CALIFORNIA
FISH-GAME

"CONSERVATION OF WILDLIFE THROUGH EDUCATION"

California Fish and Game is a journal devoted to the conservation and
understanding of fish and wildlife. If its contents are reproduced elsewhere, the
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Robert N. Lea, Ph.D., Editor-in-Chief
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u

VOLUME 76

WINTER 1990

1
]

NUMBER 1

Published Quarterly by

STATE OF CALIFORNIA

THE RESOURCES AGENCY

DEPARTMENT OF FISH AND GAME

— LDA—

STATE OF CALIFORNIA
GEORGE DEUKMEJIAN, Governor

THE RESOURCES AGENCY
GORDON VAN VLECK, Secretary for Resources

FISH AND GAME COMMISSION

ROBERT A. BRYANT, President
Yuba City

JOHN A. MURDY III, Vice President E. M. McCRACKEN, JR., Member
Newport Beach Carmichael

ALBERT C. TAUCHER, Member BENJAMIN F. BIAGGINI, Member
Long Beach San Francisco

HAROLD C. CRIBBS
Executive Secretary

DEPARTMENT OF FISH AND GAME

PETE BONTADELLI, Director

1416 9th Street

Sacramento 95814

CALIFORNIA FISH AND GAME
Editorial Staff

Editorial staff for this issue:

Editor-in-Chief Robert N. Lea, Ph.D.

Editorial Assistant Lisa L Smith

Anadromous Fishes Kenneth A. Hashagen, Jr.

Inland Fisheries Betsy C. Bolster and Arthur C. Knutson, Jr.

Marine Resources Peter L. Haaker and Paul N. Reilly

Wildlife Management Bruce E. Deuel

CONTENTS

Page
Laboratory Culture of Jacksmelt, Atherinopsis californiensis, and
Topsmelt, Atherinops affinis (Pisces: Atherinidae), with a

Description of Larvae Douglas P. Middaugh,

Michael J. Hemmer, Jonathan M. Shenker,

and Toru Takita 4

Harvest Distribution and Survival of Mallards Banded in California,

1948-82 Warren C. Rienecker 14

Homing by Chinook Salmon Exposed

to Morpholine Thomas J. Hassler and Keith Kutchins 31

Movement and Survival of Tournament-Caught Black Bass at Shasta

Lake Terrance P. Healey 36

Comparison of Steelhead Caught and Lost by Anglers using Flies with
Barbed or Barbless Hooks in the Klamath River,
California Roger A. Barnhart 43

Establishment of Red Shiner, Notropis lutrensis, in the San Joaquin

Valley, California Mark R. Jennings and Michael K. Saiki 46

NOTES

Preliminary Examination of Low Salinity Tolerance of Sperm,

Fertilized Eggs, and Larvae of Orangemouth Corvina, Cynoscion
xanthulus Robert G. Howells 58

BOOK REVIEWS 63

4 CALIFORNIA FISH AND CAME

Calif. Fish and Came 76 ( 1 ) : 4-13 1 990

LABORATORY CULTURE OF JACKSMELT, ATHERINOPSIS

CAUFORNIENSIS, AND TOPSMELT, A THERINOPS

AFFINIS (PISCES: ATHERINIDAE), WITH A

DESCRIPTION OF LARVAE 1

DOUGLAS P. MIDDAUGH, MICHAEL J. HEMMER

U.S. Environmental Protection Agency

Environmental Research Laboratory

Gulf Breeze, Florida 32561

JONATHAN M. SHENKER

Bodega Marine Laboratory

Bodega Bay, California 94923

AND

TORU TAKITA
Faculty of Fisheries
Nagasaki University
Nagasaki, 852 Japan

Embryonic and larval jacksmelt, Atherinopsis californiensis, and topsmelt, Atheri-
nops af finis, were cultured in the laboratory. Larval A. californiensis were grown for
24 days at 10, 20 and 30 %*> salinity. Survival, 80-91%, was highest at 10 %>° salinity.
Increases in standard length (SL) and wet weight were greatest for larvae cultured
at 10 or 20 7°o.

Survival of larval A. affinis cultured at 10, 20 and 30 %*> for 24 days ranged from
99-100%. Increases in SL and wet weight were greatest for larvae cultured at 20 or
30 %x> salinity.

Illustrations of day of hatch, 8-, and 24-day-old larvae are presented with
morphometric descriptions for each species. Unique melanophore patterns provide
a useful character for identification of these two closely related atherinid fishes
which occur sympatrically in California bays and estuaries.

INTRODUCTION

The jacksmelt, Atherinopsis californiensis, occurs from Santa Maria, Baja
California, to Yaquina Bay, Oregon (Miller and Lea 1972). Jacksmelt spawn
during October-March with peak reproductive activity in January-March
(Allen et al. 1983).

The topsmelt, Atherinops affinis, has a reported range from the Gulf of
California to near Sooke Harbor, Vancouver Island, British Columbia (Miller
and Lea 1972). In California, individuals spawn from May-August.

The biomass and numerical abundance of these fishes has been documented
for California bays and lagoons (Allen and Horn 1975, Horn 1980, Allen 1982,
Allen et al. 1983). Moreover, Carpelan (1955, 1961) examined the salinity
tolerance of A. affinis in hypersaline lagoons and Middaugh et al. (1988)
oserved that juvenile A. affinis were euryhaline in a laboratory study.

Several reports have provided general information on culturing A. affinis in
the laboratory (McHugh and Walker 1948, Ehrlich et al. 1979). A description of
A. californiensis and A. affinis larvae from field collected material was
reportedby Wang (1981).

Accepted for publication September 1989. Contribution No. 646 of the Gulf Breeze Environmental Research
Laboratory.

LARVAL JACKSMELT AND TOPSMELT 5

However, no data are available on survival and growth of larval A.
californiensis and A. affinis at different salinities, using a defined culture
procedure. Moreover, descriptions of larvae collected from the field did not
reveal age specific characters.

The purposes of this study was to culture each species in the laboratory and
provide data on survival and growth at several salinities. We also provide a
description and illustration of day-of-hatch, 8- and 24-day old larvae for use in
identification of field collected young.

MATERIALS AND METHODS
Larval Culture

Larval Atherinopsis californiensis were cultured from naturally spawned eggs
collected on 15 April 1986 from Tomales Bay (lat 38° 12'N, long 123° 55'W).
Eggs were identified on the basis of a description provided by White et al.
(1984). Fine-tipped scissors were used to cut —400 viable stage 20 embryos
(expansion of midbrain, Lagler et al. 1977) from the —90% nonviable embryos
in the naturally spawned string-like mass.

Thereafter, embryos were maintained in a 4 L glass beaker containing 3 L of
22 ± 1° C, 30%>o salinity seawater. An airstone provided moderate agitation and
gently circulated the demersal embryos into the water column. Hatching
occurred after 9 days of laboratory incubation.

On the day of hatching, groups of 90 larvae were acclimated to seawater at
10, 20 or 30%o salinity. The acclimation period was 4 hrs for larvae transferred
to 20°/oo and 8 hrs for 10%o, with salinity lowered 2 to 2.5%o/hr. Thereafter,
90 acclimated larvae were maintained in 18 L aquaria at the respective salinities.
Salinity dilutions were made with deionized water. A 4 mm I.D. fire-polished
glass tube equipped with a rubber bulb was used to transfer larvae between
tanks.

On the day after hatching and daily thereafter, 90,000 newly hatched
(12-hr-old) Artemia nauplii ( 5,000/ L) were added to each aquarium. Twenty
percent of the volume of each aquarium was replaced every other day with
temperature and salinity adjusted seawater.

On the day of hatching (DOH) and days 8 and 16 after hatching, 6 larvae
from each aquarium were fixed in 4% buffered formalin for subsequent
measurement of standard length (sl) and wet weight. All survivors were fixed
on day 24 posthatch and measured. Daily mortality was monitored prior to
water changes or feeding. The photoperiod for developing embryos and larval
growth was 14L:10D with an intensity of —20 jaE/s/m2 from "cool white"
fluorescent lamps.

On three occasions (June-August), we collected sexually mature Atherinops
affinis from Estero Americano, a tributary of Bodega Bay, California (lat 38°
18'N, long 123° 00'W), using a 70 m x 2 m seine with 5 mm mesh. Water
temperature ranged from 18 to 20° C and salinity was 32 to 34%o. Hydrated
eggs from two females were stripped into a 20 cm glass culture dish containing
4 cm deep 30°/oo seawater at 20.5° C, and fertilized by stripping sperm into the
dish. After 15 minutes, eggs were washed three times with ambient seawater.
The fertilized eggs, which have chorionic filaments and bind together into long
strands, were wrapped diagonally around stainless steel screens, each 12 cm X
3 cm X 8 mm mesh, to form a helical-like configuration of —700 embryos that

6 CALIFORNIA FISH AND GAME

was never more than 3 embryos thick. Each screen was placed in a separate 500
ml light-tight plastic vacuum bottle filled with 30%o seawater at 20.5° C, sealed
and returned to Bodega Marine Laboratory (BML).

In one instance, newly fertilized embryos in plastic vacuum bottles were
aerated for 30 seconds with pure oxygen. The bottles were then resealed at 19°
C and 34%o and shipped via air-express (transit time 28 hrs) to the Gulf Breeze
Laboratory (GBL) in Florida.

Upon arrival at GBL, stage 18 embryos (4 to 14 pairs of somites, Lagler et al.
1977) attached to the screen were suspended in a 4 L glass beaker containing
3 L of seawater at 21 ± 1° C and 30%>o. An airstone provided moderate
aeration. Larval A. affinis were cultured at GBL in a manner identical to that
described above for A. californiensis.

Larval Descriptions

Drawings of day-of-hatch, 8-, and 24-day-old A. californiensis and A. affinis
were prepared and melanophore patterns described. Measurements of repre-
sentative samples of each species and age were taken. All measurements were
made under a dissecting microscope (8-32x) with digital calipers to nearest 0.1
mm. Measurement of standard length (sl), preanal distance, head length, head
depth, body depth, and counts of fin rays followed the procedures of Hubbs
and Lagler (1958).

Statistical Analysis

A one way analysis of variance (ANOVA) and post-hoc Student Newman-
Keuls test, if appropriate, were performed on arc-sine transformed data for each
age group (8-, 16-, and 24-day-old) of the respective species to determine if
significant differences (a = 0.05) in SL or wet weight existed for larvae cultured
at 10, 20, or 30°/oo salinity (SAS 1985).

RESULTS
Larval Culture

Newly hatched larval Atherinopsis californiensis possessed a yolk sac and did
not begin to consume Artemia nauplii until yolk-sac absorption, 48 h after
hatching, when they fed actively at the air-water interface. Most mortalities
occurred during the first week after hatching; thereafter, a survival plateau at
each culture salinity occurred through day 24. The highest survival was 91% at
10%o, while survival at 20 and 30°/oo was 81 and 83%, respectively.

Growth of A. californiensis was rapid at the three salinities tested (Table 1 ).
Larvae cultured at 10 and 20%>o salinity were generally longer and heavier than
individuals cultured at 30°/oo. There was no significant difference (a = 0.05) in
the mean SL of 8- and 16-day-old larvae reared at the three salinities (Table 2).
However, there were significant differences in mean wet weights of 8-, and
24-day-old larvae and SL in 24-day-old individuals. Eight-day old larvae cultured
at 30%o weighed significantly less than individuals cultured at 10 or 20°/oo
salinity (Table 2). By day 24, individuals cultured at 30%>o weighed significantly
less and also were shorter in SL than larvae cultured at 10%o or 20%>o (Table
2).

LARVAL JACKSMELT AND TOPSMELT 7

TABLE 1. Summary Data for Larvae Cultured at 10, 20 and 30 7°° Salinity. Reported Values are Means
for Samples of 6 to 10 Larvae Taken on the Day-of-hatch (0) and 8-, 16- and 24-days After
Hatching.

Age (days)

0 8 16 24

Salinity %o 10 20 30 10 20 30 10 20 30 10 20 30

A californiensis

SL (mm) - 7.58 9.95 9.78 9.30 13.00 12.78 12.68 16.25 16.35 15.13

Wet wt. (mg) .... - - 2.99 6.67 6.20 4.47 16.43 15.53 14.68 38.67 40.35 31.69

A. affinis

SL (mm) - 5.19 8.68 8.80 8.51 11.60 11.51 12.35 14.65 15.31 14.95

Wet wt. (mg) .... 1.06 4.90 5.10 4.80 14.37 16.10 17.53 32.07 35.70 38.17

TABLE 2. Summary Data for Growth of Larvae Cultured at 10, 20 and 30%° Salinity and Sampled
When 8-, 16- and 24-days Old. One-way Analysis of Variance (ANOVA) an SNK Procedures
Were Conducted for Each Age Group. SL and Wet Weight are Presented in Decreasing Or-
der by Salinity, from Left to Right for Each Age Group. Underscored Means are Similar
(a = 0.05), NS — No Significant Difference for Larvae Cultured at Each Salinity.

Age (days)
8 16 24

A. californiensis

SL (mm) NS NS X20 X,0 X30

Wet wt. (mg) X,0 X20 X30 NS X20 X10 X30

A. affinis

SL (mm) NS X30X10 X20 X20 X30 X10

Wet wt. (mg) NS X30 X20 X10 X30 X20 X]0

Larval Atherinops affinis began feeding at yolk-sac absorption, 24 to 48 h after
hatching. During the 24-day growth test, survival was 100% at 10 and 20%>o
salinity and 99% at 30%o. Larval A. affinis demonstrated no salinity-related
trends in SL or wet weight after 8 days of growth (Table 1 ). At 16 days of age,
larvae cultured at 30 %o were significantly longer and heavier (a = 0.05) than
those maintained at 10%o (Table 2). At 24 days of age, larvae at 20°/oo were
significantly longer than those maintained at 10%o while larvae cultured at
30°/oo were significantly heavier than individuals cultured at 10%>o (Table 2).

Larval Identification

Atherinopsis californiensis. Day-of-hatch. Standard length and total length
(tl) of individuals were 7.9 to 8.1 mm and 8.3 to 8.4 mm, respectively (Fig. 1 ).
Two medium-sized melanophores were situated side by side above the eyes on
top of the head, and two larger melanophores were situated longitudinally
behind the former ones on the occiput and nape. Some individuals did not have
melanophores elsewhere, and some had them dorsally on the tail. The yolk sac
had melanophores dorsally. In the latter case, the melanophores were concen-
trated posteriorly. Morphometry for larval A. californiensis is summarized in
Table 3.

Atherinops affinis. Day-of-hatch. The SL and tl of described individuals
were 5.2 and 5.4 mm, respectively. Mouth was formed but was not described
in the figure, because of its position (Fig. 2). Two melanophores above the eyes
were the same as those in A. californiensis, but were not present in some larvae.
There were three additional melanophores behind the pair over the eyes, but
there were no melanophores on the tail. The yolk sac had melanophores

8

CALIFORNIA FISH AND GAME

dorsally and ventrally. On the dorsal surface they were concentrated; on the
ventral surface they were dispersed. Morphometry for larvai A. affinis is
summarized in Table 3.

Discrimination. Day-of-hatch. Larger size and early appearance of dorsal
melanophore row in A. califomiensis, and melanophore patch on ventral
surface of yolk sac in A. affinis.

A. califomiensis. 8-days old. The sl and tl were 9.8 to 10.9 mm and 10.5
to 11.7 mm, respectively (Fig. 1). Caudal fin rays were beginning to form.
Dorsal and anal fin bases had appeared. In some individuals, dorsal and anal fin
rays were being formed. Melanophores were lined dorsally from the head to the
end of the tail. Two large melanophores were located side by side above the
eyes. A small melanophore was anterior to the former ones, just above the
anterior part of the eyes, but some individuals had two melanophores of
medium size at this position. Behind the pair of large melanophores located
above the eyes, a line of melanophores occurred dorsally from the occiput to
the tail; members of the anterior pair were large and all others small. They were
in a row except where the dorsal fin was forming. Melanophores may be lined
on one or both sides of the dorsal fin. There were no melanophores ventrally.
The caudal fin had 11 to 14 rays (Table 3).

.

;\\\\\Y

1 mm

■fen

2 mm

FIGURE 1. Atherinopsis califomiensis. a. day-of- hatch, b. 8-days old, c. 24-days old.

LARVAL JACKSMELT AND TOPSMELT 9

A. affinis. 8-days old. The SL and TL were 8.4 to 9.7 mm and 9.2 to 10.1 mm,
respectively (Fig. 2). Caudal fin was beginning to form. Some individuals had
dorsal and anal fin bases; others did not. Two large melanophores were situated
side by side above the eyes. One melanophore was located in front of the two,
and behind the two, melanophores were in a longitudinal row extending close
to the end of the tail. Several melanophores were on the posterior end of the
notochord. Most individuals had melanophores on the base of the caudal fin.
Three or four melanophores were located ventrally on the abdomen, forming a
longitudinal row. A ventral row of melanophores was located on the tail, a little
below the surface and inside muscle tissue. The caudal fin had 5 to 10
rays (Table 3).

Discrimination. 8-days old. Ventral melanophore row on abdomen and tail,
and early appearance of melanophores along the posterior end of the
notochord in A. affinis. Greater number of caudal fin rays in A. calif orniensis.

A. californiensis. 24-days old. The SL and tl were 15.1 to 17.6 mm and 17.6
to 20.3 mm, respectively (Fig. 1 ). A small fin fold remained between the pelvic
and anal fins. Fins, except the first dorsal were completed or nearing
completion. A large melanophore was located above each eye and two large
ones were located longitudinally on the occiput and nape. Tiny melanophores

a

s*

at *

1 mm

1 mm

FIGURE 2. Atherinops affinis. a. day-of-hatch, b. 8-days old, c. 24-days old.

10

CALIFORNIA FISH AND CAME

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LARVAL JACKSMELT AND TOPSMELT 1 1

were scattered around the large ones and on the snout. Melanophores on the
cheek were subdermal. The row of melanophores on the dorsal edge of the
body was separated to both sides of the second dorsal fin. This separation was
not apparent at the first dorsal fin. The lined melanophores on the lateral side
were on the surface but those along the posterior end of the notochord were
inside the muscle. The caudal fin bears melanophores on the basal part. No
melanophores were on the anal fin base. A large melanophore, just in front of
the anal fin, was conspicuous. Large melanophores bearing on the abdominal
cavity wall were seen through the muscle. Fin rays were present in all but the
first dorsal (Table 3).

A. affinis. 24-days old. The sl and tl were 15.1 to 16.1 and 17.5 to 18.7 mm,
respectively (Fig. 2). All fins were completed. No fin fold remained. Many small
and medium size melanophores were scattered around the top of the head from
the snout to the nape. The row of melanophores along the dorsal edge of the
body was doubled or tripled from a point slightly anterior to the first dorsal fin
to the rear end of the second dorsal fin base. Several melanophores occurred
longitudinally in a row from the chest to the pelvic fin. Melanophores between
pelvic and anal fins formed paired longitudinal rows. Melanophores at the anal
fin base and along its sides formed three longitudinal rows. However, in some
individuals, melanophores along both sides were not obvious. Melanophores on
the posterior end of the notochord were inside the muscle. Melanophores on
the caudal fin were distributed similarly to A. californiensis, that is on the basal
part. Rays werepresent in all fins (Table 3).

Discrimination. 24-days old. A distinct melanophore slightly anterior to the
anal fin and absence of fin rays in the first dorsal of A. californiensis. Thicker
distribution of melanophores on top of the head and back, with rows of
melanophores from the chest to the rear end of the anal fin base in A. affinis.

DISCUSSION

Atherinopsis californiensis survival and growth was optimal at 10 and 20%o,
suggesting that it may prefer mesohaline salinities (~18± 5%o) when young.
Nearly all mortality occurred during the first 7 days posthatch; thereafter,
mortality was low at each salinity for the duration of the 24-day tests. A similar
trend was observed for larval inland silversides, Menidia beryllina, cultured at
salinities of 5, 15, and 30%>o, with mortality occurring during the first 6 days
after hatching (Middaugh et al. 1986). They observed no additional deaths
during the 16-day grow-out. The optimal salinity for survival was 15 %>o. This
salinity also produced growth in sl and wet weight that was significantly greater
than at 5 or 30%o.

Adult A. californiensis in southern California are reproductively active and
reside in shallow to mid-depth (~2 to 4 m) offshore areas during the colder
months, November-April (Allen et al. 1983). In warmer months, May-October,
large numbers of juveniles were found in the shore zone near Cabrillo Beach.
Salinities during this period ranged from 23 to 33%>o (Allen et al. 1983).

Survival of Atherinops affinis larvae was excellent at 10, 20 and 30%>o during
the 24-day growth test. Growth showed a general trend of significantly longer
and heavier 16- and 24-day-old individuals cultured at 20 and 30%o.

Recent laboratory studies of salinity tolerance in young A. affinis demon-
strated that they are able to tolerate low salinities as well. Young fish, 24-days

12 CALIFORNIA FISH AND CAME

old were acclimated from 10%>o to 2%>o in 2%>o/day increments. All fish
survived the period of acclimation to 2%o and for 29 days at the low salinity.
In a second experiment, 24-day-old A. affinis, initially held at 30%>o, were
subjected to a 2°/oo/day increase salinity. No mortalities occurred until 60%>o
salinity. Incremental mortality occurred as salinity increased to 80%o where the
cumulative mortality was 48%. An increase to 82°/oo salinity caused cumulative
mortality to rise to 80% (Middaugh and Shenker 1988).

Adult A. affinis are reproductively active during May-August. This period
generally coincides with low coastal rainfall and high salinities in California
estuaries and coastal lagoons (Carpelan 1961). While we observed optimal
larval growth at 20 and 30%o and collected reproductively active adults from
Estero Americano at 34%>o salinity, other field observations indicate that A.
affinis adults may spawn at salinities up to 72%>o in the Alviso Salt Ponds of San
Francisco Bay (Carpelan 1957). Moreover, Carpelan (1955) reported that
waters of the Alviso Salt Ponds only became intolerable for young A. affinis
between 80 and90%o.

Culture of larval A. californiensis and A. affinis in the laboratory enabled us
to obtain individuals of known age for preparation of drawings and identification
of distinguishing characteristics. Substantial differences, especially in melano-
phore appearance and location, were noted in individuals from each age group.
These differences should be useful in identification of field-collected larvae
(Figs. 1 and 2).

Where comparisons are possible, our measurements and fin ray counts are in
general agreement with those provided by Wang (1981). One notable
exception is the tl reported for A. affinis by Wang (1981 ) of 4.3-4.9 mm at
hatching. Our day-of-hatch larvae were substantially larger, 5.1-5.4 mm, x =
5.2 mm SL.

ACKNOWLEDGMENTS

We wish to thank the staff of the Bodega Marine Laboratory, Bodega Bay,
California, for support and equipment provided during this study.

LITERATURE CITED

Allen, L.C. and M.H. Horn. 1975. Abundance, diversity and seasonality of fishes in Colorado Lagoon, Alamitos

Bay, California. Estuar. Coastal Mar. Sci., 3:371-380.
Allen, L.C. 1982. Seasonal abundance, composition, and productivity of the littoral fish assemblage in upper

Newport Bay, California. Fish. Bull., 80(4):769-790.
Allen, L.C, M.H. Horn, F.A. Edwards II and C.A. Usui. 1983. Structure and seasonal dynamics of the fish

assemblage in the Cabrillo Beach area of Los Angeles Harbor, California. Bull. So. Calif. Acad. Sci.,

82(2):47-70.
Carpelan, L.H. 1955. Tolerance of the San Francisco topsmelt, Atherinops affinis affinis, to conditions in

salt-producing ponds bordering San Francisco Bay. Calif. Fish and Came, 41 (4):279-284.

. 1957. Hydrobiology of the Alviso Salt Ponds. Ecology, 38(3):375-390.

. 1961. Salinity tolerances of some fishes of a southern California coastal lagoon. Copeia, 1961:32-39.

Ehrlich, K.F., J.M. Hood, G. Muszynski and C.E. McCowen. 1979. Thermal behavioral responses of selected

California littoral fishes. Fish. Bull., 76(41:837-849.
Horn, M.H., 1980. Diel and seasonal variation in abundance and diversity of shallow-water fish populations in

Morro Bay, California. Fish. Bull., 78(3):759-770.

Hubbs, C.L. and K.F. Lagler. 1958. Fishes of the Creat Lakes Region. Univ. of Michigan Press, Ann Arbor.
Lagler, K.F., |.E. Bardach, R.R. Miller and DR. Passino. 1977. Ichthyology, 2nd ed. John Wiley and Sons, New York,
506 p.

LARVAL JACKSMELT AND TOPSMELT 1 3

McHugh, J.L. and B.W. Walker. 1948. Rearing marine fishes in the laboratory. Calif. Fish and Game, 34(1 ):37-38.
Middaugh, D.P., M.J. Hemmer and Y. Lamadrid-Rose. 1986. Laboratory spawning cues in Menidia beryllina and

Menidia peninsulae (Pisces: Atherinidae) with notes on survival and growth of larvae at different salinities.

Environ. Biol. Fish., 15(2):107-117.

and J.M. Shenker. 1988. Salinity tolerance of young topsmelt, Atherinops affinis, cultured in the

laboratory. Calif. Fish and Game, 74(4):232-235.

Miller, D.J. and R.N. Lea. 1972. Guide to the coastal marine fishes of California. Calif. Dept. Fish Game Bull. 157,
235 p.

SAS Institute Inc. 1985. SAS Users' Guide: Statistics, Version 5 Edition. Cary, NC. 956 p.

Wang, C.S. Johnson. 1981. Taxonomy of the early life stages of fishes. Fishes of the Sacramento, San Joaquin
Estuary and Moss Landing Harbor-Elkhorn Slough, California. Ecological Analysts Inc., Concord, CA. 168 p.

White, B.N., R.J. Lavenberg and G.E. McGowen. 1984. Atheriformes: Development and Relationships. Irr.
Ontogeny and Systematics of Fishes. H.G. Moser, W.J. Richards, D.M. Cohen, M.P. Fahay, A.W. Kendall Jr.,
S.L. Richardson (eds.). Inter. Symp. ded. mem. of E.H. Ahlstrom. Aug. 15-18, 1983, LaJolla. Am. Soc. Ichtyol.
Herpetol. Spec. Publ. No. 1:355-362.

14 CALIFORNIA FISH AND GAME

Calif. Fish and Came 76 ( 1 ) : 1 4-30 1 990

HARVEST DISTRIBUTION AND SURVIVAL OF MALLARDS
BANDED IN CALIFORNIA, 194&-82 1

WARREN C. RIENECKER2

California Department of Fish and Game

1416 Ninth Street

Sacramento, California 95814

Over 108,000 mallards, Anas platyrhynchos, were banded in the Sacramento
(Gray Lodge Wildlife Area) and San Joaquin valleys (Los Banos Wildlife Area), and
northeastern California (Klamath Basin, Honey Lake, Mountain Meadows) during
1948-82. Analysis of recoveries shows that adult males survived at a higher annual
rate (61%) than adult females did (56%), although recovery rates of males (9%)
exceeded those of females (6%). Immature mallards survived at lower rates (male
47% — female 46%) and had higher recovery rates (male 14% — female 12%) than
did adults. These survival rates were nearly identical to those reported for the
continent as a whole. Direct recoveries of each age/sex class of mallards banded
preseason at Gray Lodge and Los Banos were obtained most frequently in the region
of banding (69-84% of recoveries). This was true also for all immatures banded
preseason at Klamath Basin and Honey Lake (68-78% of direct recoveries), and
adult females at Honey Lake (73% of recoveries). However, most adult males, and
many adult females (Klamath Basin only), migrated prior to opening of the hunting
season and were recovered in areas to the south (58-64% of recoveries in Central
Valley-Bay Delta); these birds were either local or other postbreeders. or molt
migrants returning to the Central Valley. Several lines of evidence suggest that,
during the past 35 years, a progressively larger proportion of the California mallard
harvest has come from Klamath Basin and Central Valley mallard populations. First,
indirect recoveries in California of Klamath Basin preseason-banded mallards
increased proportionately from the 1950's to the 1980's; and, most of this increase
was in the Klamath Basin (1950's— 21.3% vs. 1980's— 41.7% of recoveries). Concur-
rently, indirect recoveries of Klamath Basin banded birds declined proportionately
from Canada, the Sacramento Valley, and the San Joaquin Valley. Second, the
proportion of indirect recoveries of Gray Lodge preaseason-banded mallards
increased in all California areas, but declined in all non-California recovery areas
including Canada (7.8% in the 1950's, 1.5% in the 1970's). Also, recoveries in
California of mallards banded postseason at Gray Lodge increased proportionately
in the 1980's (88.4%) compared to the 1950's (62.2%); concurrently, a proportion-
ate downward trend in out-of-state recoveries occurred, especially from Alberta
(1950's — 13.4% to 1980's — 1.9%). This increased proportion of resident mallards,
concurrent with an apparent increase in the California breeding population,
coincided with a marked increase of wintering mallards in the Columbia Basin of
Washington and Oregon, and a reduced breeding population in prairie Canada.
Thus, mallards could be managed separately in California during periods when
significant numbers of northern mallards are not present. Additional research is
recommended.

INTRODUCTION

Historically, the greatest density of breeding mallards, Anas platyrhynchos, in
North America occurred in the prairie-parklands of Alberta, Saskatchewan, and
Manitoba (Bellrose 1980). However, the estimated proportion of all North
American mallards which nest there has declined from 54% in 1955-64
(Crissey 1969), to 40% or less in 1979-85 (Reynolds 1987). The continental

' Accepted for publication October 1989.
2 Deceased

HARVEST AND SURVIVAL OF MALLARDS 15

mallard breeding population (surveyed areas only) declined from 14.4 million
in 1958 (Pospahala et al. 1974) to approximately 5.5 million in 1985 (U.S. Fish
and Wildlife Service and Canadian Wildlife Service 1985), but in California, the
mallard breeding population index increased from 35,950 (1962-73) to 47,800
(1974-85) over this time. Seventy-five percent of these breeders were recorded
in the Sacramento Valley (Pacific Flyway Waterfowl Reports, U.S. Fish and
Wildlife Service, Portland, Oregon). Also, the mallard wintering population has
not shown a marked decline in the Pacific Flyway, although numbers wintering
in California have declined since the early 1960's. The 1985 mid-winter survey
in the Pacific Flyway estimated 1,648,700 mallards compared to the 1955-85
average of 1,757,800 (Pacific Flyway Waterfowl Report, U.S. Fish and Wildlife
Service, Portland, Oregon, November 1985).

The ratio of immatures to adults in the harvest of mallards in California
invariably exceeds the mean for the Pacific Flyway (U.S. Fish and Wildlife
Service, Office of Migratory Bird Management, Administrative Reports July
1968-85) suggesting high recruitment rates. Thus, if survival rates of mallards in
California are higher than those calculated on a continental basis (Anderson
1975), coupled with high recruitment, an increased breeding population could
result. Conversely, major changes in the winter distribution of mallards within
the Pacific Flyway states could explain the decrease in the number of wintering
mallards found in California now, compared with 25 years ago.

In the California harvest, mallards rank second or third behind northern
pintails, Anas acuta, and green-winged teal, A. crecca, and mallards are now the
number one species in the harvest at most California public hunting areas
(Gilmer et al. 1989). Therefore, it is critical that information be made available
to better manage this important species.

My objectives in this study were to document distribution of the harvest and
to calculate survival rates of mallards banded in northeastern California and in
the Central Valley. This information is used to recommend research and
management programs to benefit mallards in California and the Pacific Flyway.

METHODS

I was assisted in banding mallards by biologists assigned to the Waterfowl
Studies Project, California Department of Fish and Game (CDFG). We banded
a total of 108,165 mallards (pre- and postseason combined) in California from
1948 through 1982 (Table 1). CDFG and the U.S. Fish and Wildlife Service
(FWS) cooperated in the banding on Klamath Basin National Wildlife Refuges
(NWRs). Mallards were caught in baited swim-in traps, banded with standard
FWS aluminum leg bands, and then released.

16

CALIFORNIA FISH AND GAME

TABLE 1. Mallards Banded Pre- and Postseason in California, 1948-821.

Males Females

YEARS

BANDING STATION BANDED Adult Immature Adult Immature TOTAL
Preseason:

Klamath Basin NWRs 1948-80 21,813 11,880 11,073 6,498 51,264

Honey Lake WA 1950-58 1,594 2,888 794 2,314 7,590

Mountain Meadows 1954-56 718 859 689 666 2,932

Gray Lodge W A 1948-81 2,474 6,664 2,271 3,798 15,207

Los Banos 1948-63 1,126 4,145 950 2,705 8,926

TOTAL 27,725 26,436 15,777 15,981 85,919

Postseason:

Cray Lodge WA 1950-82 12,935 8,244 21,179

Los Banos WA 1953-59 646 421 1,067

TOTAL 13,581 8,665 22,246

GRAND TOTAL 108,165

' Does not include 806 mallards banded in the Suisun Marsh 1951-55

In the 1950's and 1960's, we banded mallards at many sites in California but
in some locations we worked for only a few years or few birds were banded.
For example, only 800 mallards were banded during the 1951-55 bandings in
Suisun Marsh, so results are not included in this report. After the 1950's we
banded only at the Klamath Basin NWRs (northeast California) and at Gray
Lodge Wildlife Area (Sacramento Valley). Data from the following banding
stations were used in our analysis: (i) Klamath Basin NWRs in northeastern
California — key production, migration, and wintering areas; (ii) Honey Lake
Wildlife Area in northeastern California 240 km south of the Klamath Basin — a
nesting and migration area; (iii) Mountain Meadows in northeastern California
48 km west of Honey Lake — a minor migration and nesting area; (iv) Gray
Lodge Wildlife Area in the Sacramento Valley — the major mallard wintering
area in California; and (v) Los Banos Wildlife Area in the Grasslands of the San
Joaquin Valley — an important wintering area.

The proportion of mallards banded each month Preseason (Table 2) and
postseason (Table 3) was not constant through the years. At Klamath Basin in
the 1940's and 1950's, we banded the largest share of birds in August. From the
1960's on, we concentrated preseason banding in September. At Gray Lodge in
the 1950's and in 1968 (the only year of banding in the 1960's), we completed
the majority of preseason banding in September and October, but shifted to
August and September in the 1970's and 1980's. The largest proportion of
postseason banding at Gray Lodge was accomplished in January in the 1950's
and 1960's, but we shifted our work to February in the 1970's and 1980's when
hunting seasons lengthened requiring more time to reach banding quotas.

TABLE 2. The Proportion of Mallards Banded Preseason at Klamath Basin National Wildlife Refuges
and at Gray Lodge Wildlife Area by Month and Decade, 1950-81.

Location Decade N (years) July August September October

Klamath Basin 1950's 10 tr. 72.4 23.3 4.3

1960's 10 17.5 82.5

1970's 10 100.0

1980's 1 100.00

Gray Lodge W A 1950s 10 0.5 9.5 38.9 51.1

1960's 1 88.7 11.3

1970's 10 11.1 34.7 39.7 14.5

1980's 2 100.0

HARVEST AND SURVIVAL OF MALLARDS 17

TABLE 3. Proportion of Mallards Banded Postseason at Gray Lodge Wildlife Area by Month and
Decade, 1950-42.

Decade N (years) January February March

1950's 8 88.3 11.6 0.1

1960's 10 74.9 15.5 9.6

1970's 10 42.4 50.1 7.5

1980's 3 26.3 73.7

I divided California into eight band recovery areas (Figure 1 ), and used both
direct and indirect band recoveries obtained through August 1984 for analysis.
Direct recoveries are banded birds recovered during the first hunting season
after banding (Anderson 1975). indirect recoveries are bands recovered one or
more years following the year of banding. Thus, indirect band recoveries
occurred at any point between breeding and wintering grounds. For harvest
distribution, I only used bands recovered from birds shot during the hunting
season. All percentages are expressed as proportions of total recoveries of a
particular banded sample. To compute survival rates, I used only bands
recovered from birds shot or found dead during the hunting season.

I chose the FORTRAN computer programs ESTIMATE for postseason
bandings (adults) and BROWNIE for preseason bandings (adult and young) to
estimate survival and recovery rates in 28 mallard data sets from four (not
Mountain Meadows) banding stations (Brownie et al. 1978). A general
Chi-square test was used to test for differences in survival and recovery rates
between different time periods and between different banding sites (Sauer and
Williams 1989). Survival rate is the probability that a bird will live for a year
following the approximate midpoint of the banding period. Recovery rate is the
probability that a banded bird alive during a particular banding period will be
legally shot or found dead during the subsequent hunting season and reported
to the FWS Bird Banding Laboratory. I assumed that band reporting rates did not
change during the study period.

RESULTS AND DISCUSSION
Distribution of the Harvest

Northeastern California

Klamath Basin NWRs. Few mallards banded preseason in the Klamath Basin
moved northward; more than 90% of direct recoveries were from California
(Table 4). Harvest areas within California were similar for each age/sex class,
but migration to these areas did not occur at the same time. For example, direct
band recoveries in northeastern California were comparatively few for adult
males (32.1%) relative to recoveries of adult females (49.7%), immature males
(69.7%), and immature females (71.3%). Thus, most adult males, and even
many adult females (compared to immatures), migrated prior to opening of
hunting season, most to the Sacramento Valley, or were less vulnerable to
hunting (Table 4). The adults could have been local or other post-breeders, but
more likely, these were birds that returned to the Central Valley before the
hunting season after migrating to the northeast to molt after nesting, or
attempting to nest, in the south (M.R. McLandress and G.S. Yarris, unpubl.
data).

18

CALIFORNIA FISH AND GAME

KLAMATH BASIN

MT. MEADOWS
GRAY LOOGE

SUISUN —

LOS BANOS

LEGEND
• BANDING STATIONS

RECOVERY AREA BOUNDARY

FIGURE 1. Mallard banding stations and recovery areas.

HARVEST AND SURVIVAL OF MALLARDS 19

TABLE 4. Distribution of Band Recoveries (percent ot recoveries) from Mallards Banded Preseason
at Klamath Basin NWRs, 1948-80.

Direct Indirect 2

Adult Imm. Adult Imm.

Recovery Area ' male male female female Males Females

California

Northeast 32.1 69.7 49.7 71.3 20.0 37.3

Sacramento Valley 41.8 17.7 30.2 16.3 44.7 33.3

San Francisco Bay-Delta 12.0 3.9 8.9 3.8 11.7 10.2

San Joaquin Valley 10.5 2.8 7.7 2.8 9.7 7.7

Washington 0.1 0.1 1.9 1.5

Oregon 1.6 4.9 1.8 4.1 4.5 6.1

Idaho 0.2 - 0.1 - 1.4 0.4

Canada - - - - 3.6 1.0

AHOther3 1.7 0.9 1.6 1.7 25_ 2.5

Total Recoveries 1,815 1,474 665 607 3,588 913

1 Table includes data for recovery percentage > 1 .0 only. Complete list available from author.

2 Birds in their second year or older.

3 Recovery areas with < 1 .0.

Indirect recoveries of males (87.4%) and females (89.7%) verify that
California is the major wintering area for Klamath Basin preseason banded
mallards (Table 4), and suggest that many were California residents. Indirect
recoveries in the Sacramento Valley, San Joaquin Valley, and San Francisco
Bay-Delta for males and females banded preseason in the Klamath Basin were
in proportions similar to those of direct recoveries (adults). The remaining 9%
of mallards recovered north of California occurred over a wider area, and may
indicate breeding dispersal and northward molt migration (Martin and Carney
1977; Bellrose and Crompton 1970). Therefore, I assume that more males than
the 3.6% recovered in Canada were there during the breeding season, or
arrived as postbreeders to molt. Females with young generally remain on the
breeding grounds until after the start of the hunting season, but some, especially
failed nesters, may move north with drakes following breeding (Gilmer et al.
1977); recent evidence indicates this northern movement of adults may be
more extensive in California (G.S. Yarris, pers comm.). Thus, the 1.0% females
recovered in Canada may indicate females that are either dispersing to breed or
migrating north to molt in Canada.

During summer 1957 on Lower Klamath NWR, we banded 461 flightless
young (locals) and then, several weeks later, 486 immature mallards (Table 5).
More locals (91.4%) than immatures (79.6%) were recovered in the Klamath
Basin. This suggests that while many immatures were produced in the Klamath
Basin, some may have come from other nesting grounds and that locals were
more vulnerable at or near natal marshes.

TABLE 5. A Comparison of Direct Band Recoveries (percent of recoveries) Between 461 Flightless
Young and 486 Immature Mallards Banded During Summer on Lower Klamath National
Wildlife Refuge, 1957.

Recovery area Flightless young Immature

California

Klamath Basin 91.4 79.6

North Coast - 1.1

Sacramento Valley 3.7 10.2

San Francisco Bay-Delta 1.2 2.3

San Joaquin Valley 1.2 3.4

Oregon 2j> 3^

Total Recoveries 81 88

Recovery Rate 17.6 18.1

20

CALIFORNIA FISH AND CAME

Honey Lake Wildlife Area. The distribution of direct recoveries of Honey
Lake preseason banded mallards was similar to that from the Klamath Basin
including few recoveries north of California (Table 6). Proportions of each
sex/age class recovered in each area were similar between the two areas,
except that Nevada was more important as a minor recovery area than for birds
banded in the Klamath Basin. Adult males were recovered in lower proportions
in the northeast than were other sex/age classes; the Sacramento Valley was
most important to adult males. But, recoveries of adult females were more
closely associated with the northeast than were those of Klamath Basin banded
adult females. Also, the San Joaquin Valley was more important to Honey Lake
adult males than for Klamath banded adult males.

For mallards banded preseason at Honey Lake, the proportion of indirect
recoveries in the northeast was less than the proportion of direct recoveries
there, but direct and indirect recoveries occurred in similar proportions in the
Sacramento Valley. This suggests that molters in the northeast returned to the
Central Valley before the hunting season or were less vulnerable than young
early in the season. There were proportionately more indirect recoveries from
northeastern California, Canada, and Nevada from birds banded at Honey Lake
compared to those from Klamath Basin (Tables 4 and 6). However, fewer
Honey Lake banded birds were recovered in the Sacramento Valley, the Delta
and total California compared to those banded in the Klamath Basin.

TABLE 6. Distribution of Band Recoveries (percent of recoveries) From Mallards Banded Preseason
at Honey Lake Wildlife Area, 1950-58.

Direct Indirect 2

Adult Imm. Adult Imm.

Recovery Area ' male male female female Males Females

California

Northeast 34.4 67.9 72.5 77.8 25.6 43.9

Sacramento Valley 30.1 19.4 17.4 12.6 34.9 22.2

San Francisco Bay-Delta 9.8 5.4 2.9 2.6 8.0 6.1

San Joaquin Valley 18.4 2.0 4.3 3.2 11.2 6.6

Washington 1 4 2-5

Oregon 2.4 2.4 2.0 4.4 4.6

Idaho 0.6 3.9 0.5

Nevada 3.1 2.7 2.9 1.8 2.0 9.1

Alberta &1 30

All Others3 1.2 0.2 2.5 1.5

Total Recoveries 163 458 69 342 438 198

1 Table includes data for recovery percentage > 1.0 only. Complete list available from author.

2 Birds in their second year or older.

3 Recovery areas with < 1 .0.

Mountain Meadows. Fewer than 28% of direct recoveries of adult females
and immatures, and only 11% of adult males occurred in the northeast (Table
7). The Sacramento Valley was the most important recovery area for Mountain
Meadows mallards. The comparatively low direct recovery rate in northeastern
California from mallards banded at Mountain Meadows compared to those
banded in the Klamath Basin and Honey Lake, reflected earlier migration of the
former because of the additional 1,000 feet in elevation. But even here, adult
males (molters or local post breeders) departed earlier than the other sex/age
classes. Direct recoveries indicated some Mountain Meadows mallards mixed
with mallards east of the Sierra Mountains (Nevada, Imperial Valley). No such

HARVEST AND SURVIVAL OF MALLARDS

21

interchange was shown for mallards banded in the Klamath Basin. Indirect
recoveries show a similar northward dispersion for nesting or molt as for other
northeast banded mallards.

TABLE 7. Distribution of Band Recoveries (percent of recoveries) from Mallards Banded Preseason
at Mountain Meadows, 1954-56.

Direct Indirect 2

Adult Imm. Adult Imm.

Recovery Area ' male male female female Males Females

California

Northeast 10.7 17.8 2.7.1 28.4 5.7 24.2

North Coast 2.1

Sacramento Valley 53.4 42.3 43.8 39.2 45.0 39.4

San Francisco Bay-Delta 9.3 11.1 14.5 6.7 12.7 5.2

San Joaquin Valley 22.7 26.7 8.3 21.6 15.8 14.2

Imperial Valley 1.3 0.7 -

Washington - - - - 1.8 3.0

Oregon 1.3 0.7 2.1 1.4 3.9 4.0

Idaho - -4.4 40

Nevada 1.3 0.7 2.1 2.7 1.3 3.0

Alberta - - 6.3 2.0

Central Flyway - - 2.5 -

Mississippi Flyway _____ 1 q

Total Recoveries 75 135 48 74 158 99

1 Table includes data for recovery percentage > 1.0 only. Complete list available from author.

2 Birds in their second year or older.

The Central Valley

Gray Lodge Wildlife Area. The distribution of direct recoveries of mallards
banded preseason at Gray Lodge was proportionately similar for each age/sex
class, unlike the pattern for birds banded in northeastern California (Table 8).
Direct recoveries occurred overwhelmingly in the Sacramento Valley (77.5%
for adult females to 83.7% for immature females). The San Francisco Bay-Delta
and San Joaquin Valley were important secondary recovery areas for these
mallards, but the northeast was unimportant.

TABLE 8. Distribution of Band Recoveries (percent of recoveries) from Mallards Banded Preseason
on Gray Lodge Wildlife Area, 1948-81.

Direct Indirect 2

Adult Imm. Adult Imm.

Recovery Area ' male male female female Males Females
California

Northeast 0.8 1.2 2.5 1.5 6.1 8.5

Sacramento Valley 78.8 82.5 77.5 83.7 51.0 64.5

San Francisco Bay-Delta 12.8 10.6 11.9 10.2 13.0 7.1

San Joaquin Valley 6.8 5.1 8.1 4.6 9.4 5.7

Washington _ 0.1 - - 2.9 2.8

Oregon 4.9 3.9

Idaho _ 0.2 - - 3.0 1.2

Nevada - - _ _ 1.4 2.3

Canada 0.4 0.1 _ 6.0 2.8

AHOther3 0.4 0.2 - - 2.3 1.2

Total Recoveries 236 984 160 411 1,096 353

1 Table includes data for recovery percentage > 1 .0 only. Complete list available from author.

2 Birds in their second year or older.

3 Recovery areas with < 1 .0.

22 CALIFORNIA FISH AND GAME

The Sacramento Valley was the most important area for indirect recoveries
(Table 8), but those proportions (male 51.0% — female 64.5%) were markedly
lower than for direct recoveries reflecting affinities to breeding and/or molting
areas farther north. The proportions of indirect recoveries in the San Francisco
Bay-Delta and San Joaquin Valley were similar to those of direct recoveries. As
was found for Klamath Basin indirect recoveries of males, more bands were
recovered in Canada, especially Alberta, than in any other area outside of
California.

Recoveries of mallards banded postseason at Gray Lodge occurred over half
the time in the Sacramento Valley; other recovery areas each had fewer than
10% of recoveries (Table 9). There was a markedly more northern distribution
of recovery areas of postseason banded mallards relative to preseason banded
birds, indicating that there were migrants as well as resident birds among
mallards captured in late winter. Proportionately more females than males were
recovered in the north. Also, relatively fewer females (69.3%) than males
(82.2%) were recovered in California from postseason bandings, whereas in
preseason bandings, relatively more females (86.4%) than males (80.2%) were
recovered there. This suggests that females were more available or vulnerable
to harvest relative to males at northern areas, perhaps resulting from delayed
migration of successful breeders and molters. The similarity between relative
recovery distribution patterns of adult males from preseason and postseason
bandings suggests that molting males returned to the Valley before the hunting
season, or that males which had bred in Canada were migrating into California
prior to or early in the season, an unlikely event (Munro and Kimball 1982).

TABLE 9. Distribution of Indirect Band Recoveries (percent of recoveries) From Mallards Banded
Postseason at Gray Lodge Wildlife Area, 1950-82.

Recovery Areas ' Male Female
California

Northeast 8.8 9.5

Sacramento Valley 59.3 51.9

San Francisco Bay-Delta 8.1 3.5

San Joaquin Valley 5.6 4.1

Washington 2.4 5.3

Oregon 5.6 10.1

Idaho 2.2 2.7

Nevada 1.3 1.6

Canada 5.2 9.7

All Other2 1.5 16

Total Recoveries 2,421 823

' Table includes data for recovery percentages > 1 .0 only. Complete list available from author.
2 Recovery areas with < 1 .0.

Los Banos Wildlife Area. The San Joaquin Valley was the most important
direct recovery area of each sex/age class for mallards banded preseason at Los
Banos Wildlife Area in the Grasslands (Table 10). The Sacramento Valley and
San Francisco Bay-Delta areas were important harvest areas of Los Banos
mallards, but the northeast was not.

HARVEST AND SURVIVAL OF MALLARDS 23

TABLE 10. Distribution of Band Recoveries (percent of recoveries) from Mallards Banded Preseason
at Los Banos Wildlife Area, 1943-63.

Direct Indirect 2

Adult /mm. Adult /mm.

Recovery Area ' male male female female Males Females
California

Northeast 0.6 3.4 0.1 5.9 3.6

Sacramento Valley 9.66 16.0 13.5 11.1 24.5 13.5

San Francisco Bay-Delta 11.1 13.4 7.9 14.0 10.3 10.9

South Coast 2.2 0.5 1.1 0.7 0.4 1.0

San Joaquin Valley 76.3 69.1 74.1 73.6 43.3 62.3

Washington - - - 1.6 1.3

Oregon 2.2 3.9 3.6

Idaho - - - - 2.9 1.0

Nevada - - - 0.3 2.3 1.3

Alberta - - 3.3 0.6

AHOther3 0.8 0.2 0.2 1.6 0.9

Total Recoveries 135 643 89 307 521 304

1 Table includes data for recovery percentage > 1.0 only. Complete list available from author.

2 Birds in their second year or older.

3 Recovery areas with < 1 .0.

The proportion of indirect recoveries in California from Los Banos preseason
bandings was higher for both males (84.4%) and females (91.7%) compared
to Gray Lodge (male 80.2%, female 86.4%) (Tables 8 and 10). The San Joaquin
Valley was the most important area for indirect recoveries; but, proportions
were markedly less than for direct recoveries, especially for males, reflecting
northern (including Sacramento Valley) molting, breeding, or wintering distri-
bution.

From postseason bandings at Los Banos, recoveries of males exceeded those
of females in California (78.4% vs. 59.8%); but, delayed migration resulted in
proportionately more females than males being recovered in northern areas
(Table 11).

TABLE 11. Distribution of Indirect Band Recoveries (percent of recoveries) From Mallards Banded
Postseason at Los Banos Wildlife Area, 1953-59.

Recovery Areas ' Male Female
California

Northeast 5.6

Sacramento Valley 19.8 14.6

San Francisco Bay-Delta 5.6 3.2

San Joaquin Valley 46.9 42.0

Washington 0.6 6.4

Oregon 4.3 6.4

Idaho 3.7 3.2

Nevada 3.1 6.4

Utah 0.6 3.2

Canada 7.4 1 3.0

Central Flyway 1.2 1.6

All Other2 1.2

Total Recoveries 162 62

' Table includes data for recovery percentages > 1.0 only. Complete list available from author.
2 Recovery areas with < 1 .0.

Long Term Trends in Recoveries

To determine if recovery distributions had changed over the years, I
compared: (i) indirect recoveries from mallards banded preseason in the
Klamath Basin during the 1950's, 1960's, 1970's, and 1980's (Table 12);
(ii) indirect recoveries from mallards banded preseason at Gray Lodge during

24

CALIFORNIA FISH AND CAME

the 1950's and 1970's (Table 13); and (iii) indirect recoveries of mallards
banded postseason at Gray Lodge during the 1950's, 1960's, 1970's, and 1980's
(Table 14). For the Klamath Basin, there was a marked increase in recoveries
from the northeast part of California (100%) and a marked decline from the
Sacramento Valley, the San Joaquin Valley, and Canada. Thus, a progressively
higher percentage of northeast California's mallard harvest has come from
resident populations there. This suggests a reduced exchange of birds from
Canada and the Central Valley with the northeast.

TABLE 12. A Comparison of Indirect Band Recoveries (percent of recoveries) Among 4 Decades of
Mallards Banded Preseason at Klamath Basin National Wildlife Refuges, 1948-80.

Recovery Areas ' 1950-59 1960-69 1970-79 1980-34
California

Northeast 21.3 19.8 29.4 41.7

North Coast 0.5 1.2 0.8 0.2

Sacramento Valley 43.2 44.6 38.5 32.6

San Francisco Bay-Delta 9.1 11.9 12.1 9.4

San Joaquin Valley 8.4 10.5 9.7 5.7

Washington 3.0 2.0 0.7 2.3

Oregon 4.7 3.9 5.2 4.3

Idaho 1.4 1.8 0.8 0.8

Canada 6.3 3.3 1.3 1.0

AllOther2 2.1 0.4 1.5 2.0

Total Recoveries 1,360 967 1,422 938

' Table includes data for recovery percentages > 1.0 only. Complete list available from author.
2 Recovery areas with < 1.0.

TABLE 13. A Comparison of Indirect Band Recoveries (percent of recoveries) Between 2 Decades of

14,519 Mallards Banded Preseason on Cray Lodge Wildlife Area, 1948-79.

Recovery Areas ' 1950-59 1970-79
California

Northeast 6.2 6.9

Sacramento Valley 51.5 57.1

San Francisco Bay-Delta 10.3 13.4

San Joaquin Valley 8.5 9.4

Washington 3.3 2.5

Oregon 5.4 3.8

Idaho 2.7 2.3

Nevada 2.1 1.2

Canada 7.8 1.5

Central Flyway 1.0 0.3

All Other2 1.2 1.6

Total Recoveries 792 394

' Table includes data for recovery percentages > 1 .0 only. Complete list available from author.
2 Recovery areas with < 1 .0.

TABLE 14. A Comparison of Indirect Band Recoveries (percent of recoveries) Among 4 Decades of
21,179 Mallards Banded Postseason at Cray Lodge Wildlife Area, 1950-82.

Recovery Areas ' 1950-59 1960-69 1970-79 1980-84
California

Northeast 8.6 8.5 9.5 10.1

Sacramento Valley 47.2 60.5 59.6 62.3

San Francisco Bay-Delta 3.4 6.5 9.3 8.7

San Joaquin Valley 3.1 5.2 6.3 6.3

Washington 4.0 3.4 2.6 1.9

Oregon 9.5 6.7 5.8 2.4

Idaho 3.8 2.3 1.4 3.4

Nevada 1.9 0.9 1.6 0.5

Alberta 13.4 3.1 2.0 1.9

Saskatchewan 2.0 0.4 0.2

Central Flyway 1.5 0.8 0.2

AllOther2 1.6 1.7 1.5 2.5

Total Recoveries 712 1,202 1,123 207

1 Table includes data for recovery percentages > 1 .0 only. Complete list available from author.

2 Recovery areas with < 1 .0.

HARVEST AND SURVIVAL OF MALLARDS 25

For preseason bandings at Gray Lodge, the proportion of indirect recoveries
increased in California from 76.6% in the 1950's to 88.1% in the 1970s.
Increases were noted within all important California recovery areas. Recoveries
in Canada decreased from 7.8% to 1.5% in this period, and most recovery areas
outside of California had fewer recoveries in the later period. Thus, Cray Lodge
preseason bandings probably contained progressively more resident mallards.

Recoveries of mallards banded postseason at Gray Lodge increased propor-
tionately over the years in all recovery areas of California; the sharpest increase
occurred between the 1950's and the 1960's. The proportion of out-of-state
recoveries declined in all areas, but especially in Alberta (13.4% in the 1950s,
<2% in the 1980s). These results suggest that postseason banding samples
have contained fewer and fewer migrants. Interestingly, the apparent sharp
decrease in the presence of migratory mallards in California between the 1950s
and the 1960s corresponded to the concurrent increase in mallards overwin-
tering in the Columbia Basin of Washington and Oregon (Pacific Flyway
Waterfowl Reports, U.S. Fish and Wildlife Service, Portland, Oregon).

The data on changes in recovery distributions must be interpreted with
caution. The results seem to show that fewer northern mallards migrate to
California compared with 30 to 40 years ago. However, similar changes in
recovery distributions could have resulted from changes in hunting pressure or
in migration chronology (Jim Nichols, U.S. Fish and Wildlife Service, pers.
comm.), though such changes have not been documented. Importantly, the
apparent trends in recovery could have resulted from the changes in banding
dates over the years (Tables 2 and 3), although the evidence is contradictory.

For example, preseason banding in the Klamath Basin occurred later in the
1960s-1980s (September) than during the 1950s (August). Theoretically, these
later bandings would have included proportionately more migrants relative to
resident mallards, although few migrants arrive in California this early (Munro
and Kimball 1982). Consequently, I would have expected there to have been
progressively more northern recoveries, but the opposite occurred, supporting
the notion that fewer northern mallards are migrating to California compared to
earlier years.

The Gray Lodge bandings provided evidence contrary to that of Klamath
bandings. Preseason bandings occurred earlier (August vs. September) and
postseason bandings occurred later (February vs. January) over the years at
Gray Lodge (Tables 2 and 3). Both of these changes would be expected to
result, theoretically, in a sample containing proportionately fewer migrant
mallards relative to residents, and ultimately would result in a recovery
distribution progressively concentrated in California. Although few if any
northern mallards would be expected at Gray Lodge even as late as September
(Munro and Kimball 1982), the pattern of recoveries has changed as predicted.

To determine if the change in recovery distribution resulted simply from
changes in the period of banding or a real change in mallard distribution, I used
shorter intervals: preseason = August, September, October; postseason =
January, 1-15 February, 16-29 February, and March. I analyzed indirect
recovery distributions by decade of mallards banded in each of these intervals
for Gray Lodge bandings. I also analyzed the proportion of California recoveries
by decade for preseason bandings in southwest and westcentral Alberta, the

26 CALIFORNIA FISH AND CAME

province which contributes the greatest number of mallards to California
(Munro and Kimball 1982).

Recoveries from postseason banded mallards at Gray Lodge during each of
the shorter intervals followed the same pattern as for the entire postseason
period combined. Specifically, recoveries in California ranged from 61-68% in
the 1950's, 80-88% in the 1960's, 83-85% in the 1970's, and 85-100% in the
1980's; recoveries from Canada showed concurrent declines through the
decades: 8-12.5%in the 1950's, 3-3.4% in the 1960's, 2.3-4.1% in the 1970's,
and 0-5.9% in the 1980's depending on specific time intervals. There was no
tendency for greater California (fewer Canadian) recoveries for later bandings
(e.g., March vs. January). Likewise, distribution of preseason banded mallards
for each of the short time intervals followed the pattern of more California
(85.71-91.52% vs. 77.19-81.14%) and fewer Canadian (0.61-1.76% vs.
5.93-8.77%) recoveries between the 1970's and 1950's respectively, as shown
by the combined preseason bandings. For mallards banded in Alberta, using all
recoveries, more occurred in California in the 1950's (4.76%) than during the
other decades (2.14-3.21%). Thus, these data suggest strongly that the
documented changes in recovery distributions reflect real changes in mallard
distributions, and are not artifacts of time of banding, and that the greatest
change occurred from the 1950's to the 1960's coincident with the increase in
wintering mallards in the Columbia Basin.

Potential Migration Routes

The late migration of females and the resulting recoveries from out-of-state
are an asset in delineating breeding and migration staging areas that are
important to mallards harvested in California. Anderson and Henny (1972)
reported that the only out-of-state mallards banded preseason that contributed
significantly to the harvest in California were those banded in eastern Oregon.
Preseason mallard bandings on Malheur NWR, Oregon, 1961-71 indicated that
54.3% of the male and 57.7% of the female indirect recoveries had come from
the Central Valley, especially the Sacramento Valley (Furniss 1974). The most
important Pacific Flyway migration corridors extend from Alberta to the
Columbia Basin (Washington and Oregon), and from Alberta to the Snake River
near Boise, Idaho (Bellrose 1980). Other corridors lead to the Snake River in
eastern Idaho and the Klamath Basin in northeastern California. From these
wintering areas, some mallards continue on to the Central Valley of California,
and a few to Mexico. Data obtained from mallards banded in California indicate
that these migration routes are represented by band recoveries, but that migrant
mallard populations are far less important to California's harvest than are those
locally produced, especially since the 1960's.

Band Recovery And Survival Rate Estimates

Recovery rates based on preseason bandings are an index to harvest rates
(Anderson and Burnham 1976, Henny and Burnham 1976). The average
estimated recovery rate for California banded adult male mallards was 9%. This
compares with 6% for adult females, 14% for immature males, and 12% for
immature females (Table 15). Thus, both adult and immature males faced
greater hunting pressure than females did, but females suffered greater
non-hunting mortality (Anderson and Burnham 1976). Similar results have been

HARVEST AND SURVIVAL OF MALLARDS 27

reported for American wigeon, Anas americana, (Rienecker 1976), northern
pintail (Rienecker 1987), and continental mallards (Anderson 1975). High
nonhunting mortality of hens results from predation during nesting (Cowardin
et al. 1985).

TABLE 15. Average Annual Recovery Rate Estimates for Mallards Banded in California, 1948-61.
Standard Errors in Parentheses.

Males Females

Data set Model3 Adults Immatures Model a Adults Immatures

Preseason
Klamath Basin

1949-64 H1 0.071(0.0022) 0.130(0.0055) H2 0.033(0.0058) b 0.086(0.0065)

1965-80 H1 0.083(0.0023) 0.118(0.0054) H02 0.054(0.0024) 0.107(0.0084)

Honey Lake

1950-58 H1 0.082(0.0072) 0.153(0.0074) H1 0.095(0.0106) 0.133(0.0075)

Gray Lodge

1948-58 H02 0.082(0.0091) 0.126(0.0116) - -c -c

1972-81 H02 0.103(0.0082) 0.144(0.0100) H2 0.034(0.0089) a 0.114(0.0101 )

Grasslands

1951-59 H02 0.102(0.0079) 0.137(0.0075) H02 0.081(0.0085) 0.118(0.0097)

Postseason
Gray Lodge

1954-68 Ml 0.057(0.0021) - M3 0.038(0.0022)

1971-81 M1 0.086(0.0053) - M2 0.040(0.0032)

a Brownie et al. (1978).

b After first-year adult recovery rates, f, of Brownie et al. (1985), are presented.

c Insufficient data to calculate estimates.

Estimated average survival rates for all California banded mallards were 61%
for adult males, 56% for adult females, 47% for immature males, and 46% for
immature females (Table 16). These rates are nearly indistinguishable from
continental values 1961-70 (Anderson 1975), so survival alone cannot account
for an increasing breeding population in California. There was evidence of
variation in average survival rates among the four different banding locations
(Table 17). Anderson (1975) concluded that there were regional differences in
survival estimates of North American mallards.

TABLE 16. Average Annual Survival Rate Estimates for Mallards Banded in California, 1948-81.
Standard Errors in Parentheses.

Males Females

Data set Model3 Adults Immatures Model Adults Immatures

Preseason
Klamath Basin

1949-64 H1 0.62(0.012) 0.41(0.026) H2 0.53(0.048) 0.49(0.098)

1965-80 H1 0.63(0.011) 0.54(0.029) H02 0.55(0.013) 0.49(0.044)

Honey Lake

1950-58 HI 0.57(0.043) 0.42(0.045) H1 0.62(0.165) 0.43(0.088)

Gray Lodge

1948-58 H02 0.56(0.025) 0.51(0.064) -b -b

1972-81 H02 0.62(0.022) 0.43(0.043) H2 0.58(0.090) 0.72(0.211)

Grasslands

1951-59 H02 0.53(0.019) 0.36(0.032) H02 0.48(0.026) 0.46(0.055)

Postseason
Gray Lodge

1954-68 Ml 0.65(0.015) M3 0.57(0.016)

1971-81 Ml 0.63(0.033) - M2 0.60(0.026)

a Brownie et al. (1978).

b Insufficient data to calculate estimates.

Su

rwV<j/ Ra

tes

Recovery Rates

Age-sex

x2

df

P

X2

df

P

AM

0.4

1

0.54

14.2

<0.01

AF

0.2

1

0.69

11.2

<0.01

IM

11.1

1

<0.01

2.4

0.12

IF

0.0

1

>0.99

3.9

0.05

AM

3.2

1

0.07

2.9

0.09

AF

-

-

-

-

-

-

IM
IF

M

1.1

1

0.30

1.4

0.24

0.3

1

0.58

25.9

<0.01

F

1.0

1

0.33

0.3

0.61

AM

0.2

1

0.68

5.5

0.02

AF

0.1

1

0.74

5.2

0.02

IM

4.5

1

0.03

4.7

0.03

IF

1.1

1

0.29

0.3

0.59

AM

17.9

3

<0.01

16.4

3

<0.01

AF

1.4

2

0.49

37.9

2

<0.01

IM

4.8

3

0.19

7.2

3

0.07

IF

0.2

2

0.90

23.6

2

<0.01

28 CALIFORNIA FISH AND CAME

TABLE 17. Chi-square Tests for Temporal and Geographic Variation in Mallard Survival and Recovery
Rates Computed Using CONTRAST (Sauer and Williams 1989).

Test

Klamath Basin 1949-64 vs. 1965-80

Cray Lodge 1948-58 vs. 1972-81
( Preseason )

Cray Lodge 1954-68 vs. 1971-82

(Postseason)

Klamath Basin (1965-80) vs. Gray Lodge

(1972—81)

Klamath Basin (1949-64) vs. Honey Lake
(1950-58) vs. Gray Lodge (1948-58)
vs. Grasslands (1951-59)

Survival estimates based on banding waterfowl representing several subpop-
ulations in unknown proportions is cause for caution in interpretation of results
(Pollack and Raveling 1982). Not only do young waterfowl disperse rapidly
after fledging, but adults often migrate north to molt following the breeding
season (Gilmer et al. 1977, M.R. McLandress and G.S. Yarris, unpubl. data).
Because little nesting of mallards occurs south of California, most mallards
banded in California are believed to be resident birds. Therefore, survival
estimates of mallards banded in California are heavily weighted towards
resident birds, especially preseason banded birds, but are equivalent to
continental rates in any event.

CONCLUSIONS

The declining rate of return of California banded mallards from Canada over
the past several decades could have resulted from declining numbers of
mallards in Canada relative to California (Cooch and Boyd 1984), or from a
change in timing of migration and distribution patterns and hunting pressure.
The mallard breeding population in the southern portions of Alberta, Sadkatch-
ewan and Manitoba has declined from an average of 4.4 million during the
1970's to 3.1 million during the first four years of the 1980's (Bartonek et al.
1984, Cooch and Boyd 1984) compared to the increase in mallards breeding in
California. That fewer Canadian produced mallards winter in California also may
reflect "short-stopping" in the Columbia Basin of Washington State beginning in
the early 1960's. This resulted from increased wetland habitat and corn
production associated with the Columbia Basin irrigation project (Bureau of
Reclamation) (Pacific Flyway Waterfowl Reports, U.S. Fish and Wildlife
Service, Portland, Oregon). Only in years of extreme cold and snow in the
Columbia Basin, do significant numbers of northern mallards migrate to
California, for example 1985-86.

Recovery distributions suggest that a greater proportion of mallards banded in
the northeast part of the state have become resident there, with fewer migrating
to the Sacramento Valley. Population counts on Klamath Basin refuges no
longer show a peak population of mallards in spring (E. H. McCollum, pers.

HARVEST AND SURVIVAL OF MALLARDS 29

comm.). Apparently, mallards which used to migrate north from the Central
Valley to the Basin to nest no longer do so. Thus, at least two subpopulations
of California mallards are evident from banding analysis, one associated with the
Central Valley and the other with the northeastern part of the state.

The California breeding population of mallards has increased, but estimates of
its size may be too low. The late timing of the breeding pair survey in the Central
Valley (last week in May) relative to the peak period of nesting in late March,
only partial survey of California breeding areas and the lack of visibility
corrections, may produce potentially serious underestimates of the breeding
population (M.R. McLandress, unpubl. data). The magnitude of such an
underestimate is not known.

Male mallards normally pair in winter and follow their mates to the female's
natal home (Johnsgard 1958). Thus, in general, co-mingling of mallards from
many breeding areas during winter makes harvest management of each
breeding population difficult. Although the population wintering in California
consists largely of resident mallards, which have not suffered marked declines,
occasional but regular movement of large numbers of northern mallards into
California caused by adverse weather conditions in the Columbia Basin, as well
as the small annual influx of northern birds, suggests management should, in
general, be sensitive to Pacific Flyway objectives. However, the California
breeding population, which has steadily increased, in contrast to continental
trends, could be managed separately during the early hunting season before
significant numbers of northern mallards would be expected to arrive in
California.

My results suggest that a strengthened research effort is needed to assess the
complete breeding distribution and nesting density of mallards in California,
identify the limiting factors to mallard production throughout this breeding
range, document the locations to which fledglings disperse, completely assess
the significance of mallard molt migrations in California, and examine in detail
the relationship between mallards in California and the rest of the Pacific
Flyway. The latter includes a concerted effort to band representative samples of
mallards throughout the Flyway. Additionally, researchers need to determine
the proper timing of the spring breeding pair survey in California, as well as
reasons for geographic variation in survival rates within the state. Timing of
banding within pre- and post-season periods should remain consistent in the
future to assist interpretation of recovery distributions.

ACKNOWLEDGMENTS

I especially thank M.R. Miller, U.S. Fish and Wildlife Service, Northern Prairie
Wildlife Research Center, Wildlife Research Field Station, Dixon, California for
providing detailed assistance in the preparation, editing, and review of the
manuscript. Thanks go as well to J. D. Nichols, U.S. Fish and Wildlife Service,
Patuxent Wildlife Research Center, for his statistical calculations and interpre-
tation of data sets and to D. L. Orthmeyer, U.S. Fish and Wildlife Service,
Northern Prairie Wildlife Research Center, Dixon, California for processing
many data sets. I am grateful for the review and advice provided by J. C.
Bartonek, U.S. Fish and Wildlife Service, Portland, Oregon, and M. R.
McLandress, California Waterfowl Association, Sacramento, California. I thank
the members of the Waterfowl Studies Project of the California Department of

30 CALIFORNIA FISH AND CAME

Fish and Game who trapped and banded mallards, the staff of the Klamath Basin
NWRs for cooperating in the banding program, and Dan Connelly, Waterfowl
Coordinator, California Department of Fish and Game, for support and
manuscript review.

LITERATURE CITED

Anderson, D. R. 1975. Population ecology of the mallard: V. Temporal and geographic estimates of survival,
recovery and harvest rates. U.S. Fish and Wildl. Serv. Resour. Publ. 125. 110 p.

, and C. J. Henny. 1972. Population ecology of the mallard: I. A review of previous studies and the

distribution and migration from breeding areas. U.S. Bureau of Sport Fish and Wildl., Resource Publ. 105. 166
P

_ and K. P. Burnham. 1976. Population ecology of the mallard: VI. The effect of exploitation on survival.

U.S. Fish and Wildl. Service. Resour. Publ. 128. 66 p.

Bartonek, J. C, R. J. Blohm, R. K. Brace, F. D. Caswell, K. E. Gamble, H. W. Miller, R. S. Pospahala, and M. M.

Smith. 1984. Status and needs of the mallard. Trans. N.A. Wildl. and Nat. Resourc. Conf., 49:501-518.
Bellrose, F. C. 1980. Ducks, geese and swans of North America. 3rd ed. Stackpole Books, Harrisburg, PA. 540 p.

, and R. D. Crompton. 1970. Migrational behavior of mallards and black ducks as determined from

banding. Illinois Nat. Hist. Surv., Bull. 30: 167-234.

Brownie, C, D. R. Anderson, K. P. Burnham, and D. S. Robson. 1978. Statistical inference from band recovery
data -a handbook. U.S. Fish and Wildl. Serv. Resour. Publ. 131. 212 p.

Cooch, F. C, and H. Boyd. 1984. Changes in the net export of mallards from western Canada and the contiguous
United States, 1972-82. Canadian Wildl. Serv. Prog. Notes, No. 142, 27 p.

Cowardin, L M., D. S. Gilmer, and C. W. Shaiffer. 1985. Mallard recruitment in the agricultural environment of
North Dakota. Wildl. Monog. 92. 37 p.

Crissey, W. F. 1969. Prairie potholes from a continental viewpoint. P. 161-171 in Saskatoon wetlands seminar.
Canadian Wildl. Serv. Rep., Ser. 6. 262 p.

Furniss, S. B. 1974. Migration characteristics and survival rates of mallards banded at Malheur National Wildlife
Refuge. M.S. thesis, Oregon State Univ. 54 p.

Gilmer, D. S., R. E. Kirby, I. J. Ball, and J. H. Riechmann. 1977. Post-breeding activities of mallards and wood ducks
in north-central Minnesota. J. Wildl. Manage., 41(3): 345-359.

, J. M. Hicks, J. P. Fleskes and D. P. Connelly. 1989. Duck harvest on public hunting areas in California.

Cal. Fish and Game, 75(3): 155-168.

Henny, C. J., and K. P. Burnham. 1976. A reward band study of mallards to estimate band reporting rates. J. Wildl.
Manage., 40(1):1-14.

Johnsgard, P. A. 1958-1959. Comparative behaviour of the Anatidae and its evaluationary implications. Wildfowl
Trust Ann. Rep., 11:31-445.

Martin, E. M., and S. M. Carney. 1977. Population ecology of the mallard: IV. A review of duck hunting regulations,
activity and success, with special reference to the mallard. U.S. Fish and Wildl. Serv. Resour. Publ. 130. 137
P-

Munro, R. E., and C. F. Kimball. 1982. Population ecology of the mallard: VII. Distribution and derivation of the
harvest. U.S. Fish and Wildl. Serv. Resour. Publ. 147. 128 p.

Pollack, K. H., and D. G. Raveling. 1982. Assumptions of modern band-recovery models, with emphasis on
heterogeneous survival rates. J. Wildl. Manage, 46(1): 88-98.

Pospahala, R. S., D. R. Anderson, and C. J. Henny. 1974. Population ecology of the mallard: II. Breeding habitat
conditions, size of breeding populations and production indices. U.S. Fish and Wildl. Serv. Resour. Publ. 115.
73 p.

Reynolds, R. E. 1987. Breeding duck population, production, and habitat surveys, 1979-85. Trans. N.A. Wildl. and
Nat. Resourc. Conf., 52:186-205.

Rienecker, W. C. 1976. Distribution, harvest and survival of American wigeon banded in California. Calif. Fish and
Game, 62(2):141-153.

1987. Survival and recovery rate estimates of pintails banded in California, 1948-79. Calif. Fish and

Game, 73(4):230-237.

Sauer, J. R., and B. K. Williams. 1989. Generalized procedures for testing hypotheses about survival or recovery
rates. J. Wildl. Manage., 53:137-142.

U.S. Fish and Wildlife Service and Canadian Wildlife Service. 1985. Status of waterfowl and fall flight forecast. July
25, 1985. 32 p.

HOMING BY CHINOOK SALMON 31

Calif. Fish and Came 76(1 ): 31-35 1990

HOMING BY CHINOOK SALMON EXPOSED TO

MORPHOLINE1

THOMAS J. HASSLER AND KEITH KUTCHINS 2

U.S. Fish and Wildlife Service

California Cooperative Fishery Research Unit

Humboldt State University, Areata, California 95521

Juvenile chinook salmon, Oncorhynchus tshawytscha, of the 1977 and 1979 brood
years were exposed to 5x10 "5 mg/l of morpholine for 40 d and 17 d, respectively, in
a hatchery, and then released into Mad River, California. An unexposed control
group from each brood year was also released. During the 1979-84 spawning
seasons, when treated fish were expected to return as adults, morpholine was
added continuously to the water in the Mad River Hatchery fish ladder to maintain
a concentration similar to 5x10 "5 mg/l. Morpholine failed to increase the chinook
salmon return rate to the hatchery, probably due to incomplete imprinting.
Morpholine did not affect chinook salmon survival after release, ocean catch rate,
or growth.

INTRODUCTION

The ability of migratory salmonids to accurately locate their natal streams has
been reviewed by various authors (Hasler 1966, Harden-Jones 1968, Hasler et
al. 1978, Hasler and Scholz 1983). Olfaction appears to be the principal sense
used by the fish to identify freshwater home areas through the detection of
distinct odors in the home stream (Hasler 1966, Harden-Jones 1968, Kleere-
kooper 1969, Cooper et al. 1976, Hasler and Scholz 1983). Coho salmon,
Oncorhynchus kisutch, smolts, exposed to morpholine or phenethyl alcohol
before release in Lake Michigan, homed, as adults, to streams or an area in the
lake scented with the same odors (Cooper et al. 1976, Scholz et al. 1976,
Johnsen and Hasler 1980). Hassler and Kucas (1988) demonstrated that coho
salmon imprinted on morpholine detected and homed to morpholine after
living in the ocean for several months to 2 years. The chemical and physical
properties of morpholine and the criteria for its selection as an imprinting
chemical are described by Scholz et al. (1975). No information is available for
the use of morpholine in California. To the best of our knowledge, morpholine
was not used by any other persons near Mad River during the study.

The mean number of female chinook salmon spawned at Mad River
Hatchery from 1971-72, the first year of operation, through 1980-81 was 67 fish,
well below the 1,500 females needed for full production (Kucas 1981 ). The low
return of mature salmon may be due, in part, to poor homing to the hatchery
fish ladder. The water in the hatchery raceways is recirculated well water with
about 10% makeup from well water. At the time of this study, the water in the
fish ladder was a mixture of about 90% single pass pumped river water and
10% hatchery raceway water (Kutchins 1986), which may not have adequately
attracted returning fish, causing straying. Also, the mouth of the ladder is on the
river bank parallel to river flow, providing poor fish access.

' Accepted for publication September 1989.

2 Present address: Confederated Tribes, Umatilla Indian Reservation, P.O. Box 638, Pendleton, Oregon 97801

32 CALIFORNIA FISH AND GAME

The study objective was to determine if the proportion of chinook salmon,
Oncorhynchus tshawytscha, adults returning to Mad River Hatchery could be
significantly increased by exposing smolts to morpholine, and later using
morpholine to attract adults to the hatchery when they returned to spawn.

METHODS

The experiments were conducted at the California Department of Fish and
Game's Mad River Hatchery about 19 river km from the Pacific Ocean near
Eureka, California. The 1977 and 1979 chinook salmon brood years (here
termed BY77 and BY79) were used in the experiment. The fish were randomly
divided into two groups, treated and control, and marked with fin clips or coded
wire tags (CWT) (Table 1). Treated fish were exposed to about 5x10 "5 mg/l
of morpholine in a flow-through hatchery raceway for 17 d or 40 d before they
were released into Mad River. The BY77 fish were released in December 1978
as yearlings and the BY79 fish were released in June 1980 as fingerlings. Control
fish, held upstream in the same raceway, were not exposed to the morpholine.

TABLE 1. Description and Treatment of Chinook Salmon Used in Experiments With Morpholine at
Mad River Hatchery, California.

Size at release

Brood Days No. released and mark * Date Fork length range

year exposed Treated Control released (cm)

1977 40 40,180 LV 41,800 LP Dec1978 13-25

1979 17 18,164 CWT 18,367 CWT June1980 8-13

•* LV = left ventral, LP = left pectoral, CWT = coded wire tag and adipose fin clip.

When mature BY77 and BY79 chinook salmon began to return to the
hatchery in September of 1979-84, morpholine was added to the water in the
hatchery fish ladder as described by Hassler and Kucas (1988). The estimated
landings of CWT BY79 chinook salmon in the ocean fishery were obtained from
Pacific Marine Fisheries Commission, Portland, Oregon. A X 2-test was used to
compare the returns to the hatchery and ocean landings of treated and control
fish by brood year.

RESULTS

Of 1 18,51 1 chinook salmon released from the hatchery in the two years, only
99 (0.08%) returned to the hatchery— 58 treated and 41 control (Table 2).
Among the fish that returned in both experiments, the number of treated fish
was not statistically different ( P > 0.05 ) from that of the controls. The return rate
of chinook salmon was significantly higher for BY79 (0.18%) than for BY77
(0.04%) (P<0.05). Mean fork lengths fl of treated and control fish of BY79
that returned to the hatchery were similar (Table 3).

TABLE 2. Return of Experimental Chinook Salmon to the Mad River Hatchery, California
(T = treated, C = control).

Brood Number Number returned3

Year

:977

eleased

1979

1980

1981

1982

1983

Total

40,180 T

9

9

1

-

-

19

41,800C

8

4

1

-

-

13

18,164T

-

-

21

18

0

39

18,367 C

-

-

13

14

1

28

1979

a Numbers of treated and control fish that returned to the hatchery were not significantly different in any year.
No experimental fish returned in 1984.

HOMING BY CHINOOK SALMON

33

The numbers of treated and control chinook salmon of BY79 landed in the
ocean commercial and sport fisheries, estimated from CWT recoveries, were
not statistically different (P>0.05). The estimated landing was 268 fish — 142
treated and 126 control (Table 3). In 1982, when 96% of the fish were landed,
the length (mean and range) of treated and control fish was similar (Table 3).
The landing rate of BY79 salmon was 0.73% and the return to the hatchery was
0.18%, for a landing to hatchery escapement ratio of 4:1.

TABLE 3.

Year

Return of 1979 Brood Year Experimental Chinook Salmon to Mad River
Hatchery and Landed in the Ocean Fishery (T = treated, C = control).

Fork length (cm)

Number"

Mean (range)

1981 Returned

T 21 57 (53-64)

C 13 58 (47-64)

Landed
T 2 49 (48-50)

C 1 41

1982 Returned

T 18 79 (60-97)

C 14 78 (71-89)

Landed
T 133 70 (64-75)

C 123 69 (64-80)

1983 Returned
T 0

C 1 73

Landed

T 7 62

C 2 78

Totals Returned

67

Landed
268

a Numbers of treated and control fish landed in the ocean fishery or at the hatchery were not significantly different
in any year. No experimental fish were landed or returned in 1984.

DISCUSSION

The failure of morpholine to increase the proportion of chinook salmon
returning to Mad River Hatchery was possibly due to incomplete imprinting.
The BY79 salmon were exposed to morpholine for only 17 days before they
were released from the hatchery because of a change in hatchery management
(fish were released in early June at age 0 instead of in October at age 1 ) and
many salmon may not have imprinted to the chemical. In salmonids, high levels
of the hormone thyroxine are associated with imprinting and smoltification
(Dickhoff et al., 1978, Folmar and Dickhoff 1980, Scholz 1980). Grau et al.
(1982) identified four thyroxine peaks in BY80 juvenile chinook salmon from
Iron Gate Hatchery, California, and suggested that all of the fish may not have
peaked simultaneously. Thus, the number of chinook salmon that imprint to
morpholine may be increased by a longer exposure time. Hassler and Kucas
(1988) found that coho salmon smolts were imprinted to morpholine after 41
days of exposure at Mad River Hatchery and returns of morpholine-exposed
fish were 276% higher than those of control fish (P<0.05). It is also possible
that exposure to a higher concentration of morpholine may increase imprinting.
The small sample size of adult salmon hatchery returns reduces the strength of

34 CALIFORNIA FISH AND CAME

our finding that morpholine does not improve homing. We believe that the poor
returns of BY77 fish was due to disease (Ichthyophthirius multifilis), late release
of juveniles due to low river flows, and below average river flows for upstream
migration of spawning adults. For BY79, ocean survival was probably reduced
due to a severe El Nino in 1982-83 (Hayes and Henry 1985).

The numbers of treated and control BY79 chinook salmon landed in the
ocean fisheries were not significantly different. These data indicate that
morpholine did not affect chinook salmon survival after they were released
from the hatchery or their susceptibility to being caught in the ocean. Also, the
lengths of treated and control salmon landed in the ocean and returning to the
hatchery were similar, indicating that morpholine did not affect fish growth.

The imprinting process in salmonids is not completely understood. It is
believed that imprinting of migratory salmon occurs just before and during initial
downstream migration of smolts (Ricker 1972; Hasler and Scholz 1983).
However, downstream migratory behavior and saltwater tolerance differs
among species and within a species. Further study is required to determine the
best method and time to imprint and release chinook salmon from a hatchery.
The studies should include an accurate evaluation of the smolt transformation
period and include coloration, osmoregulatory capability, and salinity tolerance
and preference, and migratory activity.

ACKNOWLEDGMENTS

We thank the California Department of Fish and Game and Mad River
Hatchery staff for providing facilities and equipment and for helping us mark the
fish; the California Conservation Corps, the U.S. Young Adult Conservation
Corps, and student volunteers who also helped mark fish; and R. Barnhart, G.
Hendrickson, E. Loudenslager, L. B. Boydstun and C. Knutson for reviewing the
manuscript. This work was a result of research sponsored in part by NOAA,
National Sea Grant College Program, Department of Commerce, under grant
number NA 80 AA-D-00120, project number R/F-77 through the California Sea
Grant College Program, and in part by the California State Resources Agency.

LITERATURE CITED

Cooper, J. C, A. T. Scholz, R. M. Horrall, A. D. Hasler, and D. M. Madison. 1976. Experimental confirmation of

the olfactory hypothesis with homing, artificially imprinted coho salmon (Oncorhynchus kisutch). ). Fish.

Res. Board Canada, 33:703-710.
Dickhoff, W. W., L. C. Folmar, and A. Corbman. 1978. Changes in plasma thyroxine during smoltification of coho

salmon, (Oncorhynchus kisutch). Gen. Comp. Endocrinol., 36:229-232.
Folmar, L. C, and W. W. Dickhoff. 1980. The parr-smolt transformation (smoltification) and seawater adaptation

in salmonids; A review of selected literature. Aquaculture, 21:1-37.
Crau, E. C, J. L Specker, R. S. Nishioka, and H. A. Bern. 1982. Factors determining the occurrence of the surge

in thyroid activity in salmon during smoltification. Aquaculture, 28:49-57.
Harden-Jones, F. R. 1968. Fish migration. St. Martin's Press, New York.

Hasler, A. D. 1966. Underwater Cuideposts-Homing of Salmon. University of Wisconsin Press, Madison.
Hasler, A. D., and A. T. Scholz. 1983. Olfactory imprinting and homing in salmon. Springer-Verlag, New York.
Hasler, A. D., A. T. Scholz, and R. M. Horrall. 1978. Olfactory imprinting and homing in salmon. Am. Sci.,

66:347-355.
Hassler, T. )., and S. T. Kucas. 1988. Returns of morpholine-imprinted coho salmon to the Mad River, California.

North Am. J. Fish. Manage., 8:356-358.
Hayes, M. L, and K. A. Henry. 1985. Salmon management in response to the 1982-83 El Nino event, in W.S.

Wooster and D.L. Fluharty eds. El Nino North: Nino effects in the Eastern Subarctic Pacific Ocean. Washington

Sea Grant Program, University of Washington, Seattle.

HOMING BY CHINOOK SALMON 35

Johnsen, P. B., and A. D. Hasler. 1980. The use of chemical cues in the upstream migration of coho salmon,

Oncorhynchus kisutch Walbaum. J. Fish Biol., 17:67-73.
Kleerekooper, H. 1969. Olfaction in fishes. Indiana University Press, Bloomington.

Kucas, S. T. Jr. 1981. Morpholine imprinting of chinook Oncorhynchus tshawytscha and coho salmon O. kisutch
in an anadromous fish hatchery. M. S. Thesis. Humboldt State University, Areata, California.

Kutchins, K. 1986. Returns of artificially imprinted chinook salmon Oncorhynchus tshawytscha to the ocean
fishery and natal hatchery. M. S. Thesis. Humboldt State University, Areata, California.

Ricker, W. E. 1972. Heredity and environmental factors affecting certain salmonid populations. Pages 19-160 in
R. C. Simon and P. A. Larkin eds. The stock concept in Pacific salmon. The University of British Columbia,
Vancouver.

Scholz, A. T. 1980. Hormonal regulation of smolt transformation and olfactory imprinting in coho salmon. Ph.D.
thesis. University of Wisconsin-Madison.

Scholz, A. T., R. M. Horrall, J. C. Cooper, A. D. Hasler, D. M. Madison, R. J. Poff, and R. I. Daly. 1975. Artificial
imprinting of salmon and trout in Lake Michigan. Fish Manage. Rep. 80. Wisconsin Department of Natural
Resources, Madison.

Scholz, A. T., R. M. Horrall, J. C. Cooper, and A. D. Hasler. 1976. Imprinting to chemical cues: the basis for
homestream selection in salmon. Science, 196:1247-1249.

36 CALIFORNIA FISH AND CAME

Calif. Fish and Came 76 ( 1 ) : 36-42 1 990

MOVEMENT AND SURVIVAL OF TOURNAMENT-CAUGHT
BLACK BASS AT SHASTA LAKE 1

TERRANCE P. HEALEY

California Department of Fish and Game

Inland Fisheries, Region 1

601 Locust Street
Redding, California 96001

Tournament-caught smallmouth, Micropterus dolomieui, and iargemouth bass,
M. salmoides, at Shasta Lake were tagged to evaluate displaced bass movement. Of
180 tagged smallmouth bass recaptures, more than 87% moved from 1.6 km to 30.6
km from the release sites. Smallmouth bass recaptures during the first 20 days
averaged 5.8 km from the release sites. For the entire study period, the distances
between release and recapture locations for smallmouth bass averaged 83 km.

Of 34 Iargemouth bass recaptures, 62% occurred from 1.6 to 17.7 km from the
release sites. Largemouth bass recaptures averaged 2 km from the release sites in
the first 40 days while recaptures for the entire study period averaged 3.5 km from
the release sites. Annual survival rates for smallmouth and largemouth bass were
estimated at 0.13 and 0.15, respectively.

INTRODUCTION

Major black bass tournament sponsors in California are required to obtain a
permit for each event from the California Department of Fish and Game and
release all bass alive after weighing. The permit sometimes requires sponsors to
transport and release bass away from the tournament weigh-in site to ensure
dispersal, because earlier studies of bass released at initial capture locations
indicate that bass normally do not move great distances but tend to remain in
restricted home ranges for long periods (Latta 1963, Lewis and Flickinger 1967,
Miller 1975, Coble 1975). In developing permit conditions for bass tournaments,
it had been assumed that bass caught at various locations on a lake and released
at a common weigh-in site would establish a new home range at or near the
release site. Repeated bass releases at weigh-in sites were expected to result in
abnormally large bass concentrations there. To prevent bass accumulation,
redistribution seemed appropriate. However, the additional handling and
confinement associated with redistribution increases stress (Carmichael et al.
1984). Furthermore, movements of relocated smallmouth bass, Micropterus
dolomieui, were much greater than for bass that were not relocated (Forney
1961, Blake 1981, Pflug and Pauley 1983), suggesting that transporting
tournament-caught smallmouth bass to disperse them may be unnecessary. A
tagging study was initiated at Shasta Lake in 1985 to evaluate movement and
annual survival of tournament-caught smallmouth and largemouth bass, Mi-
cropterus salmodies, released at two marinas and to determine if bass
redistribution is necessary to ensure dispersal.

Accepted for publication September 1989.

TOURNAMENT-CAUGHT BLACK BASS

DESCRIPTION OF SHASTA LAKE

37

Shasta Lake is a 5,551 hm 3 impoundment formed by Shasta Dam on the
Sacramento River, 11 km upstream from Redding, California (Figure 1). The
dam was constructed by the U.S. Bureau of Reclamation in the early 1940s to
provide water for irrigation, electrical power, and flood control. The reservoir
has a surface area of 11,947 ha and 587 km of shoreline at full pool elevation
(325 m). Water is stored during the winter for agricultural use mainly during the
summer, which causes the water level to fluctuate greatly, with the highest
levels occurring in the spring and lowest in the fall.

10 HT SHKIk

FIGURE 1. Map of Shasta Lake showing tagged bass release sites and recapture locations.

METHODS

A total of 126 tournament-caught smallmouth bass and 41 largemouth bass,
from undetermined locations throughout the lake, were tagged with nonreward
trailer tags and released at the Bridge Bay Marina on March 2, 1985 (Figure 1 ).
Likewise, on 22 and 23 March, 1985, 371 smallmouth and 42 largemouth bass
were tagged and released at the Silverthorn Marina (Table 1). Green vinyl
plastic trailer tags, measuring 16 mm X mm X 0.8 mm and inscribed with the
letters "NR" and instructions for returning the tag by mail were attached to the
fish by threading soft 0.3 mm stainless steel wire through 21 -gage X 3.8 cm
hypodermic needles temporarily inserted through the back of the fish at the
anterior base of the first dorsal fin. Following removal of the needles, the wires
of the tag bridles remained in the fish and were fastened by twisting the ends
and cutting off the excess wire. Trailer tags attached in this manner were found

38 CALIFORNIA FISH AND CAME

to have high retention (Nicola and Cordone, 1969). Non-reward tags were used
rather than reward tags to eliminate possible bias from anglers who might exert
a disproportionate amount of fishing effort at the marina docks, compared to
other areas of the lake, for the purpose of catching tagged fish for the rewards.

TABLE 1. Numbers of Shasta Lake Bass Tagged and Released in 1985 by Length Class.

Smallmouth bass Largemouth bass

Bridge Bay ' Silverthorn 2 Bridge Bay ' Silverthorn 2
Fork length (mm)

280-305 10 4 1 1

306-330 80 224 6 10

331-356 22 97 17 14

357-381 10 36 10 9

382^106 2 6 4 5

407^31 14 11

432-456 1 1 1

457-481 1

482-506

507-531 - - - 1

Total 126 371 41 42

Mean fl (mm) 323 328 353 356

' Bass tagged and released on 2 March 1985.
2 Bass tagged and released on 22-23 March 1985.

Anglers who returned tags were asked to describe capture locations and dates
and mark the locations on a map. Only first time recaptures were used in the
analysis. Bass movement was measured as the shortest distance from the point
of release to the reported capture location on the lake. A few tags were returned
without recapture location information and were not used to determine
movement but were used to estimate annual survival because they were
returned in the first year.

Annual survival rates were estimated from tag return ratios between
succeeding years (both release sites combined) based on Ricker's formula 4.2
(Ricker 1958). Recaptures from day 0-365 were included as first year
recaptures. Second and third year recaptures were from day 366-730 and day
731-1,095, respectively.

RESULTS
Bass Recaptures

Total returns of the tagged bass ranged from 38.8% to 45.3% (Table 2).
Tagged bass recaptures in the first year accounted for 87% of the total returns
and ranged from 34.1% to 38.1% of numbers released. The last tagged
smallmouth and largemouth bass recaptures were made on 22 August, 1987 and
12 July, 1987, respectively.

TABLE 2. Shasta Lake Tagged Bass Recaptures.

Smallmouth Bass Largemouth Bass

Recapture Bridge Bay Silverthorn Bridge Bay Silverthorn

Year No. % No. % No. % No. %

First Year 43 34.1 128 34.5 15 36.6 16 38.1

Second Year 9 7.1 14 3.8 1 2.4 2 4.8

Third Year 0 0 2 0.5 1 2.4 1 2.4

Totals 52 41.2 144 38.8 17 41.4 19 45.3

TOURNAMENT-CAUGHT BLACK BASS

39

Smalimouth Bass Movement

Small mouth bass released at both sites were recaptured at widespread
locations. A clustering of recaptures occurred in areas where fishing effort is
known to be relatively high, which included areas near the release sites (Figure
1 ). Of 180 tagged smalimouth bass returns for which recapture information was
available, 23 (12.8%) were caught less than 1.6 km from the release sites while
157 (87.2%) were caught from 1.6 to 30.6 km from the release sites (Figure 2).

100

90

CO

LU

<r

Z)

i-
fi_
<
o
111

CE
ID

>

3

o

80 -

70

^ 0-1.6 km
1.6-8.0 km
8.0-31.0 km

20

40

60

80 100

DAYS AT LIBERTY

365

730

883

FIGURE 2. Cumulative recaptures of tagged smalimouth bass showing distances traveled from
release sites and time at liberty.

The average distances from the release sites for smalimouth bass recaptures
were 5.8 km in the first 20 days and 8.5 km for the entire study period. There
were four smalimouth bass that moved at least 17.7 km each in 10-18 days.

Largemouth Bass Movement

Largemouth bass recaptures occurred mainly near the release sites (Figure 1 ) .
Of 34 tagged largemouth returns, 1 3 ( 38.2% ) were caught less than 1 .6 km from
the release sites while 21 (61.8%) were caught from 1.6-17.7 km from the
release sites (Figure 3). Average distances from release sites were 2 km in the
first 40 days and 3.5 km during the entire study period. One largemouth bass
moved 6.4 km in 14 days.

40

CALIFORNIA FISH AND CAME

50

40 -

] 0-1.6 km
1.6-8.0 km
8.0-31.0 km

365

730

862

DAYS AT LIBERTY

FIGURE 3.

Cumulative recaptures of tagged largemouth bass showing distances traveled from
release sites and time at liberty.

Estimated Survival of Tagged Bass

Annual survival rates were calculated at 0.13 (S = 25/194) for smallmouth
bass and 0.15 (S = 5/34) for largemouth bass.

DISCUSSION AND CONCLUSIONS

Since only three smallmouth and no largemouth bass were recaptured during
the first 10 days after release, tagged bass apparently were not vulnerable to
angling shortly after release.

First year and total harvest rates were fairly uniform for all release groups and
were considered to be high for non-reward tagged fish.

More than 87% of the smallmouth bass dispersed and were recaptured at
least 1 .6 km from the release sites which is consistent with the findings of others
who have conducted similar studies. For example, Larimore (1952) observed
relocated stream-dwelling smallmouth bass and found that many returned to
their home pools. Forney (1961 ) noted that smallmouth bass released 8 to 24.1
km from an initial capture area in Oneida Lake, New York, traveled an average
of 6.8 km to 12.4 km before recapture, while bass released within 4.0 km from
their initial capture locations traveled only 3.9 km. Blake (1981) observed
greater movement of tournament-caught smallmouth bass that had been
displaced compared to bass that were caught and released at initial capture
locations on the Saint Lawrence River. Pflug and Pauley (1983) found that 79%
of the smallmouth bass that had been relocated from 0.8 to 1 1 .3 km away from

TOURNAMENT-CAUGHT BLACK BASS

41

initial capture locations in Lake Sammamish, Washington, moved away from
their new release site before recapture. They also reported that 41% of the
relocated tagged bass were able to travel up to 9.7 km to return to their initial
capture locations, while 80% of the bass that were released where initially
captured showed little or no movement. In this study, smallmouth bass moved
an average distance of 8.5 km, which is considerably greater than the averages
of 3.9 km and 1.1 km reported by Forney (1961) and Rawstron (1967),
respectively, for smallmouth bass that were not displaced.

The results of this and other smallmouth bass displacement studies indicate
that tournament-caught smallmouth bass released at a common weigh-in site
can be expected to disperse naturally.

Largemouth bass in this study moved an average of 3.5 km from the release
sites which is greater than the 1.9 and 1.1 km averages reported by Fisher
(1953) and Rawstron (1967), respectively, for largemouth bass that were
tagged and released where initially captured. The Shasta Lake average is
comparable to the 3.7 km average observed by Kimsey (1957) for some tagged
groups but less than the overall average of 7.2 km. Kimsey noted that angler
reporting errors may have affected his migration data to indicate greater
movement than actually occurred. Forty-one percent of the largemouth bass
recaptures in this study occurred within 1.6 km of the release sites, which is
similar to the results of Blake (1981 ), who reported that 44% and 52% of the
returns of displaced tournament-caught largemouth bass in the Saint Lawrence
River occurred within 1.6 km of the release sites during two tests in successive
years.

Since largemouth bass did not move as far or disperse as quickly from the
release sites as smallmouth bass, it may be appropriate for tournament sponsors
to transport largemouth bass well away from weigh-in sites, especially where
repeated tournaments are held, if it can be done without reducing survival.

The annual survival rates of 0.13 for smallmouth bass and 0.15 for largemouth
bass in this study were low compared to survival rates noted in other studies
(Table 3). Low survival rates were also reported at Shasta Lake for both
smallmouth and largemouth bass by Van Woert (1980) and were attributed to
high angler exploitation of both species.

TABLE 3. Comparative Annual Survival Rates of Smallmouth (SMB) and Largemouth Bass (LMB)
noted in Selected Waters.

Annual
Name of Water Species Survival Reference

Shasta Lake SMB 0.13 This study

Shasta Lake " 0.10-0.18' Van Woert (1980)

Merle Collins Res " 0.16 Pelzman et ai (1980)

Oneida Lake " 0.40-0.82 Forney (1961; 1972)

Lake Michigan " 0.42 Latta (1963)

Shasta Lake LMB 0.15 This study

Shasta Lake " 0.22 Van Woert (1980)

Don Pedro Res " 0.29 Horton and Lee (1982)

Merle Collins Res " 0.08-0.29 Rawstron et al (1972)

Folsom Lake " 0.11 Rawstron (1967)

Sutherland Res " 0.30 La Faunce et al (1964)

Gladstone Lake " 0.40 Maloney et al (1962)

Clear Lake " 0.44 Kimsey (1957)

Sugarloaf Lake " 0.30 Cooper and Latta (1954)

1 Annual survival rates for smallmouth bass 306-356 mm fl.

42 CALIFORNIA FISH AND GAME

ACKNOWLEDGMENTS

I thank Don Weidlein for assistance in developing the study plan tagging of
fish and review of the manuscript. W. F. Van Woert, M. Rode, V. L. King, C.
Keys, R. Calkins, T. Nichols and J. Orre helped with the tagging of fish.

LITERATURE CITED

Blake, L. M. 1981. Movement of tournament-caught and released bass. New York Fish and Game J., 28

(1)11 5—1 17.
Carmichael, C. J., J. R. Tomasso, B. A. Simco and K. B. Davis. 1984. Confinement and water quality-induced stress

in largemouth bass. Am. Fish. Soc, Trans., 113(6):767-777.
Coble, D. W. 1975. Smallmouth bass. Pages 21-33 in Henrv Clepper, ed. Black bass biology and management.

Sport Fish Inst.
Cooper, G. P. and W. C. Latta. 1954. Further studies on the fish population and exploitation by angling in Sugarloaf

Lake, Washtenaw County. Michigan. Mich. Acad. Sci., Arts and Let., Pap. (32):209-223.
Fisher, Charles K. 1953. The 1950 largemouth black bass and bluegill tagging program in Millerton Lake, California.

Calif. Fish and Game 39(4):485-487.
Forney. J. L. 1961. Growth, movements and survival of smallmouth bass Micropterus dolomieu in Oneida Lake,

New York. New York Fish and Game J., 8(2):88-105.
Forney, J. L. 1972. Biology and management of smallmouth bass in Oneida Lake, New York. New York Fish and

Game J., 19(2):132-154.
Horton, ). L., and D. P. Lee. 1982. Harvest and mortality of tournament caught and released largemouth bass at

Don Pedro Reservoir, California. Calif. Fish and Game Inland Fish. Admin. Rpt. No. 82-3, 8 p.
Kimsey, J. B. 1957. Largemouth bass tagging at Clear Lake, Lake County, California. Calif. Fish and Game,

43(2):111-118.
LaFaunce, D. A., J. B. Kimsey, and H. K. Chadwick. 1964. The fishery at Sutherland Reservoir, San Diego County,

California. Calif. Fish and Game, 50(4):271-291.
Larimore, W. R. 1952. Home pools and homing behavior of smallmouth black bass in Jordan Creek. III. Nat. Hist.

Surv. Biol. Notes, No. 28. 12 p.
Latta, W. C. 1963. The life history of the smallmouth bass Micropterus dolomieui, at Waugoshance Point, Lake

Michigan. Mich. Dept. Conserv. Inst. Fish. Res. Bull. No. 5. 56 p.
Lewis, William M. and S. Flickinger. 1967. Home range tendency of the largemouth bass (Micropterus salmoides) .

Ecology, 48:1020-1023.
Maloney, J. E., D. R. Schupp, and W. J. Scidmore. 1962. Largemouth bass population and harvest. Gladstone Lake,

Crow Wing County. Minnesota. Trans. Amer. Fish. Soc. 91 (1):42-52.
Miller, R. J. 1975. Comparative behavior of centrarchid basses. Pages 85-94 in Henry Clepper, ed. Black bass

biology and management. Sport Fish. Inst.
Nicola, S. J. and A. ). Cordone. 1969. Comparisons of disk-dangler, trailer and plastic jaw tags. Calif. Fish and

Game, 55(4):273-284.
Pelzman, R. J.; S. A. Rapp and R. R. Rawstron. 1980. Mortality and survival of smallmouth bass, Micropterus

dolomieui, at Merle Collins Reservoir, California. Calif. Fish and Game, 66(1):35-39.
Pflug, D. E. and G. B. Pauley. 1983. The movement and homing of smallmouth bass, Micropterus dolomieui, in

Lake Sammamish, Washington. Calif. Fish and Game, 69(41:207-216.
Rawstron, R. R. 1967. Harvest, mortality and movement of selected warmwater fishes in Folsom Lake, California.

Calif. Fish and Game, 53(1):40-48.
Rawstron, R. R. and K. A. Hashagen, jr. 1972. Mortality and survival rates of tagged largemouth bass (Micropterus

salmoides) at Merle Collins Reservoir. Calif. Fish and Game, 58(31:221-230.
Ricker, W. E. 1958. Handbook of computations for biological statistics of fish populations. Can. Fish. Res. Bd., Bull.

119:300 p.
Van Woert, W. F. 1980. Exploitation, natural mortality and survival of smallmouth bass and largemouth bass in

Shasta Lake, California. Calif. Fish and Game, 66(3):163-171.

STEELHEAD— BARBED AND BARBLESS HOOKS 43

Calif. Fish and Game 76(1): 43-45 1 990

COMPARISON OF STEELHEAD CAUGHT AND LOST BY

ANGLERS USING FLIES WITH BARBED OR BARBLESS

HOOKS IN THE KLAMATH RIVER, CALIFORNIA1

ROGER A. BARNHART

U.S. Fish and Wildlife Service

California Cooperative Fishery Research Unit

Humboldt State University

Areata, California 95521

Klamath River anglers lost fewer steelhead Oncorhynchus mykiss on barbed
hooks than on barbless hooks, regardless of fish size. Losses from barbed hooks of
sizes 8 and 6 did not differ with fish size. Significantly fewer "half-pounders" ( < 406
mm long) were lost from barbless hook flies of size 6 than size 8. For adult steelhead
( >406 mm long) the loss rate was the same for flies with barbless hooks of size 6
and 8.

INTRODUCTION

Trout fisheries managed for catch-and-release fishing are increasing, and are
popular with trout anglers (Graff 1987). The California Department of Fish and
Game, which manages 17 streams and 7 lakes as catch-and-release fisheries
restricted to artificial lures has recently added a "single barbless hook only"
regulation for these waters — primarily to reduce mortalities (Deinstadt 1987).

Many fly anglers, regardless of regulations, fish with barbless hooks because
they feel that captured trout are easier to release. Other anglers prefer flies with
barbed hooks because they believe fish are not hooked as deeply and are less
likely to be injured. Although many investigators have compared the hooking
mortality of trout caught on barbed and barbless hooks (Wydowski 1977;
Dotson 1982; Mongillo 1984; Titus and Vanicek 1988), the catch efficiencies of
barbed and barbless hooks have not been rigorously compared — although
Knutson (1987) reported that barbless hooks were as efficient as barbed hooks
in catching all sizes of salmon taken by charter boat anglers fishing off the
California coast.

The objective of this study was to compare numbers of Klamath River fall-fun
steelhead, Oncorhynchus mykiss, caught and lost by fly anglers, by hook type
(barbed or barbless, size 6 or size 8), and fish size ("half-pounder" or adult).

STUDY AREA

The Klamath River, in northwestern California, is an important salmon and
steelhead stream. Fall-run steelhead provide a popular sport fishery from August
to October (Kesner and Barnhart 1972). This fishery is primarily for small
steelhead called "half-pounders", along with some adult steelhead. Half-
pounders are unique in being on their first upstream migration after only a few
months in the ocean. They are immature and survivors return to the ocean,
grow, and migrate upstream in the following year as maturing adults (Kesner
and Barnhart 1972, Everest 1973). Half-pounders are popular with anglers
because of their willingness to strike and their fighting qualities. This investiga-

1 Accepted for publication September 1989.

44 CALIFORNIA FISH AND CAME

tion was confined to the lower 40 km of the river above Klamath, California,
where access is primarily by boat; it is not a catch-and-release water.

METHODS

Local fishing guides agreed to encourage their clients to participate in this
study. A form was provided for each angler each day to record the number of
half-pounders and adult steelhead caught or lost with barbed- or barbless-hook
flies of size 6 or 8. Steelhead less than 406 mm (16 inches) in total length were
considered half-pounders. Anglers were asked to fish with barbed or barbless
hooks for half the fishing day and then to switch to the alternate choice for the
rest of the day, in an effort to eliminate variability due to differences in angler
skill. A "fish lost" was defined as one that escaped the hook at any time from
the initial hooking to the beginning of the time when the angler had the fish
under control and was trying to grasp, net, or bank the fish to release or keep
it. A strike or bite did not count as a fish lost.

I used goodness of fit tests with log linear models and chi-square contingency
tables (Sokal and Rohlf 1981) to test the null hypothesis that numbers of fish
caught or lost were independent of hook type and fish size.

RESULTS AND DISCUSSION

Angling data were collected from August 17 to November 7, 1988. During this
period daytime water temperatures ranged from 14° to 22°C; they were highest
in August and lowest in November. The total of 48 anglers who participated
hooked 1,914 steelhead, of which 1,372 were caught and 542 lost (Table 1).

TABLE 1. Steelhad Caught or Lost on Flies, Arranged by Hook Type (Barbed, Barbless, Sizes 8 and 6)
and Fish Size (Half-Pounder, Adult), Klamath River 1988.

Total
Hook type and fish Caught Lost

fish size hooked (No.) No. Percent

Barbed 8

Half-pounder 244 184 60 25

Adult 42 35 7 17

Total 286 219 67 23

Barbed 6

Half-pounder 402 311 91 23

Adult 84 72 12 14

Total 486 383 103 21

Barbless 8

Half-pounder 365 225 140 38

Adult 31 21 10 32

Total 396 246 150 38

Barbless 6

Half-pounder 667 470 197 30

Adult 79 54 25 32

Total 746 524 222 30

Totals 1914 1372 542 28

Analyses of the data showed that the numbers of steelhead caught and lost
were not independent of hook type (G value 34.99, p< 0.005, 6 df) and that
fewer fish, regardless of size, were lost from barbed hooks than from barbless
hooks (G value 26.3, p< 0.005, 2 df). For half-pounders, hook sizes combined,
23% of the fish hooked on barbed hooks were lost and 33% of those hooked

STEELHEAD— BARBED AND BARBLESS HOOKS 45

on barbless hooks were lost (p< 0.005). For adult steelhead, hook sizes
combined, 15% of the fish hooked on barbed flies and 32% of those hooked
on barbless flies were lost (p< 0.005).

Analyses of the catch-loss rate by hook size showed no significant difference
for barbed hooks for either half-pounders or adults (Table 1, G value 0.46, 2df).
However, for barbless flies, significantly fewer half-pounders were lost from size
6 hooks (30%) than from size 8 hooks (38%); G value 28.53, p< 0.005, 2 df.
For adult steelhead the catch-loss rate was the same for barbless hooks,
regardless of hook size (32% lost).

The actual differences in numbers of fish lost per fishing day may not be
important to many Klamath River fly anglers, because many release most or all
of the fish caught. The creel limit for steelhead is three fish. If a fly angler
hooked 10 half-pounders and 5 adult steelhead during a day's fishing, an
average of 2 half-pounders and 1 adult would be lost from barbed hooks and
3 half-pounders and 2 adults lost from barbless hooks.

The use of barbless hook regulations to reduce fish mortality in catch-and-
release waters appears to be valid. In addition to possibly reducing the mortality
of landed fish through easier hook removal and reduced handling, the regulation
may provide additional protection for fish because fewer trout are landed. The
regulation should also help to distribute the catch among more anglers.

ACKNOWLEDGMENTS

I thank T.J. Hassler and T.D. Roelofs for reviewing the manuscript, and guides
Mike Kuczynski, Dave Schachter and Mac Stuart of Time Flies and fellow angler
Gary Tucker for helping to collect angling data.

LITERATURE CITED

Deinstadt, J.M. 1987. California's use of catch-and-release angling regulations on trout waters. Pages 49-67 in R.A.
Barnhart and T.D. Roelofs, eds. Catch-and-release fishing, a decade of experience, a national sport fishing
symposium. Humboldt State Univ., Calif. Coop. Fish. Res. Unit, Areata, CA.

Dotson, T. 1982. Mortalities in trout caused by gear type and angler-induced stress. North Am. J. Fish. Manage.,
2:60-65.

Everest, F.H. 1973. Ecology and management of summer steelhead in the Rogue River. Oregon State Game
Commission, Fishery Res. Rep. No. 7, Corvallis, OR. 48 p.

Graff, D.R. 1987. Catch-and-release, where it's hot and where it's not. Pages 5-15 in R.A. Barnhart and T.D.
Roelofs, eds. Catch-and-release fishing, a decade of experience, a national sport fishing symposium.
Humboldt State University, Calif. Coop. Fish. Res. Unit, Areata, CA.

Kesner, W.D., and R.A. Barnhart. 1972. Characteristics of the fall-run steelhead trout Sa/mo gairdneri gairdneri oi
the Klamath River system with emphasis on the half-pounder. Calif. Fish and Game, 58(3):204-220.

Knutson, A.C. Jr. 1987. Comparative catches of ocean sport-caught salmon using barbed and barbless hooks and
estimated 1984 San Francisco Bay area charterboat shaker catch. Calif. Fish and Game, 73(2):106-116.

Mongillo, P.E. 1984. A summary of salmonid hooking mortality. Wash. Dept. of Wildlife, Fish Manage. Div.,
Olympia, WA. Unpublished document. 46 p.

Sokal, R.R., and F.J. Rohlf. 1981. Biometry. W.H. Freeman and Co., San Francisco, CA. 859 p.

Titus, R.G., and CD. Vanicek. 1988. Comparative hooking mortality of lure-caught Lahonton cutthroat trout at
Heenan Lake, California. Calif. Fish and Game, 74(4):218-225.

Wydowski, R.S. 1977. Relation of hooking mortality and sublethal stress to quality fishery management. Pages
43-87 in R.A. Barnhart and T.D. Roelofs, eds. Catch-and-release fishing as a management tool, a national
sport fishing symposium. Humboldt State Univ., Calif. Coop. Fish. Res. Unit, Areata, CA.

46 CALIFORNIA FISH AND CAME

Calif. Fish and Came 76 ( 1 ) : 46-57 1 990

ESTABLISHMENT OF RED SHINER, NOTROPIS LUTRENSIS,
IN THE SAN JOAQUIN VALLEY, CALIFORNIA1

MARK R. JENNINGS and MICHAEL K. SAIKI

U.S. Fish and Wildlife Service

National Fisheries Contaminant Research Center

Field Research Station

6924 Tremont Road

Dixon, CA 95620

Red shiner, Notropis lutrensis, recently introduced into the San Joaquin Valley,
California are spreading throughout the Valley floor. Densities of shiner were
highest in irrigation canals and drains, and other small, shallow, unstable aquatic
habitats that were strongly influenced by agricultural and other human-related
activities. These habitats were characterized by elevated turbidity, conductivity,
total dissolved solids, total alkalinity, and total hardness. Fish species closely
associated with red shiner were common carp, Cyprinus carpio, threadfin shad,
Dorosoma petenense, mosquitofish, Cambusia affinis, inland silverside, Menidia
beryllina, striped bass, Morone saxatilis, fathead minnow, Pimephales promelas, and
Sacramento blackfish, Orthodon microlepidotus. All of these species are generally
able to tolerate the harsh conditions present in many streams and rivers on the
Valley floor. Limited observations on the life history of red shiner in the Valley
showed them to be similar to endemic populations in the Mississippi River basin.
Adults (mostly fish in their second growing season) were reproductively active
from April to October. Major foods of these fish included filamentous algae and
aquatic insect larvae. However, red shiner in irrigation drains and canals on the
Valley floor also consumed terrestrial ants (Formicidae). The species is expected to
eventually spread through the entire lower San Joaquin River system.

INTRODUCTION

Red shiner, Notropis lutrensis, are native to midwestern streams in the
Mississippi River and Rio Grande drainages (Movie 1976). In California, this fish
has occurred in the Colorado River since at least 1953, presumably through bait
minnow releases (Hubbs 1954). From the Colorado River, red shiner have
moved into freshwater irrigation drains around the edge of the Salton Sea. In
1985, red shiner were also discovered in Big Tujunga Creek and in Coyote Creek
at the upper end of Newport Bay within the Los Angeles basin of southern
California (Los Angeles County Museum of Natural History; LACM 44507-2,
44508-1, 44509-1, 44510-1, 44522-2). However, attempts to establish the
species elsewhere in the State as a source of live bait have generally been
unsuccessful (Kimsey and Fisk 1964, Moyle 1976, McGinnis 1984).

Red shiner were first observed in the San Joaquin Valley when Wang (1986)
collected an unspecified number of juvenile and adult fish in Millerton Lake,
Fresno County, from 1980 to 1982. During July 1981, a single fish was collected
from the San Joaquin River near Firebaugh, Fresno County (Saiki 1984). From
May to July 1984, Ohlendorf et al. (1987) obtained three composite samples of
red shiner from unspecified locations in the Grassland Water District (Grass-
lands), Merced County, about 30 km northwest of Firebaugh, for analysis of
trace elements and pesticide residues. In September 1984 and again in

' Accepted for publication October 1989.

RED SHINER IN SAN JOAQUIN VALLEY 47

September 1985, red shiner were collected in the Grasslands from Agatha
Canal, Camp 13 Ditch, and Mud Slough at Gun Club Road (M.K. Saiki, unpubl.
data). Additionally, unpublished field notes from the California Department of
Fish and Game (CDFG) indicated that three adult red shiner were collected on
29 July 1985 from Los Banos Creek, about 2 km upstream from the Los Banos
Detention Reservoir, Merced County (C. J. Brown, Jr., Associate Fishery
Biologist, CDFG, pers. comm.). This locality is about 20 km west of the
Grasslands.

Here we report the results of an extensive field survey conducted in 1986,
with supplemental collections made in 1987, that document the distribution of
red shiner in the San Joaquin River and selected tributaries on the Valley floor.
We also present data on the morphometries and ecology of this recently
established population, including observations on reproductive characteristics,
age, growth, and food.

MATERIALS AND METHODS

A total of 2? sites were intensively sampled for red shiner in September-No-
vember 1986, and additional collections were made for morphometric analyses
of specimens from eight of the sites in February-May 1987 (Figure 1 ). All fish
were collected with bag seines (6.4-mm mesh wing and 3.2-mm mesh bag, bar
measure) and backpack electrofishing gear. To compute catch-per-effort
statistics for the 1986 collections, we made all seine hauls parallel to shore over
a standard distance of about 15 m, and electrofishing was conducted for at least
10 min (the actual time spent in electrofishing was recorded).

During the 1986 collections, we measured the following environmental
variables at each site: current, water temperature, pH, turbidity, dissolved
oxygen, total alkalinity, conductivity, total dissolved solids, stream width, stream
depth, and the particle size distribution of bottom sediments. Schoklitsch's
sediment factor, s, was computed from the sediment data with a standard
formula described by Bogardi (1974). We estimated the percentages of pools,
riffles, and runs at each site by using the "ocular" method described by
Pfankuch ( 1 975 ) . We also used this method to estimate the percentage of cover
provided by emergent and submerged vegetation. Finally, we assigned each site
a subjective rating of 1-5 (with 1 being the lowest) that characterized the
extent of "human impact" (e.g., channelization, removal of riparian cover, and
water flow diversions) as perceived by one of us (M.R.J.), an experienced field
observer.

All captured fish were identified, counted, and except for representative
samples preserved in 10% formalin, returned to the water. Preserved samples
were kept for counts of fin rays and scales (Hubbs and Lagler 1958); and
determinations of fecundity (Bagenal and Braum 1978), age and growth
(Bagenal and Tesch 1978), and stomach contents (Windell and Bowen 1978).

Before conducting analysis-of-variance (ANOVA) tests, we logarithmically
transformed all catch-per-effort values to best meet the assumptions (i.e.,
symmetry, equal variances among groups, linearity, and additive structure) of
the statistical procedure. We accepted the level of significance as being P <0.05
unless otherwise indicated. When F-statistics were significant, we conducted
Tukey-Kramer "honestly significant difference" (hsd) tests to compare geo-

48

CALIFORNIA FISH AND GAME

metric means for statistical differences. We calculated Spearman's rank corre-
lations (rs ) to identify significant statistical associations between the abundance
of red shiner and various ecological characteristics (i.e., water quality and
hydrological measurements, and the abundance of other fish species).

VISALIA

Kilometers

FIGURE 1. Locations of sampling sites in the study area, and abbreviations used in Table 1: (1 )
San Joaquin River near Fort Washington Road, (2) San Joaquin River at Hwy 145, (3)
San Joaquin River at Mendota Pool, (4) San Joaquin River at Firebaugh, (5) San
Joaquin River at Hwy 152, (6) San Joaquin River at Lander Avenue, (7) San Joaquin
River at Fremont Ford State Recreational Area, (8) San Joaquin River at Hills Ferry

Continued

RED SHINER IN SAN JOAQUIN VALLEY 49

Road, (9) San Joaquin River at Crows Landing Road, (10) San Joaquin River at Laird
County Park, (11) San Joaquin River at Maze Road, (12) San Joaquin River at Durham
Ferry State Recreation Area, (13) Helm Canal, (14) Main Canal, (15) Agatha Canal,
(16) Camp 13 Ditch, (17) Mud Slough at the Los Banos Wildlife Area, (18) Salt
Slough at Hereford Road, (19) Salt Slough at the San Luis National Wildlife Refuge,
(20) Mud Slough at Gun Club Road, (21) Los Banos Creek at Gun Club Road, (22)
Merced River at George J. Hatfield State Recreational Area, (23) Tuolumne River at
Shiloh Road, (24) Stanislaus River at Caswell Memorial State Park, (25) Fresno
Slough, (26) Delta-Mendota Canal at O'Neill Forebay, and (27) Crow Creek at Hwy
33. Localities where red shiner were collected in September-November 1986 are
denoted by filled circles; in February-May 1987, by left-hand filled circles; in both
1986 and 1987, by right-half filled circles; and, where never collected, by unfilled
circles.

RESULTS AND DISCUSSION

We collected 1,341 red shiner at 17 of 27 sites on the San Joaquin Valley floor
in September-November 1986 (Figure 1). An additional 800 specimens were
collected at 6 of 8 sites in February-May 1987, with one of these sites
representing a new occurrence of the species (Figure 1 ), thus bringing the total
number of sites containing red shiner to 18.

Morphological examination of 125 specimens from 17 sites indicated that
they most resembled Notropis lutrensis lutrensis. Adults > 25 mm total length
(tl) were relatively deep bodied and closely matched the descriptions by
Hubbs and Ortenburger (1929). Average lateral line scale counts were 34.5
(range, 33-36), and anal fin rays 9 (range, 8-10) in over 80% of the fish
examined. Our specimens differed from the Colorado River populations of N.
I. lutrensis X N. I. suavis intergrades (described by Hubbs 1954) in having a
"chunkier" body shape and higher lateral line scale counts. However, the
possibility of hybrid populations of N. lutrensis in the San Joaquin Valley cannot
be ruled out. Additional studies (e.g., Matthews 1987) on the geographical
variation of native populations of N. lutrensis in the Midwest might assist in
identifying the probable origin of the San Joaquin Valley population. Voucher
specimens from all sites were deposited in collections at the Museum of
Zoology, University of Michigan (UMMZ 213990-214006).

Abundance and Distribution

Red shiner were most abundant in irrigation canals and drains of the
Grasslands (e.g., Agatha and Main canals, Camp 13 Ditch, and Mud and Salt
sloughs), followed by sites on the San Joaquin River that were adjacent to the
Grasslands or downstream from tributaries that drain the Grasslands (e.g., from
Firebaugh to Durham Ferry State Recreation Area; see Table 1). We also
collected about 20 specimens in September 1987 from Crow Creek, an
intermittent stream that flows into the San Joaquin River about 15 km
downstream from the Grasslands. Although we collected a single fish in March
1987 from the Stanislaus River, red shiner were seemingly lacking in tributaries
that drain the east side of the San Joaquin Valley and from the southern end of
the Valley floor (Table 1).

50 CALIFORNIA FISH AND CAME

TABLE 1. Abundance of Red Shiner from 26 Sites on the San Joaquin Valley Floor as
Determined by Electrofishing (Numbers of Fish per 10 Min of Fishing) and
Bag Seining (Numbers of Fish per 15-m Haul) in Sept.-Nov. 1986. Within
Regions, Sampling Sites are Tabulated in Approximate Longitudinal (Up-
stream-Downstream) Sequence; Refer to Figure 1 for Names and Locations
of Sites. Values are expressed as Unweighted Geometric Means for Each
Region and Site. Means in Each Column Followed by the Same Capital Let-
ter are not Significantly Different (P >0.05, Tukey-Kramer hsd Test). Values
in Parentheses Indicate Number of Observations.

Region and site

Electrofishing

San Joaquin River:

27

0.0

16

0.0

1

0.0

2

0.0

8

0.0

18

0.7

20

4.0

17

5.3

21

0.8

22

0.2

24

0.0

25

0.5

0.7

B (n = 33)

Grassland Water

District:

7

5.5

4

0.3

5

4.1

6

25.6

13

0.0

9

4.2

10

a

11

4.3

12

58.8

3.9

A (n = 23)

Eastern tributaries:

19

0.0

23

0.0

26

0.0

0.0

B (n=7)

Other tributaries ' :

15

0.0

3

0.0

0.0

B (n = 6)

F (df1,df2) d

6.77'

■ *

Bag seining

0.0
0.0
0.0
1.7
0.6
0.0
0.0
0.0
1.3
0.0
0.0
0.4

0.3 B (n = 62)

0.5
0.0
5.5
0.0
0.0
0.2
0.4
0.7
1.7

0.8 A (n = 53)

0.0
0.0

0.0 b

0.0 B (n=15)

0.0
0.0

0.0 B (n = 10)
4.65**

-1 No data.

b One red shiner was collected from this site in February-May 1987.

c One site (14) was omitted because fishing effort was not quantified.

d For electrofishing, dfl =4, df2 = 64; for bag seining, df1 =4, df2=135. "P < 0.01.

Relation to Water Quality and Hydrology

The ranges of geometric means of selected hydrological variables at 16 of the
18 sites where red shiner were collected are presented in Table 2. These
measurements reveal the variable influence that irrigation return flows, which
typically contain high concentrations of suspended sediments, agricultural
fertilizers, other dissolved salts, and animal wastes (Sylvester and Seabloom
1963, Miller et al. 1978), had on the aquatic habitats that we sampled.

RED SHINER IN SAN JOAQUIN VALLEY 51

TABLE 2 Ranges of Geometric Means of Selected Hydrological Variables at 16 of
the 18 Sites in the San Joaquin Valley Where Red Shiner were Collected.

Hydrological variable Range

Stream width 4-80 m

Average water depth 0.3-4.3 m

Maximum water depth 0.3-5.7 m

Current velocity < 0.01-0.52 m/sec

Water temperature 12-22°C

Turbidity 2.3-26 NTU's

Conductivity 141-2,453 u,mhos/cm @ 25°C

Total dissolved solids 80-1,600 mg/L

pH 6.9-8.0

Dissolved oxygen 7.5-9.6 mg/L

Total hardness 44-527 mg/L as CaCO 3

Total alkalinity 49-200 mg/L as CaC03

The abundance of red shiner was positively correlated with turbidity, pH,
conductivity, total alkalinity, total hardness, total dissolved solids, percentage of
runs, and degree of human impact, and negatively correlated with maximum
stream depth and stream width (Table 3). Several investigators (e.g., Matthews
and Hill 1977, 1979; Becker 1983; Matthews 1986) reported that many red
shiner populations in the plains states of the Midwest seem to thrive under
conditions of intermittent flow, high temperatures, high turbidity, and other
harsh environmental conditions similar to those in the San Joaquin Valley.

TABLE 3. Spearman's Rank Correlations (rs) Between Various Ecological Variables and the Abun-
dance of Red Shiner as Determined by Electrofisihing (Numbers of Fish per 10 Min of Fish-
ing) and Bag Seining (Numbers of Fish per 15-m Haul) *.

Ecological parameter Electrofishing Bag seining

Water quality

Dissolved oxygen —0.07 —0.10

pH 0.39* 0.29

Total alkalinity 0.62" 0.56**

Total hardness 0.74** 0.60**

Total dissolved solids 0.72** 0.60**

Conductivity 0.75** 0.59*

Temperature 0.13 —0.06

Turbidity 0.58** 0.23

Hydrology

Current velocity 0.15 -0.07

Stream depth -0.19 0.36

Maximum stream depth —0.32 —0.48**

Stream width -0.47* -0.15

Sediment factor, 5 -0.17 0.08

Pool (%) -0.05 -0.14

Riffle (%) -0.22 -0.03

Run (%) 0.50** 0.16

Other

Emergent vegetation (%) -0.04 -0.03

Submerged vegetation (%) -0.03 -0.01

Human Impact 0.40** 0.02

a Codes: * P < 0.05; ** P < 0.01.

Relation to Other Fishes

The abundance of red shiner was correlated positively with the abundance of
common carp, Cyprinus carpio, threadfin shad, Dorosoma petenense, mosqui-
tofish, Gambusia affinis, inland silverside, Menidia beryllina, striped bass,
Morone saxatilis, fathead minnow, Pimephales promelas, and Sacramento
blackfish, Orthodon microlepidotus, and negatively with the abundance of

i»*

52 CALIFORNIA FISH AND GAME

redear sunfish, Lepomis microlophus, as shown in Table 4. However, we did
not determine if these patterns were due to the environmental requirements and
tolerances of the different species, dynamic ecological interactions (e.g.,
predator-prey relations, competition), or other factors. Red shiner are the fourth
most abundant fish on the San Joaquin Valley floor after introduced threadfin
shad, mosquitofish, and inland silverside (Jennings and Saiki, in prep.), and
they are undoubtedly important prey for piscivorous fishes (Becker 1983). In
some areas, red shiner have increased their range and, in the process, displaced
other fishes with similar ecological requirements (Page and Smith 1970; Echelle
et al. 1972; Minckley 1973; Cross 1978, 1985; Deacon 1988; Greger and Deacon
1988).

TABLE 4. Spearman's Rank Correlations (/-,) Between the Abundance of Various Fish Species and
Red Shiner as Determined by Electrofishing (Numbers of Fish per 10 Min of Fishing) and
Bag Seining (Numbers of Fish per 15-m Haul)'.

Electro- Bag

Fish species Origin b fishing seining

Yellowfin goby, Acanthogobius flavimanus I 0.28 — 0.15

White sturgeon, Acipenser transmontanus N 0.28 — c

American shad, Alosa sapidissima I 0.34 — 0.15

Goldfish, Carassius auratus I —0.02 0.37

Sacramento sucker, Catostomus occidentalis N 0.36 — 0.15

Prickly sculpin, Coitus asper N 0.16 0.04

Common carp, Cyprinus carpio I 0.39* 0.17

Threadfin shad, Dorosoma petenense I 0.63** 0.09

Mosquitofish, Cambusia affinis I 0.32 0.41 *

Tule perch, Hysterocarpus traski N 0.34

White catfish, Ictalurus catus I — 0.23 0.32

Black bullhead, /. me/as I 0.07 —0.16

Brown bullhead, /. nebulosus I 0.23 — c

Channel catfish, /. punctatus I 0.09 0.24

Hitch, Lavinia exilicauda N 0.32 0.18

Green sunfish, Lepomis cyanellus I 0.14 0.24

Warmouth, L. gulosus I 0.29 0.24

Bluegill, L. macrochirus I — 0.37 — 0.04

Redear sunfish, L. microlophus I — 0.54** — 0.06

Inland silverside, Menidia beryllina I 0.40 * 0.23

Smallmouth bass, Micropterus dolomieui I — 0.05 — 0.22

Largemouth bass, M. salmoides I — 0.16 — 0.09

Striped bass, Morone saxatilis I 0.50** 0.25

Golden shiner, Notemigonus crysoleucas I 0.07 0.06

Sacramento blackfish, Orthodon microlepidotus . N 0.34 0.46 *

Bigscale logperch, Percina macrolepida I — 0.13 0.20

Fathead minnow, Pimephales promelas I 0.63** 0.47*

Sacramento splittail, Pogonichthys

macrolepidotus N 0.28

White crappie, Pomoxis annularis I 0.26 — 0.04

Black crappie, P. nigromaculatus I 0.38 — 0.11

••Codes: "P < 0.05; ** P < 0.01.
b Codes: I, introduced; N, native.
c No data

There were no significant negative correlations between the abundance of
red shiner and native fishes such as Sacramento sucker, Catostomus occiden-
talis, prickly sculpin, Cottus asper, tule perch, Hysterocarpus traski, hitch,
Lavinia exilicauda, Sacramento splittail, Pogonichthys macrolepidotus, and
Sacramento blackfish (Table 4). These data suggest that red shiner have not
yet strongly influenced the distribution and abundance of native fishes on the
Valley floor. However, the relative scarcity of the natives ( <25% of the total
species; see Table 4) might be partly responsible for our failure to detect

RED SHINER IN SAN JOAQUIN VALLEY 53

significant correlations. Nonetheless, because red shiner are newly established
in the San Joaquin Valley, the magnitude of their effects on native fishes might
still be forthcoming.

According to McGinnis (1984), the native California roach, Hesperoleucus
symmetricus, shares many ecological requirements with red shiner, and may be
vulnerable to displacement by this newcomer. Despite considerable sampling,
we collected no California roach on the Valley floor (also see Saiki 1984),
suggesting that it is either absent or rare in Valley floor watercourses. However,
California roach are present upstream at higher elevation sites in east side
(Sierra Nevada foothill) tributaries such as the Merced and Tuolumne rivers
(Moyle and Nichols 1974; M. K. Saiki, unpubl. data). Red shiner are expected
to move into these eastside habitats but, as of May 1987, they were not found
in the Merced and Tuolumne rivers, and only one specimen was collected from
the Stanislaus River. Therefore, any effects of red shiner on California roach
remain unknown.

Life History Observations

Reproduction

Adult males in breeding coloration (orange-red caudal, pelvic, anal, and
pectoral fins) were observed in the San Joaquin Valley during September-Oc-
tober 1986 and April-May 1987. Cross (1967) and Farringer eta/. (1979) wrote
that red shiner in Kansas, Texas, and Oklahoma spawn at water temperatures of
15.6-29.4°C from May to October, with most spawning probably occurring in
June and July. Wang (1986) estimated that spawning occurred during June and
July in Millerton Lake in the San Joaquin Valley.

We examined 1 1 gravid females ranging in total length from 42 to 55 mm, and
counted 1,177 to 5,411 eggs per fish (geometric mean, 2,205 eggs). These
counts were nearly fourfold higher than those reported for red shiner in central
Iowa (Laser and Carlander 1971 ). We found no significant correlation between
the number of eggs and female length (rs = —0.27, df = 9), a result also
reported by Laser and Carlander (1971). Because red shiner are "fractional"
spawners (Gale 1986), females may release their eggs on several occasions
between April and October in the San Joaquin Valley; this spawning pattern
might obscure associations between the number of eggs and size of females.

Age and Growth

As judged from cursory scale examinations of 25 fish, the oldest red shiner in
our collections had two complete annuli (i.e., the specimen was in its third
growing season). We found three gravid young-of-the-year females, but the
remaining gravid females were in their second growing season. Similar findings
were reported by Carlander (1969), Laser and Carlander (1971), and Wang
(1986).

The length-weight relation of 2,008 red shiner (tl 10-66 mm) from our study
was best described (r2 = 0.97) by the equation

log 10 W = 0.0000032 + 3.284678 log 10 L

where W is the mass of the fish (g) and L is the tl (mm).

54 CALIFORNIA FISH AND CAME

Food

We examined the stomach contents of 100 red shiner from 17 sites and noted
mostly filamentous algae and aquatic insect larvae (Table 5). Other researchers
(e.g., Cross 1967, Hardwood 1972, Minckley 1973, Becker 1983, Wang 1986,
Greger and Deacon 1988) have reported similar omnivorous diets for this fish.
Although red shiner consume filamentous algae, the food value of algae is
doubtful because of its apparently low digestibility (Becker 1983).

TABLE 5. Food Organisms in 79 of 100 Red Shiner Collected from 17 Localities in the San Joaquin
Valley, California.

Occurrence Volume

Taxa (%) (%)

Plants
Chlorophyta
Chlorophyceae
Zygnematales
Zygnemataceae 50.0 10.1

Mesotaeniaceae 15.0 3.0

Desmidiaceae 35.0 6.3

Euglenophyta

Unknown 1.2 0.1

Chrysophyta

Bacillariophyceae

Pennales 36.0 7.8

Tracheophyta
Spermopsida

Angiospermae 5.8 1 .7

Animals
Rotatoria
Monogonota
Floscularicea 2.3 0.2

Annelida
Oligochaeta

Plesiopora 7.0 5.1

Arthropoda
Crustacea
Cladocera 2.3 1 8

Copepoda 2.3 0.8

Arachnida

Araneae 2.3 1 .4

Insecta
Trichoptera

Hydropsychidae 3.5 1.8

Hymenoptera

Formicidae 15.1 10.4

Unknown 1.2 0.3

Coleoptera 1-2 1-3

Diptera
Chironomidae 10.5 4.8

Unknown 14.0 10.1

Unknown 44.2 31.8

Chordata
Osteichthyes
Cypriniformes 1.2 1.2

Additionally, we observed that terrestrial ants (Formicidae) contributed
>50% (by volume) of the total diet of red shiner collected from irrigation
canals and drains in the Grasslands (for fish from all sites combined, however,
ants contributed only 10.4% of the total diet; see Table 5). The importance of
ants as forage for fish in the Grasslands was probably due to the profusion of
overhanging grasses and other locally abundant ditchbank vegetation fre-
quented by ants.

RED SHINER IN SAN JOAQUIN VALLEY 55

CONCLUSIONS

The rapid spread of red shiner in the San Joaquin Valley parallels the
explosive population growth of this baitfish in other areas of California, Arizona,
and Nevada where it has been introduced (Minckley 1973, Moyle 1976, Cross
1985, Greger and Deacon 1988). The previous omission of this species as a
major component of the ichthyofauna from the San Joaquin Valley floor is
probably due to its recent establishment in the Valley, and its superficial
resemblance to juvenile golden shiner, Notemigonus crysoleucas, and fathead
minnow. We suspect that red shiner were first stocked into Millerton Lake and
Grasslands waters in the late 1970's to early 1980's from the bait buckets of
fishermen. From the latter locality, this species is now rapidly invading the lower
San Joaquin River system, a process that may be aided by the extensive network
of irrigation canals (especially the Delta-Mendota Canal) and drains in the
Valley, and the indiscriminant use of live "minnows" by some bait fishermen.

In 1979, the California Citizen's Nongame Advisory Committee recom-
mended to the CDFG that red shiner be removed from the list of allowable
freshwater live bait species. In 1982, a report prepared by the CDFG (Gleason
1982) recommended that the use of this species as live bait in inland waters be
limited to the Colorado River and Salton Sea. However, red shiner can still be
legally used as live bait in many areas of California, including the northern San
Joaquin Valley (i.e., north of Interstate 580 and State Highway 132, California
Department of Fish and Game 1989). Furthermore, at least five aquacultural
facilities are registered by the State of California for rearing this species in
counties lying beyond the Colorado River-Salton Sea drainage, including one in
Merced County (California Department of Fish and Game 1986). The docu-
mented establishment of this highly fecund species on the San Joaquin Valley
floor, and recent reports of new populations in other portions of central and
southern California, suggest that this baitfish should be prohibited from all
waters in California where it is not yet established. We also suggest that red
shiner not be cultured in drainages where its use as a live bait species is
prohibited.

ACKNOWLEDGMENTS

We thank K. Dray, G. Gerstenberg, G. Goldsmith, and T. Heyne for assistance
in the field; S. Burnett and G. Goldsmith for counting eggs and measuring the
stomach contents of red shiner; and C Finch, N. Crow, B. Ross, and personnel
at O'Neill Forebay, George J. Hatfield State Recreation Area, Durham Ferry
State Recreation Area, and Caswell Memorial State Park for kindly providing
access to sampling sites. Information on red shiner from the Los Angeles basin
was provided by C. Swift and J. Seigel. This work resulted from data collected
incidentally to an extensive contaminant survey of fishes in the San Joaquin
Valley, a project supported by the San Joaquin Valley Drainage Program, a
cooperative effort between the State of California and the U.S. Department of
the Interior.

LITERATURE CITED

Bagenal, T.B., and E. Braum. 1978. Eggs and early life history. Pages 165-201 in T. Bagenal (ed.). Methods for
assessment of fish production in fresh waters. IBP Handbook No. 3, Blackwell Sci. Publ., Oxford,
xv + 365 p.

56 CALIFORNIA FISH AND GAME

Bagenal, T.B., and F.W. Tesch. 1978. Age and growth Pages 101-136 in T. Bagenal (ed ) . Methods for assessment
of fish production in fresh waters. IBP Handbook No. 3, Blackwell Sci. Publ., Oxford, xv + 365 p.

Becker, C.C. 1983. Fishes of Wisconsin. The University of Wisconsin Press, Madison, Wisconsin, xii+1052 p.

Bogardi, J. 1974. Sediment transport in alluvial streams. Akademiai Kiado, Budapest, Hungary. 826 p. [Translated

by Z. Szilvassy].
California Department of Fish and Game. 1986. Registered aquacultunsts as of May 1, 1986. Calif. Dept. of Fish

and Game, Sacramento, California. 36 p.
California Department of Fish and Game. 1989. 1989 California sport fishing regulations. State Printing Office,

Sacramento, California. 12 p.
Carlander, K.D. 1969. Handbook of freshwater fishery biology. Vol. 1. Iowa St. Univ. Press, Ames, Iowa, v + 752

P
Cross, F.B. 1967. Handbook of Fishes of Kansas. Univ. Kansas Mus. Nat. Hist. Misc. Publ. (45) .1-357.

Cross, J.N. 1978. Contributions to the biology of the woundfin, Plagopterus argentissimus (Pisces: Cyprinidae), an

endangered species. Great Basin Nat., 38(4):463-468.
Cross, J.N. 1985. Distribution of fish in the Virgin River, a tributary of the lower Colorado River. Env. Biol. Fish.,

12(1):13-21.
Deacon, J.E. 1988. The endangered woundfin and water management in the Virgin River, Utah, Arizona. Nevada.

Fisheries, 13(1 j:1 8-24.

Echelle, A.A., A.F. Echelle, and L.G. Hill. 1972. Interspecific interactions and limiting factors of abundance and
distribution in the Red River pupfish, Cyprinodon rubrofluviatilis. Am. Midi. Nat., 88(1 ):109-130.

Farringer, R.T., III, A.A. Echelle, and S.F. Lehtinen. 1979. Reproductive cycle of the red shiner, Notropis lutrensis,

in central Texas and south central Oklahoma. Trans. Am. Fish. Soc, 108(31:271-276.
Gale, W.F. 1986. Indeterminate fecundity and spawning behavior of captive red shiners — fractional, crevice

spawners. Trans. Am. Fish. Soc, 115(3):429-437.
Gleason, E.V. 1982. A review of the life history of the red shiner, Notropis lutrensis, and a reassessment of its

desirability for use as live bait in central and northern California. Calif. Dept. Fish and Game, Inland Fish.

Admin. Rept. (82-1):1-16.
Greger, P.D., and J.E. Deacon. 1988. Food partitioning among fishes of the Virgin River. Copeia, 1988(2) :314-323.
Hardwood, R.H. 1972. Diurnal feeding rhythm of Notropis lutrensis Baird and Girard. Texas J. Sci., 24( 1 ):97-99.
Hubbs, C.L. 1954. Establishment of a forage fish, the red shiner (Notropis lutrensis), in the lower Colorado River

system. Calif. Fish and Game, 40(3):287-294.
Hubbs, C.L., and K.F. Lagler. 1958. Fishes of the Great Lakes region. (Rev. ed.). Bull. Cranbrook Inst. Sci.,

(26):xi + 213 p.
Hubbs, C.L., and A.I. Ortenburger. 1929. Further notes on the fishes of Oklahoma with descriptions of new species

of Cyprinidae, and fishes collected in Oklahoma and Arkansas in 1927. Univ. Oklahoma Biol Surv., Publ.

1(2-3):15-112. [in Univ. Oklahoma Bull, [n.s] (434)].
Kimsey, J.B., and L.O. Fisk. 1964. Freshwater nongame fishes of California. Calif. Dept. Fish and Game,

Sacramento, California. 54 p.
Laser, K.D., and K.D. Carlander. 1971. Life history of red shiners, Notropis lutrensis, in the Skunk River, central

Iowa. Iowa St. J. Sci., 45 (4): 557-562.
Matthews, W.J. 1986. Geographic variation in thermal tolerance of a widespread minnow Notropis lutrensis of the

North American mid-west. J. Fish Biol., 28(3):407-^tl7.

Matthews, W.J. 1987. Geographic variation in Cyprinella lutrensis (Pisces: Cyprinidae) in the United States, with

notes on Cyprinella lepida. Copeia, 1987(3) :61 6-637.
Matthews, W.J., and L.G. Hill. 1977. Tolerance of the red shiner, Notropis lutrensis (Cyprinidae) to environmental

parameters. Southwest. Nat., 22(1):89-98.
Matthews, W.J., and L.G. Hill. 1979. Influence of physico-chemical factors on habitat selection by red shiners,

Notropis lutrensis (Pisces: Cyprinidae). Copeia, 1979(1 ):70-81.
McGinnis, S.M. 1984. Freshwater fishes of California. California Natural History Guides No. 49. Univ. Calif. Press,

Berkeley, California, viii + 316 p.
Miller, W.W., J.C. Guijtens, C.N. Mahannah, and R.M. Joung. 1978. Pollutant contributions from irrigation surface

return flows. J. Environ. Qual., 7(1):35-40.
Minckley, W.L. 1973. Fishes of Arizona. Ariz. Game and Fish Dept., Phoenix, Arizona, xv + 293 p.
Moyle, P.B. 1976. Inland fishes of California. Univ. Calif. Press, Berkeley, California, viii + 405 p.
Moyle, P.B., and R.B. Nichols. 1974 Decline of the native fish fauna of the Sierra Nevada foothills, central

California. Am. Midi. Nat, 92(1):72-83.
Ohlendorf, H.M., R.L. Hothem, T.W. Aldrich, and A.J. Krynitsky. 1987. Selenium contamination of the Grasslands,

a major California waterfowl area. Sci. Total Environ., 66:169-183.

RED SHINER IN SAN JOAQUIN VALLEY 57

Page, L.M., and R.L. Smith. 1970. Recent range adjustments and hybridization of Notropis lutrensis and Noiropis

spilopterus in Illinois. Illinois St. Acad. Sci., Trans., 63(3):264-272.
Pfankuch, D.J. 1975. Stream reach inventory and channel stability evaluation; a watershed management

procedure. U.S. Dept. Agric, Forest Service/ Northern Region. 26 p.
Saiki, M.K. 1984. Environmental conditions and fish faunas in low elevation rivers on the irrigated San Joaquin

Valley floor, California. Calif. Fish and Game, 70(3):145-157.
Sylvester, R.O., and R.W. Seabloom. 1963. Quality and significance of irrigation return flow. |. Irrig. Drain. Div.,

Am. Engin., Proc, 89(IR3):1-27.
Wang, J.C.S. 1986. Fishes of the Sacramento-San Joaquin estuary and adjacent waters. California: a guide to the

early life histories. Interagency Ecological Study Program for the Sacramento-San Joaquin Estuary, Tech.

Rept. (9):ix+47 + various paginations. A cooperative study by the California Department of Water

Resources, California Department of Fish and Came, U.S. Bureau of Reclamation, and U.S. Fish and Wildlife

Service, Sacramento, California.
Windell, J.T., and S.H. Bowen. 1978. Methods for study of fish diets based on analysis of stomach contents. Pages

219-226 in T. Bagenal (ed.) Methods for assessment of fish production in fresh waters, third edition IBP

Handbook No. 3. Blackwell Sci. Publ., Oxford, xv + 365 p.

58 CALIFORNIA FISH AND GAME

Calif. Fish and Came 76 ( 1 ) : 58-62 1 990

NOTES

PRELIMINARY EXAMINATION OF LOW SALINITY

TOLERANCE OF SPERM, FERTILIZED EGGS, AND LARVAE

OF ORANGEMOUTH CORVINA, CYNOSCION

XANTHUWS

Orangemouth corvina, Cynoscion xanthulus, native to the Gulf of California,
were established through introductions from 1950 through 1955 into the Salton
Sea, an inland saline lake in the southern California desert (Walker et al. 1961,
Whitney 1961 ), where a successful sport fishery subsequently developed. Texas
Parks and Wildlife Department (TPWD) obtained subadults from the Salton Sea
in 1981 (Prentice and Colura 1984, Prentice 1985), 1984, and 1985 to develop
spawning methodology and evaluate corvina as a predator in reservoirs
containing large populations of Tilapia spp. and Dorosoma spp.

Progeny from tank-spawned corvina were successfully reared in saltwater
hatchery ponds. After Prentice (1985) indicated subadult orangemouth corvina
could be acclimated to fresh water (0.02 %>o salinity), hatchery-produced
juveniles were acclimated to fresh water and stocked in Calaveras Reservoir
near San Antonio, Texas, where a substantial sport fishery developed.

Low salinity tolerance of sex products and very early life stages remained
undefined, as did the possibility of natural reproduction in freshwater systems.
Therefore, experiments were performed to examine the low salinity tolerance of
orangemouth corvina spermatozoa, fertilized eggs, and yolk-sac larvae to
provide insight into whether reproduction among reservoir-stocked fish could
be expected, and if high salinity marine hatchery facilities were necessary for
spawning and rearing of cultured orangemouth corvina.

Tests were conducted to evaluate the effects of low salinity on (i) sperm
activity, (ii) fertilized egg incubation and hatching, and (iii) survival of larvae
through the yolk-sac stage. Photoperiod-temperature manipulated orangemouth
corvina (hormone-injected females) (Prentice and Thomas 1987, Prentice et al.
1989) and tank-spawned eggs were used as the source of study material. Salinity
of 28.9 °/oo was considered the control value because it represented brood tank
salinity where successful spawning, fertilization, and hatching had occurred.
Test solutions were prepared with synthetic sea salt.

In sperm activation tests (Table 1, A-D), sperm was obtained from
quinaldine-anesthetized males in a clean, dry pipette and held at 24°C for 5-56
min or 3°C for 30-50 min. Activation was attempted when a drop of one of nine
test salinity solutions was mixed with a drop of milt on a clean, dry slide. Sperm
activity duration was monitored in three of four tests. Activity in samples where
sperm swam vigorously and where virtually all cells activated (as seen in the
28.9 %o salinity control) was considered good; activity was considered
minimal in samples where sperm swam slowly or where only a few cells
activated.

NOTES

59

TABLE 1. Effect of Salinity on Activation and Activity Duration of Cynoscion xanthulus Spermatozoa
in Four Tests, Heart of the Hills Research Station, Ingram, Texas, 1986. One Drop of Milt
and a Drop of Test Solution was Mixed on a Glass Slide to Activate the Cells. Activity was
Rated as Good When Most Cells Activated and Swam Vigorously, and as Minimal When
Few Cells Activated or When They Swam Slowly (as Compared to Activity at 28.9 V
Salinity).

Salinity %o
Parameter 28.9 18.9 13.3 7.2 2.2 1.7 1.2 0.6 0.0

Test A
(Range-finding)

Time from removal a

5

(min)

Activity duration

(min)

Slows

Stops

Activity rating

Good

Time from removal

8

34

25

(min)

Activity Duration

(min)

Slows

6.0

3.0

Stops

7.0

5.0

abort b

Activity rating

Good

Good

Minimal

Time from removal

50

50

50

(min)

Activity duration

(min)

Slows

9.5

9.0

21.2

Stops

13.9

10.0

24.7

Activity rating

Good

Good

Minimal

Time from removal

30

30

30

(min)

Activity duration

(min)

Slows

11.2

21.7

15.3

Stops

21.0

30.0

28.7

Activity rating

Good

Good

Minimal

25

2.0

Test B
8

Good

47

Good

None None

6.0

Minimal

50

Test Cc
50

50

5.0

2.1
Good

50

56

2.0

None

50

50

None None

None None None

30

Test D
30

30

30

30

None

30

None None

None None None

None

a Time from removal from male donor until addition of test solution.

b Test was aborted because milt and test solution may not have been fully mixed at the start.
' Milt from males in tests C and D was refrigerated (3°C) between collection from the male and exposure to test
solution (25°C).

In egg incubation tests, naturally fertilized eggs were taken from an external
egg collector (Prentice and Colura 1984) attached to the brood tank. Viable
eggs with developing embryos were selected and distributed by pipette at a rate
of 36 per 90-x 20-mm Petri dish in 40 ml of one of 10 test solutions (Table 2)
and maintained at 24-25°C. Water in test dishes was not aerated or exchanged
during the 20.5-to 24.0-h observation period.

60 CALIFORNIA FISH AND GAME

TABLE 2. Effect of Salinity on Hatching Success of Cynoscion xanthulus Eggs Incubated
at 24-25°C, Heart of the Hills Research Station, Ingram, Texas, 1986. Test
Salinity, Embryonic Stage at Start of Test, and Hours from Start of Test to
Termination Are Given; All Croups Contained 36 Eggs. Eggs Were Obtained
fromAdults Spawned in a Culture Tank at 24-24*C and 28.9 %*> Salinity, and
Were Abruptly Transfered from Culture Tank Salinity to Test Salinities.

Salinity Embryonic Hours

(°/oo) stage from start Results

30.0 1 5-1 6 somites 20.5 all hatch normally

28.9 tail-free 24.0 all hatch normally

one dies after hatch
17.7 15-16 somites 20.5 all hatch normally

5.5 15-16 somites 20.5 all hatch normally

4.6 tail-free 24.0 23 hatch normally

but do not move
3.9 tail-free 24.0 26 hatch normally

but do not move
3.3 15-16 somites 20.5 hatch 1-2 h prematurely,

all die
2.2 15-16 somites 20.5 hatch 1-2 h prematurely,

all die

1.7 15-16 somites 20.5 hatch 1-2 h prematurely,

all die
0.0 tail-free 24.0 hatch 3-4 h prematurely,

all die
0.0 15-16 somites 20.5 hatch 3-4 h prematurely,

all die

Larval survival tests employed recently hatched yolk-sac larvae (1-3 h old)
which were removed from the brood tank and distributed by pipette at a rate
of 10 per 90- x 20-mm Petri dish in 40 ml of one of eight test solutions (Table
3), and maintained at 24-25°C for 48 h. Larvae were transferred directly from
incubation and hatching salinity of 28.9 %>o to test salinities abruptly with no
acclimation and as little transfer of brood tank water with each larvae as
possible. Subsequent survival was monitored. No food was provided during the
observation period and Petri dish water was not aerated or exchanged.

TABLE 3. Survival (Percent) of Yolk-Sac Cynoscion xanthulus Following Abrupt Transfer from 28.9
°/<x> Hatching Salinity, Heart of the Hills Research Station, Ingram, Texas, 1986. Each Group
Contained 10 Unfed Larvae Maintained at 24-25°C
Salinity Hours past transfer

(°/oo) 0.0 2.7 3.7 19.2 24.6 27.5 43.4 48.0

28.9 100 100 100 100 90 80 70 30

18.9 100 100 100 90a 80 70 60 a 30

13.3 100 90a 90 80 80 80 80 60

7.2 100 100 100 90 80a 80 70 50

2.2 100 100 100 100 80a 80 70 70

1.7 100 100 100 80 70 a 70 60 60

1.2 100 100 100 80 80 a 80 80 80

0.0 100 100 100 20 20 20 20 20

0.0 100 100 100 20 20 20 10 10

a Dead larvae were found trapped in the surface film, a factor that may have reflected more upon mortality than
salinity.

Sperm activation test results indicated good activity on contact with 18.9 and
28.9 °/oo salinity water when tested within 5 to 34 min for milt held at 24°C, or
30 to 50 min for milt held at 5°C after removal from the male (Table 1 ). Activity
continued in Test B for 5 to 7 min but lasted up to 30 min during other
observations (Tests C-D). Minimal activation was obtained in both refrigerated
and unrefrigerated milt samples at 13.3 %>o salinity. While sperm activity was
minimal at 13.3 %>o salinity, activity lasted 24.7 to 28.7 min, longer than at higher
salinities. Tests C and D, conducted when brood fish were near the end of their

NOTES 61

reproductive cycle, produced no activation at any of the low salinities tested.
However, Tests A and B, conducted when fish were just past their reproductive
cycle peak, resulted in minimal to good activation at 1.2 and 1.7 %>o salinities.

Eggs incubated at 5.5 %o salinity or above developed normally, hatched, and
larvae progressed through the yolk-sac stage (Table 2). Eggs incubated at 3.9
and 4.6 %o salinity appeared to develop normally with 64 to 72% hatching.
However, after hatching, these larvae remained motionless on the bottom of the
culture dish. Although eight at 3.9 %o salinity and eight at 4.6 °/oo survived over
96 h, they were severely deformed with contorted notochords, malformed
jaws, and yolk-sacs still present at death. In specimens incubated at 1.7, 2.2, and
3.3 %o salinities, all embryos were ejected from the chorion about 1-12 h prior
to normal hatching. All were dead when observed. Eggs incubated at 0.0 %>o
ejected embroyos 3-4 h early and were also dead when observed.

Early yolk-sac larvae survived abrupt transfer from 28.9 %>o incubation
salinity to all test solutions with no immediate mortality (Table 3). The first
mortalities were observed 19.2 h after transfer, excluding the loss of a single
larvae at 13.3 %o salinity found trapped in the surface film after 2.7 h. Test
salinities of 1.2 %o or greater had 30 to 80% survival after 48.0 h.

Results of these tests suggested successful orangemouth corvina reproduction
can occur above about 13 %o salinity, and may occur at substantially lower
salinities. Inconsistent sperm activity at 1.2 and 1.7 %>o salinities may have
reflected time between removal from the male and activation, or storage
temperature during that time, or stage in the reproductive cycle when milt was
obtained. Loss of access to brood fish prevented replication of this work.
Duration of sperm activity suggests that in culture situations where adults are
stripped, and milt and roe mixed, sufficient time should be allowed to obtain
maximum fertilization. Short sperm motility periods of 35 sec to 2 min, often
associated with artificial culture techniques (Bonn et al. 1976, Piper et al. 1982),
could be extended in orangemouth corvina. Clearly though, additional infor-
mation is needed on the effects of time, temperature and reproductive state on
sperm activation and activity duration.

Eggs incubated from the 15- to 16-somite stage and older, developed and
hatched at or above 5.5 %o salinity, with salinities below 5.5 %o causing
premature hatching or deformed larvae. The impact, if any, of low salinity
incubation from the moment of fertilization through hatching still needs to be
examined.

Similarly, larval development, at least through the yolk-sac stage, proceeded
well at or above 1.2 %>o salinity. Whether these larvae would feed and continue
to develop through the larval period and transform normally to the juvenile
stage also remains to be examined.

Brocksen and Cole (1972) suggested metabolic problems limit growth rate in
young-of-the-year below 32 %>o salinity; however, experimental work with
orangemouth corvina in the laboratory (Prentice 1985) and with orangemouth
corvina and their hybrids with spotted seatrout, C. nebulosus, in a freshwater
reservoir (TPWD, Austin, unpubl. data) have shown good survival and growth
in fresh water.

Mortalities recorded for larvae after 20-30 h, when yolk-sac absorption
normally occurs and exogenous feeding should begin, may be more a function

52 CALIFORNIA FISH AND CAME

of starvation than of salinity. Higher survival rates after yolk-sac absorption
might have occurred had test specimens been fed.

Even if moderate to high salinity water was required for orangemouth corvina
reproduction, eggs can be transferred to lower salinities, and recently hatched
larvae to still lower salinities. This suggests implications in fish culture facilities
where brood fish may be spawned in saltwater tanks, but where larvae can be
transferred to very low salinity rearing ponds like those that exist at some
hatcheries both in Texas and California. Lastly, it should be noted that salinity
changes described for eggs and larvae here were abrupt; slow acclimation to
low salinity could possibly provide decreased stress with subsequent increased
long-term survival.

ACKNOWLEDGMENTS

Efforts and advice from numerous personnel with the California Department
of Fish and Game — Inland Fisheries, Salton Sea Fish and Wildlife Club, and
Occidental College — Biology Department made research on orangemouth
corvina in Texas possible.

LITERATURE CITED

Bonn, B.W., W.M. Bailey, ).D. Bayless, K.E. Erickson, and R.E. Stevens (eds.). 1976. Guidelines for striped bass
culture. Am. Fish. Soc, Bethesda, MD.

Brocksen, R.W., and R.E. Cole. 1972. Physiological responses of three species of fishes to various salinities. Fish.

Res. Board Canada, J. 29(4):399-405.
Piper, R.C., IB. McElwain, L.E. Orme, J. P. McCraren, L.C. Fowler, and ).R. Leonard. 1982. Fish hatchery

management. U.S. Fish and Wild. Serv., Washington, D.C
Prentice, J. A. 1985. Orangemouth corvina survival in fresh water. Prog. Fish-Cult., 47(1):61-63.
, and R.L. Colura. 1984. Preliminary observations of orangemouth corvina spawn inducement using

photoperiod, temperature and salinity. World Maricul. Soc, J., 15:162-171.
, and P. Thomas. 1987. Successful spawning of orangemouth corvina following injection with des-Cly ,0

[D-Ala b]-lutenizing hormone-releasing hormone (1-9) ethylamide and pimozide. Prog. Fish-Cult.,
49(1):66-69.

_, R.L. Colura, and B.W. Bumguardner. 1989. Induced maturation and spawning of orangemouth corvina.

Calif. Fish and Came, 75:27-32.

Walker, B.W., R.R. Whitney and G.W. Barlow. 1961. The fishes of the Salton Sea. Pages 77-164 in B.W. Walker,
ed. The ecology of the Salton Sea, California, in relation to the sport fishery. Calif. Dept. Fish and Game, Fish
Bull. 113:1-204.

Whitney, R.R. 1961. The orangemouth corvina, Cynoscion xanthulus Jordan and Gilbert. Pages 165-183 in B. W.
Walker, ed. The ecology of the Salton Sea, California, in relation to the sport fishery. Calif. Dept. Fish and
Game, Fish Bull. 113:1-204.

— Robert C. Ho wells. Texas Parks and Wildlife Department, Heart of the Hills
Research Station, Junction Star Route, Box 62, Ingram, Texas. Accepted for
publication October 1989.

BOOK REVIEWS 63

BOOK REVIEWS

THE STARRY ROOM

NAKED EYE ASTRONOMY IN THE INTIMATE UNIVERSE

By Ered Schaaf. John Wiley & Sons, Inc., New York, NY, 1988. vi + 264 p. cloth $19.95.

The title of this book only subtly alludes to some of the topics discussed. That is, many are
daytime phenomena. Being introduced to sun pillars, sun dogs, double suns, the counter sun, and
halo phenomena made me wonder if I have had blinders on all my life. And, although 100 rainbows
(title of chapter 4) is a bit of an exaggeration in reference to the number of different bows that may
actually be seen, the true number is indeed astonishing.

The excitement related by Fred Schaaf of looking out his window and seeing virtually all of the
worlds in the solar system at once, as was possible near 12 February 1982 and near 13 January 1984
(and won't be again for a long long time), made me sad that I hadn't been more attentive to the
occasions.

The author's campaign against light pollution is a worthy one, and results are indeed possible
largely because there are cost benefits that can be advertised to developers, city planners, et cetera.

This book is largely a pep talk for skv watchers. If you have a casual (or greater)
knowledge/ interest in naked eye sky watching and want to get pumped up, then The Starry Room
is for you.

—Jack Ames

BATTLING THE INLAND SEA: American Culture,

Public Policy, & the Sacramento Valley, 1850-1986

By Robert Kelley. 1989. University of California Press, Berkeley, CA, 416 p., $35.00

This book presents an excellent history of flood control efforts in the Sacramento valley primarily
from the 1850's through 1920, when the present flood control system had been adopted and its
implementation was well underway. Events from 1920 through the flood of 1986 are described
briefly. The author describes the interrelationships between flood control, swampland reclamation
and hydraulic mining. It is a story of repeated failures but eventually largely successful conclusion,
as the largest flood of record was contained with minimal harm.

The author is a historian, and an important feature of the book is how he has interwoven flood
control activities with the underlying social and political events. Among the latter is the evolution
from a constitutional requirement that governmental actions be prescribed in detail in law to the
acceptance of iaws delegating considerable discretion to the executive branch to act within broad
policy. Also of interest, is the shifts back and forth between populist driven local control and
centralized professional management, depending primarily on whether the Democrats or Repub-
licans controlled government.

In the Preface the author acknowledged that reclamation of the valley "ended in the destroying
of a large natural environment". He, however, makes no attempt to describe the resources which
were lost. Nevertheless, those interested in the evolution of our present society in the Sacramento
valley will find the book worth reading.

— Harold K. Chadwick

64 CALIFORNIA FISH AND CAME

90 80077

Photoelectronic composition by
CALIFORNIA OFFICE OF STATE PBINTINC

INSTRUCTIONS TO AUTHORS

EDITORIAL POLICY

California Fish and Game is a technical, professional, and educational journal
devoted to the conservation and understanding of fish and wildlife. Original manu-
scripts submitted for consideration should deal with the California flora and fauna
or provide information of direct interest and benefit to California researchers and
managers. Authors should submit the original manuscript plus two copies, including
tables and figures.

MANUSCRIPTS: Authors should refer to the CBE Style Manual (Fifth Edition) and
a recent issue of California Fish and Game for general guidance in preparing their
manuscripts. Some major points are given below.

1. Typing — All text submitted, including headings, footnotes, and literature cited
must be typewritten doublespaced, on white paper. Papers shorter than 10
typewritten pages, including tables, should follow the format for notes. Letter
quality computer print-out is acceptable.

2. Citations — All citations should follow the name-and-year system. The "library
style" is used in listing literature cited.

3. Abstracts — Every article must be introduced by a concise abstract. Indent the
abstract at each margin to identify it.

4. Abbreviations and numerals — Use approved abbreviations as listed in the CBE
Style Manual. In all other cases spell out the entire word.

TABLES: Each table should be typewritten with the heading margin left justified.
Tables should be numbered consecutively beginning with "1" and placed together
in the manuscript following the Literature Cited section. Do not double space tables.
See a recent issue of California Fish and Game for format.

FIGURES: Consider proportions of figures in relation to the page size of California
Fish and Game. The usable printed page is 11 7 by 191 mm (4.6 by 7.5 in.). This must
be considered in planning a full page figure, for the figure with its caption cannot
exceed these limits. Photographs should be submitted on glossy paper with strong
contrasts. All figures should be identified with the author's name in the upper left
corner and the figure numbers in the upper right corner. Markings on figures should
be made with a blue china marking pencil. Figure captions must be typed on a
separate sheet headed by the title of the paper and the author's name.

PROOF: Galley proof will be sent to authors approximately 60 days before publi-
cation. The author has the ultimate responsibility for the content of the paper and
is expected to check the galley proof carefully.

PAGE CHARGES AND REPRINTS: All authors will be charged $35 per printed page
and will be billed before publication of manuscripts. Reprints may be ordered
through the editor at the time the proof is submitted. Authors will receive a reprint
charge schedule along with the galley proof.

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