epithet. The species is named after Jennifer Read, an excellent
technician who has produced outstanding digital images for my publications on
Mymaridae.

Diagnosis. Ooctonus readae is distinguished from most other Nearctic species by the
frenum medially smooth or almost so (with reticulate sculpture much weaker or absent
medially than laterally), a feature shared with O. silvensis and O. vulgatus.

Ooctonus readae differs from O. vulgatus by its larger ocelli (smaller in O.
vulgatus), smaller eye (larger in O. vu/gatus), longer marginal vein (shorter in O. vu/gatus),
shorter and relatively wider fl,, and narrower pentagonal areole that does not extend to the
metascutellum (wider areole extending to metascutellum in O. vulgatus). Ooctonus readae

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

differs from O. silvensis by the presence of mps on fl, and fl, (mps absent on fl, and usually
on fl, in O. silvensis).

Description. Female. Body length 1024-1178 (n=10). Head and mesosoma dark brown,
almost black, petiole brownish yellow, metasoma very dark brown; radicle yellow, scape
laterally and ventrally and pedicel apically brownish yellow, flagellum dark brown; legs
yellowish, almost always with strong brown suffusion medially on femora and tibiae and
sometimes procoxa; apical tarsomere of each leg dark brown (Fig.2). Head. Head (Fig. 36)
width 295-309 (n=5). Vertex (Fig. 58) without stemmaticum; mid ocellus diameter 21—26;
LOL about 2.5. Antenna. Flagellum (Fig. 73) with | mps on fl,, usually | (sometimes 0) mps
on fl,, and 2 mps on fl, and fl,. Fl, and fl, equally long, slightly the longest funicle segments.
Fl, fi, length/width ratios (n=5): fl, 2:3 2=3).00! fly 1k97=2:37; MAS 2027 fl u8S= 2S he
Ii 88- 2 12, fi, 1.35—-1.68; clava 3. 09- 3.31 as long as wide, he slightly eae than fl,- fi,
together. Measurements (length/width; n=5): scape 189-204/40-43, pedicel 66—71/35— 26,
fl, 51-60/19-24, fl, 47-53/21—24, fl, 48-55/23—25, fl, 41-47/21—24, fl, 51-59/25-30, fi,
42-48/26- 30, fl, AS=5i1/313i1s fl, 46- 52/36-39, eilana 165—175/50- 59. Total flagellum
length 539-600. Mesosoma. Pronotiim (Figs. 116, 119) with collar wide, moderately long
and clearly visible in dorsal view, with well defined carina. Mesonotum (Figs. 94, 116, 119)
wide; midlobe of mesoscutum with meshes engraved; scutellar setae fairly short, extending
slightly posterior to medially almost straight frenal line; frenum 0.60—0.68* mesoscutellum
length and smooth or almost so medially, reticulate laterally. Metanotum with metascutellum
smooth. Propodeum (Figs. 8, 135) smooth between carinae; anterior margin with stub just
lateral to lateral margin of metascutellum; median areole separated from metascutellum
by median carina; plica straight or slightly curved outward and not divided anterodorsally,
ending just anterior to stub. Wings. Fore wing (Figs. 18, 154) length 1137-1194, width
395-412, length/width 2.86—2.97, longest marginal setae 62—71, about 0.17* as long as
greatest wing width (n=5). Marginal/stigmal vein 117—134, about 0.5 submarginal vein
length. Hind wing (Fig. 154) length 864—921, width 49-62, longest marginal setae 98—107.
Metasoma. Petiole as long as metacoxa. Gaster (Fig. 168, 176, 190) with ovipositor length
415-509 (n=5), 1.02—1.19x as long as metatibia (397-427).

Male. Body length. 973-1075 (n=10). Antenna (Fig. 86). Measurements, length
(n=1): scape 158, pedicel 66, fl, 103, fi, 104, fl, 104, fl, 102, fl, 107, fi, 103, fl, 104, fl, 102,
fi, 104, fl, 84, fl,, 91. Total Aree la length 1095. Bl length width 3. 67 and ae 6(72) mps.
Mid pceilus Gemerer 25!

Barcoding. One of three specimens yielded barcodes (CNCHYM07464) and two did not
(CNCHY M07465 and CNCHYM 07466) even though they were collected into 95% ethanol

in a Malaise trap in 2010, so intraspecific variation based on DNA cannot be assessed.

Hosts and habitat. Hosts are unknown. The type series came from a Malaise trap located
on a sandy lawn at the edge of a deciduous/coniferous forest.

AT

Huber JESO Volume 143, 2012

Ooctonus silvensis Girault
(Figs. 4, 16, 24, 36, 59, 74, 87, 96, 117, 120, 136, 165, 169, 177, 182, 194)

Ooctonus silvensis Girault, 1916a: 70; Girault, 1929: 22 (key); Peck, 1951: 411 (catalogue);
Peck, 1963: 19 (catalogue); Burks, 1979: 1027 (catalogue).

Type material. Holotype Y in USNM (examined), on slide (Fig. 24) labeled: 1. “Ooctonus
silvensis Girault. Y type”. 2. “19375”. The holotype is in poor condition, crushed and
broken up (Fig. 16) under one cover slip.

Diagnosis. Ooctonus silvensis females are distinguished from most other Nearctic species
by the frenum mostly smooth except laterally (Fig. 117), a feature shared with O. readae
and O. vulgatus.

Ooctonus silvensis differs from O. vulgatus by its longer marginal vein (shorter
in O. vulgatus), larger ocelli (ocelli minute in O. vulgatus), shorter and relatively wider fl,
(longer and narrower in O. vulgatus), and narrower pentagonal areole that does not extend
to the metascutellum (wider areole extending to metascutellum in O. vulgatus). Ooctonus
silvensis differs from O. readae by the absence of mps on fl, and fl, (mps present on fl, and
usually on fl, in O. readae).

Description. Female. Body length 850-1019 (n=10). Head and mesosoma black (fresh
specimens) or very dark brown (faded specimens), petiole brownish yellow, metosoma
brown; radicle yellow, scape laterally and ventrally and pedicel apically brownish yellow,
flagellum brown; procoxa and tarsomeres 5 brown, meso- and metacoxa and all femora and
tibiae yellowish brown but yellowish at apices, trochanters and tarsomeres 1-4 yellow (Fig.
4).

Head. Head (Fig. 37) width 251-270 (n=5). Vertex (Fig. 59) without stemmaticum; mid
ocellus diameter 24, LOL about 2.0 greatest diameter of ocellus.

Antenna. Flagellum (Fig. 74) with 2 mps on fl, and fl,, and 7 mps on clava. FI, slightly
the longest funicle segment. Fl —fl, length/width ratios (n=5): fl, 2.33-3.30, fl, 1.70-2.24,
fl, 1.60—2.04, fi, 1.55—2.02, fl, 1.42—1.82, fi, 1.39-1.51; clava 2.68-3.34x as long as wide,
and slightly shorter than fl—fl, together. Measurements (length/width): scape 169—182/
34-38, pedicel 59-61/31-35, fi, 49=51/16=20;nile 3540/1721 E4220 ea
35-39/21—23, fl, 40-42/23—24, fl, 3638/2426, fil, 48-51/29—34, fi, 4448/3240, clava
158—173/51—59. Total flagellum length 482-524. Mesosoma. Pronotum (Figs. 117, 120)
with collar moderately wide and short but clearly visible in dorsal view, with well defined
carina. Mesonotum (Figs. 96, 117, 120) very wide; midlobe of mesoscutum with meshes
engraved; scutellar setae short, extending at most to slightly posterior to medially almost
straight frenal line; frenum about 0.7* mesoscutellum length and smooth medially, reticulate
laterally. Metanotum with metascutellum smooth. Propodeum (Fig. 136) smooth between
carinae; anterior margin with stub just lateral to lateral margin of metascutellum; median
areole separated from metascutellum by median carina; plica straight and not divided
anterodorsally, ending just anterior and medial to stub.

Wings. Fore wing (Fig. 155, 156) length 1010-1088, width 318-363 (n=5), length/width
3.00-—3.25, longest marginal setae 76-92, about 0.24 as long as greatest wing width (n=5).

48

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Marginal/stigmal vein 118-131, at least 0.51* submarginal vein length. Hind wing length
795-816, width 42-52, longest marginal setae 76-98. Metasoma. Petiole shorter than
metacoxa + metatrochanter. Gaster (Fig. 169, 177) with ovipositor 311—367 long (n=5),
1.03—1.08* metatibia length (323-359).

Male. Body length. 840-1126 (n=10). Antenna (Fig. 87). Measurements, length
(n=4): scape 141-146, pedicel 60-63, fl, 75—89, fl, 72—96, fl, 76-95, fl, 79-95, fl, 80-93, fl,
79-94, fl, 82-98, fl, 82-95, fl, 88-99, fl,, 87-108, fl,, 90-100. Total flagellar length 1049
1067. Fl, length/width 3.0-3.2, with 7 (8?) mps. Mid ocellus diameter 21. Genitalia very
wide for its entire length (Fig. 182, 194).

Hosts and habitat. Hosts are unknown. Ooctonus silvensis has been collected mainly in
forested areas but also open field or ‘prairie’ type areas. Label data include mesic hardwood
forest, pine/oak savannah, hardwood forest/beaver swamp, meadow, upland deciduous
forest/field ecotone, ‘prairie’, hardwood forest and swamp.

Barcoding. Three of the ten specimens | identified as O. si/vensis or near O. silvensis based
on morphology yielded a barcode (CNCHYM07491, CNCHY M07496, CNCHYM 07498)
and seven did not (CNCH Y M07489, CNCH Y M07490, CNCH Y M07492, CNCHY M07493,
CNCHYM07494, CNCHY M07495 and CNCHY M07497). There was very little variation
between two barcodes (one from Florida and one from Missouri). The specimen from Guelph
with an almost complete barcode (Fig. 200: 0OOBBHY M-696) is intermediate between the
Florida and Missouri ones. On this basis I consider that all three specimens belong to O.
silvensis.

Material examined. 1269 and 46¢. CANADA. Ontario. 2 mi. SE. Innisville, 45°3'N
76°15'E, 12-19, 19-26.vi.1991, L. Masner, J. Denis, MT and YPT (22,, CNC); St. Lawrence
Islands National Park, Grenadier Island, Centre, 11.vi.1975, E. Sigler (19, CNC),
16.vi.1975, R.J. McMillan, CNCHYM07490 [barcode failed] (19, CNC), 27.vi.1979, G.
Gibson (12, CNC). Quebec. Mont Pinnacle near Frelighsburg, 20.vi.1991, M. Sharkey
(12, CNC); Pare de la Gatineau, 2 km W. chemin Pilon, 8-14.vii.1992, and 2 km E. chemin
Pilon, 26.v-2.vi.1992, CNC Hymenoptera Team, CNCHYM07489 [barcode failed] (2°,
CNC). USA. Colorado. 1563, C.F. Baker [no other data] (19, 1¢, USNM). Florida.
Alachua Co.: Gainesville, AEI, 3-12.x.1986, J. Allen (14, CNC), 20-27.xi.1986, 18-25.
Iv, 25.vi-3.vii. 1987 CNCHYM07492 [barcode failed], 20.xi.87-20.ii.1988, D.B. Wahl, FIT,
(10, 24, CNC), 1-7.xii CNCHYM07491, 21-31.xii.1986, 1-11.i, 12-20.i, 20-30.i, 15-22.
ii, 1-15.iii, 18-22.iii, 23-31.1987 W.R.M. Mason (1692, 34, CNC), 12-20.i.1987, L. Masner,
mesic hardwood forest, MT (39, 1¢, CNC), vi-vii, 3-17.vii.1987, CNC Hymenoptera Team
(22, CNC). Wakulla Co.: Apalachicola National Forest, 30°19.751'N 84°30.309'W, 13-
20.v1.2005, F. Ronquist, pine/oak savannah, MT (12, UCRC), hwy 65, post office bay,
30°03.565'N 84°59.057'W, 12-20.v.2005, S. Joshi, A. Deans, D. Murray, MT (14, UCRC).
Georgia. Clarke Co.: Athens, 25-30.iv.1987, beaver swamp (14, CNC), 1.x-23.xi.1987,
hardwood forest, beaver swamp (1d, CNC). Union Co.: Cooper’s Creek, WMA, 655m,
34°45'56"N 84°05'46"W, 15.v.2002, D. Yanega (14, UCRC). Illinois. Union Co.: Shawnee
National Forest, ca. 2 and 15 mi. S Murphysborough, roadside of route 127, 14.iv.2004, R.
Rakitov, meadow, vacuum (22, 14, UCRC). Maryland. Calvert Co.: Port Republic, viii-

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Huber JESO Volume 143, 2012

ix.1986, M. Sharkey, MT (49, CNC); 4 mi. S. Prince Frederik, 16.iv-7.v.1987, L. Masner,
MT (32, 1¢, CNC), 7 km S. Prince Frederick, 24.ix-14.xi.1987, CNC Hymenoptera Team,
hardwood forest, MT, CNCHYM07493 [barcode failed] (19, CNC). Prince George's Co.:
Patuxent Research Station, 6-20.x.1980, M.E. Schauff, upland deciduous forest/open field
ecotone, MT (119, 1¢, USNM). Mississippi. Bolivar Co.: 19 km W. Boyle on hwy 446,
Dahomey Wildlife Reserve, 33°42'’N 90°56'W, 8-24.vil.1997, N.M. Schiff, MT (12, CNC).
Missouri. Wayne Co.: Williamsville, 21.x-11.x1.1987 CNCHYM07498, 111.1988, 1.xi-10.
xii. 1988, J.T. Becker, MT (172, 1¢, CNC). Ohio. Franklin Co.: Columbus, Kinnear Road
“prairie”, 1-16.1x, 2-10.x.2003, N.F. Johnson, MT (19, CNC). Oklahoma. Latimer Co.: Red
Oak environs, xi.1994, K. Stephan, FIT, CNCHY M07496 (62, 24, CNC). Texas. Kerr Co.:
Kerrville State Recreation Area, 1800’, 1.vii.1982, G. Gibson (14, CNC). Brazos Co.: Lick
Creek Park, 25.v.1989, G. Zolnerowich (14, CNC). Bastrop Co.: Bastrop State Park, 24-
27.v.1983, M. Kaulbars (19, 1¢, CNC). Robertson Co.: 8 mi. E. Hearne, 1-21.iv.1991, M.
Hallmark, MT (19, CNC). San Patricio Co.: Welder Wildlife Foundation Refuge, 4.x1i.1999,
hackberry forest and swamp, L. Masner, sweeping, CNCHYM07497 [barcode failed] (39,
44, CNC), 28°6'42""N 97°24'24"'W, 1 .ii-1.ii11.2004, S. Peck, MT (49, 44, UCRC). Virginia.
Fairfax Co.: near Annandale, 6-12.v, 20-26.v.1990, D.R. Smith, MT (29, USNM). Hardy
Co.: 3 mi. NE. Matthias, 38°55'N 78°49'W, 17.iv-3.v.2002, D.R. Smith, MT (12, CNC).
Louisa Co.: 4 mi. S. Cuckoo, 13-27.v.1987, 29.111-11.iv, 27.v-7.vi, 8-18.vi.1988, J. Kloke,
D.R. Smith (99, 42, USNM). Montgomery Co.: 8 km NW. Blacksburg, 1000m, 18-28.iv,
8.1v-9.v, 9-19.v, 29.v-9.v1 CNCHYM07494 and CNCHYM07495 [both barcodes failed],
9-19.vi, 19-30.vi, 29.1x-12.x, 8-25.1x, 12-24.x, 24.x-8.x1.1987, CNC Hymenoptera Team,
rural area, MT (199, 134, CNC).

Ooctonus triapitsyni Huber, sp. n.
(Figs: 255 38, 609755 12 123 1372 si alO))

Type material. Holotype ° (CNC), on slide (Fig. 25) labelled 1. “Canada: AB, Writing-on-
Stone, Prov. Park 13-18.vii.1990, D. McCorquodale, sage south”. 2. “Ooctonus triapitsyni
Huber Holotype ¥ dorsal”.

Paratypes. 362 and 16¢. CANADA. Alberta. Lethbridge, Agriculture Canada
Research Station, 9-15.vii.1980, G. Gibson, PT (12, 64, CNC); 16 mi. S. McGrath,
McIntyre Ranch, 27.vii-2.viii, 26.viii-9.ix.1990, D. Griffith, PT (89, 34, CNC); Tolman
Bridge Recreation Area, 17 km E. Trochu on hwy 585 near Red Deer River, 16-18.
vii.1989, J. O'Hara (12, 14, CNC); Writing-on-Stone Provincial Park, 20-30.vii.1981,
D. McCorquodale, PT (19, CNC); 5 mi. W. Writing-on-Stone Provincial Park, Milk
River Valley, 15.vii.1980, G. Gibson, sweeping (12, CNC); 0.5 km E. Writing-on-Stone
Provincial Park, 5-13.vii, 30.viii-ix.1981, D. McCorquodale, PT (22, CNC). Ontario.
3.5 km E. Almonte, 25-29.v.1993, F.W. Grimm, MT & PT, alvar, F.W. Grimm (39, 10,
CNC). Quebec. Gatineau Park, Luskville Falls, top, 11.ix.1985, H. Goulet (29, 14, CNC);
Luskville Falls, 300m, 8-15.vii.1986, J. Denis, L. Dumouchel (29°, CNC). Saskatchewan.
Saskatoon Landing, 23.vi.1956, O. Peck (19, CNC). USA. Alaska. Fairbanks, Badger road
near North Pole, 18.vii.1985, H. Andersen (29, UCRC), University of Alaska campus,
19.vii.1985, H. Andersen, CNCHYM07523 [barcode failed] (32, 1¢, CNC). Arizona.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Cochise Co.: Huachucha Mts., Ash Canyon road, 0.5 mi. W. hwy 92, 5100’, viii and 1-11.
xi.1993, N. McFarland, MT, CNCHYMO07512 [barcode failed], CNCHYM07513 (6%,
24, UCRC); 12 mi. S. Sierra Vista, Ramsey Canyon, 1700m, 6-13.vii, 4-22.1x.1986, B.V.
Brown, MT, oak/juniper (29, CNC). Santa Cruz Co.: Sycamore Canyon, Harkt and Yank
Spring, 4200’, 7-8.vii.1982, G. Gibson, CNCHYM07409 [barcode failed] (1¢, CNC).
South Dakota. Charles Mix Co.: Pickstown, 26.vii.1985, J.D. Pinto (19, 14, CNC).

Derivation of specific epithet. The species is named after Serguei Triapitsyn, entomology
collection manager, University of California, Riverside, a good colleague who has published
many papers on Mymaridae.

Diagnosis. Ooctonus triapitsyni is distinguished from other Nearctic species by the
combination of 2 mps on fl,—fl,, (sometimes only | mps on fl,), uniform yellow leg colour,
ovipositor longer than metatibia length, and body length greater than about 1075.

Ooctonus triapitsyni is most similar to O. readae and O. notatus but differs from
the former by the uniform yellow legs (brownish in O. readae) and presence of one or two
mps on fl, (none in O. notatus). An occasional specimen appears to lack mps on f1,, as in O.
notatus, but O. triapitsyni has a longer body (at least 1075) compared to O. notatus (at most
1000).

Description. Female. Body length 1075—1331 (n=10). Head and mesosoma very dark
brown, metasoma brown; fl —fl, light brown to brown, remainder of flagellum dark brown;
petiole, legs except apical tarsomere, scape and pedicel uniform yellow.

Head. Head (Fig. 38) width (n=10) 305-352. Vertex (Fig. 60) without stemmaticum. Mid
ocellus diameter 19-24.

Antenna. Flagellum (Fig. 75) with 2 mps on fl,, fl, and fl,,and 7 mps on clava, fl, with |
mps but occasionally (3 of 7 specimens measured) | and 2 mps on the same individual, and
exceptionally (1 of 10 specimens measured) with 2 mps on each antenna. FI. slightly longer
than the remaining funicle segments. Fl—fl, length/width ratios (n=5): fl, 2583.09, fi,
2.38-2.89, fl, 2.13—2.75, fi, 1.72-2.19, fl, 1.58—-2.07, fi, 1.45—1.81; clava 3.34-4.29x as long
as wide, and slightly shorter than fl,—fl, together. Measurements (length/width, n=10): scape
210-249/34 44, pedicel 62—75/32-A1, fl, 57-64/20—23, fl, 52-62/21—26, fl, 55—65/24-29,
fl, 42—-63/24—30, fl, 56—70/32—36, fl, 48-63/31—37, fl, 54—70/35—39, fl, 5163/3842, clava
200—236/53—S6. Total flagellum length 615-756. Mesosoma. Pronotum (Figs. 121, 123)
with collar moderately narrow and short but clearly visible in dorsal view, with well defined
carina. Mesonotum (Figs. 121, 123) wide; midlobe of mesoscutum with meshes raised;
scutellar seta short, extending just posterior to medially straight frenal line; frenum about
(0.66 mesoscutellum length and entirely reticulate. Metanotum with metascutellum smooth.
Propodeum (Fig. 137) smooth between carinae and its anterior margin with a stub; median
areole separated from metascutellum by a very short to slightly longer median carina;
plica straight, with a very short bifurcation anteriorly (median arm slightly longer than
lateral arm), extending to apex of stub almost in line with or just lateral to lateral margin
of metascutellum. Wings. Fore wing (Figs. 155, 156) length 1097-1313, width 352-436,
length/width 2.82—3.24, longest marginal setae 25-50, about 0.06—0.13* as long as greatest
wing width (n=10). Marginal vein length 124-149. Hind wing (Figs. 155, 156) length

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Huber JESO Volume 143, 2012

870-985, width 49-54, longest marginal setae 95-108. Metasoma. Petiole shorter than
metacoxa + metatrochantellus. Gaster (Fig. 170) with ovipositor length 548-634 (n=10),
1.16—1.40x as long as metatibia (408-479).

Male. Body length 998-1254 (n=5). Legs slightly darker yellow than in female,
scape and pedicel with brown especially dorsally, flagellum uniformly brown. Antennal
measurements, length (n=3): scape 188-192, pedicel 59-65, fl, 104-111, fl, 107-127, fl,
109-131, fl, 110-128, fl, 112-127, 1, 109-125, fi. NO7—125; fi; LOG=107, Ae Og igen
106-113, fl,, 110-117. Total flagellar length 1160-1329. FI, length/width 3.06—4.12 and
with 7 or 8 mps. Mid ocellus diameter 26-29.

Barcoding. One of the specimens (CNCHYM 07513) yielded barcodes so
nothing can be said about intraspecific variation based on DNA. The specimen is treated as
unassigned in Table 2; it may actually belong to O. arizonensis.

Hosts and habitat. Hosts are unknown. Specimens were collected in the boreal forest, and
in prairie (G. Gibson, personal communication).

Ooctonus vulgatus Haliday
(Figs. 5,39, 61, 76588; 122, 124.138; 158; 1711185; sl86)

Ooctonus vulgatus Haliday, 1833: 344; lectotype 2 in NMID (not examined), designated by
Hincks, 1952: 157. Type locality: likely England or Ireland. Synonyms and their
types treated by Triapitsyn (2010).

Ooctonus vulgatus Haliday: Foerster, 1847: 197, 200 (mouthparts, description); Ratzeburg,
1848: Plate 3, Fig. 27 (fore wing, male antenna); Schmiedeknecht, 1909: 490
(catalogue); Kloet and Hincks, 1945: 305 (checklist, Britain); Kryger, 1950: 78
(list); Bouéek and Graham, 1978: 109 (checklist, Great Britain); Trjapitzin, 1978:
524 (taxonomy, European distribution); Viggiani and Jesu, 1988: 1023 (doubtful
host record); Kalina,1989: 127 (checklist, Czechoslovakia); Hansson, 1991: 49
(Sweden checklist); Triapitsyn 2010: 54 (redescription, literature, synonyms,
misidentifications), 56 (records from Canada and USA); Huber et al. 2010: 231
(New Zealand records).

Ooctonus americanus Girault 1916a: 69; Girault, A.A. 1929: 21 (key); Whittaker, 1931: 192
(key); Peck, 1951: 410 (catalogue); Weaver and King, 1954: 17 (host, parasitism
rate); Burks, 1958: 62 (reference correction); Peck, 1963: 18 (catalogue); Burks,
1967: 213 (catalogue, host); Burks, 1979: 1027 (catalogue, host); Triapitsyn 2010:
54 (synonymy).

Ooctonus askhamensis Hincks, 1952: 156; Kalina, 1989: 127 (checklist, Czechoslovakia).

Ooctonus auripes Whittaker, 1931: 190; Peck, 1951: 410 (catalogue); Burks, 1979: 1027
(catalogue); Triapitsyn, 2010: 28 (synonymy under nofatus). Syn. nov.

Ooctonus sp.: Triapitsyn 2010: 54 (species identification, New Zealand records); Huber et
al., 2010: 231 (New Zealand records).

Type material. Ooctonus americanus. Holotype ° in USNM (examined), on slide labeled:
1. “Ooctonus americanus. Girault 9 type.”. 2. [red label] “19353.”. The holotype is

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

in poor condition, crushed and partly broken up (Fig. 16) together with a specimen
of Gonatocerus (Lymaenon) under one cracked cover slip.

Ooctonus auripes. Lectotype ° (BMNH, examined), here designated to avoid ambiguity
about the status of the one specimens of this species, on card His 1. “Lectotype
[purple edged circle]”. 2. “Type [red rectangular label]”. 3. “Chilliwack, B.C.
1553826. Goll.O:W.? 4" one O. Whittaker Coll. per W. r Storey. B.M. 1947
- 212.”. 5. “Ooctonus auripes Whitt. 9 Det. O. Whittaker”. 6. “B.M. Type Hym.
5.2319”. Type mounted (Fig. 11) on said with wings, legs, ms antennae (in dorsal
view) spread out but metasoma missing.

Triapitsyn (2010: 28) synonymized O. auripes under O. notatus, based on
examination of the paralectotype. The lectotype (Fig. 11) is a different species that matches
O. vulgatus. Ooctonus auripes is therefore placed here in synonymy under O. vulgatus
instead.

Diagnosis. Ooctonus vulgatus is distinguished from other Ooctonus species by the single
row of bullae inside the female clava (Fig. 76). Otherwise, it is similar to O. notatus, O.
silvensis, and O. readae in size but differs by antennal proportions, mps distribution, ocelli
size, frenum sculpture, marginal vein length, and propodeal carinae pattern.

Description. Female. Body length 691—1075 (n=10). Head and mesosoma almost black
(fresh specimens) or very dark brown (faded specimens), petiole brownish yellow, metasoma
dark to light (almost yellowish) brown; radicle yellow, scape laterally and ventrally and
pedicel apically brownish yellow, flagellum brown; legs almost entirely brown to entirely
yellow except apical tarsomere of each leg. Head. Head width 245-290 (n=5). Vertex
without stemmaticum; mid ocellus minute, diameter about 16. LOL at least 4= greatest
diameter of mid ocellus. Antenna. Flagellum (Fig. 76) with 2 mps on fl, and on fl,,and 7 mps
on clava. Fl, slightly the longest funicle segment. Fl —fl, length/width ratios (n=5): fl, 3.05—
4.42, fl, 2.69-4.08, HEE OS—21695 fh 152-22 il. 137 1.80, fi, 1.35—-1.64; clave. 3.5x
as long. as wide, and about as long as fl,—fl, together, with a anal row of about 6 abutting
spherical bullae internally along ventral margin. Measurements (length/width, n=5): scape
161-186/23—30; pedicel 51—61/29—33, fl, 50—59/12-17, fl, 45—58/14—17, fl, 41-53/18—23,
iy 30-37/16-20; fl, 30—36/18—23, fi, 29— 36/21 = 23H 42— 50/25-30, fl, 41-45/28- 30, clava
M4 132/36—46. Total flagellum length 422-506. Mecosurm Bonen (Figs. 122, 124)
with collar moderately wide and short but clearly visible in dorsal view, with well feared
carina. Mesonotum (Figs. 122, 124) very wide; midlobe of mesoscutum with meshes raised;
scutellar seta short, extending at most slightly posterior to medially almost straight frenal
line; frenum about 0.7* mesoscutellum length and apparently smooth medially (at most very
faintly reticulate), reticulate laterally. Metanotum with metascutellum smooth. Propodeum
(Fig. 138) smooth between carinae; anterior margin with stub slightly lateral to lateral
margin of metascutellum; median areole abutting metascutellum, the median carina absent
and replaced by the two carinae forming inner margin of dorsolateral areoles; plica almost
straight and not divided anterodorsally, ending just anterior and medial to stub. Wings. Fore
wing (Fig. 158) length 862-1049, width 266-375 (n=5), length/width 2.69-3.26, longest
marginal setae 49-77, about 0.19 as long as greatest wing width. Marginal /stigmal vein

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Huber JESO Volume 143, 2012

80-94, at most 0.48 submarginal length. Hind wing length 668-802, width 35—49, longest
marginal setae about 2.26* greatest wing width. Metasoma. Petiole shorter than metacoxa.
Gaster (Fig. 171) with ovipositor 368-464 long (n=5), 1.14—-1.27< as long as metatibia
(357-403).

Male. Body length. 794-1152 (n=3). Antenna (Fig. 88). Measurements, length
(n=3): scape 153-159, pedicel 58-63, fl, 69-72, fl} 87-103, fi, 87-103) fl, 19=947 ieee
106, fl, 85-103, fl, 86-99, fl, 86-94, fl, 90-93, fl, 85-88, fl,, 86-87. Total flagellar length
918-1050. Fl, length/width 3.50-4.40, with 5(6?) mps. Mid ocellus diameter 24. Genitalia
fairly wide for most of its length (Fig. 185, 186).

Barcoding. Four ofthe five specimens yielded barcodes (CNCH Y M07484, CNCHY M07485,
CNCHY M07487, and CNCHY MO07488) and one did not (CNCHYM07486). The variation
among the specimens was not uniform and the sequences were of low or medium quality
except for CNCHYM07485. The two specimens from Virginia varied more between them
than each did to the single specimens from Ontario and British Columbia.

Hosts and habitat. The only known host is Philaenus spumarius (L.) [= P. leucophthalmus
(L.)| (Cercopoidea). Weaver and King (1954) collected 304 host eggs in 1951 and obtained
21 individuals of O. vulgatus (named as O. americanus), a parasitism rate of 6.9%. In 1952
they collected 1084 eggs, 10.7% of which showed evidence of parasitism but parasitoids
did not emerge from all these. The authors concluded that 10% parasitism rate is therefore
too high an estimate. Specimens have been collected in a weedy garden, urban lot, mixed
grass prairie, rocky knoll with intact Manzanita/Arbutus, hardwood/deciduous forest, sugar
bush [maple forest], old field, ocean side vegetation, ex soil. Presumably, O. vul/gatus occurs
wherever its host occurs. It has been intercepted on thyme cuttings from France.

Distribution. Palaearctic Region (Triapitsyn 2010), New Zealand (Triapitsyn 2010, Huber
2010, as an unintentional introduction), Nearctic Region (Triapitsyn 2010, and additional
records below).

Material examined. 3239 and 7¢. CANADA. Alberta. 0.5 km E Writing-on-Stone
Provincial Park, 8-17.ix.1981, D. McCorquodale (1°, CNC). British Columbia. Burnaby,
Simon Frazer University, 26.xii.1979-2.1.1980, D. Gillespie, PT (52, CNC); Burnaby
Mountain, 6.x-12.xi.1979, 7-21.iii, 21.iii-3.iv.1980, D. Gillespie, YPT (249, CNC); Queen
Charlotte Islands, Graham I., Masset, 9-13.vii.1983, I.M.Smith (19, CNC); Shushwap
Lake, Blind Bay, 15-31.viii.1986, 11-21.vii.1987, C.A. Elsey, MT (22, CNC); Sorrento,
17-20.vii.1991, H. Goulet, weedy garden, YPT (12, CNC); Upper Carmanah Valley, 12-
27.viii, 28.viii-9.ix, 10-29.ix, 17-26.x.1991, N. Winchester, MT (82, 33, CFS-Victoria);
Victoria vicinity, 48°32’N 123°30'W, 248m, 4-18.i1x.2005, N. Winchester, rocky knoll, intact
Manzanita/Arbutus, CNCHY M07485 (32, CNC). Nova Scotia. Bridgetown, 26.vil, 8.viii,
16.vili, 4.1x, 16.1x, 23.ix, 1.x.1913, G.E. Saunders (129, USNM). Ontario. Alfred Bog,
13.vii. 1981, L. LeSage (19, CNC); Ancaster, 4-11.vi.1994, B. DeJonge, prairie remnant,
CNCHY M07484 (12, CNC); near Ancaster, 43°15'N 80°00'W, 29.1x-27.v.1995, B. DeJonge,
bush/prairie, MT (12, CNC), Newton Woods, 20-31.v.1996, B. DeJonge, forest, MT (19,
CNC); 15 km SW. Chaffey’s Locks, 28.v.1987, C. Yoshimoto, C. Hayward, sweeping,

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

CNCHYM07486 [barcode failed] (49, CNC); Chatham, emerged xii.1956 ex Philaenus
leucophthalmus, H.B. Wressell, G.R. Driscoll (79 on 2 slides, CNC); Chatterton, 13 mi.
N. Belleville, 20 and 30.v.1962, 1.x.1970, C.D. Dondale, meadow (3%, CNC); Guelph,
University of Guelph arboretum, 43° 32'N 80° 13’W, 14.v, 12-32.v, 24-31.v, 5.vi, 2006, L.
Coote (92, UCRC); Hamilton, 15.v.1981, M. Sanborne, MT (22°, CNC); Joker’s Hill (near
Newmarket), hwy 9 between Dufferin & Bathhurst Streets, 1-9.vi.2002, A. Bennett, sugar
bush, MT (12, CNC); London, Fanshawe Experimental Farm, 5.ix-2.x.1981, 5.xi.1982, A.
Tomlin (22, 1¢, CNC); Middleville, White Lake road, 13.v.1986, H. Goulet, S. Peck, car
net (12, CNC); Milton, 2.vi.1978, J.M. Heraty, YPT (19, CNC); Point Pelee National Park,
3.x.1984, A. Borkent (19, CNC). USA. Arkansas. Montgomery Co.: Ouachita National
Forest, 270m, 34° 33'N 94°37'W, 3-4.vi.2003, R. Kula, M. Yoder (1°, UCRC). California.
Marin Co.: Lily Pond, Alpine Lake, 1500’, D.D. Munroe, 4-10.v.1971 (12, 1¢, CNC). San
Bernardino Co.: 5 mi. E. Wrightwood, Summit Valley, 21.v.1981, M.E. Schauff, sweeping
(12, USNM). Stanislaus Co.: Oakdale, 37°46'57"N 120°46'59”"W, 30.iv.2007, rural yard,
R. Shurtz, S. Fullerton (22, UCFC). Kansas. Riley Co.: Konza Prairie Biological Station,
Watershed 2C, 39°04.254'N 96°33.639'W, 26.vi-3.viil.2006, G. Zolnerowich, Metlevski,
MT (12, USNM). Maryland. Calvert Co.: American Chestnut Land Trust, Warrior’s Rest
Sanctuary, 38°31'54.37"N 76°32'35.71"W, 14.ix.2007, M. Gates, R. Kula (12, USNM);
Port Republic, viii-ix.1986, M. Sharkey, MT (12, CNC); 4 mi. S. Prince Frederick, 16.iv-
7.v, 24.ix-14.xi.1987, L. Masner, hardwood forest, MT, FIT (122, CNC). Howard Co.:
Clarksville, 8.xi.1986, A. Denno, E. Grissell, MT (12, USNM). Montgomery Co.: 4 mi.
SW. Ashton, 5.v.1985, G.F. and J.F. Hevel (12, USNM), Silver Springs, 11-2.vii.1980,
E.E. Grissell (12, UCRC). Prince George's Co.: Beltsville Agriculture Research Center,
18.viii.1983, M.E. Schauff, sweeping old field (12, USNM); Laurel, Patuxent Wildlife
Research Center, 16-25.v, 25.v-1.vi.1979, M.E. Schauff (32, USNM). New Jersey.
Sussex Co.: 17.1.1962, L.D. Parker, ex meadow spittlebug (59 on one slide, USNM). New
York. Tompkins Co.: McLean, McClean Bog, 736’, 42°32.687'N 76°15.995'W, 26.v.2007,
E.F. Drake, YPT on leaf duff (12, UCRC). Ohio. Cuyahoga Co.: Cleveland, urban lot,
41°27'49.84""N 81°36'43.14",W, K. Freeman, YPT (12, CLEV); Hunting Valley, Luce Creek
Preserve, 15-26.v.2003, T. Pucci (12, CLEV). Fairfield Co.: Barnebey Center, 39°36’N
82°37'W, 28.iv-6.v.1993, N. Johnson, MT (62, CNC). Warren Co.: 4.2 km SSE Donaldson,
Rock Run, 540m, 41°37'41"N 78°59'11"W, 12.v.1994, M. Ricke (12, ICCM). Wayne Co.:
Wooster, 28.iv.1952, ex meadow spittlebug, C.R. Weaver (5% on one slide, USNM); same
locality, [no month] 1951, ex spittlebug eggs, R.C. Weaver (2°, on one slide USNM), [no
specific locality], x.1950, ex spittlebug egg, C.R. Weaver (12 on point, USNM). Oregon.
Baker Co.: 18.vii.1981, R.E. Orth (12, CNC). Jackson Co.: 10.5 mi. E. Ashland, road to
Howard Prairie Lake, 42.2404°N 122.5263°W, 4.v.2005, R. Rakitov, vacuum (19, UCRC).
Lincoln Co.: 2 mi. S. Newport, South Beach State Park, 23.viii.1984, M.E. Schauff, P.
Hanson, sweeping ocean side vegetation (59, USNM). Pennsylvania. Cambia Co.: 3 km
N. Wilmore, 650m, 30.v.1991, L. Masner, sweeping (12, CNC). Dauphin Co.: Harrisburg,
2301 Cameron Street, emerged from soil under Andorra juniper, soil collected 21.11, adult
emerged 28.11.1975, J. Steinhauer (12, USNM). Warren Co.: Weldbank, 41°45.749'N
79°5.752'W, 29.v.2007, E.F. Drake, YPT (19, UCRC). Virginia. Clarke Co.: 2 mi. S. Boyce,
University of Virginia, Blandy Experimental Farm, 19-30.iv, 6-18.iv, 24-30.iv, 1-13.v, 14-
24.v, 28.viii-11.ix.1990, D.R. Smith, MT (629, 14, USNM). Fairfax Co.: near Annandale,

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Huber JESO Volume 143, 2012

4.1v.1986, 22-28.iv, 24-30.iv.1988, 29.iv-5.v, 6-12.v, 1-13.v, 13-19.v, 27.v-2.vi, 26.viii-1.
ix.1990 (392, USNM); Turkey Run Park, 38°57.9'N 77°09.4'W, 29.iv.2010, J. Huber, H.
Goulet, deciduous forest, sweeping (29, 14, CNC). Hardy Co.: 3 mi. NE. Mathias, 38°55/N
78°49'W, 15-30.v.2001, 17.1v-3.v.2002, D.R. Smith, MT, CNCHYM07487 (82, CNC);
Montgomery Co.: 8 km NW. Blacksburg, 1000m, 8.iv-9.v, 18-28.iv, 9-19.v.1987, rural
area, CNC Hymenoptera team, MT (259, CNC); Page Co.: Shenandoah National Park,
Big Meadow, 18-28.iv, 17.1v-5.v, 5-22.v, 5.v-5.vi.1987, 1300m, CNC Hymenoptera team,
CNCHYM07488 (242, CNC), Compton Dry Run, 15-16.iv.1995, L. Masner, YPT (19,
CNC), Compton Gap, 800m, 17.iv-5.v.1987, CNC Hymenoptera team, MT (89, CNC).
Washington. Pacific Co.: 6 mi. N. Raymond, 19.vii.1988, J.D. Pinto (14, CNC).
FRANCE. Intercepted on thyme cuttings, New York port of entry, 19.x.1951, L.J. Uttal,
(12, USNM) [det. as O. heterotomus by B.D.Burks [= O. notatus] and O. ?vulgatus by S.NV.
Triapitsyn].

Unassigned specimens. About 90 additional specimens, mostly males but also a few females,
either cannot be identified or may represent additional species. If the females represent
new species more material is needed to describe them properly. Five barcoded specimens
are unplaced to species. One female from Ontario, Ancaster, 12-19.1x.1994, B. DeJonge,
meadow prairie CNCHY M075 14, which was initially identified as O. /ongipetiolus is very
likely not this species because of a difference of 12 base pairs (Fig. 200). Other specimens
from the same locality are treated as O. /ongipetiolus but with slight reservations because the
groove on the mesoscutum and the petiole are somewhat shorter. Two males from Alberta,
Beaverlodge area, Saskatoon Mt., 962m, 55°13.20’N 119°16.92'W, 25.vii. 2.vili.2007, J.
Otani, natural meadow, sweeping, CNCHYM07480, CNCHYM07522 appear to be closest
to O. notatus but differ by about 14 base pairs. Until females can be associated with them they
cannot be described. Two specimens from Mexico (CNCHYM07520, CNCHYM07521)
differ from species north of Mexico and will be described elsewhere.

Discussion

The following European material was examined: 141 O. notatus, 92 O. hemipterus,
66 O. vulgatus, 59 O. insignis, 5 O. sublaevis, and 4 O. novickyi Soyka [CNC, NMPC]. The
first three of these species occur in North America, perhaps not surprisingly because they
are the three most common and widespread European Ooctonus species. They appear to
occur mainly in open, man-made habitats and the host of one, O. vu/gatus, is a widespread
European introduction in North America, occurring mainly in agricultural habitats. Likely,
all are accidental introductions, not naturally Holarctic species. The last three species have
not been found in North America. Ooctonus insignis, the largest European Ooctonus, might
also have been expected to occur there as an accidental introduction because it is almost as
common (based on collected material seen) as O. vulgatus but so far I have not seen North
American specimens. The two remaining European species do not occur in North America.
This is not surprising because they appear to be rare in Europe so the possibility of accidental
human transport is small. So far none of the eastern Palearctic or Oriental species have
been found in North America. However, the eastern Palaearctic species O. orientalis Doutt

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

resembles O. canadensis, and O. spartak Triapitsyn resembles O. occidentalis, suggesting a
closer association of some western North American Oocfonus to eastern Asian species than
to eastern North American and European species.

Males are very difficult or impossible to identify confidently based on morphology.
It was hoped that barcoding would help associate males with females. If all 64 specimens
submitted for barcoding at the Biodiversity Institute of Ontario had yielded barcodes
of reasonable length (at least 200 base pairs) it is likely that the males would have been
associated correctly with corresponding females. But only 33 of 64 (52%) specimens
yielded such barcodes. An additional specimen barcoded by Guelph (O9BBHY M696) is
included in the Neighbour-joining tree (Fig. 200); it is a specimen of O. silvensis. Bar
codes corresponded to the species identities based on morphological characters, and helped
to correct identification errors based on morphology. In one case, the series of three male
specimens successfully barcoded contained two specimens of O. occidentalis (correctly
identified, based on morphology) and one of O. canadensis (initially misidentified as O.
occidentalis). In the second case, a male of O. notatus was misidentified as a male of O.
boltei but their bar codes were identical so they are clearly the same species and I assigned
them to O. notatus. In the third case, a barcode divergence of 4% suggested two species
within O. longipetiolus.

No barcodes were obtained for two males that I could not place to species based
on morphology or by association with females. One male (CNC) with the same collection
data as a specimen of O. hemipterus, namely, Cantwell, Denali hwy, route 8, mi. 85-130,
24.vi1.1984, S. & J. Peck, taiga-tundra, car netting, CNCHYM07524 [barcode failed]
is clearly not O. hemipterus based on morphology. And one male (CNC) from Alberta,
Edmonton, 22.viti.1984, T.G. Spanton, CNCHYM07526 [barcode failed] also cannot be
identified to species.

On the basis of morphology and/or barcodes more species of Ooctonus occur in
North America north of Mexico than are treated here. Much more material is needed to be
able to describe them meaningfully.

Acknowledgements ©

I thank the curators and institutions listed in Methods for lending me specimens,
including primary types, for study. Molecular analyses were performed at the Canadian
Centre for DNA Barcoding, University of Guelph, Guelph, Ontario, and funded by the
Government of Canada through Genome Canada and the Ontario Genomics Institute
(2008-OGI-ICI-03). I especially thank J. Fernandez-Triana and A. Bennett (CNC, Ottawa)
for extracting the barcoding information on the BOLD website to produce Fig. 200 and
helping to interpret it for me. I. Miko, Pennsylvania State University, State College,
Pennsylvania, provided the HAO numbers for Table 2. Finally, J. Read produced the superb
digital images and compiled them into plates, proof read the ms, and provided invaluable
general assistance.

Da

Huber nuloy © JESO Volume 143, 2012

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Burks, B. D. 1958. Superfamily Chalcidoidea. Pp. 62—84 in Krombein, K. V. (ed),
Hymenoptera of America north of Mexico. Synoptic catalog. United States
Department of Agriculture, Agriculture Monograph 2. First Supplement. 305 pp.

Burks, B. D. 1967. Superfamily Chalcidoidea. Pp. 213-282 in Krombein, K. V. and Burks,
B .D. (eds), Hymenoptera of America north of Mexico. Synoptic catalog. United
States Department of Agriculture, Agriculture Monograph 2. Second Supplement.
584 pp.

Burks, B.D. 1979. Family Mymaridae. Pp. 1022—1033 in Krombein, K.V., Hurd, P.D. Jr.,
Smith, D.R., and Burks, B.D. (eds), Catalog of Hymenoptera in America North of
Mexico 1. Washington, DC: Smithsonian Institution Press. 1198 pp.

Dalla Torre, C.G. de. 1898. Subfam. Mymarinae. Pp. 422-431 in Catalogus hymenopterorum
hucusque descriptorum systematicus et synonymicus. Vol. 5: Chalcididae et
Proctotrupidae. Lipsiae [Leipzig]: Guilelmi Engelmann. 598 pp.

Doutt, R. L. 1961. The hymenopterous egg parasites of some Japanese leafhoppers. Acta
Hymenopterologica 1(3): 305-314.

Dupo, A. L. B. and Barrion, A. T. 2009. Taxonomy and general biology of delphacid
planthoppers in rice agroecosystems. Pp. 3-156 in Heong, K. L. and Hardy, B.
(eds), Planthoppers: new threats to the sustainability of intensive rice production
systems in Asia. Los Bafios (Philippines): International Rice Research Institute.
460 pp.

Ewan, H. G. 1961. The Saratoga spittlebug. A destructive pest in red pine plantations. United
States Department of Agriculture, Technical Bulletin 1250: 11 + 52 pp.

Foerster, A. 1847. Ueber die Familie der Mymariden. Linnaea Entomologica 2: 195-233.

Gibson, G. A. P. 1997. Chapter 2. Morphology and terminology. Pp.16—44 in Gibson, G. A.
P., Huber, J. T., and Woolley, J. B. (eds), Annotated keys to the genera of Nearctic
Chalcidoidea (Hymenoptera). Ottawa: NRC Research Press. 794 pp.

Gibson, G. A. P. 2004. A new species of Oozetetes De Santis (Hymenoptera: Chalcidoidea:
Eupelmidae) attacking oothecae of Myctibora acaciana Roth (Orthoptera:
Blatellidae). Journal of Hymenoptera Research 13: 13-23.

Girault, A. A. 1916a [1915]. Two new Mymaridae from the eastern United States (Hym.).
Entomological News 27: 69-70.

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Revision of the genus Oocfonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Girault, A. A. 1916b. New miscellaneous chalcidoid Hymenoptera with notes on described
species. Annals of the Entomological Society of America 9: 291-308.

Girault, A. A. 1929. North American Hymenoptera Mymaridae. Pp.1—27 + Addendum. in
New insects, mostly Australian. pp. 28-29. Privately printed.

Goulet, H. 1996. Revision of the Nearctic species of the arcuata group of the genus Tenthredo
with notes on the higher classification of the Tenthredinini (Hymenoptera,
Symphyta, Tenthredinidae). Contributions of the American Entomological Institute
29(2). 135 pp.

Graham, M. W. R. de V. 1982. The Haliday collection of Mymaridae (Insecta, Hymenoptera,
Chalcidoidea) with taxonomic notes on some material in other collections.
Proceedings of the Royal Irish Academy (B) 82: 189-243.

Haliday, A. H. 1833. Essay on the classification of the parasitic Hymenoptera of Britain,
which correspond with the Ichneumones minuti of Linnaeus. Entomological
Magazine 1: 259-276, 333-350, 490-491.

Hamilton, K. G. A. 1982. The spittlebugs of Canada, Homoptera: Cercopidae. The Insects
and Arachnids of Canada 10. 102 pp.

Hansson, C. 1991. A catalogue of Chalcidoidea described by C. G. Thomson, with a checklist
of Swedish species. Entomologica Scandinavica, Supplement 38. 70 pp.

Herting, B. 1972. Homoptera. A catalogue of parasites and predators of terrestrial
arthropods. Section A. Host or Prey/Enemy. 2:1 +210 pp. Slough: Commonwealth
Agricultural Bureaux.

Hincks, W. D. 1952. The British species of the genus Ooctonus Haliday, with a note on some
recent work on the fairy flies (Hym., Mymaridae). Transactions of the Society for
British Entomology 11: 153-163.

Huber, J. T., Read, J. D. and Noort, S. van. 2010. The genus Ooctonus Haliday (Hymenoptera:
Mymaridae) in the Afrotropical Region, with comments on other southern
hemisphere species. African Entomology 18: 221—234.

Ivanova, N. V., deWaard, J. R., and Hebert, P. D. N. 2006. An inexpensive automation-
friendly protocol for recovering high-quality DNA. Molecular Ecology Notes 6:
998-1002.

Kalina, V. 1989. Chalcidoidea. Pp. 97-127 in Sedivy, J. (ed), Checklist of Czechoslovak
Insects HIl (Hymenoptera). Acta Faunistica Entomologica Musei Nationalis
Pragae 19: 1-194.

Kieffer, J.-J. 1913. Description de cinq hyménopteres nouveaux. Bulletin de la Société
d'Histoire Naturelle de Metz 28: 1-4.

Kloet, G. S. and Hincks, W. D. 1945. A check list of British Insects. Arbroath: Bunckle and
Co. 483 pp.

Krogmann, L. and Vilhelmsen, L. 2006. Phylogenetic implications of the mesosomal
skeleton in Chalcidoidea (Hymenoptera, Apocrita) — tree searches in a jungle of
homoplasy. /nvertebrate Systematics 20: 615-674.

Kryger, J. P. 1950. The European Mymaridae comprising the genera known up to c. 1930.
Entomologiske Meddelelser 26: \—97.

Milliron, H. E. 1947. Description of a new mymarid which parasitizes the eggs of the
Saratoga spittlebug. Annals of the Entomological Society of America 40: 217-
220.

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Nault, L. R. 1989. Leafhopper and planthopper transmission of plant viruses. Annual Review
of Entomology 34: 503-529.

Peck, O. 1951. Superfamily Chalcidoidea. Pp. 410-594 in Muesebeck, C. F. W., Krombein,
K. V., and Townes, H.K. (eds), Hymenoptera of America north of Mexico —
synoptic catalog. Washington, D.C.: United States Department of Agriculture.
Agriculture Monograph 2. 1420 pp.

Peck, O. 1963. A catalogue of the Nearctic Chalcidoidea (Insecta: Hymenoptera). The
Canadian Entomologist, Supplement 30. 1092 pp.

Porco, D., Rougerie, R., Deharveng, L., and Hebert, P. D. N. 2010. Coupling non-
destructive DNA extraction and voucher retrieval for small soft-bodied arthopods
in a high-throughput context: the example of Collembola. Molecular Ecology
Resources 10: 942— 945.

Ratnasingham, S. and Hebert, P. D. N. 2007. BOLD: The Barcode of Life Data System
(www.barcodinglife.org). Molecular Ecology Notes 7: 355-364.

Ratzeburg, J. T. C. 1848. Die Ichneumonen der Forstinsecten in forstlicher und
entomologischer Beziehung,; ein Anhang zur Abbildung und Beschreibung der
Forstinsecten. Zweiter Band. Berlin: Nicolai’schen Buchhandlung. 238 pp. + 3
Tables + 3 Plates.

Schmiedeknecht, O. 1909. Hymenoptera Fam. Chalcididae. Genera Insectorum 97. 550 pp.
+ 8 Plates.

Soyka, W. 1941. Beitrage zur Klarung der européischen Arten der Mymariden. Das Genus
“Ooctonus” Haliday. (Mymaridae, Chalcidoidea, Hymenoptera). Natwurhistorisch
Maandblad 30: 77-80.

Takaie, H. 1999. A morphological study of an encyrtid fly, Microterys clauseni Compere
(Hymenoptera: Encyrtidae). Tokyo: privately printed. 122 pp.

Triapitsyn, S. V. 2010. Revision of Palaearctic species and review of the Oriental species of
Ooctonus (Hymenoptera: Mymaridae), with notes on extralimital species. Zootaxa
2381: 1-74.

Trjapitzin, V. A. 1978. 18. [Family Mymaridae — mymarids]. Pp. 516-538 in Medvedev,
G. S. (chief ed.) [Keys to the insects of the European part of the USSR]. Volume
III. Hymenoptera, Part 2. [Trjapitzin, V. A. (Ed.)]. Leningrad: Nauka, Leningrad
division. [In Russian] [pp. 942-982 in 1987 English translation, New Delhi:
Amerind Publishing Co. Ptv. 1341 pp.]

Viggiani, G. 1970. Ricerche sugli Hymenoptera Chalcidoidea. XXIV. Sul valore tassinomico
dell’organo copulatore nei Mimaridi del genere Anagrus Hal. Bollettino del
Laboratorio di Entomologia Agraria “Filippo Silvestri” 28: 10-18.

Viggiani, G. 1988. A preliminary classification of the Mymaridae (Hymenoptera:
Chalcidoidea) based on the external male genitalic characters. Bollettino del
Laboratorio di Entomologia Agraria “Filippo Silvestri” 45: 141-148.

Viggiani, G. and Jesu, R. 1988. Considerazioni sui mimaridi italiani ed 1 loro ospiti (1).
Atti dell’XV Congresso Nazionale Italiano di Entomologia, L’Aquila, 1988: 1019—
1029.

Ronquist, F. and Nordlander, G. 1989. Skeletal morphology of an archaic cynipoid /balia
rufipes (Hymenoptera: Ibaliidae). Entomologica Scandinavica, Supplement No.
33. 60 pp.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

Walker, F. 1846. Descriptions of the Mymaridae (and Errata and Addenda.viii). Annals and
Magazine of Natural History 18: 49-54.

Weaver, C. R. and King, D. R. 1954. Meadow spittlebug Philanenus leucophthalmus (L.).
Qhio Agricultural Experiment Station, Research Bulletin 741. 99 pp.

Westwood, J. O. 1839. Synopsis of the genera of British insects: 78, 79. [Appendix, pp. 49
80, in An introduction to the modern classification of insects 2. London: Longman,
Orme, Brown, Green, and Longmans]

Whittaker, O. 1931. Four new species of Mymaridae from British Columbia (Hymenoptera).
Proceedings of the Entomological Society of Washington 33: 189-192.

Wilson, L. F. 1978. Saratoga spittlebug. United States Forest Service, Forest Insect &
Disease Leaflet 3. 4 pp.

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TABLE |. Abbreviations used in the figures descriptions. Codes in parentheses are entries in
the Hymenoptera Anatomy Ontology project website (HAO) [accessed 12 October, 2012],
where applicable. Entries can be accessed using the structure http://purl.obolibrary.org/obo/
HAO XXXXXXX, where XXXXXXX is the HAO ID number.

Body (Figs. 6—8, 195-199)

ac acropleuron (HAO 0001155)

as anterior scutellum (HAO 0001167)

ax axilla (HAO 0000155)

axe axillar carina (HAO 0000156)

axl axillula (HAO 0000160)

axls_ axillular sulcus/carina (HAO 0001159)

brfl basal ring of femur ( = trochantellus) (HAO 0001033)
clm collum (= neck) (HAO 0000837)

clr collar (HAO 0000832)

cos costula (HAO 0000486)

cxl procoxa (HAO_0001122)

cx2 mesocoxa (HAO_0000635)

cx3 metacoxa (HAO_ 0000587)

del prodiscrimen (HAO 0000823)

dc2 mesodiscrimen (HAO 0000545)

dor = no3m dorsellum (= metascutellum or mid panel of metanotum) (HAO 0000625)
epm2 mesepimeron (HAO_ 0000539)

eps2 mesepisternum (HAO_0000541)

fin funicle segment (females) or flagellomere (males) (HAO_ 0000342)
fmd femoral depression (HAO 0000326)

fr frenum (= posterior scutellum) (HAO_0000355)

fra frenal arm (HAO_ 0001903)

frl frenal line (HAO 0000354)

fu2p mesofurcal pit (HAO 0000549)

gsn gastral sternum (HAO 0002023)

gtn gastral tergum (HAO _ 0002024)

Ilm lateral lobe of mesoscutum (HAO 0000466)

LOL least ocellar length (Fig. 52) (HAO_0000480)

Ipa lateral panel of axilla (HAO 0000468)

mlm midlobe of mesoscutum (HAO 0000520)

mps multiporous plate sensilla (= longitudinal sensilla, of authors) (Fig. 76) (HAO_0001936)
mtp metatrochantinal plate (HAO_ 0000588)

not notaulus (HAO 0000647)

nol pronotum (HAO_ 0000853)

noll lateral panel of pronotum (HAO_ 0002025)

nolm midlobe of pronotum

no2 mesonotum (HAO 0000556)

no3 metanotum (HAO 0000603)

no31 lateral panel of metanotum (HAO 0000600)

no3m = dor mid panel of metanotum (= metascutellum = dorsellum) (HAO 0000625)
od mid ocellar diameter (Fig. 53) (HAO_0002027)

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Revision of the genus Oocfonus (Hymenoptera: Mymaridae)

TABLE | continued...

OOL ocular-ocellar length (Fig. 52) (HAO_0000662)
ovip ovipositor (HAO 0000679)

pea pronotal carina (HAO_0001031)

pd propodeum (HAO_0001248)

phl phallobase (HAO_0000713)

ple plica (HAO_0000735)

pls mesopleural suture (HAO_0001706)

pll_ propleuron (HAO 0000862)

pl2 mesopleuron (HAO_0000566)

pl3_ metapleuron (HAO_0001272)

POL postocellar length (Fig. 52) (HAO 0000759)
pre prepectus (HAO_0000811)

prs propodeal stub

psp propodeal spiracle (HAO_0000329)

ptl petiole (HAO 0000020)

sc mesoscutum (= mlm + Ilm) (HAO_ 0001490)
scl mesoscutellum (HAO 0000574)

stl prosternum (HAO 0000873)

st2 mesopleurosternum (HAO_0001710)

tg tegula (HAO 0000993)

trl protrochanter (HAO 0001123)

tr2 mesotrochanter (HAO_0001130)

tr3. metatrochanter (HAO_0001139)

tsa transscutal articulation (HAO 0001204)

tss transepisternal suture (HAO_0001205)

Fore wing (Figs. 9, 10)

av anal vein (HAO_0000093)

ax 3rd axillary sclerite (HAO 0001009)

be basal cell

bf basal fold

ca claval area (clavus) [(vannal area of Gibson (2004)]
ef claval fold/claval flexion line

ce costal cell

cusl cubital line of setae

dm distal macrochaeta

ff frenal fold [subcubital fold of Gibson (2004)]
hp! humeral plate (HAO 0000403)

hy hypochaeta

pm proximal macrochaeta

ps! placoid sensilla

pst parastigma

smyv submarginal vein

stv stigmal vein

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Huber JESO Volume 143, 2012

FIGURES 1-5. Ooctonus females, lateral habitus. 1, hemipterus, short winged specimen; 2,
readae; 3, quadricarinatus; 4, silvensis; 5, vulgatus. Scale bars are 1000 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 6, 7. Ooctonus spp., scanning electron micrographs (SEM). 6, guadricarinatus
mesosoma, coxae, and petiole, lateral; 7, guadricarinatus, mesosoma, dorsal. See Table |
for terms.

Huber JE SO Volume 143, 2012

8

median
metascutellum carina

dorsellun ; :
cae Jail Big 2 4 plica

ns (dorsal
propodeal | portion)
seta 3 —.

dorso-
, - lateral
dorsal Za —- Ee . areole
submedian we ae Z
carina : _ a | ae plica
(ventral

metapleuron =r \ of - ea portion)

ventral i y ig median

submedian a jit areole
carina 4 ¥ ha

ventro-

lateral

areole

9

FIGURES 8-10. Ooctonus spp. 8, readae, propodeum, dorsal, SEM; 9, longipetiolus, fore
wing base, dorsal, SEM; 10, readae, fore wing base, transmitted light. See Table | for
terms.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 11-14. Ooctonus spp., lectotoypes. 11, auripes; 12, canadensis; 13, fuscipes; 14,
occidentalis. Scale bars are 1000 tm.

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Huber JESO Volume 143, 2012

16

FIGURES 15-17. Ooctonus spp., primary types. 15, americanus, holotype; 16, si/vensis,
holotype; 17, guadricarinatus, lectotype. Scale bars are 1000 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

19

21

ongipeti clus P
Huber

CANAPA:ON DB
Buckhawm Bay

es.49 xs/N
2z.\1087W
1S§-20 .Vi20\o

dorsa\ TReady MT
AL EIIOIERED

Qac onus P ms onsen Poy Pa 29
riapitsgny 1318 :
H rver

FIGURES 18-25. Ooctonus spp., primary type slides. 18, americanus; 19, arizonensis; 20,
boltei; 21, longipetiolus; 22, quadricarinatus; 23, readae; 24, silvensis; 25, triapitsyni.

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Huber JESO Volume 143, 2012

31

FIGURES 26-31. Ooctonus females, head, anterior view. 26, aphrophorae; 27, arizonensis;
28, boltei, holotype; 29, canadensis; 30, fuscipes; 31, hemipterus. Scale bars are 100 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 32-37. Ooctonus females, head, anterior view. 32, /ongipetiolus, holotype; 33,
notatus; 34, occidentalis; 35, quadricarinatus; 36, readae; 37, silvensis. Scale bars are 100
um.

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Huber JESO Volume 143, 2012

FIGURES 38, 39. Ooctonus females, heads, anterior view. 38, triapitsyni; 39, vulgatus.
Scale bars are 100 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 40-45. Ooctonus females (except as noted), heads, dorsal view. 40, arizonensis,
holotype; 41, canadensis, male; 42, fuscipes, male; 43, hemipterus; 44, notatus; 45,
occidentalis. Scale bars are 100 um.

73

Huber Lie OL = JESO Volume 143, 2012

FIGURES 46-51. Ooctonus females (except as noted), head, dorsal view, SEM. 46,
aphrophorae; 47, aphrophorae, male; 48, arizonensis, male; 49, boltei; 50, canadensis,
male; 51, fuscipes. Scale bars are 100 um.

74

FIGURES 52-57. Ooctonus females (except as noted), head, dorsal view, SEM. 52,
hemipterus; 53, longipetiolus, male; 54, notatus; 55, notatus, male; 56, occidentalis, male;
57, quadricarinatus, male. Scale bars are 100 um.

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Huber : JESO Volume 143, 2012

FIGURES 58-62. Ooctonus females, head, dorsal view, SEM (except Fig. 62). 58, readae;
59, silvensis; 60, triapitsyni; 61, vulgatus; 62, hemipterus, lateral view, transmitted light.
Scale bars are 100 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

oF

FIGURES 63-69. Ooctonus females, antenna, lateral view. 63, aphrophorae, 64,
arizonensis, holotype; 65, boltei, holotype; 66, canadensis; 67, fuscipes, 68, hemipterus;
69, longipetiolus, holotype. Scale bars are 200 um.

a

Huber JESO Volume 143, 2012

FIGURES 70-76. Ooctonus females, antenna, lateral view. 70, notatus; 71, occidentalis;
72, quadricarinatus; 73, readae; 74, silvensis; 75, triapitsyni;, 76, vulgatus (inset is fl, +
clava, showing row of six bullae). Scale bars are 200 um; inset is 100 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

= Pa,

=~

FIGURES 77-82. Ooctonus males, antenna, lateral view. 77, aphrophorae; 78, arizonensis;
79, canadensis; 80, fuscipes; 81, hemipterus; 82, longipetiolus. Scale bars are 500 tm.

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Huber JESO Volume 143, 2012

FIGURES 83-88. Ooctonus males, antenna, lateral view. 83, notatus; 84, occidentalis; 85,
quadricarinatus, lectotype; 86, readae; 87, silvensis; 88, vulgatus. Scale bars are 500 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 89-96. Ooctonus females (except as noted), mesosoma, lateral view. 89,
aphrophorae, male; 90, arizonensis, male; 91, fuscipes, male; 92, hemipterus; 93,
longipetiolus; 94, readae; 95, quadricarinatus; 96, silvensis. Scale bars are 200 um.

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Huber JESO Volume 143, 2012

FIGURES 97-99. Ooctonus females, mesosoma, dorsal view. 97, aphrophorae; 98,
arizonensis, holotype; 99, boltei, holotype. Scale bars are 200 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 100-102. Ooctonus females (except as noted), mesosoma, dorsal view, SEM.
100, aphrophorae, male; 101, arizonensis; 102, boltei. Scale bars are 200 um.

83

Huber JESO Volume 143, 2012

FIGURES 103-105. Ooctonus females, mesosoma, dorsal view. 103, canadensis; 104,
fuscipes; 105, hemipterus. Scale bars are 200 um.

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Revision of the genus Oocfonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 106-108. Ooctonus females (except as noted), mesosoma, dorsal view, SEM.
106, canadensis, male; 107, fuscipes; 108, hemipterus. Scale bars are 200 um.

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Huber JESO Volume 143, 2012

FIGURES 109-111. Ooctonus females, mesosoma, dorsal view. 109, /ongipetiolus,
holotype; 110, notatus; 111, occidentalis. Scale bars are 200 wm.

86

FIGURES 112-114. Ooctonus females (except as noted), mesosoma, dorsal view, SEM.
112, longipetiolus, male; 113, notatus; 114, occidentalis, male. Scale bars are 200 um.

87

Huber JESO Volume 143, 2012

FIGURES 115-117. Ooctonus females, mesosoma, dorsal view. 115, guadricarinatus; 116,
readae, holotype; 117, silvensis. Scale bars are 200 um.

88

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 118-120. Ooctonus females (except as noted), mesosoma, dorsal view, SEM.
118, quadricarinatus, male; 119, readae, holotype; 120, silvensis. Scale bars are 200 um.

89

Huber JESO Volume 143, 2012

FIGURES 121, 122. Ooctonus females, mesosoma, dorsal view. 121, triapitsyni; 122,
vulgatus. Scale bars are 200 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 123, 124. Ooctonus females, mesosoma, dorsal view, SEM. 123, triapitsyni; 124,
vulgatus. Scale bars are 200 um.

9]

Huber —_ JESO Volume 143, 2012

FIGURES 125-130. Ooctonus females (except as noted), posterior part of frenum to
propodeum, dorsal view, SEM. 125, aphrophorae; 126, arizonensis; 127, boltei; 128,
canadensis, male; 129, fuscipes; 130, hemipterus. Scale bars are 50 um.

Revision of the genus Ooctonus (Hymenoptera: Mymaridae)

_JESO Volume 143, 2012

FIGURES 131-136. Ooctonus females (except as noted), posterior part of frenum to
propodeum, dorsal view, SEM. 131, /ongipetiolus, male; 132, notatus; 133, occidentalis,
male; 134, guadricarinatus, male; 135, readae; 136, silvensis. Scale bars are 50 um.

Huber iy JESO Volume 143, 2012

' anterior
~ scutellum

fenestra

t,t, muscle scutellar
fenestra

frenum

FIGURES 137-140. Ooctonus females; 137 and 138, posterior part of frenum to propodeum,
dorsal view, SEM. 137, triapitsyni; 138, vulgatus. 139, dorsum of mesonotum, inside view,
SEM. 140, quadricarinatus, scutellum (slightly below surface), transmitted light. Scale bars

are 50 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

; eee
SA

WAAL 149 Fy mee fill 150
FIGURES 141-150. Ooctonus females (except as noted), wings. 141, aphrophorae; 142,
arizonensis, holotype; 143, boltei, male; 144, canadensis; 145, fuscipes; 146, hemipterus;
147 and 148, hemipterus, short winged forms; 149, hemipterus, male; 150, longipetiolus.
Scale bars are 500 um except 100 um for Figures 147 and 148.

95

Huber JESO Volume 143, 2012

7

ai

a

ai

LIFT ITTTT OTT
Yj, f SAL)

SS

iTV | 153) 154

= SSS N
< SAS S x
ONS So
= SS
SSS SES
SSS See
Sa See oN

a
<<

ree

CHU

RIYEP OE St

FIGURES 151-158. Ooctonus females (except as noted), wings. 151, notatus; 152,
occidentalis; 153, quadricarinatus, male; 154, readae; 155 and 156, silvensis, showing
variation; 157, triapitsyni, holotype; 158, vulgatus. Scale bars are 500 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 159-165. Ooctonus females, petiole + gaster, dorsal view. 159, aphrophorae;
160, arizonensis, holotype; 161, boltei, holotype; 162, canadensis; 163, fuscipes; 164,
hemipterus; 165, longipetiolus. Scale bars are 200 um.

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Huber JESO Volume 143, 2012

FIGURES 166-171. Ooctonus females, petiole + gaster, dorsal view. 166, notatus; 167,
occidentalis; 168, readae, holotype; 169, silvensis; 170, triapitsyni; 171, vulgatus. Scale
bars are 200 um.

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Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 172-177. Ooctonus females, petiole + gaster, ventral view. 172, hemipterus; 173,
longipetiolus, holotype; 174, notatus; 175, occidentalis; 176, readae; 177, silvensis. Scale
bars are 200 um.

99

Huber JESO Volume 143, 2012

FIGURES 178-186. Ooctonus males, gaster and genitalia, ventral view (except as noted).
178, aphrophorae; 179, fuscipes; 180, occidentalis; 181, quadricarinatus, dorsal; 182,
silvensis, 183, canadensis, dorsal; 184, longipetiolus; 185, vulgatus, dorsal; 186, vulgatus.
Scale bars are 200 um.

100

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 187-192. Ooctonus females (except as noted), petiole + gaster, lateral view.
187, aphrophorae; 188, hemipterus; 189, quadricarinatus; 190, readae; 191, aphrophorae,
male; 192, guadricarinatus, male. Scale bars are 200 um.

101

Huber JESO Volume 143, 2012

digital spine paramere aedeagus

paramere,

)

—dedeaga
Jamina

anterodorsal ——>
opening of
phallobase <—— aedeagal
apodeme

FIGURES 193, 194. Male genitalia. 193, canadensis, dorsal; 194, silvensis, ventral.

102

Revision of the genus Ooctonus (Hymenoptera: Mymaridae) JESO Volume 143, 2012

FIGURES 195-199. Ooctonus quadricarinatus, metasoma, except Figures 197 and 199.
195, female, lateral; 196, male, lateral; 197, male, mesosoma, ventral; 198, male, ventral;
199, Ooctonus sp., male, ventral. See Table | for terms.

103

Huber JESO Volume 143, 2012

Ooctonus occidentalis |CNCHYM 07504|422 bp
Ooctonus occidentalis |CNCHYM 07507|422 bp
Ooctonus canadensis |CNCHYM 07506|422 bp
Ooctonus sp. |CHCHYM 07514|422 bp
Ooctonus longipetiolus |CHCHYM 07516|422 bp
Ooctonus hemipterus |CHCHYM 07478] 422 bp
Ooctonus hemipterus |CHCHYM 07477|422 bp
Ooctonus hemipterus |CHCHYM 07476|422 bp
Ooctonus notatus |CHCHYM 07462|614 bp
Ooctonus notatus |CHCHYM 07459|567 bp
Ooctonus notatus |CHCHYM 07461/422 bp
Ooctonus readae |CHCHYM 07464) 307 bp
Ooctonus vulgatus |CHCHYM 07488|364 bp
Ooctonus vulgatus |CHCHYM 07484|340 bp
Ooctonus vulgatus |CHCHYM 07487|350 bp
Ooctonus vulgatus |CHCHYM 07485|422 bp
Ooctonus quadricarinatus |CHCHYM 07472|422 bp
Ooctonus quadricarinatus |CHCHYM 07470|422 bp
hoe quadricarinatus |CHCHYM 07471] 422 bp
Ooctonus sp. |CHCHYM 07522|539 bp
Ooctonus sp. |CHCHYM 07480|614 bp
Ooctonus sp. |CHCHYM 07520|613 bp
Ooctonus sp. |CHCHYM 07521|614 bp
Ooctonus silvensis |CHCHYM 07491|615 bp
Ooctonus fuscipes |CHCHYM 07499|276 bp
Ooctonus fuscipes |CHCHYM 07501|246 bp
Ooctonus fuscipes |CHCHYM 07503|265 bp
Ooctonus fuscipes |CHCHYM 07502|277 bp
Ooctonus arizonensis |CHCHYM 07511|283 bp
Ooctonus silvensis |CHCHYM 07498|615 bp
Ooctonus silvensis |09BBHYM-696|634 bp C200)

FIGURE 200. Neighbour-joining tree based on Kimura-2-Parameter distances for
cytochrome c oxidase I.

104

Revision of the genus Ooctonus (Hymenoptera: Mymaridae)

TABLE 2. CNC barcode and Genbank accession numbers for Nearctic Ooctonus species.

arizonensis

canadensis

fuscipes

hemipterus

longipetiolus

notatus

occidentalis

quadricarinatus

readae

silvensis

vulgatus

Unassigned

BWW NM NO =

Ooctonus species

CNCHY M#

07511
07506
07499
07501
07502
07503
07476
07477
07478
07516
07459
07461
07462
07504
07507
07470
07471
07472
07473
07464
07491
07498
07496
07484
07485
07487
07488

07514
07480
O22
07520
07521
07513

Ow,

Oy Qy OyfOy Oy][Oy 40 +4+0]40

OM

nO) RO)}| |KO)

Arizona
California
British Columbia
Oregon
Oregon
Oregon
Ontario
Quebec
Ontario
Virginia
Ontario

Prince Edward Island

Alberta
California
California
Nova Scotia
Ontario
Nova Scotia
Nova Scotia
Ontario
Florida
Missouri
Oklahoma
Ontario
British Columbia
Virginia
Virginia

Ontario
Alberta
Alberta
Mexico
Mexico
Arizona

State/Province/Countr

JESO Volume 143, 2012

Genebank
Accession #
KC157669
KC157670
KC157672
KC157673
KC157674
KC157671
KC157675
KC157676
KC157677
KC157678
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KC157682
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KC157684
KC157685
KC157686
KC157687
KC157688
KC157689
KC157690
KC157691
KC157701
KC157700
KC157699
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KC157695
KC157697
KC157696
KC157694
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Status of C. grvneus populations in SW Ontario JESO Volume 143, 2012

STATUS OF JUNIPER HAIRSTREAK (CALLOPHRYS GRYNEUS
HUBNER) POPULATIONS IN SOUTHWESTERN ONTARIO

S. DENOMME-BROWN, G. W. OTIS*
School of Environmental Sciences
University of Guelph
Guelph, ON NIG 2W1
e-mail: gotis@uoguelph.ca

Abstract J. ent. Soc. Ont. 144: 107-114

Populations of Juniper Hairstreak (Callophrys gryneus [Hiibner]) at Point
Pelee National Park (PPNP) and Pelee Island have declined over time and
are at risk of extirpation. We monitored them in the Red Cedar Savannahs
of PPNP from late May—end August and on Pelee Island in early June. Two
flights of adults occurred (maximum numbers observed daily in parentheses)
from 29 May—12 June (4 at PPNP; 11 at Pelee Island) and 19 July—12 August
(10 at PPNP) in and near intermediate-sized (mostly 5-7 m tall) junipers
among the upper dunes of a small portion of the point’s western shore and in
one clearing on Pelee Island. The primary nectar resource used by the first
brood was Prelea trifoliata L.; the second brood nectared infrequently on
several floral species.

Published December 2012

Introduction

The Juniper or Olive Hairstreak (Callophrys (Mitoura) gryneus gryneus (Hibner
[1819]) (hereafter “hairstreak”’) occurs in eastern Canada along the Frontenac Axis/Napanee
Plain of eastern Ontario; in a single site on the Gatineau escarpment in Quebec; and in the
western Lake Erie Basin (Layberry et al. 1998). First discovered in southwestern Ontario at
Point Pelee in 1882 (Saunders 1885), the population there has declined over time and nearly
disappeared between 1976—1984 (Layberry et al. 1998; Wormington 1999). In 1998, their
numbers increased dramatically, with a record daily maximum of 139 individuals observed
(Wormington 1999), but they have subsequently decreased markedly (Wormington, pers.
comm.). On Pelee Island, the species was reported to be extirpated (Layberry et al. 1998),
but a modest population was subsequently rediscovered (Hanks and Hess 1992). For the
other islands of western Lake Erie, there is a published record of only one individual
(Kelleys Island: Nault et al. 1989). The next closest populations are in southern Ohio and
western Pennslylvania. Adults occur in two broods each summer, the first beginning in late
May and the second in early to mid-July (Wormington, 1998).

* Author to whom all correspondence should be addressed.

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Denomme-Brown and Otis JESO Volume 143, 2012

Except when nectaring, Juniper Hairstreaks are almost always observed perched
or ovipositing on their larval host plant, the Eastern Red Cedar (Juniperus virginiana L.)
(henceforth ‘cedar’; Douglas and Douglas 2005). Males maintain territories on cedars but
are sedentary, making them difficult to detect without disturbing the trees (Iftner et al. 1992:
Douglas and Douglas 2005). Although most often reported in open stands of cedar 5—8
m tall (Iftner et al. 1992), C. grvneus, when abundant, can also be found on lone cedars
(Glassberg, 1999). The species has been reported to have disappeared from some sites that
have become overgrown or in which cedars have grown too large (Layberry et al. 1998).

Point Pelee National Park (PPNP) is located on the tip of a narrow peninsula that
extends southward into Lake Erie and contains Lake Erie Sand Spit Savannah habitat that
is exceptionally rare in Canada, existing only at PPNP, Rondeau Provincial Park, Long
Point, and Pelee Island (Dougan and Associates 2006). Numerous rare plant and animal
species are isolated on Point Pelee by water on two sides and by extensive farmland to the
north (McLachlan and Bazely 2002). In PPNP, C. gryneus has historically been found in
the savannah habitat that exists along the point’s western shore (Layberry and Jones 2008;
O’Neill, pers. comm.; Wormington, pers. comm.; C. Jones, pers. comm.). Its scarcity at
Point Pelee and on the Lake Erie Islands coupled with its isolation from other populations
renders it potentially at risk. PPNP personnel are considering the use of an ecosystem-
based approach to conserve C. gryneus and the rare habitat in which it lives (Dougan and
Associates 2007). A few patches of upper beach have already been cleared to improve habitat
for C. gryneus and several other endangered species. The Nature Conservancy of Canada
has begun habitat restoration on Pelee Island, including the planting of cedars, with the
stated goal of increasing the C. gryneus population there (Nature Conservancy of Canada
2008). Because knowledge of the population size of C. gryneus and its habitat requirements
is integral to future management initiatives, we monitored and observed Juniper Hairstreaks
in the cedar savannah of PPNP from late May—end August, and on Pelee Island in early
June, 2011.

Methods

Because C. gryneus is seldom observed far from host plants, PPNP reports (Dougan
and Associates 2007) and staff were consulted in order to determine the distribution of
cedars within the park. We focused on the three areas where cedars are abundant and the
habitat may be suitable for this species: clearings along the entire West Beach Footpath, the
small garden area north of the PPNP Visitors’ Centre, and clearings at the north end of the
DeLaurier Homestead Trail. We performed surveys from 11:00—16:00h on days when the
temperature was >17° C and there was no precipitation, climatic criteria consistent with
published butterfly survey techniques (Pollard 1977; Wikstrom et al. 2009).

We conducted surveys every few days, from 25 May —26 June, 2011, for the first
brood, and from 19 July—19 August, 2011, for the second brood. We stopped surveying
only after failing to record hairstreaks on three consecutive surveys. Initially, in order to
limit disturbance to the sensitive habitat, we shook all cedars (as described below) within
2.5 m of established trails. Upon encountering the first hairstreak of each flight period, we
conducted more intensive surveys both on- and off-trails, during which we disturbed every

108

Status of C. gryneus populations in SW Ontario JESO Volume 143, 2012

cedar tree by grasping and moving small trees or tapping and shaking taller trees with a
stick at a height of 3.75 m. All flowers within clearings were inspected as well. This was
performed along the West Beach Trail south of the PPNP Visitors’ Centre (29, 30 May; 2, 8,
9, 12, 15, 18, 20, 24, 25 June; 9, 19, 22, 23, 31 July; 1, 4, 6, 12, 17, 18, 19 Aug.); West Beach
Trail north of the PPNP Visitor’s Centre (29 May; 15, 17, 25, 26 June; 1, 3, 5, 15 Aug.);
in front of the PPNP Visitor’s Centre (1, 8, 9, 20, 25 June; 9, 23 July; 4, 17, 19 Aug.); and
along the DeLaurier Trail (1, 8, 14, 22 June; 3, 11 Aug.). Despite reports that the hairstreaks
prefer small to medium-sized cedars (Layberry et al. 1998), we inspected cedars of all sizes
to prevent bias in our survey.

For each hairstreak observed, we recorded GPS coordinates, habitat characteristics
(cedar height, nearby flowering plant species, and estimates of vegetation density),
and butterfly behaviour (flight height and pattern, perching, feeding behaviour, and
oviposition).

Between 4-6 June, 2011, two observers surveyed at least once all sites on Pelee
Island with sizeable Red Cedar populations. Five sites suggested to us by John Ambrose
(pers. comm.) included the locations where hairstreaks have been seen in recent history
(C. Jones, pers. comm.). Their coordinates are: N41.750° W82.647°, N41.757° W82.677°,
N41.752° W82.631°, N41.809° W82.644° and N41.761° W082.645°.

Results

At PPNP, from 29 May—12 June, we had 9 sightings of hairstreaks of the first
brood, with a daily maximum of 4 individuals recorded on 12 June. Individuals of the
second brood were observed from 19 July—12 August (45 individuals; maximum daily count
of 10 recorded on 4 August). All sightings were along the West Beach Footpath, from the
trailhead west of the PPNP Visitors’ Centre south to the end of the Tip Road. We observed
no hairstreaks elsewhere, although one was reported outside the PPNP Visitors’ Centre on 5
Aug. by park naturalist J. Brownlie. The sites occupied by hairstreaks were generally open
sandy areas with grasses up to 0.5 m high, numerous cedars and many Common Hoptrees
(Ptelea trifoliata L.). These clearings were either sheltered from the beach by vegetation or
the hairstreaks were >30 m from Lake Erie.

Five hairstreaks of the first brood were observed feeding on the blossoms of
Common Hoptree. They generally walked along branches from one inflorescence to another
rather than flying between them. Other flowering plant species at this time were scarce,
the most common being Hoary Puccoon (Lithospermum canescens (Michx.) Lehm.). The
remaining 4 hairstreaks were perched 2—6 m above ground on mid-sized cedars (6—7.5 m
tall). Most were sedentary until disturbed, at which point they made short flights to nearby
trees or back to the original branch. Flights were weak and erratic, with many directional
changes.

Forty-two of the 45 hairstreaks of the second brood that we observed were on
cedars. Most were perched 5-7 m above the ground. Flight behavior was consistent with
hairstreaks of the first brood. Two females were observed ovipositing at a height of ~3 m on
6—7.5 m tall cedars. Twenty-five observations were ina single clearing (Figure 1). Only three
second-brood individuals were observed feeding, all on non-native species: Bouncing Bet

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Denomme-Brown and Otis JESO Volume 143, 2012

FIGURE 1. Clearing typical of habitat along West Beach Footpath where Juniper Hairstreaks
were found. This particular clearing was the location of 25 (56%) of all second brood
sightings.

(Saponaria officinalis L.), Queen Anne’s Lace (Daucus carota L.), and White Sweet Clover
(Melilotus alba Medik.). Despite extending its proboscis, the individual on Saponaria may
not have successfully fed due to the long corolla length of the flower. Spotted Knapweed
(Centaurea maculosa Lam.), a very common invasive species, was in bloom close to all
observed hairstreaks, but we saw none feeding upon it. Other plants in flower nearby were
Common Mullein (Verbascum thapsus L.), Rough-Fruited Cinquefoil (Potentilla recta
L.), Staghorn Sumac (Rhus typhina L.), Wild Bergamot (Monarda fistulosa L.), and the
endangered Eastern Prickly Pear Cactus (Opuntia humifusa (Raf.) Raf.).

During the Pelee Island surveys on 4—6 June, we encountered 9, 10, and 11
hairstreaks on 4, 5, and 6 June, respectively. All were sighted in a single sheltered clearing
with scattered cedars in a forested part of the Richard and Beryl Ivey Conservation Area
(N 41.757 W 082.677). As at PPNP, these hairstreaks were predominantly on Common
Hoptree flowers, but one was observed feeding on Raspberry (Rubus idaeus L.) flowers. At
times up to three were observed feeding on a single Common Hoptree inflorescence (Figure
2). Other flowers nearby included Hairy Beardtongue (Penstemon hirsutus L.) and Eastern
Red Columbine (Aquilegia canadensis L.).

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Status of C. gryneus populations in SW Ontario JESO Volume 143, 2012

: a % ie " ‘
FIGURE 2. Two Juniper Hairstreaks oie on Common Hionuse flowers.

Discussion

The C. gryneus populations we observed at PPNP and on Pelee Island were
small. We did observe more individuals than have been reported in recent years (Layberry
and Jones, 2009; C. Jones, pers. comm.); this may reflect in part our intensive surveying
methods. The first brood of hairstreaks at PPNP is reported to be usually larger than the
second (Wormington, pers. comm.) but this was not the case in 2011. The late spring and
frequent rain in June may have negatively affected the size of the first brood or positively
affected the numbers in the second brood. From our observations, Common Hoptree flowers
were the primary nectar source for the first brood of C. grvneus both at PPNP and on Pelee
Island, either by preference or from lack of suitable alternatives.

The absence of hairstreaks along the West Beach Trail north of the Visitors’ Centre
was likely due to the overgrowth of trees and shrubs (Figure 3), causing extensive shade
and a low abundance of nectar sources (e.g., Common Hoptrees were absent). Sections of
this path that were not overgrown were often quite exposed and beach-like, with no shelter
from the lake and with fewer, often large (>12 m tall) cedars that were likely too large to be
suitable for oviposition (Layberry et al. 1998).

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Denomme-Brown and Otis JESO Volume 143, 2012

FY
i]
*

»

BS fot ee hehe PY eS: ae oe 2:
FIGURE 3. Overgrown Red Cedar Savannah typical of West Beach Footpath north of the
Point Pelee Visitors’ Centre, with a Red Cedar tree visible in the center of the photo. No
Juniper Hairstreaks were observed in this habitat.

The clearings at the northern portion of DeLaurier Homestead Trail appeared
very similar to sites where we observed hairstreaks except that Common Hoptrees were
scarce. The absence of a suitable nectar source for the first brood may have contributed to
the hairstreaks’ absence from this otherwise apparently suitable habitat. Individuals of the
second brood were infrequently observed feeding on only three species of flowers despite
many other species being present. The lack of hairstreaks feeding on Spotted Knapweed
was striking, particularly since Alan Wormington (pers. comm.) has observed C. gryneus
nectaring on it in other years.

Unfortunately, we could not mark the hairstreaks due to the fragility of these small
butterflies and concerns that we might harm them and further reduce their populations.
However, because of our intensive search method for hairstreaks both on cedars and on
flowers, their sedentary nature, and their tendency to return to the same site after disturbance,
we are confident that we observed a high proportion of the hairstreaks that were present at
both Point Pelee and Pelee Island. It is therefore likely that the populations at both sites
consisted of less than 100 individuals. This is well below the effective population size that
is generally considered critical for a population to maintain sufficient genetic variation for
adaptive evolution to occur (Lynch and Lande 1998). Therefore, the efforts to open up
overgrown cedar stands, as have already begun by the staff at PPNP and the NCC, and
increasing the number of appropriate adult nectar sources would seem to be suitable first
steps to hairstreak population recovery at PPNP and Pelee Island. The status of the Juniper
Hairstreak on the other Lake Erie Islands is unknown: the only reports have been of three

112

Status of C. gryneus populations in SW Ontario JESO Volume 143, 2012

individuals from Kelleys Island, in 1988 (Nault et al.1989), ~2000 (B. Coleman, pers.
comm.), and as recently as 2010 (D. Horn, pers. comm).

The geographic isolation of the Lake Erie Basin metapopulation from other
populations of Juniper Hairstreaks prompts questions regarding its genetic distinctness. It
would be interesting to know the degree of genetic dissimilarity with C. gryneus from the
three closest populations: Napanee, Ontario (~500 km to the east), southern Ohio/west-
central Indiana (~260-400 km to the south and southwest), and western Pennsylvania (~300
km to the southeast). This species should be surveyed in other Red Cedar Savannah habitats
at Rondeau Provincial Park, Long Point, and the Lake Erie Islands of Ohio.

Acknowledgements

We are grateful to Alan Wormington for sharing his vast knowledge of the butterflies
of Point Pelee. Thanks also go to Henrietta O’Neill for her advice regarding our surveys.
Timothy J. Brown assisted with fieldwork on Pelee Island. Colin Jones compiled data
regarding Juniper Hairstreaks from records of the Toronto Entomologists’ Association. Barb
Coleman, Cleveland Museum of Natural History and Dave Horn shared their observations
from Kelleys Island. Mhairi McFarlane and the staff of the Nature Conservancy of Canada
granted us use of the Ivey Research Station on Pelee Island. John Ambrose shared his
extensive knowledge of the flora of Pelee Island. The entire staff of PPNP was supportive
and shared their knowledge throughout the entire project. Comments of Peter Hall, an
anonymous reviewer, and the journal editor greatly improved this manuscript.

References

Dougan and Associates. 2007. Point Pelee National Park Ecological Land Classification
and Plant Species at Risk Mapping and Status, Prepared for Parks Canada Agency,
Point Pelee National Park, Leamington, Ontario. 109 pp. + Appendices A—H +
Maps.

Douglas, M. M. and Douglas, J. M. 2005. Butterflies of the Great Lakes Region. University
of Michigan Press, Ann Arbor, MI, USA. 345 pp.

Glassberg, J. 1999. Butterflies through Binoculars: The East. A Field Guide to the Butterflies
of Eastern North America. Oxford University Press, Oxford, UK. 400 pp.

Hanks, A. J. and Hess, Q. F. (eds.). 1992. Butterflies of Ontario & Summaries of Lepidoptera
Encountered in Ontario in 1991. Toronto Entomologists’ Association, Toronto,
ON, Canada. 94 pp. (www.ontarioinsects.org/Publications/Summaries/1991.pdf).

Iftner, D. C., Shuey, J. A. and Calhoun, J. V. 1992. Butterflies and Skippers of Ohio. Ohio
Biological Survey Bulletin, New Series, Vol. 9, College of Biological Sciences,
Ohio State University, Columbus, OH, USA. 212 pp.

Layberry, R. A., Hall, P. W. and Lafontaine, J. D. 1998. The Butterflies of Canada. University
of Toronto Press, Toronto, ON, Canada. 376 pp.

113

Denomme-Brown and Otis JESO Volume 143, 2012

Layberry, R. A. and Jones, C. D. (eds.) 2008. Ontario Lepidoptera 2006-2007. Toronto
Entomologists’ Association, Toronto, ON, Canada. 93 pp. (www.ontarioinsects.
org/Publications/Summaries/2006-07.pdf)

Lynch, M. and Lande, R. 1998. The critical effective size for a genetically secure population.
Animal Conservation 1: 70-72.

McLachlan, S. M. and Bazely, D. R. 2002. Outcomes of longterm deciduous forest restoration
in southwestern Ontario, Canada. Biological Conservation 112: 159-169.

Nature Conservancy of Canada. 2008. Management Guidelines: Pelee Island Alvars. NCC—
Southwestern Ontario Region, London, ON, Canada. 43 pp.

Nault, B. A., Rings, R. W. and Horn, D. J. 1989. Lepidoptera recorded from the islands
of western Lake Erie, with a brief account of the geology and flora. Great Lakes
Entomologist 22: 111-119.

Pollard, E. 1977. A method for assessing changes in the abundance of butterflies. Biological
Conservation 12: 115-134.

Saunders, W. 1885. Brief notes of a trip to Point Pelee, with additions to our list of Canadian
butterflies. The Canadian Entomologist 16: 50-53.

Wikstrom, L., Milberg, P. and Bergman, K. O. 2009. Monitoring of butterflies in semi-natural
grasslands: diurnal variation and weather effects. Journal of Insect Conservation
13: 203-211.

Wormington, A. 1998. The Butterflies of Point Pelee National Park: a Seasonal Guide and
Checklist. The Ontario Natural History Press, Leamington, ON, Canada.
Wormington, A. 1999. An outbreak of Olive Hairstreaks (Callophrys grynea) at Point
Pelee, Ontario, in 1998. (Pp 9-11) in Hanks, A. J. (ed.), Butterflies of Ontario
& Summaries of Lepidoptera Encountered in Ontario in 1998. The Toronto
Entomologists’ Association, Toronto, ON, Canada. 81 pp. (www.ontarioinsects.

org/Publications/Summaries/1998.pdf)

114

Larval parasitoids of the Cabbage Looper in SW Ontario JESO Volume 143, 2012

LARVAL PARASITOIDS OF THE CABBAGE LOOPER,
TRICHOPLUSIA NI (LEPIDOPTERA: NOCTUIDAE), IN FIELD
TOMATO CROPS IN SOUTHWESTERN ONTARIO

H. MURILLO’, D. W. A. HUNT?, S. L. VANLAERHOVEN?
Department of Biology, University of Windsor,
401 Sunset Avenue, Windsor, ON, Canada NOB 3P4.
email: murilloph@gmail.com

Scientific Note J. ent. Soc. Ont. 143: 115-119

The Cabbage Looper, Trichoplusia ni Hiibner (Lepidoptera: Noctuidae) is a
cosmopolitan insect pest that causes damage in more than 160 species of plants (Sutherland
and Greene 1984), and has become a chronic pest of Canadian greenhouse vegetable crops
(Gillespie et al. 2002). Each spring, the overwintering population of 7: ni migrates north
from the southern United States to establish seasonal populations in Canada (Lafontaine
and Poole 1991). In commercial indoor settings, growers rely on Btk (Bacillus thuringiensis
var. kurstaki) products to manage outbreaks of 7: ni. Outdoors, growers rely on chemical
pesticides. Btk appears to be compatible with natural enemies and insect pollinators although
the recent development of 7: ni resistance to Btk is a major concern in the vegetable industry
(Janmaat and Myers 2003) and new and effective natural enemies are needed. The objective
of this study was to determine the native parasitoid assemblage of larval stages of 7. ni
in tomato fields in southwestern Ontario for the selection of potential biological control
agents.

A survey for larval parasitoids of 7. ni was conducted on field tomato (Solanum
lycopersicum Mill.) (Solanaceae) crops in 2005 and 2006 in Essex County, Ontario. Three
2000-plant plots of commercial processing tomato were planted with the varieties Heinz
Q909, TH4, and an experimental hybrid in 2005. In 2006, Heinz 9478 was used in all
three plots. Plots were located on three different farms separated by about 5 km from each
other. One hundred tomato plants per plot were sampled weekly beginning on May 20 in
2005 and on June 13 in 2006. Larvae collected from the survey were reared individually
on a pinto bean diet (Shorey and Hale 1965) in a growth chamber at 24°C, with a 12:12
photoperiod and 60% RH until emergence of parasitoids or an adult 7. ni moth. The number
of parasitised larvae of each instar of 7. ni by each parasitoid was recorded and compared
using Chi-Square tests.

Nine species of primary parasitoids (eight Hymenoptera and one unidentified
Diptera—Tachinidae) were reared from larval stages of 7: ni, but only 7 of them within each
of the two years (Table 1) and one hyperparasitoid, Trichomalopsis viridescens (Walsh)

Published December 2012
' Author to whom all correspondence should be addressed.
* AAFC —- Greenhouse and Processing Crops Research Centre, 2585 County Rd. 20, Harrow,

ON, Canada NOR 1G2
> Same address as first author.

115

JESO Volume 143, 2012

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116

Larval parasitoids of the Cabbage Looper in SW Ontario JESO Volume 143, 2012

(Hymenoptera: Pteromalidae), was reared from Campoletis sonorensis (Cameron). Although
Braconidae had the higher number of species, Ichneumonidae had the greatest parasitism
rates due to dominance of the solitary larval endoparasitoid C. sonorensis (Table 1), which
was found parasitising 7. ni larvae from the collection date of 7. ni larvae within each year.
Other larval parasitoids were rarely found (Table 1). From 400 7: ni larvae in 2005 and
365 in 2006 for which we determined the instar at collection, the 2" instar of 7. ni was the
larval stage with the highest parasitism rates by C. sonorensis and by all the other parasitoid
species as well (Table 2). The number of parasitised 2" instars differed significantly from
all other parasitised instars combined in both years (2005: X°, , = 43.422, P< 0.001; 2006:
Xx? , = 59.038, P< 0.001).

In North America, Copidosoma floridanum (Ashmead) and Cotesia marginiventris
(Cresson) are reported as common parasitoids of 7: ni (Marston et al. 1984; Martin et al.
1984: Godin and Boivin 1998; Waterhouse 1998; Shelton et al. 2002; Wold-Burkness et al.
2005), C. sonorensis and Microplitis alaskensis (Ashmead) have rarely been collected from
T. ni (Martin et al. 1984; Waterhouse 1998), Cotesia plathypenae (Muesebeck) is a new
record for 7. ni, and Euplectrus species are commonly reported but Meteorus species are
not (Marston et al. 1984; Martin et al. 1984; Waterhouse 1998; Wold-Burkness et al. 2005).
The hyperparasitoid T. viridescens is associated with several braconid and ichneumonid
parasitoids attacking Noctuidae (Lepidoptera) (Gibson and Floate 2001) but our work
seems to be the first report on C. sonorensis and T: ni.

Campoletis sonorensis has been well studied for control of Helicoverpa species and
Spodoptera frugiperda (J.E. Smith) in corn and cotton crops (Lingren 1977; Isenhour 1986)
but has been reported on T. ni only once in southern California in lettuce (Lactuca sativa
L., Asteraceae) (Henneberry et al. 1991) and once (as C. websteri) in Texas (crop host not
reported) (Carlson 1972; Harding 1976). We believe C. sonorensis should be evaluated as a
biological control agent for 7. ni in field and greenhouse crops in southwestern Ontario due
to its high natural abundance and synchrony with 7: ni populations (Murillo et al. 2009).

TABLE 2. Overall total percent parasitism of Trichoplusia ni larval instars. Numbers in
bold indicate significantly higher parasitism rates as compared to other instars (Chi-Square
test, P>0.05).

Year 2005 2006
Larvae Campoletis All other Larvae Campoletis All other

Instar (#) sonorensis (%) parasitoids (%) (#) sonorensis (%) parasitoids (%)

1 4] 0.0 0.0 7 0.0 0.0

2 210 DAL) 3.8 7 31.6 8.5

3 118 D5) ibei 84 8.3 4.8

4 24 0.0 0.0 54 0.0 129

5 7 0.0 0.0 43 0.0 0.0
Total 400 Pou DRS 365 a3) DS)

117

Murillo et al. JESO Volume 143, 2012

Acknowledgements

We thank the Ontario Centre of Excellence, Gualtieri Farms, Agriculture and Agri-Food
Canada, and the University of Windsor for the financial support of this research. We also
thank the Canadian National Collection of Insects staff Dr. A. Bennett (Ichneumonidae),
Dr. H. Goulet (Braconidae), Dr. J. Huber (Eulophidae) and Dr. G. Gibson (Encyrtidae and
Pteromalidae) for the identification of parasitoids.

References

Carlson, R. W. 1972. Suppression of the name Campoletis perdistincta (Hymenoptera:
Ichneumonidae) and the identity of species to which the name has been applied.
Entomological News 83: 75-82.

Gillespie, D. R., Raworth, D. A and Shipp, J. L. 2002. Trichoplusia ni Hiibner, Cabbage
Looper (Lepidoptera: Noctuidae). Pp. 269-271, in Mason, P. G., and J. T. Huber, J.
T. (eds), Biological Control Programmes in Canada, 1981-2000. CABI Publishing,
New York, NY.

Gibson, G. A. P. and Floate, K. D. 2001. The species of Trichomalopsis (Hymenoptera:
Pteromalidae) associated with filth flies (Diptera: Muscidae) in North America.
The Canadian Entomologist 133: 49-85.

Godin, C. and Boivin, G. 1998. Lepidopterous pests of Brassica crops and their parasitoids
in southwestern Quebec. Environmental Entomology 27: 1157-1165.

Harding, J. A. 1976. Seasonal occurrence, hosts, parasitism and parasites of cabbage and
soybean loopers in the Lower Rio Grande Valley. Environmental Entomology 5:
672-674.

Henneberry, T. J., Vail, P. V., Pearson, A. C. and Sevacherian, V. 1991. Biological control
agents of noctuid larvae (Lepidoptera: Noctuidae) in the Imperial Valley of
California. Southwestern Entomologist 16: 81—89.

Isenhour, D. J. 1986. Developmental time, adult reproductive capability, and longevity
of Campoletis sonorensis (Hymenoptera: Ichneumonidae) as a parasitoid of
fall armyworm, Spodoptera frugiperda (Lepidoptera: Noctuidae). Annals of the
Entomological Society of America 79: 893-897.

Janmaat, A. F. and Myers, J. H. 2003. Rapid evolution and the cost of resistance to Bacillus
thuringiensis in greenhouse populations of cabbage looper, Trichoplusia_ ni.
Proceedings of the Royal Society of London B 270: 2263-2270.

Lafontaine, J. D. and Poole, R. W. 1991. Noctuoidea, Noctuidae (part) — Plusiinae. Fascicle
25.1. The moths of America North of Mexico. The Wedge Entomological Research
Foundation, Washington, DC.

Lingren, P. D. 1977. Campoletis sonorensis: Maintenance of a population on tobacco
budworms in a field cage. Environmental Entomology 6: 72-76.

Marston, N. L., Hostetter, D. L., Pinnell, R. E., Dickerson, W. A. and Smith, D. B. 1984.
Natural mortality of lepidopteran eggs and larvae in Missouri soybeans. Annals of
the Entomological Society of America 77: 21-28.

118

Larval parasitoids of the Cabbage Looper in SW Ontario JESO Volume 143. 2012

Martin, P. B., Lingren, P. D. and Greene, G. L. 1984. Role of parasitoids and predators
in regulating populations. Pp. 76-91, in Lingren, P. D. and Greene, G. L. (eds),
Suppression and management of cabbage looper populations. USDA Technical
Bulletin 1684.

Murillo, P. H., Hunt, D. W. A. and VanLaerhoven, S. L. 2009. Parasitism dynamics of
Campoletis sonorensis Cameron (Hymenoptera: Ichneumonidae) as a larval
endoparasitoid of the Cabbage looper, Trichoplusia ni Hiibner (Lepidoptera:
Noctuidae). JOBC/WPRS Bulletin 49: 233-238.

Shelton, A. M., Wilsey, W. T., Hoebeke, E. R. and Schmaedick, M. A. 2002. Parasitoids of
cabbage Lepidoptera in central New York. Journal of Entomological Science 37:
270-271.

Shorey, H. H. and Hale, R. L. 1965. Mass-rearing of the larvae of nine noctuid species on a
single artificial medium. Journal of Economic Entomology 58: 522-524.
Sutherland, D. W. and Greene, S. G. L. 1984. Cultivated and wild host plants. Pp 1—13, in
Lingren, P. D. and Greene, G. L (eds), Suppression and management of cabbage

looper populations. USDA Technical Bulletin 1684.

Waterhouse, D. F. 1998. Trichoplusia ni. Pp. 317-348, in Biological Control of Insect
Pests: Southeast Asian Prospects. Australian Centre for International Agricultural
Research. Canberra.

Wold-Burkness, S. J., Hutchison, W. D., Lee, J. C., Hines, R. L., Bolin, C. and Heimpel,
G. E. 2005. A long-term survey of parasitoid species composition and parasitism
of Trichoplusia ni (Lepidoptera: Noctuidae), Plutella xylostella (Lepidoptera:
Plutellidae), and Pieris (=Artogeia) rapae (Lepidoptera: Pieridae) in Minnesota
cabbage. Journal of Entomological Science 40: 211—221.

119

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The first Nearctic record of C. atrimana JESO Volume 143, 2012

FIRST NEARCTIC RECORD OF CAMILLA ATRIMANA
(DIPTERA: CAMILLIDAE)

J. H. KITS*, J. HOLDENRIED, S. M. PAIERO
School of Environmental Sciences, University of Guelph
50 Stone Road West, Guelph, ON, Canada NIG 2W1
e-mail: joel.kits@gmail.com

Scientific Note J. ent. Soc. Ont. 143: 121-124

Members of Camillidae are among the least known Diptera in the Nearctic Region.
Worldwide, this small family consists of four extant genera and approximately 40 species
(Pape et al. 2011). Most species occur in the Palearctic and Afrotropical regions, and the
family was not recorded in the New World until McAlpine (1960) noted the occurrence of
Camilla glabra (Fallen) in Ottawa, Ontario. Camilla glabra is a widespread Palearctic species
and its occurrence in the New World presumably represents an accidental introduction.
The family was included in McAlpine (1987) on the basis of this population. Barraclough
and Wheeler (1995) later described two endemic species of Afrocamilla Barraclough from
Arizona and California and one of Camilla Haliday from Baja California, and Barraclough
and Fitzgerald (2001) described an additional species of Afrocamilla from Colorado.
Barraclough and Wheeler (1995) examined the status of C. glabra , noting that specimens
were only collected in a small area of Ottawa between 1954 and 1965 and suggesting that
this population is likely extirpated. Thus the current known Nearctic fauna of Camillidae
consists of three species of Afrocamilla and one of Camilla. Here we record and key an
additional species of Camilla in the Nearctic region.

The specimens of Camilla atrimana Strobl reported here were collected with a
Vortis suction sampler (Burkard Manufacturing Co. Ltd., Hertfordshire, UK) during an
invertebrate survey of experimental grass plots at the Guelph Turfgrass Institute. They
are deposited in the University of Guelph Insect Collection, Guelph, ON (DEBU); we
also examined material from the Canadian National Collection of Insects, Arachnids &
Nematodes, Ottawa, ON (CNCI).

Key to Nearctic Camilla species

1 Scutum mostly shining. Wing apex rounded. Legs yellow. ...............0:ccccsceseeees 2

~ Scutum covered with microtomentum. Wing apex distinctly pointed. Femora 1-3
and tibia 1! blacketibiac 2 andes bray as (Bice sooo = onan cs csec le racsecisneeneseeceneeees

Published December 2012

* Author to whom all correspondence should be addressed.

121

Kitts et al. JESO Volume 143, 2012

2 About 7 genal bristles subequal to vibrissal length. Tegite 2 without enlarged
median bristles....¢5%.A 445.5. 34 56 A000 te SOE OS Bee
Sco doce C. glabra (Ontario, adventive; Nearctic population probably extirpated)
One genal bristle subequal to vibrissal length. Tergite 2 with medial pair of bristles
enlargeds.20h accel tees iN Ree ih ee C. arnaudi (Baja California)

Camilla atrimana Strobl

Camilla glabra var. atrimana Strobl 1910
Camilla atripes Duda 1934

Camilla atrimana: Papp 1985 (key, illustration)

FIGURE 1. Lateral habitus of female Camilla atrimana from Guelph, Ontario.

The first Nearctic record of C. atrimana JESO Volume 143; 2012

Material examined. Canada: ON: Guelph, Guelph Turfgrass Institute, 43°32'56”N
80°13'06"W, June 2010, J. Holdenried (2 ¢ 199, DEBU). Germany: Ingelheim am Rhein,
Malaise trap, July 1965 (2 ¢ 4 2, CNCI). Great Britain: Devon: Paignton, 6 June 1960,
J.R. Vockeroth (2 4, CNCI), same but 23 August 1960 (1 @, CNCI); Devon: Clennon
Valley, Paignton, 23 August 960 (1 2, CNCI), same but 26 August 1960 (1 ¢ 2 2, CNCI);
Devon: Torquay, 25 June 1960, J.R. Vockeroth (1 ¢@, CNCI); Devon: Berry Head, Brixham,
1 September 1960 (1 2, CNCI).

Members of the family Camillidae can be separated from other Nearctic Diptera
based on a combination of characters: one proclinate and one reclinate orbital bristle, arista
with long dorsal rays and very short ventral rays, an episternum with at least one strong
bristle, fore femur with anteroventral spines, mid tibia with preapical dorsal bristle, cell cup
not developed, and cells bm and dm confluent. Species of camillids are most similar to those
of Drosophilidae and Diastatidae, which also have proclinate and reclinate orbital bristles
and often a plumose arista; however, species in both these families lack a strong anepisternal
bristle, have two reclinate orbital bristles and a complete cell cup, and usually have the
arista with dorsal and ventral rays of similar size. Camilla atrimana is a typical member of
the genus, based on the plumose arista, two dorsocentral bristles, clear wing, and abdominal
tergite 2 not bulging posteriorly. There is no single key to all the species of Camilla, but
Papp (1985) covers all Palearctic members of the genus. The three African species can be
excluded as they lack the preapical dorsal bristle on the mid tibia and anteroventral spine
on the fore femur (Barraclough 1993). The newly collected Guelph specimens externally
match the descriptions and available European material of C. atrimana, and the genitalia of
a dissected male match illustrations of this species provided by Papp (1982).

In general, camillid specimens are rarely collected. Three of the Nearctic species
are known from single specimens (Barraclough and Wheeler 1995), and the Afrotropical
diversity was almost entirely unknown until collectors began to focus on rock hyrax, Procavia
capensis (Pallas), latrines and bat guano in caves (Barraclough 1997). Most Camillidae
are associated with small mammal nests and burrows but the biology of C. atrimana is
unknown; it is unlikely to be of any economic significance and potential ecological impacts
cannot be determined until more information about its biology and New World distribution
is known. Suction trapping appears to be an effective method of collecting some acalyptrate
Diptera groups that are generally under-recorded by standard sampling techniques (e.g.,
some Anthomyzidae). Whether this accounts for the lack of previous records of C. atrimana
from the New World, or if this Palaearctic species only recently became established in the
Nearctic region is unknown.

Acknowledgements

Samples were obtained through research led by Jonathan Newman (University of Guelph)
and funded by OMAFRA. Jeffrey Skevington (CNCI) loaned material for comparison.
Stephen Marshall (University of Guelph) and two anonymous reviewers provided valuable
suggestions on earlier drafts of this note.

123

Kitts et al. JESO Volume 143, 2012

References

Barraclough, D. A. 1993. Teratocamilla, a new genus of Camillidae (Diptera) and two new
species of Camilla, from southern Africa. Annals of the Natal Museum 34: 19-30.

Barraclough, D. A. 1997. The African species of Afrocamilla Barraclough, 1992 (Diptera:
Schizophora), a genus of Camillidae associated with rock hyrax latrines. Annals of
the Natal Museum 38: 2\—S3.

Barraclough, D. A. and Fitzgerald, S. J. 2001. A new Afrocamilla from Colorado, the third
species of Camillidae (Diptera: Schizophora) from the United States. Tijdschrift
voor Entomologie 144: 1-4.

Barraclough, D. A. and Wheeler, T. A. 1995. Three new species of Camillidae (Diptera)
from the southwestern Nearctic region, the first species of the family described
from the New World. Proceedings of the Entomological Society of Washington
97: 737-745.

McAlpine, J. F. 1960. First record of the family Camillidae in the New World (Diptera). The
Canadian Entomologist 42: 954-956.

McAlpine, J. F. 1987. Camillidae. Pp. 1023-1025 in McAlpine, J. F., et al. (eds), Manual of
Nearctic Diptera, Volume 2. Agriculture Canada Monograph 28.

Pape, T., Blagoderov, V. and Mostovski, M. B. 2011. Order DIPTERA Linnaeus, 1758. Pp.
222-229, in Zhang, Z.-Q. (ed), Animal biodiversity: An outline of higher-level
classification and survey of taxonomic richness. Zootaxa 3148.

Papp, L. 1982. A revision of the species of Camilla Haliday described by J. E. Collin
(Diptera: Camillidae). Memoirs of the Entomological Society of Washington
10: 125-135.

Papp, L. 1985. Akey to the world species of Camillidae (Diptera). Acta Zoologica Hungarica
31: 217-227.

First record of Drvocosmus kuriphilus in Canada JESO Volume 143, 2012

FIRST RECORD OF THE ORIENTAL CHESTNUT GALL WASP,
DRYOCOSMUS KURIPHILUS YASUMATSU (HYMENOPTERA:
CYNIPIDAE), INCANADA

JT HUBER*; J: READ
Natural Resources Canada, c/o Canadian National Collection of Insects, AAFC,
960 Carling Avenue, Ottawa, ON, Canada, K1A 0C6
email: john.huber@agr.gc.ca

Scientific Note J. ent. Soc. Ont. 143 : 125-128

The Oriental Chestnut Gall Wasp, Drvocosmus kuriphilus Yasumatsu (Hymenoptera:
Cynipidae), originally from China, has become established in several other Asian countries,
the USA, and Europe where it is parasitized by various species of Chalcidoidea that normally
exploit oak gall wasps (Aebi et al. 2007). In the USA, D. kuriphilus was first recorded in
1974 and has been found in 10 states as far north as Pennsylvania and Ohio, on two Nearctic
species of Castanea: C. dentata (Marshall) Borkhausen, and C. pumila Miller (Dixon et
al. 1986; Anagnostakis 1997; Warmund 2009). Viggiani and Nugnes (2010) described and
illustrated the larva. Numerous other Nearctic species are assigned to Drvocosmus (Burks
1979), the most recently described on Chrysolepis spp. (Buffington and Morita 2009).

We record for the first time the presence of D. kuriphilus in Canada and illustrate
the adult and leaves with galls (Figs. 1-9). The galls (Figs. 8, 9) on a Chinese chestnut
tree, C. mollissima Blume, had been collected in Niagara-on-the-Lake and submitted
for identification to the National Identification Service, Canadian National Collection of
Insects, Arachnids and Nematodes, Ottawa (CNC). The twigs were placed in a rearing cage
and one Dryocosmus specimen eventually emerged. Because no identified material of this
species for comparison was in the CNC and there is no North American key to species of
Dryocosmus they could only be tentatively identified by us as D. kuriphilus. Photographs
were sent for identification to a specialist in Hungary and he confirmed that the genus was
correct, and the species was almost certainly D. kuriphilus. The actual specimen was sent
to a specialist in USA who confirmed that it is indeed this species. Another specimen, a
species of Jorymus (Hymenoptera: Torymidae), was found crawling about on the outside
of the rearing cage and was collected. Presumably, it also emerged from the galls and found
its way out of the cage (which had a narrow gap at the top) but there is a faint possibility
that it came through an open window from elsewhere and not from the D. kuriphilus galls.
Photographs of the Zorymus (Figs. 10-17) were sent to a specialist in Czech Republic and he
identified the species as the widespread, polyphagous species, 7. tuwbicola (Osten Sacken)
(Hymenoptera: Torymidae).

Material examined. CANADA: ON, Niagara on the Lake, 21.vi.2012 (galls
collected), 9.vii.2012 (cynipid emerged), A. Harnden, ex Castanea mollissima (12, CNC).
Torymidae: likely same data but collected in mid July (12, CNC).

Published December 2012

* Author to whom all correspondence should be addressed.

125

Huber and Read JESO Volume 143, 2012

FIGURES 1-7. Dryocosmus kuriphilus. 1, habitus, lateral; 2, head, anterior; 3, mesosoma,
dorsal; 4, antenna; 5, mesosoma, lateral; 6, ovipositor, ventral; 7, propodeum, dorsal.

First record of Dryocosmus kuriphilus in Canada JESO Volume 143, 2012

FIGURES 8—17. 8 and 9, Castanea mollissima leaves with galls. 8, upper leaf modified with
gall; lower leaf normal. 9, deformed leaf with gall. 10-17, Zorymus tubicola. 10, habitus,
lateral; 11, fore wing venation; 12, tibial spurs and basitarsus; 13, head, dorsal; 14, head and
antennae, lateral; 15, clypeus; 16, metasoma, dorsal; 17, mesosoma, posterodorsal.

127

Huber and Read JESO Volume 143, 2012

Acknowledgements

We thank J. Holmes (Canadian Food Inspection Agency, Hamilton) for submitting fresh
chestnut leaves with galls for rearing, identification and photography. G. Melika (Budapest
Pest Diagnostic Laboratory, Directorate of Plant Protection, Soil Conservation and Agri-
environment, Budapest) and M. Buffington (Systematic Entomology Laboratory, USDA,
Washington, DC), both specialists on Cynipoidea, identified the gall wasp. The parasitoid
was identified by P. Jansta (Department of Zoology — Entomology, Charles University,
Prague). Their prompt help is much appreciated.

References

Aebi, A., Schénrogge, K., Melika, G., Quacchia, A., Alma, A. and Stone, G. N. 2007.
Parasitoid recruitment to the globally invasive chestnut gall wasp Dryocosmus
kuriphilus. EPPO Bulletin 37: 166-171.

Anagnostakis, S. L. 1997. Oriental chestnut gall wasp found on American chestnut trees.
The Connecticut Agriculture Experiment Station. http://www.ct.gov/caes/cwp/
view.asp?a=2815&q=376818 [content last modified on 6/28/2012] (accessed 2
October, 2012).

Burks, B. D. 1979. Superfamily Cynipoidea. Pp. 1045-1107 in Krombein, K. V., Hurd Jr.,
P. D., Smith, D. R., and Burks, B. D. (eds), Catalog of Hymenoptera in America
north of Mexico 1. Washington, DC: Smithsonian Institution Press. 1198 pp.

Buffington, M. L. and Morita, S. I. 2009. Not all oak gall wasps gall oaks: the description
of Dryocosmus rileypokei, a new, apostate species of Cynipini from California.
Proceedings of the Entomological Society of Washington 111: 244-253.

Dixon, W. N., Burns, R. E. and Stange, L. A. 1986. Oriental chestnut gall wasp, Dryvocosmus
kuriphilus Yasumatsu (Hymenoptera: Cynipidae). Florida Agriculture & Consumer
Service., Division of Plant Industry, Entomology Circular 287. | p.

Viggiani, G. and Nugnes, F. 2010. Description of the larval stages of Dryokosmus [sic]
kuriphilus Yasumatsu (Hymenoptera: Cynipidae), with notes on their phenology.
Journal of Entomological and Acarological Research, Series 2 42: 39-45.

Warmund, M. 2009. Oriental chestnut gall wasp Dryocosumus [sic] kuriphilus Yasumatsu.
University of Missouri Extension. Pest Alert 100. http://extension.missouri.edu/
explorepdf/agguides/pests/pal00.pdf (accessed 2 October, 2012).

JESO Volume 143, 2012

THE ENTOMOLOGICAL SOCIETY OF ONTARIO
OFFICERS AND GOVERNORS
2012-2013

President: J. SKEVINGTON

Agriculture and Agri-Food Canada,

K.W. Neatby Building

960 Carling Avenue, Ottawa, ON K1A 0C6
jskevington@gmail.com

President-Elect: J. MCNEIL

Department of Biology

Biological and Geological Sciences Building
University of Western Ontario, London, ON N6A 5B7
jmeneil2@uwo.ca

Past-President: B. GILL

Entomology Unit, Ontario Plant Laboratories,

Canadian Food Inspection Agency. Building 18 C.E.F.

960 Carling Ave., Ottawa, ON K1A 0C6
bruce.gill@inspection.ge.ca

Secretary: N. MCKENZIE

Vista Centre, 1830 Bank Street, P.O. Box 83025
Ottawa, ON K1V 1A3
nicole_mekenzie@hc-sc.ge.ca

Treasurer: S. LI

Pest Management Centre, Building 57
Agriculture and Agri-Food Canada

960 Carling Ave., Ottawa, ON K1A 0C6
Dr.Shiyou.Li@nrcan.ge.ca
Directors:

C. BAHLAI

School of Environmental Science
University of Guelph

Guelph, ON NIG 2W1
cbahlai@uoguelph.ca

R. BUITENHUIS (2011-2013)
Vineland Research and Innovation Centre

4890 Victoria Ave. North, P.O. Box 4000
Vineland, ON LOR 2E0

rose. buitenhuis@vinelandresearch.com
S. CARDINAL

Agriculture and Agri-Food Canada
960 Carling Ave., Ottawa ON KIA 0C6
sophie.cardinal@agr.ge.ca

J. GIBSON

Department of Integrative Biology
University of Guelph

Guelph,ON NIG 2W1
jfgibson@uoguelph.ca

B. SINCLAIR

Department of Biology

University of Western Ontario
London, ON N6A 5B7
bsincla7@uwo.ca

(2012-2014)

(2013-2015)

(2012-2014)

(2013-2015)

ESO Regional Rep to ESC: H. DOUGLAS
Canadian Food Inspection Agency

960 Carling Ave., Ottawa ON K1A 06C
douglash@inspection.ge.ca

Librarian: J. BRETT

Library, University of Guelph

Guelph, ON NIG 2W1
jimbrett@uoguelph.ca

Newsletter Editor: A. GRADISH

School of Environmental Science

University of Guelph, Guelph ON N1G 4Y2
agradish@uoguelph.ca

Student Representative: A. FREWIN
Integrated Biology, University of Guelph
Guelph, ON NIG 2W1
afrewin@uoguelph.ca

Website: M. JACKSON

School of Environmental Science

University of Guelph, Guelph, ON N1G 2W1
jackson@uoguelph.ca

JESO Editor: J. HUBER

Canadian National Collection of Insects
Agriculture and Agri-Food Canada

960 Carling Ave. Ottawa, ON,K1A 0C6
John. Huber@agr.ge.ca

Technical Editor: J. VICKRUCK

Dept. of Biological Sciences, Brock University
500 Glenridge Ave., St. Catharines, ON L2S 3A1
jess.vickruck@brocku.ca

Associate Editors:

A. BENNETT

Agriculture and Agri-Food Canada

960 Carling Ave., Ottawa ON K1A 06C

N. CARTER

Engage Agro Corporation

1030 Gordon St., Guelph, ON, NIG 4X5
neilcarter@engageagro.com

J. SKEVINGTON

Agriculture and Agri-Food Canada

Eastern Cereal and Oilseed Research Centre
960 Carling Ave., Ottawa, ON K1A 0C6

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ENTOMOLOGICAL SOCIETY OF ONTARIO

The Society founded in 1863, is the second oldest Entomological Society in North America
and among the nine oldest, existing entomological societies in the world. It serves as an
association of persons interested in entomology and is dedicated to the furtherance of
the science by holding meetings and publication of the Journal of the Entomological
Society of Ontario. The Journal publishes fully refereed scientific papers, and has a
world-wide circulation. The Society headquarters are at the University of Guelph. The
Society’s library is housed in the McLaughlin Library of the University and is available
to all members.

An annual fee of $30 provides membership in the Society, and the right to publish in the
Journal, and receive the Newsletter and the Journal. Students, amateurs and retired
entomologists within Canada can join free of charge but do not receive the Journal.

A World Wide Web home page for the Society is available at the following URL:
http://www.entsocont.ca

APPLICATION FOR MEMBERSHIP

Please send your name, address (including postal code) and email address to:
Nicole McKenzie, Secretary, Entomological Society of Ontario
c/o Vista Centre, 1830 Bank Street, P.O. Box 83025 Ottawa, ON K1V 1A3
email: nicole mckenzie@hc-sc.ge.ca

NOTICE TO CONTRIBUTORS

Please refer to the Society web site (http://www.entsocont.ca) for current instructions to
authors. Please submit manuscripts electronically to the Scientific Editor
(john. huber@agr.gc.ca).

Journal of the Ent AMNH LIBRARY
society of Ontario Illi ill
American Museus of

100217430 —

History
Received on: 03-05-13

CONTENTS

I. FROM THE EDITOR (....cc0cccccc.ecbssensesseoscsvesconcacseosapaggessesrussensossacsezeysessusesscencvsersehsetaaeteT te tnnnam 1
Il. ARTICLES
R. M. TRIMBLE — Optimization of synthetic pheromone blend for use in monitoring

Choristoneura rosaceana (Lepidoptera: Tortricidae) in Niagara Penninsula, Ontario, apple
OF CHATS. .sccccccsssscsvnsveveocosevestsacestevsessapncuaccgssssnebeccuchsdctcesessebaceacsdelcesuncotssedt sotwteens teeseentceteene tt eeeEamnn 3-14

S. DENOMME-BROWN and G. W. OTIS — Status of Juniper Hairstreak (Callophrys gryneus)
populations in southwesterw) OnMtaniors..cicccccavscscccocssccsocsescseoceesecoreccsverccreseuacescesatenenaneninena” 107-114

Ill. NOTES
H. MURILLO, D. W. A. HUNT and S. L. VANLAERHOVEN — Larval parasitoids of the
Cabbage Looper, Trichoplusiani(Lepidoptera: Noctuidae), in field tomato crops in southwestern

ONG ATIO srr. csccsscceconescocuccesnssesecocseverteceucenesonneocedonestescearascnenseecstenesnptscseraettsnaet ect tat tt natant 115-119

J.H. KITS, J. HOLDENRIED and S. M. PAIERO — First Nearctic record of Camilla atrimana
(Diptera: Camillidae).......cceccsccoccsecccsscsocoteassacseaccecsorsocnecscnovesdeuacoetcoesnssvevenesseuresnieeteeee tant 121-124

J.T. HUBER and J. READ — First record of the Oriental Chestnut Gall Wasp, Dryocosmus

kuriphilus Yasumatsu (Hymenoptera: Cynipidae) in Camada............ssssssesssessssssssessseess 125-128
IV. ESO OFFICERS AND GOVERNORS 2012-2013............s.scsscsssssssssssssssssessscesssseressesesensssensoss 129
V. ESO OFFICERS AND GOVERNORS 2011-2012............scssssssessessssssesseese inside front cover
VI FELLOWS OF THE ESO iiicssccsscasscccesssssaseocaseaceeceasancsucesscavenneuraceunsvareearers sere inside front cover
VII. APPLICATION FOR MEMBERSHIP............c.scsccsssosscscscesconscassescsncvessoss inside back cover

VIM. NOTICE TO) CONTRIBUTORS riisnscccoccscccvscstasenestcvsncvasstcessenvereseneuraners inside back cover