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The Coralline Genus
clathromorphum Foslie emend. Adey

Biological, Physiological, and Ecological
Factors Controlling Carbonate Production
in an Arctic-Subarctic Climate Archive

Walter H. Adey,
Jochen Halfar, and Branwen Williams

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SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES © NUMBER 40

The Coralline Genus
Clathromorphum Foslie emend. Adey

Biological, Physiological, and Ecological
Factors Controlling Carbonate Production
in an Arctic-Subarctic Climate Archive

Walter H. Adey,

Jochen Halfar, and Branwen Williams

Smithsonian Institution DEC
Ji.
Scholarly Press
WASHINGTON D.C.

ABSTRACT

Adey, Walter H., Jochen Halfar, and Branwen Williams. The Coralline Genus Clathromorphum Foslie emend. Adey: Biological, Physi-
ological, and Ecological Factors Controlling Carbonate Production in an Arctic-Subarctic Climate Archive. Smithsonian Contributions
to the Marine Sciences, number 40, iv + 42 pages, 29 figures, 1 table, 2013.— The coralline algal genus Clathromorphum is a dominant
calcifier in the rocky Subarctic biogeographic region, stretching through the lower Arctic from the Labrador Sea to the Bering Sea.
Although commonly 2-10 cm in thickness, Clathromorphum can reach a thickness of up to S50 cm while forming an annually layered
structure that can reach currently documented ages of up to 850 years. Geochemical and growth information archived in annual growth
bands of Clathromorphum sp. has been used to provide long time series of past environmental conditions in regions that are poorly un-
derstood major drivers of Northern Hemisphere climate. However, information on Clathromorphum calcification, growth, and ecology
that would allow interpretation of these records has previously been quite limited. Here we relate extensive field and laboratory data on
the biology, physiology, and ecology of species of this genus and their controlling environmental parameters. We show that Clathromor-
phum has evolved a unique mode of double calcification, with high-magnesium calcite crystals, that enhances long life and leads to a
multielement climate archive. Growth rates are controlled by temperature, and carbonate density is controlled by light, determined by
both latitude and sea ice cover, whereas carbonate buildup and ultimate thickness are determined by local geomorphology and faunal
interactions. Reproduction is complexly linked to vegetative anatomy. Precise paleoenvironmental information can be retrieved from

Clathromorphum because of its unique cytological and anatomical structures, described and modeled for the first time in this volume.

Cover images: (left) One thousand year-old Clathromorphum compactum mound buried in a rhodolith bed (Lithothamnion
tophiforme) in northern Labrador. Photo by Michael D. Fox; (center) Boulders at 25m depth heavily encrusted with C. compactum
on the shore of low rocky island in northern Labrador. © Nick Caloyianis. Reprinted with permission; (right) Boulder with 200-300
year-old crust of C. compactum from southern Labrador. Coralline crusts on boulder sides are mostly Lithothanmnion spp. © Nick

Caloyianis. Reprinted with permission.

Published by SMITHSONIAN INSTITUTION SCHOLARLY PRESS
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Library of Congress Cataloging-in-Publication Data
Adey, Walter H.
The coralline genus Clathromorphum foslie emend. adey : biological, physiological, and ecological factors
controlling carbonate production in an arctic-subarctic climate archive / Walter H. Adey, Jochen Halfar, and Branwen Williams.
pages cm — (Smithsonian contributions to the marine sciences ; number 40)
Includes bibliographical references and index.
1. Coralline algae. 2. Algae—Effect of temperature on. 3. Ecology—Cold regions. I. Halfar, Jochen, 1969-
II. Williams, Branwen, 1980- III. Title.
QK569.C8A325 2013
581.7--de23
2013026877

ISSN: 0196-0768 (print); 1943-667X (online)

€) The paper used in this publication meets the minimum requirements of the American National Standard for Permanence of
Paper for Printed Library Materials Z739.48-1992.

Contents

INTRODUCTION
The Subarctic Shallow Benthos and Cold-Water Carbonates
The Distribution of Clathromorphum Species
Biology and Ecology of Clathromorphum
Calcification
The Need for an Arctic-Subarctic Archive
Corallines as Climate Proxies
Me/Ca Ratios and Seawater Temperature
Ba/Ca Ratios and Salinity
Growth as a Climate Archive
Isotopic Composition
MATERIALS AND METHODS
Clathromorphum compactum (North Atlantic, Labrador Sea, and Arctic)
Clathromorphum nereostratum (Aleutian Islands)
Specimen Preparation
Terminology
RESULTS
Reproduction
Reproduction in Clathromorphum compactum
Reproduction in Clathromorphum nereostratum
Cellular and Anatomical Structure
Biologically Induced Etching as a Source of Information
Growth Rate
Wall Structure and Calcification
Ecology and Geomorphology
Tissue Irregularity
Chiton Grazing
Sea Urchin Grazing
Conceptacle Breakout
Death Due to Disease
DISCUSSION
Climate Archives
Mechanisms of Calcification

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iv e© SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

Primary Production and Growth Rates
Interfilament Calcification
Conceptacle-Based Growth Analyses
Changing Ocean pH

CONCLUSIONS
ACKNOWLEDGMENTS
REFERENCES

34
35
37
37

38

39

39

The Coralline Genus Clathromorphum
Foslie emend. Adey

Biological, Physiological, and Ecological Factors Controlling
Carbonate Production in an Arctic-Subarctic Climate Archive

Walter H. Adey, Department of Botany, National
Museum of Natural History, Smithsonian Insti-
tution, Washington, D.C., 20013-7012, USA;
Jochen Halfar, Department of Chemical and
Physical Sciences, University of Toronto Missis-
sauga, Mississauga, Ontario LSL 1C6, Canada;
Branwen Williams, Keck Science Department,
Claremont McKenna-Pitzer-Scripps Colleges,
Claremont, California 91711, USA. Correspon-
dence: W. H. Adey, adeyw@si.edu. Manuscript
received 17 October 2012; accepted 5 June 2013.

INTRODUCTION

Millennial understanding of past climate variability in the Subarctic and Arctic re-
gions is crucial to prediction of the impacts of anthropogenic climate change both in the
Northern Hemisphere and globally. In warmer latitudes, abundant tree ring and pollen
data in the terrestrial environment and coral and bivalve data in the marine environment
can provide data on past climates. However, considering the crucial role that sea ice,
with its albedo effect, plays in controlling incoming solar energy, midlatitude data are
inadequate to provide an understanding of global climate processes. Although recent
studies have shown that encrusting coralline algae, abundant in shallow high-latitude
seas, can record paleoclimatic information, considerable variation of unknown origin
has provided conflicted analyses. In this volume we endeavor to show how an extensive
field and laboratory effort directed at species of the coralline genus Clathromorphum
can provide a detailed understanding of the complex biology, physiology, ecology, and
habitat geomorphology of these species, which, in turn, can direct laboratory analysis
and data interpretation.

THE SUBARCTIC SHALLOW BENTHOS AND COLD-WATER CARBONATES

The Northern Hemisphere Subarctic region, as defined by the Thermogeographic
Model, quantitatively demonstrated with crustose corallines (Adey and Steneck, 2001),
and further supported by quantitative analyses of benthic seaweeds (Adey and Hayek,
2011), stretches from the northwestern North Pacific to the northwestern North Atlantic.
Many benthic species that characterize the Subarctic occur in both Pacific and Atlantic
segments of the region (Olsen et al., 2004; Adey et al., 2008), although the separated
populations tend to be genetically distinct (Addison and Hart, 2005; Coyer et al., 2006).
Relatively few species are endemic to the North Atlantic Subarctic, whereas many spe-
cies are endemic to the considerably larger North Pacific Subarctic (Briggs, 2003). The
Arctic has very few endemic genera and only a small number of species; it is dominated
by Subarctic species (Adey et al., 2008).

2 © SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

Wherever rocky bottom occurs in the sublittoral Subarctic
(typically to 40 m, depending upon exposure and salinity), it is ir-
regularly coated by an extensive but patchily discontinuous crust
of biogenic calcium. This carbonate crust (typically 0.5-10 cm
thick, but to over 0.5 m in thickness; Lebednik, 1976) is present
on all but the most mobile or friable rock surfaces (Frantz et al.,
2005; Adey and Hayek, 2011). Because it is a high-magnesium
carbonate, laid down mostly by coralline red algae, this crust
can be called a cor-strome. It also occurs in the Arctic, where
it is built largely by Subarctic coralline species (specimens and
images in the U.S. National Herbarium); however, its continuity
is unknown. The depth zone immediately below the cor-strome,
where broken fragments accumulate and some species of Litho-
thamnion continue to grow in the mobile state as rhodoliths, has
received some attention (Freiwald and Heinrich, 1994), but the
cor-strome itself remains largely unstudied.

In both the Atlantic and the Pacific, these carbonate-

«

encrusted bottoms have been widely referred to as “coralline,
sea urchin barrens” (Mathieson et al., 1991; Estes and Duggins,
1995; Steneck et al., 2002); however, this description is certainly
a misnomer, as they may well be among the richer shallow ma-
rine bottoms of the marine Holarctic (Himmelman, 1991; Che-
nelot et al., 2011). The Chenelot et al. (2011) study focused on
abundant invertebrates resident in Clathromorphum nereostra-
tum in the Aleutian Islands, but it is likely that a similar relation-
ship exists for cor-stromes in the northwestern North Atlantic.
Drying fragments of cor-strome on research vessel laboratory
benches generally release large quantities of invertebrates, espe-
cially grazing chitons and filter-feeding brittle stars. A Labrador
ford Lithothamnion glaciale cor-strome produced 740 macro-
invertebrates from 637 cm? of crust (Adey, unpublished field
notes). Thus, there is little question of the coral reef-like richness
of these bottoms; what is lacking is geographically widespread
quantitative research on invertebrate diversity and biomass.
Considerable debate exists concerning the primary eco-
logical drivers of ecological structure on Subarctic-Boreal rocky
bottoms (e.g., Steneck et al., 2002; Springer and Estes, 2003;
Estes et al., 2005; Trites et al., 2007); is it climate, top preda-
tors, overfishing, or some complex of the three that drives the
major fluctuations of the associated kelp beds observed over the
last half century? These issues carry special weight because of
the collapse of numerous major cold-water fisheries over the last
several decades, the currently expanding Arctic fisheries, and the
ongoing debate over climate change and its causes. Much of this
debate has focused on the Bering Sea and Aleutian Islands and
the Gulf of Maine and Nova Scotia. However, the carbonate
bottom, with the rich diversity it harbors, has been considered
at best a backdrop in the debate over large seaweeds, grazing
invertebrates, and sea mammals and at worst a “barren” created
by imbalances among the major, large players. As we will dis-
cuss at depth, the age of the cor-strome frequently reaches one to
three centuries, and the maximum age of specimens now under
study exceeds 800 years in the Aleutian Islands and 600 years
in the Labrador Sea. The biological constant in these regions of

scientific dispute, a basal calcified coralline crust with centuries
of growth, is the least studied element.

Several species each of the genera Clathromorphum, Litho-
thamnion, and Leptophytum are the dominant producers of the
Subarctic-Arctic cor-strome. In the fully Subarctic northwestern
North Atlantic, Clathromorphum compactum is an abundant
species encrusting rocky bottoms in the mid-photic zone (10-20
m; Adey, 1966b), being largely replaced by Clathromorphum
circumscriptum in shallower waters and Lithothamnion glaciale
in deeper waters. Lithothamnion glaciale also tends to replace
C. compactum as the dominant cor-strome producer in inner bays
and fjords, where siltier and fresher waters usually dominate.
In many localities, depressions within the rocky cor-strome bot-
toms are filled with mobile nodules (rhodoliths) largely derived
from fragments fractured from the Lithothamnion cor-strome by
waves and bioturbation. Extending below the rocky cor-strome
and continuing to significant depths (20-60 m), beds of rhodo-
liths, usually as part of a shelly gravel substrate, are widespread.
However, the full extent of these beds is poorly known. Two
species of Lithothamnion (L. glaciale and L. tophiforme) are the
dominant producers of rhodoliths, the former species being more
Subarctic and the latter more Arctic (Adey et al., 2005).

As previous studies have demonstrated (Halfar et al., 2007,
2008, 201 1a; Frantz et al., 2005; Hetzinger et al., 2011; Williams
et al., 2011), these centuries-old carbonate formations, through
analysis of their temperature- and light-dependent growth layers
and the trace chemical structure of their carbonate cell walls,
can provide significant climate archives. The coralline provides
a surface for algal epiphytes, and both the corallines and the
epiphytes are grazed by many invertebrates. They are also very
important producers of secondary biomass, mostly by providing
a porous, reef-like habitat to innumerable invertebrates that uti-
lize mostly planktonic sources of primary production (Chenelot
et al., 2011). Additionally, they provide significant ecosystem
support for Subarctic-Arctic fisheries that are now expanding in
importance. These key Arctic and Subarctic ecosystems have a
detailed history written into their basal biogenic carbonate; to
read this history, we need only to extract the Rosetta stone of
anatomical and geochemical information.

THE DISTRIBUTION OF CLATHROMORPHUM SPECIES

Although a few species of the genus Clathromorphum
have been described for the colder Southern Hemisphere
(http://www.algaebase.org), their relationship to the abun-
dant Northern Hemisphere species is currently uncertain. In
the Northern Hemisphere, the four epilithic species are largely
restricted to the Subarctic and Arctic or its fringes, including
the Aleutian Islands (Lebednik, 1976). Two additional species,
C. parcum and C. reclinatum, are obligate epiphytes with limited
archival value, and we will not discuss them further; phyloge-
netic studies currently underway (Adey et al., unpublished) show
that these two species belong to a different clade. They are Bo-
real and fringe Subarctic in distribution only in the North Pacific.

Clathromorphum circumscriptum is the most widely dis-
tributed member of the genus, ranging from Hokkaido, Japan,
and British Columbia (Adey et al., 1976; Lebednik, 1976) in the
North Pacific through the Arctic to the southern Gulf of Maine in
the western Atlantic and Iceland and the Norwegian fjords south
to Trondheimsfjord (Adey, 1965, 1971) in the eastern Atlantic.
Restricted largely to intertidal pools and the shallow sublitto-
ral, C. circumscriptum can (rarely) achieve 5-10 cm in thick-
ness. However, both the conceptacles and the intraconceptacle
vegetative crust in this species always break out at reproductive
maturity, considerably disrupting thallus layering. Together with
a tendency to experience greater environmental disturbance, it is
a possible, but generally poor, subject for climate archiving.

Clathromorphum compactum, a cold-water carbonate
builder and a primary subject of this volume, extends from north-
eastern Hokkaido, Japan, through the Arctic to the central Gulf
of Maine in the western Atlantic (Adey et al., 2008) (Figure 1).
Clathromorphum compactum is not reliably known from Iceland
or Norway, occurs in deeper water, and is conspicuously more
limited to colder water than C. circumscriptum (Adey, 1965;
Adey et al., 1976). Adey et al. (2008) treated C. compactum as

Clathromorphum

compactum

NUMBER 40 e 3

an Arctic species, although it is more likely Subarctic in origin
and distribution. Although collection sites in the Arctic are only
scattered, Clathromorphum compactum is generally an abundant
species wherever it is found, and rock substrate, coastal salinity,
and a high sediment load are not limiting.

Clathromorphum nereostratum (Figure 1) and Clathromor-
phum loculosum are cor-strome formers and appear to be largely
restricted to the Aleutian Islands; both species are reported for
the Asian mainland coasts, but insufficient definitive work has
been carried out in the Okhotsk and western Bering Seas to deter-
mine whether they are significant components of the algal flora.
Clathromorphum loculosum has a leafier growth morphology
(Lebednik, 1976), and its archival potential is unknown. Clath-
romorphum nereostratum is the most massive of the Clathro-
morphum species, largely because of its Subarctic-Boreal fringe
environment in the Aleutian Islands. Clathromorphum nereo-
stratum and C. compactum are conspicuously layered, often
with buried conceptacles, and provide the greatest opportunities
for climate archiving. Both the Arctic and the northeastern Asian
mainland and its off-lying islands provide a largely unknown and
potentially rich region for cor-strome climate archiving. Here we

2 2012 Google

US Dept of State Geographer
12 MapLink/Tele Atlas
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FIGURE 1. Known geographic distribution of principal Clathromorphum clathrostrome formers.

Clathromorphum nereostratum has been reported from the mainland coast of easternmost Asia,

but records need to be verified.

4 e SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

FIGURE 2A. Clathromorphum compactum buildup (clathrostrome) crowning large cobble in cor-strome, including branching Lithothamnion

spp. at 20 m depth in southern Labrador. Crusts are 2-4 cm thick and 100-250 years old. Green sea urchins (Strongylocentrotus droebachien-

sis) are 30-50 mm in diameter. © Nick Caloyianis. Reprinted with permission.

introduce the term clathrostrome to refer to extensive carbonate
crustal buildups dominated by the two Clathromorphum spe-
cies, C. compactum and C. nereostratum.

BIOLOGY AND ECOLOGY OF CLATHROMORPHUM

As with most red algae, crustose corallines have a basic
filamentous structure; in this group, the filaments are fused into
a calcified crust (Figures 2A—2C). As described by Adey (1964,
1965, 1966a, 1966b) and Adey et al. (1982; 2005), crustose
corallines combine these filaments into complex tissues with
the filaments linked by fusions and/or secondary pits. Also, sev-
eral different patterns of growth, within the carbonate frame-
work, characterize different genera (Adey et al., 2005). In many
cases the development of reproductive structures occurs within
perithallial tissue and is integrated with the growth of that tissue.
Given damage to the overlying meristem or in the formation of
conceptacle fertile discs, meristematic activity can be reinitiated

within the uppermost years of perithallial tissue (forming char-
acteristic wound repair tissue).

Like many higher plants and unlike all other red algae, cor-
allines have an intercalary meristem (Adey, 1964; Adey et al.,
2005; Figure 2C); along with other elements of their anatomy
and reproduction, this characteristic has led to their separation
as an order of red algae (Corallinales; Silva and Johansen, 2007).
Recent phylogenetic work suggests the group may be separable
at the level of subclass on the basis of the structure of cell pit
connections (Bittner et al., 2011). In a multigene analysis of gen-
era with multipored conceptacles, currently under development
with colleagues (Adey et al., unpublished), we are able to show
that Clathromorphum forms a distinct clade most closely related
to Leptophytum and distant from the Lithothamnion and Phy-
matolithon clades.

Corallines occurring on hard bottoms in shallow seas can
be reef formers in the tropics (Adey, 1998) and rock-blanketing
carbonate formers (cor-stromes) in colder waters. They are often

fossilized and have been used as paleoecological indicators from
the early Tertiary (Adey, 1979). Coralline growth is slow; yearly
bands in Clathromorphum in the warmer fringes of the Subarctic
and the Aleutian Islands are 300-400 pm in thickness. In the
colder Subarctic, the principal habitat of C. compactum, they are
considerably thinner and drop below 100 pm yr"! in the Arctic.
Although the potential for climate archiving with corallines has
been known since the 1960s (Adey, 1965; Chave and Wheeler,
1965), its application has been frustrated until recently by a lack
of understanding of their anatomical complexity and its irregu-
larities, as well as by the lack of appropriate instrumental tools.

Species of Clathromorphum have a unique anatomy that is
particularly useful in the development of climate archives in Sub-
arctic marine environments (Adey, 1965; Halfar et al., 201 1a).
Unlike the progressive cell growth in other Subarctic corallines,
where maximum cell length is achieved several to a dozen cells
below the meristem, creating a diffuse, time-delayed band of cal-
cifying cells, Clathromorphum produces all of its growth and
calcification in the meristem cell layer (a cambium analog; Adey
et al., 2005; Figure 2C). As shown here, in Clathromorphum the
band of calcification and growth is even narrower than meristem
cell length, occurring on a plane a few microns thick passing lat-
erally through the meristem; this ensures the tight temporal link-
ing of ambient water climate and chemistry to a narrow plane
of calcite crystals. These species have an intricate anatomy that
includes calcite crystals that preserve, in their trace element and
isotopic structure, an array of environmental proxies.

In addition to their carbonate skeleton, species of Clath-
romorphum have evolved partial protection against grazing by
invertebrates in both their anatomy (the sunken meristem) and
their primary asexual reproduction (conceptacles are sunken in
the crust and produced in winter). Working with Clathromor-
phum circumscriptum, Steneck (1982) demonstrated a “co-
evolved interdependency” with the limpet Acmaea testudinalis.

NUMBER 40 e 5

FIGURE 2B. Polished section of 4-cm-thick, 220-year old
mound of C. compactum (same locality as Figure 2A). Note
distinctive yearly banding, variably abundant conceptacles
(ovoid holes), and large unconformity near the base of the
specimen (up arrow). Partial unconformities are scattered
throughout crust (down arrow).

Removal of epithallial surface cells by limpets during grazing
equaled the production rate of epithallial cells in the meristem
while freeing the surface of epiphytes. The same relationship
likely exists for C. compactum and C. nereostratum, as fine graz-
ing marks are abundant on the surface of most collected speci-
mens (in most of the Subarctic, the chiton genera Tomicella and
Ischnochiton dominate). Since routine grazing by chitons and
limpets is concentrated on the upper surface of the epithallium,
the perithallium, which builds cell-by-cell below the meristem,

Date :6 May 2011 Timi
Output To = Defaul
Cycle Time = 1.

FIGURE 2C. SEM image of fractured C. compactuwm mound. The
lower right face (right arrow) shows calcified perithallium filaments.
The upper thin slab breaking off is epithallium. The exposed surface
to the left (left arrow) is meristem, separated through the middle of
the layer at the plane of growth and calcification.

6 e SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

FIGURE 2D. Vertical fracture of C. compactum from southern
Labrador with late mature asexual (multipored) conceptacles. The

conceptacle to the right shows a roof and sporangial pore, exposed
by the breakout of the conceptacle cap (epithallial plug overlying
developing conceptacles). The roof of the postmature conceptacle to
the left is growing in with new meristem.

can provide an archive of water climate that is often undisturbed
for centuries by grazers or other organisms.

Most corallines form reproductive structures in peripher-
ally uncalcified packets, called conceptacles, which can be scat-
tered or densely arrayed across the crust surface; conceptacles
are integral with perithallial tissue but can either be buried below
the surface or protuberant above the crust surface. Patterns of
origin and development, relative to the perithallial tissue, vary
widely between genera. In some genera, conceptacles originate
deep within the perithallium, sloughing off caps of overlying
perithallial carbonate at maturity (e.g., Phymatolithon and
Leptophytum; Adey, 1964, 1966a). In Clathromorphum con-
ceptacles originate in the meristem, develop upward, as allowed
by the growth of the surrounding vegetative tissue, and remain
buried in that carbonate-encasing tissue at least until maturity
(Adey, 1965). Some species of Clathromorphum, including
C. compactum and C. nereostratum, bury their conceptacles
with continued growth; successive years leave layers of con-
ceptacle “holes” in the crust that document seasonality (Fig-
ures 2B, 2D, 2E). The principal Clathromorphum species with
archival value initiate conceptacle development in the early
autumn, apparently regardless of latitude. In the later stages
of conceptacle maturation, to make room for the enlarging
sporangia, the calcite in the immediately surrounding tissue
is first dissolved, and then the remaining organic tissues are
crushed by the enlarging sporangia; roughly 30%-50% of a
conceptacle cavity’s height and 50% of its width result from
this crushing.

CALCIFICATION

The skeletal carbonate in corallines forms as prismatic high-
magnesium calcite crystals, perpendicular to the filament axis,
within the organic wall of each cell (Adey, 1998). In most coral-
line genera, a thin layer of tabular crystals forms between the
individual filaments and serves as a “glide plane,” allowing dif-
ferential cellular extension (growth; Adey et al., 2005). Clath-
romorphum species lack differential cellular growth and have
a very different mode of calcification, which we will describe in
detail below. In the Subarctic and its fringes, some Clathromor-
phum species can be very long-lived (at least many centuries).
Given favorable environmental and geomorphological circum-
stances, C. compactum and C. nereostratum can build crusts
with a substantial thickness of biogenic, high-magnesium car-
bonate (Figures 2B, 2F). With the convergence of an enhanced
understanding of species ecology and preservational geomor-
phology, multiple complementary analytical techniques, and a
full understanding of cellular anatomy, limitations to the climate
archive potential of these species are finally being overcome.

THE NEED FOR AN ARCTIC-SUBARCTIC ARCHIVE

Much of the climate variability in the North Atlantic is dic-
tated by the North Atlantic Oscillation (NAO), which is a hemi-
spheric meridional oscillation in atmospheric mass with centers
near Iceland (low) and over the subtropical Atlantic (high; Hur-
rell, 1995). However, the Labrador Sea and its coastal currents
(the West Greenland Current and the Labrador Current) func-
tion somewhat independently of the NAO. Variability in North
Atlantic Deep Water formation in the Labrador Sea impacts both
the global Thermohaline Circulation and the cold and relatively
fresh Labrador Current (Drinkwater and Mountain, 1997; Col-
bourne, 2004). Future climate predictions depend on a clear un-
derstanding, reaching back many centuries, of the relationships
among the dominant climate parameters: the NAO, water tem-
perature and salinity, the North Atlantic Deep Water formation,
and Labrador Current mass transport.

The main branch of the Labrador Current flows along
the edge of the Labrador and Newfoundland shelf (Lazier and
Wright, 1993), whereas an inshore branch follows the various
cross-shelf saddles and inshore troughs (Colbourne, 2004).
Rapid climate changes beginning in the late 1980s produced an
enhanced outflow of low-salinity waters from the Arctic and a
general freshening of the Labrador Current (Greene and Persh-
ing, 2007). Recent and substantial evidence for rapid changes
in North Atlantic climate include increased Arctic air tempera-
tures (Thompson and Wallace, 1998), decreased sea ice extent
(Comiso, 2006), record minimum sea ice (Gersonde and Vernal,
2013), increased melting of the Greenland ice sheet, and freshen-
ing of the North Atlantic (Curry and Mauritzen, 2005). Under-
standing the mechanisms responsible for the recently observed
changes in the strength of the Labrador Current and climate
variability in the subarctic Atlantic requires analysis of long cli-
mate time series (Sutton and Hodson, 2003).

NUMBER 40 e 7

FIGURE 2E. Polished slab of C. nereostratum from the Aleutian Islands, showing 244 years of growth.

FIGURE 2F. Clathromorphum nereostratum from the Aleutian Islands. At 20 cm thick, the crust is over 400 years old.

8 © SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

Likewise, a millennial understanding of past ocean climate
variability in the North Pacific-Bering Sea region is crucial to
the prediction of the impacts of anthropogenic climate change
on this rich ecosystem and on the role played by this region in
Northern Hemisphere climate at large. Links between the North
Pacific and North Atlantic climates clearly exist, but they are
poorly understood (Hetzinger et al., 2012). The Bering Sea, a
region transitional between Arctic, Subarctic, and Boreal regions
in the North Pacific (Adey and Hayek, 2011), is particularly sen-
sitive to warming because of its seasonal ice cover (Sigler, 2010);
continuation of the warming trend of the past decade (Overland
and Stabeno, 2004) will have a major impact on its fisheries
and seabird and marine mammal populations (Grebmeier et al.,
2006). As in the Labrador Sea, limited instrumental climate data
for the North Pacific and Bering Sea are available, only from
1900; significant sea surface temperature (SST) information is
available only from the mid-1950s (Hetzinger et al., 2012).

At present, schlerochronological analyses of the bivalve mol-
lusk Arctica islandica provide the bulk of annual- to subannual-
resolution paleoclimate data for near-surface waters in the north-
western North Atlantic (Wanamaker et al., 2008, 2011). How-
ever, the northernmost confirmed occurrences of A. islandica are
found along the southern shore of Newfoundland (Dahlgren et
al., 2000), which is the southern boundary of the core Subarctic.
Limited paleoproxy archives exist for the North Pacific, but most
high-resolution climate reconstructions are inferred from tree
ring chronologies and do not provide oceanic SST patterns (Hetz-
inger et al., 2011). Recent studies have shown that encrusting
coralline algae are high-quality recorders of extratropical paleo-
climatic signals because of their (1) abundance in mid- to high-
latitude oceans, (2) multicentury life span (Halfar et al., 201 1a),
and (3) annual incremental growth patterns in a high-Mg calcite
framework that can be targeted for high-resolution geochemical
sampling (Halfar et al., 2007; Williams et al., 2011).

Clathromorphum has an intricate anatomy and reproduc-
tion; the climate history of the late Holocene is written in its
yearly banding and calcite crystals. This study demonstrates
how an understanding of the biology, physiology, ecology, and
habitat geomorphology of two principal species of this genus is
essential to the further development of a high-resolution climate
archive for the Arctic and Subarctic. Reading this climate archive
requires not only an intimate knowledge of the interactions be-
tween climate and the complex linkages among the reproduc-
tion, growth, anatomy, and ecology of these two species but also
high-resolution analytical techniques that reveal the underlying
structural details that are the outcome of these interactions.

CORALLINES AS CLIMATE PROXIES
Mg/Ca Ratios and Seawater Temperature
The magnesium content of coralline algal skeletons re-
cords temperature changes (Figures 3, 4; Adey, 1965; Chave and

Wheeler, 1965). Such records have been greatly expanded (Hetz-
inger et al., 2009, 2011; Gamboa et al., 2010; Kamenos, 2011)

using laser ablation—inductively coupled plasma—mass spectrom-
etry and electron microprobe analyses. Research currently un-
derway is producing data covering multicentury time scales.

Ba/Ca Ratios and Salinity

The barium content of the calcium carbonate skeletons of
several marine calcifiers has served as a proxy for identifying
changes in the mixing of cold, nutrient-rich deep waters at the
surface (Lea et al., 1989; Fallon et al., 1999) or as a tracer for
riverine inputs. Chan et al. (2011) have shown that changes in
the Ba/Ca ratio in Clathromorphum indicate freshwater-induced
changes in ocean stratification. Analyses of this ratio provide a
proxy for assessment of salinity changes resulting from meltwa-
ter introduced into the Gulf of Alaska and the Alaskan Coastal
Current, as well as being an important source of information on
freshwater delivery into the Arctic Ocean.

Growth as a Climate Archive

A 115-year growth record from specimens of C. compactum
from Newfoundland and Quebec (Figure 5) produced a century-
long proxy archive for temperature in the northwest Atlantic
(Halfar et al., 2011b). This chronology was successfully compared
to climate patterns of the Atlantic Multidecadal Oscillation. Halfar
et al. (201 1a) linked information from yearly band widths with
cloud cover related to the Aleutian low-pressure system. Combined
with Mg as a proxy for temperature, a 640-year record of annual
growth for C. compactum in the Labrador Sea has been correlated
with sea ice cover (Halfar et al., unpublished manuscript).

Isotopic Composition

The oxygen isotope composition in the skeletons of Clath-
romorphum species records ambient seawater temperature.
Similarly, the high-magnesium carbonate content of these species
records 6'°C values from the dissolved inorganic carbon in the
surrounding seawater. Williams et al. (2011) measured 6¥C in
the coralline alga C. nereostratum to reconstruct the entry of
anthropogenic CO, into the northern North Pacific Ocean and
Bering Sea (Figure 6). From 1887 to 2003, the average decadal
rate of decline in 6'°C values increased from 0.03% yr in the
1960s to 0.095% yr! in the 1990s; this result is higher than ex-
pected from the 6'°C Suess effect. The authors concluded that an
increasing intensity of the Aleutian atmospheric low was respon-
sible for the upwelling of carbon-rich deep water.

MATERIALS AND METHODS

The collections utilized in this study were taken on scuba
dives based from small research vessels, which allowed bottom
surveys and assessments of the ecology and geomorphological
characteristics of cor-stromes. The research vessels were equipped
with laboratory facilities that allowed microscopic examination

NUMBER 40

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es) | |

© 0.08 |NIT ! :

SS 2

Sites }

= | Annual 3 |
aa Cycle \ Coldest month»

0 300 600 900 1200 1500

Distance from living surface (um)

FIGURE 3. (top) Annual Mg/Ca cycles (moles) measured by laser ablation—inductively coupled plasma—
mass spectrometry. (bottom) Mg/Ca cycles superimposed on a cross-section view of C. compactum. The
white line laser transect is along the growth axis (Halfar et al., 201 1a).

a7 &
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~ 1950 1960 1970 1980 1990 2000

--- Temperature annual — Mg/Ca annual

--- Temperature 5yr average —— Mg/Ca 5yr average

FIGURE 4. Mg/Ca time series from C. compactum near St. Johns, Newfoundland (average of two samples), and
instrumental temperatures at a nearby oceanographic station (station 27.0 m depth; 1950-2004); 7, = 0.51,
p < 0.001 (Gamboa et al., 2010).

10 e¢« SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

Average Growth

1890 1910 1930 1950
Year

Average Growth === 10-year
AMOgesst

3-year mean

=== 1-year ---- 3-year mean 2

ro)
X9pu| ISSYAONV

1970 1990 2010

FIGURE 5. Ten-year moving average of 115-year growth increments; master chronology of Newfoundland C. compac-
tum compared to the Atlantic Multidecadal Oscillation (AMO; r = 0.74; Halfar et al., 201 1a).

and specimen labeling, drying, and initial measurement. Extrac-
tions from rocky bottoms were mostly made manually, with a
hammer and chisel; although 10%-20% of specimens were re-
moved with the rock substrate still attached to the base, the ma-
jority separated cleanly from the substrate.

CLATHROMORPHUM COMPACTUM (NorTH ATLANTIC,
LABRADOR SEA, AND ARCTIC)

More than 200 stations, at depths ranging from approxi-
mately 0 to 35 m, including the Gulf of Maine, Nova Scotia,

34 Attu 11-4

the Gulf of St. Lawrence, the island of Newfoundland, and
the Labrador coast northward to Cape Chidley, were sam-
pled by Walter Adey and his students. The Gulf of Maine
(GOM) specimens were collected primarily from 1960 to
1963. Some of the Labrador (LAB), northeast Newfoundland
(NENF) and northern Gulf of St. Lawrence (NGSL) speci-
mens were collected during a 1964 cruise, and a limited num-
ber of photographic bottom images are available from that
cruise. However, the majority of the C. compactum specimens
were collected during expeditions of the R/V Alca i during
the summers of 2010 and 2011. The research base comprises

513C (%ovpps)
oO

1880 1900 1920 1940

AM-KR-80 AM4-1

1960 1980 2000

FIGURE 6. Annually resolved 6°C values for three C. nereostratum speci-
mens collected off two Aleutian Islands with the 3-year running mean in bold.

(Williams et al., 2011).

approximately 4,000 specimens of coralline algae, including
C. compactum, now housed at the Smithsonian’s National
Museum of Natural History in Washington, DC. These collec-
tions have not been formally accessioned to the U.S. National
Herbarium, but are available by contacting the first author.
During the 2010-2011 cruises, the bottoms from which the
collections were taken were extensively documented with
digital still images and video. This digital image archive will
be available with the collections. A single large sample of
several fused plants, partially reported here, was collected by
M. Goobie and E. Edinger at Arctic Bay in northern Baffin
Island at 72°N. Digital images of the cor-strome bottom in
Arctic Bay are available with the collection.

CLATHROMORPHUM NEREOSTRATUM (ALEUTIAN ISLANDS)

Three important C. nereostratum specimens utilized in this
study were collected by Lebednik (1976) at Amchitka; two oth-
ers were collected by R. Steneck in 2004. The remainder of the
material (21 specimens) was collected in the summer of 2008 by
Jochen Halfar (JH, with S. Hetzinger and R. Steneck) on a cruise
from Akun Island (165°W) in the east to Attu Island (175°E) in
the western Aleutian chain.

SPECIMEN PREPARATION

Many of the specimens collected from 1960 to 1964 were
diamond sawed into smaller blocks and then fixed, decalcified,
and microtome sectioned in paraffin before being studied with a
compound light microscope. A large microscope slide collection
remains part of this material. Recently collected large specimens
were usually first cut with a diamond saw and then fractured (es-
sentially randomly) with wire cutters. Fragments with the desired
orientation were then selected for mounting and then carbon
coated for examination with a Leica Stereoscan 440 scanning
electron microscope (SEM).

Hiatella arctica is an abundant mollusk clathrostrome borer,
especially in the Labrador Sea but also in the Aleutian Islands
(Chenelot et al., 2011). Shells of this bivalve are relatively soft and
ill suited to scraping; burrows are clearly constantly enlarged by
dissolution of the Clathromorphum skeleton, perhaps by release
of an acid. The net effect this enlargement is a natural etching of
the coralline skeleton. Burrow walls were extracted by diamond
sawing followed by wire cutter trimming. The appropriate sur-
faces, carbon coated for SEM examination, have been invaluable
for understanding biological and mineralogical patterns.

The SEM images were typically taken at 50x, 500x, and
3,000x (occasionally at 10,000x) as appropriate to the data
sought. Although many single images were utilized, especially
of cellular and calcification features, often multiple images were
compiled into mosaics of vertical fractures. These mosaics allow
large-scale examination of conceptacle and anatomical layer-
ing as well as the determination of the vertical growth pattern
over time. Conceptacle-based growth rates were determined by

NUMBER 40 e 11

aligning a fixed grid to the specimen growth lines on the mo-
saic then measuring yearly thickness wherever conceptacles were
present. These rates are supported by seasonal cycling of Mg as
measured by laser-mass spectrograph and electron microprobe.
Some direct measurements of yearly growth were made on so-
lution ridges in Hiatella cavities. Conceptacle dimensions were
obtained by measuring all conceptacles in a mosaic for which
the pore plate could be clearly discerned. Seasonal stages of re-
production were estimated by examining multiple, haphazardly
selected specimens with a dissecting microscope.

TERMINOLOGY

In this volume we use modified classical terms for coral-
line anatomy. Hypothallium applies to the basal cell filaments,
where the long axis of the cell is parallel to the substratum (in
Clathromorphum, multiple layers of cells grow parallel to the
substratum). The bulk of the thallus, built with filaments whose
cells have their long axis perpendicular to the substratum, is
termed the perithallium. When the intercalary meristem was
first described (Adey, 1964), two new cell types, the meristem
itself and the photosynthetic epithallium (previously called cover
cells) distal to the meristem, were added to the lexicon. In Clath-
romorphum, the cells of both perithallial and hypothallial fila-
ments become linked horizontally by fusion tubes that serve to
transport metabolites. Epithallium, perithallium, and hypothal-
lium are primary tissues; additional secondary tissues are formed
in reproduction and wound healing as we shall describe in this
volume.

RESULTS
REPRODUCTION

Like most corallines, Clathromorphum species have a basic
red algal triphasic life cycle in which isomorphic 2n (diploid)
plants (asexual in much of the literature) bear either 1 (hap-
loid through meiosis) or 27 spores in sporangia, which are in
turn borne in reproductive structures called conceptacles. The
2n spores produce new (asexual) spore-bearing plants. The 7
spores, on the other hand, produce separate isomorphic male
and female plants. Both male and female plants produce either
spermatangia or carpogonia (egg cells) in similar conceptacles
that are typically considerably smaller than the asexual concep-
tacles. When the carpogonia are fertilized by the amoeboid sper-
matia released from the spermatangia, they produce fusion cells
that in turn develop filaments bearing 27 carpospores. This set of
2n filaments, borne on the n female plants, is sometimes referred
to as a carposporophyte generation. The carpospores give rise
to the 27 (asexual) generation (Adey, 1965; Lebednik, 1976).
The maturing sporangia and/or their spores of both asexual
and carposporophyte concptacles dissolve the calcified perithal-
lium surrounding the conceptacle, considerably enlarging the

12 e

conceptacle. Whereas sexual and cystocarpic gametangial con-
ceptacles have a single large pore at their apex, asexual sporan-
gial conceptacles are multipored.

Sporangial (apparently diploid) plants (with abundant bi-
or tetrasporangium-bearing conceptacles) are seasonally com-
mon among the principal Clathromorphum species, whereas
gametangial plants (apparently haploid male and female) and
conceptacles are more or less rare. Adey (1965) examined re-
production in C. compactum, and Lebednik (1976) extensively
studied reproduction in C. nereostratum. Herein we provide ad-
ditional information for both species. The earlier work by Adey
and Lebednik was accomplished with decalcified material stud-
ied with light microscopes. Here we emphasize SEM sections,
observing the conceptacles as they occur buried in the fully calci-
fied skeleton. The diameter and height of sporangial conceptacles
for both species and for sexual conceptacles of C. nereostratum
are given in Figure 7. Complete dimensional analyses of surficial,

400

350 C. nereo

C. comp N. Lab
C. comp S. Lab
C. comp NENF
C.comp. GOM

300

<5 8 8

250

200

150

100

Conceptacle Height (um)

0 50 =100

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

mature conceptacles, with roof dimensions and burial depth at
maturity, are provided in Adey (1965) and Lebednik (1976).
Since gametangial conceptacles develop in spring rather than
autumn (when sporangial conceptacles develop), distinguishing
between them may be necessary in temporal analyses of tissue
chemical composition.

Adey (1965; for C. compactum) and Lebednik (1976; for
C. nereostratum) provided photographic images of several stages
of development of sporangial conceptacles. However, neither au-
thor showed the details of development, particularly relative to
the simultaneous and essential growth in vegetative tissue, that
are required for understanding the relationship between anat-
omy and seasonality. This information is potentially important
in climate archiving for determining the seasonality of carbonate
deposition in each vegetative cell. Figure 8 shows the stages of
development of sporangial conceptacles in C. compactum rela-
tive to the surrounding vegetative tissue. Developmental stages

|
|
C. nereo mean
i]
al e .

fh (excluding GOM)

150 200 250 300 350 400 450 500

Conceptacle Diameter (um)

FIGURE 7. Dimensions of mature conceptacles of C. compactum (105 conceptacles, 13 plants, and 9 stations)

and C. nereostratum (84 conceptacles, 11 plants, and 7 stations). Colored squares are means of individual

plants. Female conceptacle data are for C. nereostratum Lebednik, 1976. Male and cystocarpic data are derived
from a combination of this study and Lebednik (1976). The long arrow describes the path of development of
C. nereostratum female conceptacles, from unfertilized carpogonia through postfertilization to mature

carposporangia.

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FIGURE 8. Development of asexual, bispore-producing C. compactum conceptacles described from specimens col-
lected in the northeastern Gulf of Maine. (A) Early sporangial mother cells and distinctive supporting cells (Septem-
ber—October). Fertile disk (nemathecium) 100-120 pm in diameter; it expands vertically, without primary calcification
(sporangia or intersporangial filaments), to form a fertile uncalcified cylinder. Initiated as meristem cells at 10-20 pm
of length, sporangia expand vertically, accommodated by growth in the surrounding calcified vegetative tissue. (B)
Later stage: sporangia over 100 pm in length with a thick, organic, apical wall or cuticle (to form spore release pore).
Here a decalcification “front” below and to the sides of the fertile cylinder is seen; cell crushing has yet to occur. Eight
to 12 vegetative cells have developed in the surrounding vegetative crust to allow sporangial growth. (C) SEM image
of an aborted conceptacle just prior to the stage shown in B (northern Labrador). (D) Later stage with further decalci-
fication; sporangial enlargement laterally and some crushing of surrounding vegetative cells. The overlying epithallial
cells have broken off to expose the conceptacle roof (white disks seen from surface). A later surface view of this stage
is shown in Figure 9C, D. (E) Light microscopic image of mature conceptacle at full, mature dimensions (December—
January), with decalcification and crushing of lateral and underlying vegetative cells, and spores forming inside the
sporangia. A, B, and D were drawn from microtome sections of winter plants. C is a SEM image of a calcified, frac-
tured section. E is a decalcified and stained microtome section. All images are at the same scale, indicated by the bar.

e

13

14 .

of C. nereostratum are not shown in similar detail since full sea-
sonal, decalcified, and sectioned material is not available. How-
ever, it is clear from preliminary analyses that the patterns are
very much the same.

Reproduction in Clathromorphum compactum

Adey (1965) demonstrated the seasonally determined de-
velopment of sporangial conceptacles in C. compactum in the
Gulf of Maine, where conceptacles are initiated in early autumn
(September and October), reach maturity in midwinter, and are

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MAG= 60X |!Probe= 90pA b——-4

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SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

fully overgrown by late spring. The farther north C. compactum
plants grow, the later their reproductive maturity is; in northern
Labrador, most plants are at the peak of the reproductive cycle in
midsummer, the surficial conceptacles being full of ripe sporan-
gia (Figure 9; Table 1). Conceptacle initiation is likely controlled
by the photoperiod, with light rapidly diminishing in Septem-
ber and October; temperature is likely not a significant factor
as there is a considerable difference in temperature from south
(approximately 10°C ) to north (approximately 5°C) at this time.

The developmental morphology of a typical sporangial con-
ceptacle of C. compactum from southern Labrador is shown in

Apr 2011 Tim
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MAG= 50X /Probe= S90pA

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FIGURE 9. SEM images of typical C. compactum surfaces from different regions showing reproductive state during midsummer (see

Table 1). (A) Northeastern Newfoundland, conceptacles mostly grown in, but remain clearly visible. (B) Southern Labrador, conceptacles
ranging from immediately postmature to grown in. (C) Northern Labrador, conceptacles mostly fully mature; the low mound in the
lower center is a submature conceptacle with a conceptacle cap not fully broken out. (D) Conceptacle roof at larger scale; pores for exit of

the spores are mostly free of sporangial cap walls; a few dried pore plugs remain. During summer in the Gulf of Maine, conceptacle roofs

with visible pores are not found, and only faint conceptacle “ghosts” appear in 60%-70% of the population. Note the strong chiton
grazing marks in A and C and also in B, although somewhat grown out.

NUMBER 40 e 15

TABLE 1. Summer reproductive state as a percentage of specimen surface.

Mature Conceptacles Faint conceptacle
Not reproductive* Initial state> conceptacles growing out remains
Subregion (%) (%) (%) (%) (%)
Northern Labrador 19 0.3 40 36 3.5
Southern Labrador 32 0 32 31 4.5
NE Newfoundland 62 0 3 15 20
Northern Gulf of St. Lawrence 52 0 Trace 3.1 45
Gulf of Maine‘ 30 0 0 10 60

“Midsummer (July-August) reproductive (asexual) state in Clathromorphum compactum from northern Labrador to the Gulf of Maine. The values

for each of the Subarctic subregions are estimated from 40 haphazardly selected sets of undamaged specimens with a 20-50 cm? surface, estimated

using a dissecting microscope.
’Conceptacle caps.
‘From Adey (1965).

Figure 10A. The sporangial caps (plugs), which are embedded in
the calcified conceptacle roof tissue, and the uncalcified sporan-
gial mother cells are together about 150 pm long at maturity (be-
fore spore formation). The sporangia and surrounding vegetative
filaments form a developmentally uncalcified fertile cylinder that
is approximately 100 pm in diameter and 100 pm long before
final expansion to sporangial maturity. As we shall show, fertile
cylinder development requires the accompanying production of
about 10-12 cells in each filament of the surrounding vegetative
tissue. Near sporangial maturity, the carbonate component of an
80-ym-thick underlying vegetative tissue is dissolved beneath the
enlarging sporangia, with an additional 70-80 pm of carbonate
also dissolved laterally, to make room for the large sporangia to
fully mature. The sporangia produce bispores, each of which is
approximately 1,000 times greater in volume than the individual
surrounding vegetative cells. The total noncalcified, organic vol-
ume of crushed vegetative cells is approximately equal to the
final spore volume. In the southwestern Labrador Sea, this final
expansion phase occurs in late spring and early summer, just
after ice breakup, when available light should be at a maximum.
Figure 10B, reduced to show primarily sporangial development,
provides a mean pattern for northern Labrador, where concep-
tacle maturation is delayed even longer into the next summer.

Sporangial conceptacle development is initiated in early au-
tumn, and at maturity carbonate solution and crushing of previ-
ously formed summer vegetative tissue occurs to about 80 pm
below the plane of sporangial initiation. In southern Labrador
and northernmost Newfoundland, there is a greater level of veg-
etative cell fusion for a limited period at the time of sporangial
initiation. This cell fusion creates a weak zone in the carbonate,
and horizontal fractures are easily induced on this plane, as can
be seen in Figure 11.

As shown by Adey (1965) for the Gulf of Maine and here
for the core Subarctic (Table 1), 20%-30% of the plant surface
in each year does not become reproductive. This is seen in an

analysis of conceptacle bands in a C. compactum plant from Lab-
rador (Figure 12A,B), where every fifth to seventh year a growth
ring is devoid of a conceptacle band. Specimens have been found
in which extensive conceptacle production has occurred for sev-
eral consecutive years, followed by years with few or no con-
ceptacles (Figure 2B). In one very old specimen from northern
Labrador, several hundred years’ worth of missing conceptacle
bands were seen. This phenomenon implies that anatomy must
be consulted, in addition to measuring the number of concep-
tacle bands or the thickness between bands, in order to obtain
an accurate yearly archive. If it is suspected that several years are
missing, this suspicion is relatively easy to confirm with anatomy.
If conceptacles were apparently missing for many years, it would
be necessary to confirm by counting each year’s Mg cycle. As
shown in Figure 12B, broken-out conceptacles can “grow in”
by regrowth of vegetative cells from the base and sides, nearly
obliterating evidence of the presence of the conceptacle in a su-
perficial analysis. The perithallial tissue that has grown back into
the conceptacle cavity will have formed several months later than
the surrounding tissue, depending on geographic latitude.

In the specimen shown in Figure 12B, the years 2005 and
2006 lack buried conceptacles. For the year 2007, a broken-
out conceptacle appears on the right (note the presence of a full
conceptacle farther to the left). During the summer following
breakout, new tissue formed at the base of the conceptacle and
refilled the cavity during the following summer. This new tissue
was formed months later than the surrounding vegetative tissue.
A laser scan passing through the broken-out and grown-in con-
ceptacle would show carbonate chemistry totally out of phase
with that of the larger specimen on the same plane, unless the
presence of this grown-out conceptacle were taken into consid-
eration. Conceptacle cavities are oblate spheroids; because spo-
rangial formation begins in autumn (see Figure 10), a horizontal
plane through the principal diameter of the spheroid approxi-
mately marks the beginning of October.

16 e

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

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FIGURE 10. Clathromorphum compactum conceptacle and sporangial formation. (A) Di-
mensional and cellular development of average bisporic conceptacle in southern Labrador

relative to season and vegetative tissue. Numbers to the right are averages and can vary with

region of development. (B) Sporangial development with time in northern Labrador. In the

Gulf of Maine, because of higher vegetative growth rates, this process occurs from October

to January.

Reproduction in Clathromorphum nereostratum

A
C. nereostratum is not available and would require a set of
specimens taken in the Aleutian Islands throughout the autumn.
Nevertheless, the photographic images published by Lebednik
(1976) are adequate to show that the pattern is similar enough
to that of C. compactum to allow the use of Figure 8 (developed
for Gulf of Maine populations) but not Figure 10 (developed

detailed developmental analysis of reproduction in

for Labrador). However, there are a number of additional dif-
ferences that are critical to interpretation for climate archiving.

Of the 26 specimens of C. nereostratum examined from the
Aleutian Islands, 24 were collected in summer (June-August)
and 2 in December. Of the 24 specimens collected during the
summer, 2 had single-pored gametangial conceptacles at their
surface. One of these two plants had mature fertilized female
conceptacles (carposporangial conceptacles), whereas the other
had postprime male conceptacles with open pores remaining.

Date :14 Dec 2011

=10,00kV WD= 15mm 200um

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60X |Probe= 90pA b—+ : Neycle 1 me = 39,

NUMBER 40 e 17

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FIGURE 11. Horizontal fracture in a specimen of C. compactum collected in summer of 2010 (Great Northern Peninsula of Newfound-

land). (A) The narrow bench to the left is the meristem fracture zone. (B) The main fracture bench (center in A) occurred on a plane with

a high level of cell fusion in the autumn of 2009 (when sporangial development initiated). Also visible is the transition from summer to

winter in perithallial tissues.

Although degenerate (broken-out) or faint ghosts of growing-in
sporangial conceptacles were sometimes present in the remaining
22 specimens and buried sporangial conceptacles were present
in section, no mature, multipored sporangial conceptacles were
seen at their surfaces. In section, the most recent band of buried
conceptacles occurred about 100 pm below the meristem, indi-
cating maturity the previous winter.

Both specimens collected in December presented premature
to mature sporangial conceptacles (Figure 13A). It is not usually
possible in SEM images to distinguish between bisporangia and
tetrasporangia in buried conceptacles (the latter likely indicat-
ing meiosis and reduction to the haploid state in the spores).
However, both December specimens presented tetrasporangia,
and Lebednik (1973) found only tetrasporangial conceptacles in
this species. Although the data are minimal, this finding suggests
that C. nereostratum generally has the triphasic and isomorphic
alternation of generations described earlier. In this case, sporan-
gial (2n) plants reproduce in autumn, maturing in winter (as in
C. compactum in the Gulf of Maine and Nova Scotia) and gam-
etangial (1n) plants reproduce in spring, maturing in summer.

On the basis of available collections, gametangial plants are
probably infrequent in C. nereostratum (very extensive collec-
tions demonstrate rarity in C. compactum). Thus, especially in
C. nereostratum, it is essential to identify the type of conceptacle
(sporangial or gametangial) in order to determine the develop-
mental timing of the conceptacle compared to the vegetative tis-
sue. Male and female conceptacles are quite small compared to
sporangial conceptacles; although both become buried, they are
not likely to be confused for sporangial conceptacles (Figures 7,
13). Fertilized female conceptacles (producing carposporangia)

are somewhat larger in diameter than sporangial conceptacles
(Figures 7, 13). However, they are not as tall, suggesting that
carposporangial tissue dissolution is not as extensive beneath the
conceptacle. Since carposporangia are produced only laterally
from fertilized carpogonia (egg cells), centrally there is no disso-
lution, resulting in the formation of a central columnella, leading
to dumbbell-shaped conceptacles. For a detailed description of
the development of sexual conceptacles in C. nereostratum, see
Lebednik (1976). Carposporangial conceptacle development has
not been described in C. compactum, but it is likely quite simi-
lar. The presence of a central columnella and dumbbell-shaped
conceptacles shows that it is the developing sporangia (bisporic,
tetrasporic, or carposporic), not the vegetative cells, that provide
the acid for surrounding carbonate dissolution.

Female conceptacles are located midway through the yearly
cycle (Figure 13B,C), with a sharp perithallial boundary in late
autumn (see below). On the other hand, sporangial conceptacles
are located near the upper (later) boundary of the cycle (Fig-
ure 13A). In medial sections, sporangial conceptacles are oval in
shape, whereas female conceptacles are dumbbell shaped, with
a central columnella. In sporangial conceptacles, the recalcified
sporangial walls are vertical, whereas the female conceptacle car-
posporangia and supporting structures appear as packed spheres
of many sizes (Figure 13B).

CELLULAR AND ANATOMICAL STRUCTURE
Aside from a basic pattern of upright filaments of cells

combining to form a calcified mat showing vague “rings,” the
perithallial vegetative anatomy of Clathromorphum, as seen in

18 e© SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

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FIGURE 12. (A) Thickness of yearly bands in C. compactum from southern Labrador (specimen 10-7S (1a)). The
number of asexual conceptacles in each band, in the limits of the SEM mosaic, is indicated. (B) SEM of C. compac-
tum trom the Great Northern Peninsula of Newfoundland, showing yearly bands of conceptacles. This is a faceted
specimen, with the facet boundary represented by the abrupt change in the slope of the conceptacle planes and ragged
vertical lines on the left (see Figure 18). A broken-out conceptacle (2006/2007) is shown by the arrow on the right,
with tissue formed from the base of the conceptacle refilling cavity; this tissue formed months later than the surround-
ing vegetative tissue.

HM EHT=10.00kV WD= 13mm 200um Date AY Apr 2012 Time
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FIGURE 13. Clathromorphum nereostratum conceptacles in SEM images. Note that recalcified sporangium cell walls tend to be vertical

in asexual conceptacles (A; reflecting vertical orientation of sporangia), whereas cystocarpic conceptacles (B) appear as small angular

circles of various sizes (left arrow in B; cells of gonimoblast filaments [upper arrow] produce cystocarpic sporangia laterally). (A) Yearly

layers of buried bi- or tetrasporangial conceptacles (sporangial walls recalcified after burial; arrows). (B) Mature female (cystocarpic)

conceptacles. Midsections show a dumbbell shape (bottom right arrow) because of dissolution of the surrounding carbonate by periph-

erally developed spores. (C) Small, ovoid, male conceptacles with recalcified spermatangial mother cell walls (arrow).

a dissecting microscope view of a vertical fracture or polished
slice, may superficially appear to be without structure. However,
at higher magnification, it is seen to be a rich mosaic, deriving
from the genetic control of cellular and tissue development as
influenced by the physical and biological environment. Mea-
surements of cell dimensions in SEM images demonstrate this
genetic-physical interaction. As shown in Figures 14A, 14B, and
15, cell dimensions change seasonally. Cells within each filament
are linked by pore plates (pit connections and pit plugs in most
red algae), and the length, pore plate to pore plate, varies more
or less consistently from about 8 to 15 ym for both species; the
cell lumen diameter likewise ranges from 2 to 6 um. There is a
strong tendency for cells to be shorter and wider in the winter
and early spring, with a lengthening and narrowing of the lumen

in the summer and early fall (Figures 14A, 14B, 15). This pattern
is strongly apparent in most C. nereostratuim specimens from the
Aleutian Islands but less so in C. compactum specimens from the
northwestern North Atlantic.

Since total filament diameter, including the calcified cell
walls, is fixed at roughly 10-11 pm in C. nereostratum and
9-10 pm in C. compactum (except when filament branching
and tissue expansion is occurring), it is the total calcified cell
wall thickness that changes seasonally (Figure 16A,B). As can be
seen clearly in Figures 16 and 17, there is a well-defined inner
wall, with small, prismatic, radially oriented calcite crystals that
maintain about the same length (1 pm) and character through-
out their distribution and annual cycle. This wall type has
been described for most corallines for the last several decades

20

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FIGURE 14 A. Clathromorphum compactum variation in cell dimen-
sions with depth in perithallium: mean perithallial cell dimensions,
as measured in two crusts, from meristem, with depth (summer col-
lected in southern Labrador; mean of two consecutive years, three
cell rows). L/W = length/width.

(reviewed by Adey, 1998; see also Adey et al., 2005). However,
in Clathromorphum species, especially during summer and au-
tumn, the space between the filaments becomes filled with much
larger, often spear-shaped, vertically or diagonally oriented cal-
cite crystals (interfilament crystals). As shown in Figure 17C, the
inner-wall crystals are formed within the organic membranes of
the cell, whereas the deltoid interfilament crystals are formed
in the cavity between the filaments (Figures 16A, 17B,C). This
phenomenon is coincident with the narrowing of cell lumens.
Interfilament crystals tend to be present year-round. However,
in winter they are far less abundant, the cell lumens being larger
in diameter. Thus, summer and fall tissue is considerably denser
than winter tissue.

Unlike the closely related, sheet-forming species Clathromor-
phum circumscriptum (which occurs in shallower water and tide
pools), mature C. compactum tends to be dome shaped. Large
sheetlike (clathrostrome) formations often develop, especially in
the northern Subarctic, but they form from the coalescing of ad-
jacent C. compactum plants. Although smooth, dome-shaped,

SMITHSONIAN CONTRIBUTIONS TO THE MARINE

SCIENCES

64-38 Nachvak Fjord, N. Labrador

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FIGURE 14B. Clathromorphum compactum variation in cell di-
mensions with depth in perithallium: mean dimensions from five

continuous years, matched peak to peak (summer collected from
northern Labrador). L/W = length/width; Tk = thickness

individual plants are common, especially in the warmer part of
the C. compactum range, domes featuring more or less flat facets
separated by slightly grooved ridges are more typical (Figure 18).
Facets arise when the scattered filament branching required to
form the domed morphology of C. compactum occurs in local-
ized vertical planes. Facets can shift with time or split in two
for several years. Conceptacles generally do not form near facet
boundaries; when a facet does develop, previous nearby concep-
tacle areas can become nonreproductive. Also, different facets
on the same plant can grow at different rates. For that reason,
growth rates in mound-forming C. compactum are taken in the
middle of the dome.

Clathromorphum nereostratum can develop into a much
thicker crust (up to 50 cm) than C. compactum (up to 12 cm).
This is partly due to the much slower growth of C. compactum
in the colder water of the core Subarctic and Arctic (see below).
The crust thickness achieved by C. compactum in warmer Lab-
rador waters, for example, is comparable to that of C. nereo-
stratum, taking into account the difference in the yearly growth

Clathromorphum nereostratum
_ Amchitka AM-KR-80 Spec. B, Sample 1

_Winter E g

15 9. Fall ____Summer ____Spring_

Cell Length (pit plates)(um)

Avg. Cell Width (jun)

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20 30 40 50
Cell Position
(beginning 9 cells above 1st growth line)

NUMBER 40 e 21

08-05-24, Amchitka

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Avg. Wall Thickness (10m).

+ T r T 1 r r +

0 5 10 15 20 25 20 45 40 45 50
Cell Position From Start of Winter

FIGURE 15. Clathromorphum nereostratum cellular anatomy. Cell dimensions with depth in

perithallial tissue. (left) Amchitka plant taken in the 1970s. Mean cell dimensions, two successive

years. (right) Plant from Amchitka, taken in 2008. Mean, three parallel filaments, single year.

rates. However, even in the Gulf of Maine, the southern limit
of C. compactum, where the yearly mean temperature and
growth rates are similar to those of C. nereostratum, C. com-
pactum plants remain much thinner. This is partly due to the
“leafy” growth morphology of the hypothallium (the basal tis-
sue that grows parallel to the substrate) of C. nereostratum. In
C. compactum, the hypothallium has a mean thickness of 3.5
cells (maximum 6 cells) and 22 pm (maximum 43 pm), and
the cells are tightly adherent to the substrate (Adey, 1965). In
C. nereostratum, on the other hand, the hypothallium has a mean
thickness of 16.8 cells (maximum 24) and 135 pm (maximum
206 pm; Lebednik, 1976); the growing margin is thick enough to
be structurally freestanding and often becomes cantilevered off
the substrate for a considerable distance.

Clathromorphum nereostratum is thus capable of grow-
ing over obstacles, and if the growing margin is damaged, a
secondary hypothallium, formed from perithallium, grows out
over the damaged area (primary hypothallium develops initially
from a settled spore on the rock or shell substrate). Individual
C. nereostratum plants can thus be much broader than those
of C. compactum (Figure 2F) and have the capability to
achieve greater thickness in a single plant. Clathromorphum
compactum produces a clathrostrome largely by the fusion of
many individual small plants. These can be any size, depend-
ing upon the recruitment density. At the warmer margin of its
temperature limits in the Gulf of Maine, perhaps because of the
warmer summer temperatures, which allow greater invertebrate

damage to crusts, and likely because of less successful recruitment,
C. compactum plants are more scattered and rarely exceed sev-
eral centimeters in thickness and 100 years of age. As noted
above, C. nereostratum likely evolved from a C. compactum-—
like ancestor (Adey, unpublished data); the primary innovation
was the development of a thicker hypothallium allowing a free-
standing cantilevered morphology.

BIOLOGICALLY INDUCED ETCHING AS A SOURCE OF INFORMATION

Hiatella arctica is a common Subarctic bivalve that estab-
lishes burrows within the calcified perithallium tissue of Clath-
romorphum crusts. Apparently, H. arctica larvae settle at the
margin or on a damaged surface of a young plant and are buried
by plant growth. The bivalve then grows along with the perithal-
lium, enlarging its burrow by gradually decalcifying the coral-
line walls surrounding it. If a coralline sample is collected with
the animal still alive, the burrow wall can be seen to be etched
into ridges and valleys corresponding to the yearly layers of C.
compactum growth (Figures 19, 20). The etching is probably ac-
complished with an acid secretion, although localized CO, pro-
duction by the bivalve, accompanied by pH reduction within the
confined space of the burrow, could also be a factor. The cell wall
carbonate formed in summer, being about two times denser than
that in winter, forms the ridges, and the less dense winter cell
walls form the valleys. Also, particularly as seen in longitudinal

22 e¢ SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

I EHT=10.00kV WD= 18mm 2um
MAG= 6.06KX!Probe= 75pA /— 4

Date 4 May 2011 Time :15:01:39
Output To = Default Printe
Cycle Time = 2.5 Secs

FIGURE 16. Clathromorphum compactum calcified wall structure. (A) Transverse fracture showing summer cells with large interfila-

ment calcite crystals between rings of small, radial, inner-wall crystals (crystals 1 am long). (B) Longitudinal fracture of summer cells

showing large, angular interfilament calcite crystals and thin inner walls of fine, radially oriented crystals. (C) Winter cells of fine, radial,

inner-wall calcite crystals. Interfilament crystals are only at cell “corners.”

fractures (Figures 16B, 17C,D), interfilament crystals are much
larger (to 5-6 ppm long) than inner-wall crystals and tend to be
arrowhead shaped (Figure 17B).

A closer look at the etched valleys shows that the smaller,
radial, inner-wall crystals are more resistant to solution than the
larger, vertically oriented, interlamellar crystals. This is a differ-
ence in crystal morphology that results in winter cells that tend
to break out of the carbonate matrix as silt-sized, hollow grains
(Figures 19D, 20A). The inner-wall crystals are embedded in an
organic matrix that likely controls their development (Giraud
and Cabioch, 1979). Thus, they are somewhat protected from
dissolution (Ries, 2011). As discussed below, the interfilament
(interlamellar) crystals may be precipitated because of CO, re-
moval in the inorganic interfilament space and therefore lack
protection from dissolution from an organic matrix.

GrowTH RATE

On the basis of combined analyses of conceptacle bands
and cellular anatomy, the thickness of yearly bands in Clathro-
morphum compactum and C. nereostratum can be defined using
mosaics of SEM images. Further combined with measurements
of the bivalve-etched ridges, as described earlier, regional growth
rates for Clathromorphum compactum are shown in Figure 21.
There is a highly significant and consistent drop in overall crustal
growth rate from south (Gulf of Maine) to north (northern Lab-
rador and Arctic Bay, Baffin Island). The plants for which these
intervals were measured were selected haphazardly from avail-
able SEM sections having clearly defined conceptacle bands. No
effort has been made to compare the same years in each region, as
this would require a more defined ecological depth range for each.

& a > *
EHT= 8.00kV WD= 12mm Dee ee
MAG= 2.01KX!Probe= 90pA [1 Cycle Time -

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MAG= 5.01KX!Probe= 90pA inal Ne

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FIGURE 17. Clathromorphum nereostratum from the Aleutian island of Amchitka. (A) SEM of vertical fracture with overlying epithal-
lium, underlying perithallium, and meristem with a break in calcification. Inner cell layer of radial crystals (red arrow); vertically oriented
interfilament crystals (blue arrow). (B) SEM looking downward into meristem with epithallium removed. A smooth organic material
coats the inner wall (red arrow); large deltoid interfilament crystals (blue arrow), apparently with no integral or overlying organic mate-
rial, lie between the inner wall organic material. (C) Unfractured meristem cells showing the inner-wall inner membrane (IM) and outer
membrane (OM), the fractured calcification zone (CZ), and the precipitation cavity (PC). (D) Clathromorphum nereostratum from Rat
Islands, Aleutian Islands. Summer perithallial cells showing cell fusions formed after burial in the perithallium (horizontal arrows) and

pit connections (vertical arrows) between cells of a filament.

The regional growth rates presented in Figure 21 are plotted
as a function of yearly mean regional temperature in Figure 22.
The Arctic Bay temperature is an estimate based on a 9-month
sea ice interval of -1.8°C and a 3-month ice-free interval of
3.5°C. As we will show in a future paper (Halfar and Adey, un-
published), when sea ice is consistently present longer than about
2 months, growth ceases, probably because of a lack of suffi-
cient stored photosynthate. This drop in expected growth rela-
tive to temperature is producing a highly significant proxy for
sea ice cover. Using the straight-line (GOM to southern Labra-
dor) part of the yearly growth curve with the greatest amount of

information (Figure 22), converted to monthly rates and plotted
against the regional temperature curves (Figure 23A), monthly
regional growth curves can be derived (Figure 23B). Total yearly
growth and the rate of conceptacle maturation (based on the
regional height requirement for maturation) can then be summed
from the monthly rates. The latter match the data presented in
Table 1. Although laboratory-produced growth rates for Clath-
romorphum compactum are not yet available, those for C cir-
cumscriptum (Adey, 1970, 1973) suggest that at temperatures
below 5°C-6°C, temperature (and not light) is the primary en-
vironmental factor controlling vertical growth. Monthly growth

24 e© SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

FIGURE 18. Shallow-water habitat (3-5 m), with young (estimated 60 years old),
mound-forming plants of C. compactum in NE Newfoundland. Some plants are

strongly faceted (right arrow); others are more dome-shaped without facets (top arrow).

Several plants are fusing and with time will develop clathrostromes. The branching red

coralline is Lithothamnion glaciale (left arrow). Image by Alok Mallick.

rate as a function of temperature fully explains differences in
both mean yearly thickness and conceptacle maturity time for
C. compactum from the Gulf of Maine to Labrador and for C.
nereostratum in the North Pacific. Since detailed temporal con-
ceptacle development data are not available for C. nereostratum,
approximate temperature-growth curves are presented, but con-
ceptacle development is not included on the graph. On the basis
of a comparison with Gulf of Maine data, conceptacle matura-
tion of C. nereostratum in the North Pacific should be similar
to, but a little slower than, that of C. compactum in the Gulf of
Maine. Field data from the Aleutian Islands are inadequate to
fully verify this hypothesis.

WALL STRUCTURE AND CALCIFICATION

As demonstrated by Adey (1965) for C. compactum and
by Lebednik (1976) for C. nereostratum, all perithallial growth
and calcification in Clathromorphum occurs in the primary
meristem. Herein growth and calcification are shown to occur
along a narrow horizontal plane through the meristem (Figures
17, 24). With no bridging calcification (perithallium to epithal-
lium), a fracture plane can be easily induced. Although a sec-
ondary meristem can form within broken-out conceptacles or
on damaged surfaces (in the uppermost perithallium), the pri-
mary meristem produces most of the calcified tissue. As shown
in Figures 16A,B, 17B,D, and 24B and unlike other genera of

corallines (Adey et al., 2005), the interfilament calcite crystals in
Clathromorphum are larger and more irregular than the inner-
wall crystals; the latter are short, prismatic, very fine, and ori-
ented radially. The interfilament crystals are oriented vertically
or diagonally and tend to be deltoid in shape. The thickness of
the radial, inner-wall crystals remains largely unchanged season-
ally, whereas interfilament calcification is thick in summer and
absent or thin and irregular in winter. This pattern also occurs
in the naturally etched surfaces of bivalve-bored cavities, where
the layers form ridges in the summer and grooves in the winter
(Figures 19, 20).

In decalcified sections (Figure 8E), epithallial filaments,
lacking cell fusions, often disaggregate. In perithallial tissues, the
filaments are mostly cohesive because of the fusions organically
linking adjacent filaments. Nevertheless, between the fusions and
in the cells below the meristem where fusions are lacking, fila-
ments can locally disaggregate since there is no common inter-
filament wall. In the perithallium, inner calcified cell walls are
organically framed, whereas the space between the filaments is
apparently devoid of organic material and may or may not be
filled with carbonate, depending on the season. It has been widely
accepted that calcification in corallines is “simple” precipitation
resulting from removal of CO, during photosynthesis, with or-
ganic nucleation centers specifying calcite rather than aragonite
(Ries, 2010; however, see Adey, 1998). This is highly unlikely in
Clathromorphum species of Arctic and Subarctic seas because as

NUMBER 40. e

| EHT= 10.00 kV WD = Output To = Default Printe é ve Oupetto-
MAG = 3.00 K X | Prob Cycle Time = 39.2 Secs | i Cycle Time = 39.2 Secs HI

FIGURE 19. Images from Hiatella-etched cavities in C. compactum from southern Labrador. (A) Ten years of growth with ridges and
valleys for each year (summer, top arrow; winter, bottom arrow). (B, C) Surface of summer-fall ridge showing dense interfilament crystals
(vertical arrow) maintaining structural integrity (horizontal arrow in C shows inner radial crystals). (D) Winter valley showing the break-
ing out of minimal interfilament crystals (horizontal arrows) and the integrity of individual cells and their organic radial-crystal-embedded
walls (vertical arrow). (E) Oblique view of the ridge side, showing the intermediate breakdown stage and the great difference between fine
inner-wall crystals (vertical arrows) and large, angular interfilament crystals (horizontal arrows).

25

26 © SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

zt
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FIGURE 20. Sections of C. compactum from nearby stations in northern Labrador,
off Nain, over a single year of growth, showing two summer bands (arrows) of
dense interfilament calcification separated by a wide band of winter cells having
little interfilament calcite. (A) Etched wall of a Hiatella cavity, 9-11 m depth at Jenks
Island. (B) Vertical fracture of a plant from Baker Island, 12-14 m depth. These
yearly bands are not of the same age; B shows a year with 20% more year growth

than A, as arrows indicate.

has been shown (discussed further below), they can continue to
grow and calcify for at least part of a sunless winter. (Laboratory
studies underway also show repairs to damage of the perithal-
lium with growth in total darkness; Adey et al., unpublished).
Moreover, in Labrador and the high Arctic, where clath-
rostromes lie 10-30 m deep under several meters of sea ice and
snow for 6-10 months of the year, winter calcification driven
directly by photosynthetic CO, removal seems unlikely. The
pattern of inner-wall calcification remains seasonally constant,
changing only in cell length and requiring only additional radi-
ally placed integral crystals of the same form. As suggested by
Adey (1998), inner-wall crystals in corallines are likely nucleated

on organic templates and metabolically emplaced by ion pumps
in cell membranes. If so, rather than being diffusely distributed
over the length of the meristem cell and into upper perithallial
cells, these carbonate additions occur in a plane in the meristem
(i.e., a ring around the “middle” of each cell). On the other hand,
interfilament calcite formation in northern waters, strongly tied
to summer tissues, could result from precipitation as a result of
photosynthetic CO, removal by the epithallium. This remains to
be determined in laboratory studies.

Clathromorphum spp., along with many coralline genera,
not only have a considerable ability to turn calcification on and
off (for example, in conceptacle formation) but are also broadly

capable of dissolving already emplaced carbonate. In the concep-
tacle fertile cylinder, during the formation of sporangia from the
meristem, carbonate is not laid down in the cell walls of intra-
sporangial filaments; 100 pm away in the vegetative tissue, nor-
mal calcification continues to occur. As sporangia enlarge, they
are able to dissolve a large volume of cell wall carbonate in the
surrounding and underlying vegetative tissue. These decalcified
tissues are crushed by the final enlargement of sporangia prior to
spore formation. Later, after spores are released, the thin, empty
sporangial walls become calcified (Figures 12B, 13A). Likewise,
the inner walls of meristem cells and the interfilament space are
(in summer) emplaced in the meristem fracture zone with car-
bonate; when cut off by cell division, this carbonate joins the
underlying perithallium. Then, two to five cells into the perithal-
lium, passages (fusions) are excavated out of calcified cell walls,

500

NUMBER 40 e 27

laterally, to join the lumina of adjacent cells. Especially in the
autumn, when sporangia begin development, these fusions may
extend laterally for several cells (Figure 11B). Although the num-
ber of fusions varies considerably at the autumn “break,” when
sporangial formation is initiated, they are often so abundant
that they develop a plane of weakness that fractures horizontally
when breaking stresses are applied when creating fracture sec-
tions (Figure 11A).

Where bivalve boring (and carbonate etching) and deeply
grooved sea urchin grazing occur, breaking the “seal” of living
tissue over dead carbonate, alteration of carbonate chemistry is
likely. These diagenetic zones have ecological signatures, often
with the formation of epi- and endophytes on the dead crust. Also,
in thick clathrostromes, occasional fractures develop because of
wave or moving substrate stresses. Alteration of carbonate along

—s— Regional Means

400 = Specimen means

= 14 N (number of Measurements)

=e

co)

©

~ 300

Pex

= i3

Oo

:

© 200 ;

>.)

=_ 24 1

© 18 18

Ne 40 14

100 16m 9 os
a
5
.
GOM NENFS.Lab. N. Lab. Arctic Bay

42 44 46 48 50 52 54 56 58

60 62 64 66 68 70 72 74

Latitude (°N) and Subregion

FIGURE 21. Clathromorphum compactum. Regional yearly crustal accretion of haphazardly selected specimens and years as a function of
latitude in the northwestern North Atlantic, Labrador Sea, and Arctic Bay, northern Baffin Island. The red squares are individual specimens.
In Newfoundland (NF) and Labrador, each data set included one sample from Hiatella-etched burrows; otherwise, data are from analyses of
conceptacle layers on SEM mosaics.

28 e© SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

500

14

400

300

25
12

200

Yearly Growth Rate (um/yr)

100

8 7 6 5

—s— Regional Means
16 @ Specimen means
N (number of Measurements)

N.Lab. °

S. Lab. Arctic

3 2
Yearly Mean Temperature (°C)

(by region)

FIGURE 22. Growth rate of C. compactum (red) and C. nereostratum (blue) as a function of mean yearly ambient temperature. The regional
temperature derivation is described in the Figure 23 caption. The downturn in the curve on the right is due to the length of winter sea ice (Halfar,

unpublished data).

such fractures is sometimes clearly visible in SEM images. Gener-
ally, such alteration occurs only near damage sites and is easily
detected and avoided. As older clathrostromes are discovered, it
will be necessary to carefully examine the oldest part of the coral-
line carbonate for potential diagenesis.

ECOLOGY AND GEOMORPHOLOGY

The 2010-2011 cruises to Labrador demonstrated that outer
coast islands can provide localized optimum conditions (Figures
2A,B, 25A,B) for the development of clathrostromes of Clathro-
morphum compactum. On the leeward sides of these islands and

especially on the more protected parts of outer coast island com-
plexes, where wave exposure is moderated, clathrostromes are
often well developed. Particularly, where stable bedrock shores
have a minimum overburden of glacial till (avoiding wave tools)
yet have enough wave action to seasonally limit sea urchin graz-
ing, an optimum environment for carbonate production in C.
compactum is present. Low-lying, domed bedrock islets lacking
the high cliffy shores that could shed falling boulders and cobbles
onto the underlying shore can have particularly well-developed
clathrostromes. Moderately steep bottoms of cobbles and large
boulders that limit downslope movement create the optimum
conditions for preserving clathrostromes for many centuries.

NUMBER 40 e 29

13
12 GOM
11
Yi
10 Central
9 Aleutian
8 |stands
7 NE NF
7 6 :
O 5
,
eB: O 4 S. Lab
=
(ob) 3
aa 2
1 Sj
ine
0 Fits
-1

A 2 a

Aug Sept Oct Nov Dec Jan Feb Mar Apr May Jun Jul Aug

50
45 4Go
40
C. nereo
35
oD GOM yr mn
230 {NENF a
fe
= 325
5 S Lab
20 iad ig iscnnmnniabenenin ofan NN NENG m
xpandmatur ot. yr 240.1 um
2 eS ee eee ee ne see “yexpan& mature _
15 fo I Lab yr mn
tot yr 184.5 um
10 a =

5
B Aug Sept Oct Nov Dec Jan Feb Mar Apr May Jun Jul Aug

FIGURE 23. Model demonstrating regional temperature control of monthly growth in thickness and reproductive maturation in C. compac-
tum, using the yearly temperature curve of Figure 22 (see text for complete description). (A) Regional temperature at 12-17 m depth for coastal
waters (the Gulf of Maine from Gulf of Maine Ocean Observing System buoys, mean of Penobscot and eastern shelf buoys, 2 and 20 m, 2011
data, -1.0°C for samples from 1960s) and southern Labrador and NE Newfoundland summer data from 1964 and 2003-2011 cruises of the
R/V Alca i, with winter estimated as —1.5°C when sea ice was present (from U.S. Navy Hydrographic Office Sailing Directions). (B) Expected
regional monthly growth rates derived from the curves in A and Figure 22, summed for yearly means. The expected time of conceptacle develop-
ment based on 100-ym perithallial growth to reach expansion phase and | month for expansion and 1 month to maturity. Dashed horizontal
lines are conceptacle development time. Clathromorphum nereostratum curves are added for comparison, but conceptacle development is not
shown (see text).

30 e SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

26 May 2011 Time :152
put To = Default P
"

3 ix
Date 6 May Time :14:48:0
‘Output To = Default Printe:
Cycle Time = 39.2 Secs

FIGURE 24. Meristem fracture and calcification zone in a specimen of C. compactum from southern Labrador for comparison with

C. nereostratum (Figure 17). (A) The meristem (arrow to the right) shows fracturing in the calcification zone. The conceptacle formed the
previous fall and winter, with expansion down into the previous summer band. A new meristem formed over roof but has not yet filled
the depression in the epithallium (see Figure 9B). (B) Fracture zone in the meristem. (C) Fracture zone in the meristem opened up to reveal
distinct interfilament grooves (precipitation cavities?) between meristem cells (arrows). (D) Meristem fracture zone (in summer) looking
into the perithallium. Dense organic material covers the inner-wall crystal band, with interfilament crystals having no organic cover.

Hiatella arctica, a boring bivalve, is the chief biotic com-
ponent responsible for degrading and limiting Clathromorphum
compactum buildup in the northwestern Atlantic. Hiatella arc-
tica also occurs in C. nereostratum in the North Pacific (Che-
nelot et al., 2011), but it is overshadowed by an abundance of
other invertebrate infauna. Hiatella arctica must gain access to
the C. compactum crust during settlement at a growing coralline
margin or following sea urchin grazing or other injury. The inter-
calary meristem, with an epithallium subject to constant chiton
grazing (and more occasionally sea urchin and limpet grazing),
prevents most invertebrate and seaweed recruitment. When re-
cruitment of several coralline species has been optimal, entirely
covering a rock surface with coralline carbonate, and when sea
urchin grazing is limited, H. arctica recruitment is minimal.

Thus, there is an inverse relationship between the success of
C. compactum and H. arctica; when the factors supporting strong
clathrostrome development are optimal, boring by H. arctica is
most limited. Burial of the base of old C. compactum mounds by
accumulating fine sediment can also create anaerobic zones that
prevent further Hiatella boring. Under these conditions, continu-
ous carbonate accumulations exceeding 1000 years can develop
(Adey, unpublished).

Lithothamnion lemoineae, a branching coralline species,
has an ecology similar to that of Clathromorphum compactum.
Although generally less abundant, it is an integral component of
northwestern Atlantic clathrostromes. Lithothamnion lemoineae
is a particularly important component of clathrostromes in that
it often “seals” the sides of C. compactum mounds, thereby

limiting Hiatella access. In the more protected bays and fjords of
inner coasts, C. compactum is considerately less abundant and
often absent. Where lower salinities and higher sedimentation
are present, Lithothamnion glaciale becomes the dominant cor-
alline species of northern rocky bottoms.

In the northwestern Atlantic, Clathromorphum com-
pactum is most abundant, relative to other corallines, at mid-
photic depths (10-20 m; Adey 1965, 1966b). We have developed
a clathrostrome index utilizing the number of samples from
each station depth, the mean thickness of collected samples,
and the maximum single-sample thickness as an indicator of

FIGURE 25. (A) Typical boulder slope on low islands in northern
Labrador (at 25 m depth). Rock surfaces covered with coralline
crust dominated by C. compactum. Large, angular, sheet-fracture-
produced boulders protect glacial cobbles and small boulders from
downslope movement. (B) Diver with 105-mm-thick clathrostrome
extracted from the same locality. At a summer temperature of 5°C-
8°C, the growth rate of this crust was about 130 pm yr‘, with an
age exceeding 800 years.

NUMBER 40 e 31

clathrostrome development (Figure 26). Since all collections
(2010-2011) were taken by a single individual and dives were of
a uniform length, the number of samples (N) taken at each sta-
tion depth are an indicator of the abundance of thick material.
As shown in Figure 26, for southern Labrador, clathrostrome
buildup also tends to peak at optimum abundance depths and
at mid-wave exposures. This is generally below the shallower
Alaria kelp zone but within the Agarwm savanna (Adey and
Hayek, 2011), from 10 to 25 m. In northeastern Newfound-
land and the northern Gulf of St. Lawrence, where the water
is generally more turbid, peak clathrostrome development oc-
curs at shallower depths (5-10 m). The thickest C. compactum
collected in the northwest North Atlantic to date were taken
off Hopedale, Labrador, in the summer of 2011. Several crusts
exceeding 100 mm in thickness were found.

TISSUE IRREGULARITY

Under some conditions, the perithallial tissues of Clath-
romorphum compactum and C. nereostratum, as produced
by an essentially planar (faceted) or domed meristem, can be
quite regular. However, grazing by sea urchins, death due to
disease, and grow-out from damaged postmature conceptacles
can change not just cellular orientation but also planar tem-
poral variations in seasonality and therefore calcite crystal
chemistry. When the meristem and upper perithallial tissue
are removed by grazing or other abrasion, meristem regenera-
tion is possible, approximately to level of the base of the most
recent layer of conceptacles (200-500 pm deep). While wound
tissue tends to repair these irregularities, in large part, it is this
meristem regeneration on an irregular surface, rather than on
a planar or domed surface, that renders archiving potentially
problematic.

The most difficult scenarios for climate archiving are the
removal of calcified tissue and the death of the meristem and
upper perithallium to below the level at which cells are capable
of meristem regeneration. In the clathrostrome environment,
this “dead” surface is for a time occupied by other crustose or
filamentous species of algae, boring algae, and encrusting inver-
tebrates. Eventually, the dead surface is likely to be overgrown
by new Clathromorphum tissue from the sides or in some cases
by new spore settlement. However, several years may intervene,
creating a disconformity or even an unconformity of unknown
longevity. By matching several seasonal bands or patterns in ad-
jacent perithallium or other plants or by dating, it may be pos-
sible to fill in such unconformities.

Chiton Grazing

In the northwestern North Atlantic Subarctic, chitons and
limpets are prominent grazers of Clathromorphum compactum
surfaces. Chitons, particularly the species Tomicella rubrum, are
ubiquitous on coralline surfaces, especially those of C. compac-
tum. Collected specimens of C. compactum, left to dry, usually
reveal many small animals that were not visible at the time of

32 SMITHSONIAN CONTRIBUTIONS TO THE MARINE §S

collection; these mostly nocturnal invertebrates crawl out of nu-
merous crevices and borings in the drying crusts. The shallow,
parallel, scraped groove patterns of chiton grazing are abundant
and easily visible in SEM images of C. compactum surfaces (Fig-
ure 9). However, chitons rarely affect the regularity of carbonate
buildup since they graze only the surficial part of the epithal-
lial tissue; indeed, like grazers of grasslands, chitons are prob-
ably nearly symbiotic in their relationship to Clathromorphum
plants, preventing settling by organisms, algal or invertebrate,
that otherwise might cover the surface (Steneck, 1992).

Sea Urchin Grazing

Strongylocentrotus droebachiensis, the green sea urchin, is
an often-abundant species on most shallow rocky shores in the
northwestern North Atlantic. Like Clathromorphum, the echi-
noid S. droebachiensis is a member of a North Pacific group (the
Strongylocentrotidae) and is circumboreal in distribution, North
Atlantic and North Pacific. In the Bering Sea, additional species

CIENCES

of Strongylocentrotidae join with S. droebachiensis. These spe-
cies are typically grazers of brown seaweeds, including Alaria,
Saccharina, Laminaria, and Chordaria, where they are avail-
able. Green sea urchin grazing can be strongly limited by wave
action in exposed, shallow waters, and they are known to move
to deeper waters in winter to avoid the more destructive wave
action common at that time of the year. Controlled by shallow-
water wave action, they will aggregate into “fronts” or lines and
can graze into the margins of shallow kelp beds, reducing the kelps
to stubble or “barren grounds.” However, S. droebachiensis will
actively avoid some common algae of northern Atlantic regions
(e.g., Agarum, Desmarestia, Ptilota) because they are protected
by distasteful or toxic chemical compounds. At the depths where
C. compactum is most abundant and well-developed clath-
rostromes are most common, it is these protected species of fleshy
algae that form the overstory; these species create a patchy “sa-
vanna” of coralline alternating with fleshy algal forests that have
been mistakenly referred to as coralline-urchin barrens. Strongylo-
centrotus droebachiensis, at moderate density but with insufficient

Clathrostrome index (N x mn + max)

WAVE

<= EXTREME

Balanus balanoides
Saccorhiza dermatodea

Nas

oO

"orate

\ G at ee selene ° ili

minaria 0 Wg
° digitata (|: [( y

cant .

"—~Ptilota serrata :
; oa

’

( Varn
Turnerella
pennyi

\
sediment bottom
gravel mud

ss Bes + baa
prawns
Be 56.0 0 p%

2000900 090

EXPOSURE
MODERATE

Fucus vesiculosus
dees distichus

Desmarestia
viridis

Paco)
° v 7

i (e)

Agarum clathratum Ke (
\~?
Saccorhiza Pe
Soreness ,
Saccharina longicruris

and S./atissima

FIGURE 26. Clathrostrome index for the southern Labrador coast (see text for explanation of formula) from the 2010
cruise of the R/V Alca i. The base diagram is a community structure model for western Atlantic Subarctic rocky shore

from Adey and Hayek (2011). Abundance and thickness of C.

exposed shores. LWST = low water spring tides.

compactum crusts peak from 12 to 20 m on moderately

algal food, can survive by severely slowing their growth and can
even become reproductive on overgrazed coralline bottoms (see
Adey and Hayek, 2011, for a review of this topic).

In the northwestern Atlantic, when larger fleshy algae are
not available, large populations of very small green sea urchins
can subsist in crevices, without growth, on diatom and filamen-
tous algal mats (Himmelman, 1986). Coralline-dominated bot-
toms, including clathrostromes, usually harbor populations of
young urchins that can survive for many years awaiting more
favorable feeding conditions. This is an unstable situation, and
although very small “standby” urchins are not likely to signifi-
cantly affect the growth and anatomy of Clathromorphum com-
pactum, population explosions leading to larger urchins, with
transitory fleshy algae for support, can do considerable damage
to C. compactum plants. Occasionally, adult green sea urchins
will graze surfaces of C. compactum. Although the sea urchins
typically remove only scattered patches or grooves of coralline
surface that will be regenerated, this grazing can create an irregu-
lar terrain of secondary tissue. When sea urchin grazing is very
extensive, reaching below the regenerative surface band, an un-
conformity will develop. Usually, this surface is overgrown again
from the side, beginning with new basal, or hypothallial, tissue.
The result can be several years of missing carbonate. Sometimes
this is obvious (Figure 2B) because a layer of epiphytes and en-
dozoic green algal borers, or even other corallines, have settled;
however, if the missing periods are not recognized from SEM ob-
servations, the resulting archive can be seriously misinterpreted.

Conceptacle Breakout

Typically, during post reproduction and after spores are re-
leased, cells at the margins of the conceptacle roofs, or the roof
itself, will regenerate meristem cells (Figures 9, 10, 12B). This
leaves conceptacle cavities often with secondary calcification in
the sporangium walls; these are quite visible and easily avoided
during geochemical analysis. However, in some cases, a con-
ceptacle roof can break out, either autonomously or because of
grazing. When that happens, secondary meristems form, and
new tissue from the sides and bases of the conceptacle cavities
develops (Figure 12B). The accompanying cellular carbonate,
although showing a minimum pattern disruption, is formed
many months later than the surrounding carbonate. This can
be hard to recognize without SEM examination.

Death Due to Disease

Killing disease has been documented in corallines (Littler and
Littler, 1994) and has long been recognized in Subarctic waters.
Typically seen as white, expanding patches with green centers (as
epiphytic and endophytic algae occupy the dead crust), these patches
are usually no more than a few to 10 cm in diameter. However, they
can expand to a meter or more. Generally, when the patches are
small, they are regrown laterally by secondary hypothallium; in the
case of larger patches, resettlement probably occurs. Sometimes,

NUMBER 40 e 33

grazing by green sea urchins on the epiphytic and endophytic sec-
ondary algae in the dead patch can remove several years of Clathro-
morphum carbonate accretion. This can develop an unconformity,
with new growth layers not being parallel to the pre-disruption lay-
ers; the number of missing layers would have to be documented by
matching of cyclic patterns or cross dating.

DISCUSSION

We have described the patterns of growth, reproduction,
and layered carbonate formation, the intricacies of calcifica-
tion, and the basic ecological patterns for the most abundant
Subarctic-Arctic Clathromorphum spp. This description provides
a framework for increasing our understanding of a key element
of a widespread and characteristic ecosystem and its basal bio-
genic carbonate component. The structure of the overlying fleshy
seaweed community in the northwestern Atlantic, characterized
with quantitative data and supported by many published studies
of plant-animal interactions, has been summarized by Adey and
Hayek (2011). Although ecological studies of the Subarctic fringe
occurrence of this ecosystem in the Aleutian Islands have been
published (e.g., Steneck et al., 2002; Springer and Estes, 2003;
Estes et al., 2005; Trites et al., 2007; Chenelot et al., 2011), the
information for the northwestern North Pacific and for C. nereo-
stratum is more fragmentary. A better understanding of the aut-
ecology of C. nereostratum in the Aleutian Islands and the island
and mainland coasts of the Bering and Okhotsk Seas is necessary.

CLIMATE ARCHIVES

The information we have presented can also provide criti-
cal support for further development of already promising Arctic-
Subarctic climate archives from both C. compactum and
C. nereostratum. In the skeletons of these species, there is po-
tentially a wealth of ecological and water state (climate) infor-
mation available in the complex formation of yearly layers of
carbonate-encased cells and reproductive structures. Also, there
is no known biological limitation, inherent in the coralline struc-
ture itself, to the preservation of the information built into the
carbonate, although the high-magnesium calcite itself is relatively
unstable and subject to later diagenesis. Given geographic iden-
tification of sites with the geomorphological and oceanographic
conditions that produce long-term continuous accumulation of
carbonate, more than a thousand years of detailed subannual
ecological and climate information can be obtained. Data de-
rived solely from anatomical features not degraded by chemical
alteration (e.g., thickness of yearly bands) could extend the ar-
chive considerably further. Recovery of specimens transported to
sedimentary environments could also produce records of longer
duration. However, as we have described, the complexity of the
Clathromorphum skeleton is such that considerable care needs
to be taken to understand the details inherent in the anatomy of
this genus if analytical variation is to be separated from environ-
mental variation.

34 e¢ SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

MECHANISMS OF CALCIFICATION

The mechanisms of calcification in Clathromorphum also
need to be fully understood with intensive laboratory research if
sources of measurement variation are to be removed from these
archives. In this genus multiple calcification sites and autogenic
dissolution are general capabilities of the organism. Whether
secondary calcification (e.g., sporangial wall calcification) is
metabolic or, as is more likely, simply carbonate chemistry in
the mostly enclosed conceptacle cavity environment remains
unknown. Although the precise chemistry of carbonate disso-
lution by both vegetative cells (fusions) and sporangia remains
unknown, there is little question of its routine occurrence. This
is also true for the interfilament (outer cell wall) formation of
calcite crystals, although a role for light in directly controlling
chemistry seems possible in this case.

As we noted in the Introduction, all coralline genera have
cell walls with prismatic, high-magnesium calcite crystals in-
serted in the cell wall perpendicular to the cell lumen. Since
cell elongation in some genera is progressive with depth in the
perithallium and in many genera each filament has independent
cell division and growth, cells have a very thin outer wall of flat
crystals parallel to the filament axis that functions as a glide
plane (Adey et al., 2005). On the other hand, two very different,
concurrent mechanisms for calcification in Clathromorphum are
distinguished in this volume. Although developed specifically
on the basis of the abundant information available for C. com-
pactum, there is little obvious difference found in the tissues of
C. nereostratum. Primary calcification is likely an ion pump—
driven process that forms inner cell walls that include high-
magnesium calcite crystals. These crystals are embedded in an
organic matrix that provides a mineralogical template. At winter
temperatures (0°C to -1.8° C) on the southern Labrador Coast,
cells of C. compactum are typically 9-10 jm long; at summer
temperatures (3°C-4°C), they are longer (12-13 jm) and have a
length-based increase of inner-wall carbonate volume.

The production of new inner cell walls with calcite crystals
appears to be directly controlled by temperature; the higher the
temperature is, the greater the vertical extension of the organic
wall is. Vertical extension (growth) occurs with crystal emplace-
ment in the inner-wall matrix of a meristem cell, along with or-
ganic wall material. In the Labrador winter, not only is there a
roughly 20% reduction in cell length, there is also an approxi-
mately 30% reduction in the number of cells produced per month.
These factors are reflected in the 60% reduction in yearly growth
from the south northward on the North American coast and a
further 75% reduction continuing northward to northern Baffin
Island (Figures 21, 22). The thickness of inner cell walls, with
their embedded prismatic calcite crystals being radially oriented
and less than a micron in length, is constant with temperature,
light, and time. It would appear that Clathromorphum species
and perhaps crustose corallines in general have “boxed” them-
selves into a carbonate framework that is limited by temperature
control of metabolic calcite crystal emplacement and not by po-
tential productivity. If the growth curve of Figure 22 is extended

to a tropical temperature of 25°C, yearly accretion would be 1-2
mm yr', approximately the rate of algal ridge accretion in the
Caribbean by Porolithon pachydermum (Adey, 1978).

Except for a few obligate parasites, crustose corallines are
photoautotrophs with plastids, chlorophyll a, and phycobilipro-
tein pigments; photosynthesis is required at least at some point
in a plant’s life cycle. Whereas Adey (1998) had presented a
model for crustose coralline calcification that is driven by ion
pumps, some recent researchers (Ries, 2010) have suggested
that all calcification in corallines is directly driven by the pho-
tosynthetic removal of CO, followed by a corresponding pH
increase and chemical precipitation. The calcified tropical green
algae Halimeda is a well-published model for CO, removal-
induced aragonite formation in enclosed algal tissues. However,
as we have described, at least in Clathromorphum, where winter
growth in Arctic darkness and additionally beneath sea ice is a
significant part of total calcification, the formation of high-
magnesium calcite crystals must be metabolically driven using
stored photosynthate.

Precipitation might be the dominant form of calcification in
non melobesioid tropical genera of corallines, which have been the
subject of most calcification research. However, a survey of high-
magnification SEM scans of several tropical genera has shown
that inner-wall calcification morphology is quite similar to that
described here. It is likely that other Arctic-Subarctic genera (e.g.,
Lithothamnion and Leptophytum), which lack significant interfila-
ment calcification (see Adey et al., 2005), also calcify metabolically,
not only during the dark of Arctic winters but also year-round.

PRIMARY PRODUCTION AND GROWTH RATES

Crustose corallines, particularly at higher latitudes, are very
low-level primary producers (Adey, 1970, 1973) and commonly
are the deepest abundant algae at all latitudes. In laboratory ex-
periments, Clathromorphum circumscriptum, an intertidal and
shallow sublittoral plant, demonstrated a compensation point
of 35 lux at 0.3°C; at the highest temperatures usually encoun-
tered by this species (10°C-16°C), the compensation point was
200-300 lux. In the same experiments, the deeper-water Subarc-
tic Leptophytum leave showed compensation points at optimum
growth temperatures (5°C-12°C) of 35 lux. Both C. compac-
tum and C. nereostratum are mid-depth species. It is likely that
the compensation points at the temperatures that both of these
species encounter range from approximately 10 to 50 lux. As
we demonstrated above, the growth rate of C. compactum in
the northwestern Atlantic ranged from roughly 100 to 400 pm
yr! latitudinally; our analysis suggests a direct relationship with
temperature. One could argue that light could also be a factor
over that north-south range. However, Gulf of Maine waters are
highly turbid because of tidal mixing; also, in the years that WHA
collected the Gulf of Maine samples from which the growth data
were extracted, Saccharina kelp was abundant in most C. com-
pactum habitats. In contrast, the Labrador C. compactum sam-
ples used for growth analysis were taken from very clear waters,
with near-tropical visibilities, and from savanna-like habitats of

Agarum clathratum (Adey and Hayek, 2011), with mostly open
C. compactum terrain. Laboratory experiments to confirm this
analysis are now underway; however, it seems unlikely that light
variation is a significant direct growth rate factor in the mid-
depth range of C. compactum and C. nereostratum.

There is no anatomic or reproductive indication that growth
in C. compactum ceases during low temperatures. Growth ex-
periments currently underway have shown at least short term
growth in total darkness at 2°C. Also, growth curves suggest
that under the null light conditions below sea ice in northern
winters growth continues for a short period. Figure 27 shows a
10-year mean plot of molar Mg/Ca in four C. compactum crusts
collected off Quirpon in northernmost Newfoundland. These
data were derived from equally spaced points in vertical sec-
tions. Here sea ice usually arrives along the coast in late January
and remains until sometime in early April, when temperatures
are near or below -1°C (Figure 23). The cold and warm peaks
are virtually symmetrical, both occurring at midlevels of solar
radiation, making this a temperature proxy with little direct
light component. Farther north in northern Labrador and Baffin
Island, these curves are quite asymmetric, suggesting that with
much longer sea ice intervals (December—June), growth stops be-
cause of a lack of sufficient stored photosynthate.

0.12
0.10
10 year mean

Cl 1998-2007
2
—
ro)
= 0.08
D
=

0.06

NUMBER 40 e 35

INTERFILAMENT CALCIFICATION

The large and coarse interfilament (outer wall) crystals ap-
pear to be growing downward (perithallium) and upward (epi-
thallium) from the fracture plane between meristem cells (Figure
28). It seems likely that these crystals are precipitated in the
small cavities that ring each filament in the meristem calcifica-
tion zone, perhaps because of removal of CO, by the overlying
photosynthetic epithallium. From decalcified paraffin sections
and SEM imaging of the meristem fracture zone, it seems likely
that no organic material is present in this interfilament area. This
process could involve a secondary mechanism of ion pumps de-
livering calcium ions to and removing hydrogen ions from the
interfilament spaces of the fracture zones. However, the meristem
fracture plane is directly below the primary photosynthetic tis-
sue of these plants (epithallium), and the overlying carbonate
(within the epithallium) appears to be made up of large, but thin,
vertical sheets that likely provide a quite porous connection to
the water at the surface of the plant. Also, in the Labrador Sea,
the perithallium interfilament crystals are only formed during
summer in any significant quantity. Thus, the interfilament wall
component could represent the CO, removal and carbonate for-
mation suggested by Ries (2011).

+
ep)
1)

month

FIGURE 27. Ten-year mean molar Mg/Ca from four C. compactum specimens taken off Quirpon, northern

Newfoundland (sample QP4-3; see text). See curves for the Mg/Ca molar ratio (proxy for temperature) in

Figure 3.

36 e¢ SMITHSONIAN CONTRIBUTIONS TO THE

Zone of

Calcification

Ll,

—_—
=> >

uli,

SS
AUT

Wn)

—=SDSS>

Summer

ANN

—

Dy

AS

interhlament
crystals

lumina or
innerwall crystals
Y

Perithallium Cells

Winter

TW

eg

}

™—

/NN)

l

—-

)

—_

eS

> = —<—

MARINE SCIENCES

organic
epithallium

=

epithallium cell

7 ~
a —

DANONE

meristem
fracture
plane

meristem cell

5 um

FIGURE 28. Working model of calcification in C. compactum. Inner-wall crystals (short, prismatic crystals perpendicular to the filament axis)
form in the meristem (fracture) plane within an organic matrix and form year-round at the same dimensions; increasing numbers of calcite
crystals and their organic matrix (longer cells) and production of a greater number of cells produce increased growth. Note the organic wall
extending across the inner-wall crystal zone but not extending into interfilament space. Interfilament crystals (large, angular crystals parallel or
diagonal to filament axes) formed, primarily in summer, in nonorganic space between filaments. Interfilament crystals extend upward into the

epithallium and are thinner and flatter.

The seasonal formation of these crystals, narrows the cell lu-
mina (since the inner-wall crystals remain the same length), and
typically creates the summer high carbonate density and character-
istic seasonal banding obvious in many Clathromorphum plants.
However, development of this banding, which is partly dependent
upon available sunlight, is complex. In the southernmost locality
known for C. compactum in the Gulf of Maine, where sunlight
is present in winter, seasonal banding tends to be weak because
some interfilament crystals form year-round. In northern New-
foundland, with less winter sunlight, the banding tends to be more
pronounced. However, in the western Labrador Sea, where sea ice
forms in midwinter and remains through a large part of the spring,

the return of sunlight is greatly delayed, and the summer band of
high density is very narrow (Figure 20). On the other hand, in
deeper water in the same region, at the lower extent of the C. com-
pactum range, peak summer temperature and maximum growth
occurs in October, whereas light peaks earlier in June, at nearly the
minimum water temperature. Thus, whereas high carbonate den-
sity corresponds approximately to high growth rates and long, nar-
row cells over most of the range of both Clathromorphum species,
under some environmental conditions, the reverse occurs, with
maximum density (due to interfilament formation) coinciding with
short cells formed under low temperature. In the Aleutian Islands,
C. nereostratum often has very strong seasonal banding,

presumably related to the intense storminess and heavy cloud
cover of late winter and spring.

One of the difficulties of potentially mapping yearly layers
solely from changes in carbonate density (due to interfilament
crystallization that is directly photosynthesis driven) is that inter-
filament crystallization is directly responsive to the light regime.
Although light tends to parallel temperature, ecological varia-
tion in the availability of light is extensive; perhaps more criti-
cal, shading by sea ice and snow cover on the Labrador Coast
and farther north greatly delays the return of light in the spring.
Although the winter temperature in shore waters at 10-20 m is
little different from northern Labrador (0°C to -1.8°C) to the
Gulf of Maine (0°C-1°C), the winter solar radiation under the
sea ice in northern regions is nil and is greatly reduced until at
least May, whereas in the Gulf of Maine and the Aleutian Islands,
solar radiation is considerable throughout the winter. In southern
Labrador, in shallow water (8-12 m), the period of significant
interfilament crystallization is mid-May through mid-September.

CONCEPTACLE-BASED GROWTH ANALYSES

As shown in Figures 2B and 12B, reproduction, especially
in C. compactum, can be patchy in time and space, limiting the
use of simple conceptacle-based analyses in archiving. Also,
damage to and even loss of yearly perithallial tissue from urchin
grazing and other physical factors commonly disrupts simple
seasonal layering. However, SEM imaging and mapping, accom-
panied by SEM-matched microprobe analysis, not only solves
this problem but concurrently increases ecological and climatic
discrimination. Laser ablation-inductively coupled plasma—mass
spectrometry (LA-ICP-MS) has been successfully employed on
C. compactum and C. nereostratum to detect changes in Mg/
Ca (for temperature) and Ba/Ca (for salinity; Gamboa et al.,
2010; Chan et al., 2011; Hetzinger et al., 2011), although with
considerable unidentified variability (Figure 3; Gamboa et al.,
2010; Williams et al., unpublished). Kamenos et al. (2008) have
employed microprobe and LA-ICP-MS methods for identifying
Mg/Ca variation with time, and herein extensive SEM imaging
has identified structural and reproductive complexities. It seems
likely that SEM mapping of laser tracks, with parallel micro-
probe sensing wherever anatomical complexities appear, could
resolve most of the variation inherent in plant structure. This
would require specimen manipulation (e.g., back-to-back anal-
ysis) since geochemical methods require polished surfaces that
prevent detailed SEM analyses.

Finally, although Clathromorphum compactum is primarily
an outer coast rather than a bay species, ecological and oceano-
graphic variation in temperature and salinity along the complex
rocky shores frequented by C. compactum is a widespread and
inevitable source of variation. It is essential for accurate environ-
mental archiving that multiple samples from known depths and
localities be secured for analysis. The value of C. compactum as
a millennial climate archive will also likely be enhanced by lesser
growth rates in the lower SST of northern Labrador and the high
Arctic. Clathromorphum compactum occurs throughout the

NUMBER 40 e 37

Arctic (Figure 29), and it is likely that this species can provide a
pan-Arctic climate archive of considerable significance. High Arc-
tic reconnaissance, collection, and study will need to be under-
taken to fully understand the extent of clathrostrome formation.

CHANGING OCEAN PH

In the last decade, ocean acidification, resulting from in-
creasing CO, diffusion from the atmosphere, has been recognized
as a potential problem limiting organism calcification. Aragonite
formation and high-magnesium calcite, where the magnesium
concentration exceeds about 12 mol %, are susceptible to reduc-
tions in rates of formation and increase in rates of dissolution
(Morse et al., 2006; Anderson et al., 2008) at lower pH. The sea-
sonal MgCO3 range in C. compactum in the southern Labrador
Sea is about 6-12 mol %, and therefore, the effects of reduced
carbonate saturation on cor-stromes may be minimal. In tropical
waters, where magnesium content is much higher, this may be an
issue of concern (however, see Nash et al., 2013).

Primary C. compactum calcification is metabolic, and as we
have discussed, the organism maintains significant physiologi-
cal control over both placement and dissolution of carbonate.
Decreased pH might reduce secondary interfilament precipita-
tion (and therefore skeletal density of summer growth). How-
ever, secondary calcification takes place internally, within highly
photosynthetic tissues; it is light that limits skeletal density, and
how much of a role ambient water pH plays is uncertain (Roleda
et al., 2012). Chan et al. (unpublished) did not find a significant
decrease in Clathromorphum calcification rates in recent decades
in the North Pacific.

The primary function of the calcium carbonate in corallines
is grazing protection. There are competing, noncalcified red spe-
cies that form crusts and are more or less abundant, but usually
not dominant, in Labrador Sea clathrostromes. These species
and the dominant macroalgae of the community (Agarum clath-
ratum, Desmarestia viridis, and Ptilota serrata) probably possess
protective chemicals (Adey and Hayek, 2011). Perhaps lower
PH levels could shift the balance between competing crusts, so
that the nonealcified crusts would become dominant, greatly
limiting development of clathrostrome structure and secondary
production.

Grazers are abundant on clathrostrome bottoms. Limpets
and chitons have a mutualistic relationship with C. compactum,
feeding on epithallial cells and epiphytes; not only do they rarely
impact the crusts on which they feed, but they likely enhance
productivity by preventing abundant algal and invertebrate epi-

“

phytism. Epithallium calcification is quite “chalky,” probably as
a result of minimal inner-wall carbonate and the more “leafy”
interfilament calcification. Reduced calcification might increase
grazing depth, eventually reaching the meristem and causing
reduced growth. However, in the short term, increased grazing
depth could remove additional decaying epithallial cells and in-
crease photosynthesis and secondary calcification. Sea urchins
can significantly damage coralline surfaces and primary calcifica-
tion. However, adult sea urchins do not target corallines, and

38 © SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

FIGURE 29. Cor-strome, with abundant C. compactum, from 10-20 m in Arctic Bay in northernmost Baffin Island (73°N). These plants are

growing in an inner-bay environment, not the optimum habitat for this species. Although only a single image, it suggests that extensive clath-

rostrome development in intermediate-exposure, island-complex environments is likely in the high Arctic. © Nick Caloyianis. Reprinted with

permission.

if fleshy algae production were to be enhanced in a more acidic
sea, sea urchin grazing on corallines might actually be reduced
because of greater access to preferred seaweed foods. Finally,
most significant grazers in clathrostrome environments also have
critical carbonate hard parts that could be impacted by increased
seawater acidity. Ocean acidification will certainly impact ben-
thic communities, but the changes will be hard to predict with-
out extensive ecosystem level experiments. Single-species studies
are inadequate to the task.

CONCLUSIONS

Calcified encrusting coralline algae have a considerably more
complex anatomical structure than a reading of current literature
would suggest. As we document here, the genus Clathromor-
phum, widespread in Subarctic and Arctic seas, provides a highly

integrated anatomy and reproduction, modified by numerous envi-
ronmental elements. Understanding this complexity is essential to
the accurate interpretation of geochemical analyses of the skeleton
and has already led to the development of a new archive for sea
ice providing paleoclimatic information not previously available.

Also, the role of corallines in general, and keystone Clath-
romorphum species in particular, in forming cold-water rocky-
bottom carbonates has been widely interpreted as a degraded
ecosystem resulting from intensive overfishing. As we show,
Clathromorphum species grow very slowly, primarily under tem-
perature control, and have developed anatomical and cellular
structures that potentially allow longevities of many centuries.
This understanding is crucial to interpreting the ecological im-
portance of this widespread carbonate structure, with its unique
associations of organisms as a key ecosystem of Subarctic and
Arctic rocky shores; its age shows clearly that it is not a degraded
system. Also, we show how understanding geomorphological

controls laid on ecological patterns identifies carbonate build-
ups, potentially of millennial ages, which are further crucial to
acquiring lengthy paleoclimatic data.

Finally, contrary to the prevailing view of corallines as sim-
ple cushions built by filaments, we show how multiple complex
anatomical features, which can be called tissues, and reproduc-
tive structures of combined tissues, which can be interpreted as
organs, are the norm. These are key elements to understanding
phylogenetic analyses and evolutionary patterns in corallines
and other red algae.

ACKNOWLEDGMENTS

This was a multiyear project that covered thousands of
miles of coast and was carried out with a research vessel that at
times used the services of many boatyards and ports in the Cana-
dian Maritimes and the Gulf of Maine. It would be impractical
to acknowledge individually the many crew members and shore
supporters who helped our research, and here we credit only the
key individuals involved directly in collection and research.

Matthew Suskiewicz was our chief diver for the 2010 and
2011 cruises and did all of the collecting during that period.
Nick Caloyianis provided the key underwater images, and David
Grimard and Steve Allen were the principle support divers.
Karen Loveland Adey and Erik Adey provided considerable lo-
gistic support both at sea and during the analytical phases. The
superb SEM facilities of the Smithsonian’s National Museum of
Natural History and the ever-present and critical support of its
director, Scott Whittaker, made possible the large set of critical
SEM images. Dean Calahan and Jennifer Barker provided signifi-
cant editorial services. Collections made in the Aleutian Islands
and Baffin Island were credited in Materials and Methods.

Funding for this project was provided by Ecological Systems
Technology, Natural Sciences and Engineering Research Council
of Canada, through the University of Toronto and Laval Univer-
sity and the Botany Department of the Smithsonian’s National
Museum of Natural History.

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