

doi:10.3402/polar.v35.29383


R E S E A R C H / R E V I E W A R T I C L E

Adjustment of pigment composition in Desmarestia
(Desmarestiaceae) species along a sub-Antarctic to Antarctic
latitudinal gradient
Andrés Mansilla,1,2 Fabio Méndez,1,2,3 Silvia Murcia,1 Juan Pablo Rodrı́guez,1,2,3 Johanna Marambio,1,2,3

Sebastián Rosenfeld,1,2,3 Nair Yokoya4 & Kai Bischof5

1
Laboratory of Antarctic and Sub-Antarctic Marine Ecosystems, University of Magallanes, 01855 Bulnes Ave., Punta Arenas 6200000, Chile

2 Institute of Ecology and Biodiversity, Las Palmeras St. 3425, Ñuñoa, Santiago 8320000, Chile
3

Conservation and Management of Natural Resources in Sub-Antarctic Environments MS Program, University of Magallanes, 01855 Bulnes Ave.,

Punta Arenas 6200000, Chile
4

Institute of Botany, São Paulo State Department of the Environment, 3687 Miguel Estéfano Ave., São Paulo 04301-012, SP, Brazil
5 Marine Botany Department, University of Bremen, NW2 Leobener St., Bremen DE-28359, Germany

Keywords

Macroalgae; Phaeophyceae;

photosynthesis; physiology; environmental

heterogeneity; Chile.

Correspondence

Silvia Murcia, Laboratory of Antarctic and

Sub-Antarctic Marine Ecosystems,

University of Magallanes, 01855 Bulnes

Ave., Punta Arenas 6200000, Chile.

E-mail: silvia.murcia@umag.cl

Abstract

Photosynthesis at high latitudes demands efficient strategies of light utilization

to maintain algal fitness and performance. The fitness, and physiological

adaptation, of a plant or algae species depends in part on the abundance and

efficiency of the pigments it can produce to utilize the light resource from its

environment. We quantified pigment composition and concentration in six

species of the brown macroalgal genus Desmarestia, collected from sub-

Antarctic sites (Strait of Magellan, Beagle Channel�Cape Horn Province) and
sites on the Antarctic Peninsula and adjacent islands. Sub-Antarctic Desmarestia

species exhibited lower concentrations of chlorophyll a, chlorophyll c and

fucoxanthin than endemic Antarctic species. Antarctic samples of D. menziesii

and D. antarctica collected along a decreasing latitudinal gradient showed

spatial and interspecific differences in light-harvesting pigment composition.

Our results suggest distinct physiological adjustments in Desmarestia species in

response to heterogeneous abiotic environmental conditions. The marine sub-

Antarctic and Antarctic ecosystems are characterized by harsh environments

(e.g., extreme irradiance, photoperiod, temperature, salinity) to which the

physiology of macroalgal species must adapt.

The Chilean sub-Antarctic ecoregion of Magallanes (or

Magellan) hosts a coastal, benthic community that is

highly distinct from other temperate rocky shores on the

South American Continent in terms of species composi-

tion, richness and structure. Such distinctions could be the

result of several factors, such as the geomorphology

generated by the glacial erosion during the advance and

retreat of ice in the Quaternary (Silva & Calvete 2002);

oceanographic gradients combining unique current flows,

salinity, and thermal (Dayton 1985; Silva & Calvete 2002),

photoperiod and irradiance regimes; presence of glaciers

with predominant west-to-east gradients of winds and

rainfall (Aravena & Luckman 2009) and freshwater coastal

discharge; variable substrate types with abrupt change in

geomorphology of the sub-Antarctic system of fjords and

channels (Valdenegro & Silva 2003), resulting in unique

physical and biogeochemical seawater conditions (e.g.,

nutrient cycles, carbonate system dynamics [Torres et al.

2014]) that generate a distinct algal structure. The envi-

ronmental heterogeneity governing sub-Antarctic and

Antarctic coastal ecosystems has shaped the evolution-

ary history and physiological adaptations of the local

macroalgal flora.

From phylogenetic, morphological and eco-physiological

studies of the genus Desmarestia (Lamouroux 1813) con-

ducted in the Antarctic ecoregion of Magallanes, it was

Polar Research 2016. # 2016 A. Mansilla et al. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0
International License (http://creativecommons.org/licenses/by-nc/4.0/), permitting all non-commercial use, distribution, and reproduction in any medium, provided the
original work is properly cited.

1

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found this species originated from an Antarctic ancestor,

then radiated north, eventually reaching the Northern

Hemisphere through long-distance natural dispersal

(Peters et al. 1997). Within the sub-Antarctic Chilean

ecoregion of Magallanes, the genus Desmarestia is repre-

sented by D. confervoides (Bory de Saint-Vincent) M.E.

Ramı́rez & A.F. Peters, D. chordalis J.D. Hooker & Harvey

and D. ligulata (Stackhouse) J.V. Lamouroux. Currently, D.

distans and D. muelleri are considered subspecies of D.

ligulata (Setchell & Gardner 1925; Guiry & Guiry 2014;

Yang et al. 2014).

The representative Desmarestia species in the Antarctic

continent are D. anceps Montagne, D. menziesii J. Agardh

(Lamb & Zimmermann 1977; Wiencke et al. 1995) and

D. antarctica Silva & Moe (Moe & Silva 1989; Wiencke et al.

1991). These Desmarestia species, together with Himan-

tothallus grandifolius (A. Gepp & E.S. Gepp) A.D. Zinova

(1959), comprise a large proportion of the macroalgal

biomass along the Antarctic Peninsula (Amsler et al. 1995;

Brouwer 1996; Quartino et al. 2001; Quartino et al. 2005),

yet are largely understudied despite supporting a diverse,

associated floral and faunal community.

Photosynthetic pigment composition can reveal poten-

tial adaptation and acclimation success, and the physiolo-

gical traits of macroalgae (Motten 1995; Plastino &

Mansilla 2004). A species’ reaction to the given radiation

climate is determined by the interaction between genetic

adaptation and physiological acclimation where adapta-

tion must precede acclimation to changing environmental

conditions (Bischof et al. 2006). That is, the species-

dependent and variable genetic preadaptations to limiting,

but also potentially harmful, radiation would shape its

physiology in the natural environment. For example, in

Lessonia nigrescens of the Southern Hemisphere, the photo-

synthetic responses to seasonally changing irradiance

levels are some of its adaptations, along with its ontogenic

development (Huovinen et al. 2006). Pigment composi-

tion is frequently used as a biomarker to infer physiological

adaptations of plants and algae (e.g., Dring 1981; Ramus

1983) to differing environmental variables across biore-

gions (Falkowski & LaRoche 1991). Laminaria saccharina,

for instance, may be capable of optimizing photosynthesis

over a wide range of light levels by complex metabolic

regulation (Machale et al. 1996). And, under variable

irradiance, the red algae Gracilaria lemaneiformis showed

differential vegetative and physiological strategies to

adapt to environmental stress by regulating different

metabolic processes (e.g., photosystem II reaction centres

normalization; Wu et al. 2015). The biochemical reactions

of photosynthesis are directly coupled to light availability

(Plastino & Mansilla 2004), and the respective share of chl a

as reaction centre pigment to chl c and other accessory

pigments, such as the xanthophyll Fucox, may reveal

adaptive responses towards heterogeneous light and climate,

fluctuating with latitude, depth, season or a combination

of all (Mansilla & Alveal 2004; Plastino & Mansilla 2004).

In addition to irradiance and photoperiod (hours daylight:

hours darkness), temperature, salinity and nutrients may be

further limiting factors at high latitudes, affecting the

efficiency of light capture for photosynthesis.

Our objectives were to examine (1) the adjustments or

intraspecific differences in pigment composition and ratio

(chl c/chl a; chl c/Fucox) in species of the genus

Desmarestia spatially from sub-Antarctic to Antarctic

marine habitats and (2) the intraspecific differences in

pigment concentration in two Antarctic species within

the genus Desmarestia (D. antartica, D. menziesii). We

hypothesized that primary (chl a) and accessory (chl c

and Fucox) pigment composition in Desmarestia species

will differ among sites along the latitudinal gradient of

sub-Antarctic to Antarctic waters; and along the Antarc-

tic Peninsula, despite site proximity and past connec-

tivity, reflecting response to local conditions such as

different duration and intensity of solar irradiance

between regions. The overall results of this investigation

will contribute to current knowledge and understanding

of macroalgal eco-physiology. Marine photosynthetic

physiology in sub-Antarctic and Antarctic irradiance

regimes is likely to become increasingly relevant in the

context of present and future global changes.

Materials and methods

Study sites

Two sites in Chile’s sub-Antarctic region and eight sites

along the Antarctic Peninsula were selected to represent a

range of environmental conditions (Table 1). We used a

Solar Light† radiometer (model: PMA 2200) and a Yellow

Spring Instrument† handheld multiparameter (model:

MPS) at some sites (e.g., Saint Ana) or a conductivity�
temperature�depth recorder (SBE 19plus V2 SEACAT
Sea-Bird Electronics Inc.) measurements to first 10 m

depth at other sites (e.g., Deception). When not available,

approximates of environmental data were obtained from

published literature for the given site (e.g., Santana et al.

2006; Clarke et al. 2008; Smith & Comiso 2008; CEAZA-

MET 2010; Table 1).

Abbreviations in this article
chl a, b, c: chlorophyll a, b, c
Fucox: fucoxanthin
FW: fresh weight
PAR: photosynthetically active radiation

Pigment composition in Desmarestia species A. Mansilla et al.

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Field sample collection

Fronds of Desmarestia confervoides and the subspecies D.

ligulata subsp. ligulata f. distans and D. ligulata subsp.

muelleri were collected in the austral summer period

(December 2011�February 2012) at two sites along the
Strait of Magellan to the Beagle Channel (Table 1; Fig. 1).

D. antarctica, D. menziesii and D. anceps were collected in

Antarctica by scuba diving in February 2013 off Fildes

Bay (Fildes), Hanna Point (Hanna), Prat Point (Prat),

Deception Island (Deception), Spring Point (Spring),

Argentine Islands (Argentine), Rothera Base (Rothera;

except D. antarctica, not found) and Carvajal Base

(Carvajal; Table 1, Fig. 1). All specimens were placed in

freeze�cooler containers to prevent sulfation of Desmarestia
individuals and/or degradation of pigments from exposure

to light and temperature changes. Sub-Antarctic samples

were processed upon collection immediately at the

Laboratory of Antarctic and sub-Antarctic Marine Eco-

systems, University of Magallanes, in Punta Arenas,

Chile. Antarctic samples were transported in coolers,

over the short 5- to 10-min Zodiac ride back to our

research vessel where they were frozen at �258C to
avoid loss of pigment or similar deterioration for later

analysis at the laboratory.

Pigment analyses

Seven random, individual samples of each species of

Desmarestia (7 n �6 species �42) were taken to the
laboratory. The frozen samples were thawed, washed

with sterilized seawater of salinity 34 psu and were

carefully brushed to remove epiphytic organic material.

Random ca. 2 cm
2

subsamples (0.125 g FW) from the

fronds were gently patted with paper towel to remove

excess water and weighed in a Radwag analytical balance

(AS 220/c/2) for pigment analysis (Seely et al. 1972). Our

prior work (unpublished) and that of Seely et al. (1972)

showed that dimethyl sulfoxide readily extracts pig-

ments without further addition of acetone. One mL of

dimethyl sulfoxide was added to 0.125 g FW (FW and

incubated for 15 min in complete darkness). The super-

natant was then placed into a 2.5-mL cuvette for spec-

trophotometric analysis (Genesys 10 UV). No further

dilution was necessary. Light absorbance was recorded at

wavelengths of 480, 582, 631 and 665 nm once com-

pleteness of extraction was determined (white samples).

Pigment concentration was quantified using equations

from Seely et al. (1972):

chl a ¼ A665=72:8; (1)

Table 1 Environmental and habitat variables registered in 2011, 2012 and 2013 during collection of five Desmarestia species at 10 study sites in

sub-Antarctica and Antarctica. Shown are the mean or mean range values.

Desmarestia species name Study site

Depth

(m)

PAR

(mE /m2s)
Salinity

(psu)

Temperature

(8C)
Dissolved O2

(mg/L)

Habitat

substrate type

Sub-Antarctica

D. confervoides St Ana Point 5�7 526.4 32.53 9.73 12.8 Cliff
D. ligulata subsp. ligulata

f. distans

St Ana Point (S53808?;
W71800?)

5�7 526.4 32.53 9.73 12.8 Cliff

D. ligulata subsp. muelleri St Ana Point 5�7 526.4 32.53 9.73 12.8 Cliff
D. confervoides Paula Bay 5�7 164�165 32.17 4.7�10.9 � Boulders
D. ligulata subsp. ligulata

f. distans

Paula Bay (S54855?; W67855?) 5�7 164�166 32.17 4.7�10.9 � Boulders

D. ligulata subsp. muelleri Paula Bay 5�7 164�167 32.17 4.7�10.9 � Boulders
Antarctica

D. antarctica Fildes (S62812?; W58854?) 5�7 729�787 34 2 10.9 Cliff
D. menziesii Fildes 5�7 729�787 34 2 10.9 Cliff
D. anceps Prat (S62827?; W59844?) 9�12 748�768 33.85 2.1 8.0 Boulders
D. menziesii Prat 5�7 748�768 33.85 2.1 8.0 Cliff
D. antarctica Prat 5�7 748�768 33.85 2.1 8.0 Boulders
D. anceps Hanna (S62839?; W60837?) 10 729�787 34 1.8 7.1 Cliff
D. antarctica Hanna 5�7 729�787 34 1.8 7.1 Cliff
D. menziesii Deception (S62859?; W60835?) 5�7 901.21 33.87 2.1 8.0 Boulders
D. antarctica Deception 5�7 901.21 33.87 2.1 8.0 Rocky shore
D. antarctica Spring (S64817?; W61805?) 5�7 729�787 33.4 0�1 � Cliff
D. menziesii Spring 5�7 729�787 33.4 0�1 � Cliff
D. menziesii Argentine (S65814?; W64815?) 5�7 729�787 33.4 0�1 � Cliff
D. menziesii Rothera (S67833?; W68807?) 5�7 1005.9 33.29 1.72 12.6 Cliff
D. menziesii Carvajal (S62812?; W58854?) 5�7 739.6 32.59 0.24 13.3 Cliff
D. antarctica Carvajal 5�7 739.6 32.59 0.24 13.3 Rocky shore

A. Mansilla et al. Pigment composition in Desmarestia species

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chl c ¼ðA632 þA582 � 0:297A665Þ=61:8; (2)

Fucox ¼ðA480 � 0:772 ðA631 þA582 � 0:297A665Þ
� 0:049A665Þ=130 (3)

Data analysis

Pigment concentrations were compared among six species

(N �7 per species) between sub-Antarctic and Antarctic
sites using the Kruskal�Wallis non-parametric test be-
cause data were not normally distributed. All conclusions

were based on a 95% confidence level (P �0.05). In addi-
tion, we calculated pigment ratios for species of the sub-

Antarctic region and the Antarctic Peninsula and adjacent

islands. All statistical analyses were carried out using the

software package STATISTICA, version 7.1 (2004).

Results

Study sites

The sub-Antarctic sites showed lower average salinity and

PAR light (32.35 psu and 345.5 mE/m2s, respectively) but

generally showed higher average temperature and dis-

solved oxygen (8.48C and 12.8 mg/L, respectively) than the
sites along the Antarctic Peninsula (33.4 psu, 811.2 mE/m2s,
1.7 8C and 9.6 mg/L; Table 1). Average depth and habitat
substrate types where Desmarestia specimen could be

collected from for this study remained fairly constant

variables across sites in both regions (Table 1).

Spatial and interspecific differences

Overall, higher average concentrations of chl a, chl c and

Fucox were observed in Desmarestia species from Antarc-

tic sites compared with sub-Antarctic sites (except D.

ligulata subsp. muelleri; Fig. 2a). Among the sub-Antarctic

species of Desmarestia, the highest chl a concentration

was measured in D. confervoides from Paula Bay (Beagle

Channel, Cape Horn Province) and the highest Fucox

concentration in D. ligulata subsp. muelleri (lowest chl a)

from the Strait of Magellan (Fig. 2a). Chl a concentration

differed significantly between D. ligulata subsp. ligulata f.

distans and Antarctic D. menziesii (P �0.001; Fig. 2a). The
chl c content of sub-Antarctic D. confervoides was signifi-

cantly different from all Desmarestia species tested (all P

B0.002; Fig. 2a). Statistically, Fucox was most variable

between the sub-Antarctic species (P �0.009; Fig. 2a).
The ratio of chl c/chl a was similar in the sub-Antarctic

species D. confervoides (1.68), D. ligulata subsp. ligulata

f. distans (2.09) and D. ligulata subsp. muelleri (1.61;

Fig. 2b). Large differences in the ratio of Fucox/chl a

were found between D. ligulata subsp. muelleri, which

exhibited an increased proportion of Fucox (5.41 in

specimen from Paula Bay, Beagle Channel, Cape Horn;

Fig. 2b), and all Desmarestia species tested. The data show

similar pigment concentrations and ratios among the

Antarctic Desmarestiales and overall fairly lower than

in sub-Antarctic species (all between 0.31 and 0.38;

Fig. 2b).

Interspecific differences along the Antarctic Peninsula:

D. antarctica and D. menziesii.

The higher concentrations of chl a (0.4590.17 mg.g
�1

FW) and chl c (0.2090.08 mg.g
�1

FW) were generally

found in D. menziesii. But we measured nearly identical

concentrations of Fucox in both, D. menziesii and D.

antarctica (Fig. 3a, b).

No clear latitudinal effect was observed for chl a

concentration in D. menziesii along the Antarctic Penin-

sula (Fildes to Carvajal; Table 1, Fig. 3a). High concen-

tration of chl a in D. menziesii was recorded in Deception,

followed by Rothera and Carvajal (0.6390.04, 0.649

0.03 and 0.6390.05 mg �g�1 FW, respectively), especially
at the lowest temperature and salinity sites, near the

Antarctic Circle (Table 1, Fig. 3a). A decreasing trend in

Fig. 1 Study sites sampled for Desmarestia species from which photo-

synthetic pigments chl a chl c and Fucox were extracted. Shown are the

sites in the sub-Antarctic ecoregion: (1) Saint Ana Point (Brunswick

Peninsula); (2) Paula Bay (Beagle Channel) and the study sites sampled in

the Antarctic Peninsula; (3) Fildes Bay (Fildes); (4) Hanna Point (Hanna);

(5) Prat Point (Prat); (6) Deception Island (Deception); (7) Spring Point

(Spring); (8) Argentine Island (Argentine); (9) Rothera Base (Rothera); and

(10) Carvajal Base (Carvajal).

Pigment composition in Desmarestia species A. Mansilla et al.

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pigment concentration with increasing latitude was

observed from Deception to Spring and Argentine sites.

Chl a, chl c and Fucox in D. menziesii at Fildes, Spring and

Argentine, with similar abiotic features (Table 1), ranged

in similar, and lower, concentrations (all between 0.18

and 0.3090.03 mg �g�1 FW; Fig. 3a) than sites with
variable PAR, temperature, salinity or substrate type

(Table 1).

In D. antarctica, chl a concentration varied markedly

among sites on the Antarctic Peninsula, the highest chl a

concentrations were recorded in Deception (0.5690.2

mg �g�1 FW) and Carvajal (0.5690.07 mg �g�1 FW;
Fig. 3c, d). Chl c concentration in D. antarctica decreased

towards lower latitudes, from the highest values found at

Deception (0.1590.09 mg �g�1 FW) to almost half of the
concentration in samples from Fildes Bay. Fucox con-

centrations barely changed along the latitudinal gradient,

between Deception and Spring (Fig. 3b) in spite of

different environmental features (Table 1).

We identified overall higher ratios of chl c/chl a in D.

menziesii than in D. antarctica, and overall higher ratios of

Fucox/chl a in D. antarctica than in D. menziesii consider-

ing all locations along the Antarctic Peninsula (Fig. 3c, d).

Among samples of D. menziesii, the highest chl c/chl a

ratio was registered in Fildes (0.83), the lower latitude

site, and the highest Fucox/chl a ratio was registered in

Argentine (Fig. 3c). Samples of D. antarctica from loca-

tions along the Antarctic latitudinal gradient, showed

low chl c/chl a ratio (Fig. 3d). The Fucox/chl a ratios in D.

antarctica from Fildes (1.23) and Spring (1.14) were

nearly triple (and double in Spring Point) that of D.

menziesii (all sites; Fig. 3c, d).

Discussion

We analysed intraspecific and interspecific differences in

pigment composition in sub-Antarctic and Antarctic

samples of the genus Desmarestia. In the six species studied,

Fig. 2 (a) Mean 9 SD pigment concentration (N �7 per species) of chl a, chl c and Fucox and (b) ratios of mean pigment concentration (N �7) of
chl c/chl a and of Fucox/chl a in species of the genus Desmarestia from the sub-Antarctic region of Chile and the Chilean Antarctic Peninsula.

A. Mansilla et al. Pigment composition in Desmarestia species

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we found the lowest concentrations of chl a, chl c

and Fucox in the species from sub-Antarctic sites, versus

the higher pigment concentrations in species along the

Antarctic Peninsula (Table 1; Fig. 3), that is, increasing

pigment composition towards the prevailing radiation

climate. Though we registered differences between sites,

we expected to see a gradient of photosynthetic pigment

concentration reflecting the latitudinal gradient along the

Antarctic Peninsula. We did not see this pigment gradient

from our results (Fig. 3). Such a gradient may have

suggested the presence of more accessory pigments in

subtidal specimen as a possible strategy to optimize

photosynthetic efficiency in regions with shorter light

exposure (Gómez et al. 1997). Nevertheless, we saw an

important tendency for higher chlorophyll concentrations

at our two sites closest to the polar circle (Carvajal and

Rothera) and the high-latitude site Deception, especially

with D. menziesii (D. antarctica not collected in Rothera).

Several biotic and abiotic factors, such as temperature,

salinity, nutrients (Ramus 1978; Dhargalkar 2004; Nygård

& Dring 2008) and thalli morphology (Peckol & Ramus

1988; Johansson & Snoeijs 2002), may also influence

efficiency of light absorption and geographical distribution

of macroalgae, survival, growth rates and reproductive

success (Van den Hoek 1982; Breeman 1988) at both sub-

Antarctic and Antarctic sites.

At lower temperature (usually higher latitude), high

rates of photosynthesis are observed among terrestrial and

aquatic plants and usually relate to an increased ratio of chl

a to b (e.g., Eggert et al. 2006). Similar photosynthetic

adaptations are most likely in macroalgae at high latitudes,

such as those endemic species of the Antarctic Peninsula.

Although the depth of light dispersion influences photo-

synthetic pigment composition, our samples of Desmarestia

species were all collected in the ca. 5 m depth range in sub-

Antarctica and Antarctica. It is unlikely that depth was an

influential factor on the observed pigment differences.

But, the variation in pigment composition among sites on

the Antarctic Peninsula may be influenced by the seasonal

variation in light, related in turn to variation in tempera-

ture, inducing variable pigment production and metabolic

rate (e.g., Barko & Smart 1981; Aguilera et al. 2002).

Similarly, seasonal sea-ice and snow coverage (Zacher

et al. 2009), influencing salinity and nutrients, may also

affect the physiology of photosynthesis and algal pigment

content (e.g., Nygård & Dring 2008).

Desmarestia’s pigment concentration may vary under

different salinities or according to life history stage (Gómez

& Wiencke 1996). Salinity changes affect cellular struc-

tures responsible for the synthesis and metabolism of

proteins, affecting the life cycle and pigment concentra-

tion of some brown algae (Nygård & Dring 2008) and are

likely to affect Antarctic species of Desmarestia. Nutrients

also influence photosynthesis and growth rate. For exam-

ple, cultivation of Fucus vesiculosus from the Baltic Sea

(5 psu) showed higher photosynthetic activity (as electron

transfer rate) and relative growth rate at low salinities

(B10 psu) than F. vesiculosus from the Irish Sea (35 psu),

which decreased sharply in salinities below 20 psu

Fig. 3 Pigment concentration of (a) Desmarestia menziesii and (b) D.

antarctica along a latitudinal gradient in the Antarctic Peninsula. Shown

are the means 9 SD (N �7) concentration of chl a, chl c and Fucox, and
mean concentration ratios of chl c/chl a and Fucox/chl a in (c) D.

menziesii and in (d) D. antarctica from study sites along the Antarctic

Peninsula’s latitudinal gradient (N �7).

Pigment composition in Desmarestia species A. Mansilla et al.

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(Nygård & Dring 2008). Fucus specimens from both Baltic

(5 psu) and Irish (20 psu) sites under high-nutrient

conditions performed better at low salinities than those

grown in low-nutrient cultures (Nygård & Dring 2008).

Salinity may therefore be a stronger influence on differ-

ences in photosynthesis (and growth) between specimens

from two geographic regions or populations, followed by

differences in nutrient concentrations. A marked coastal

isocline is more characteristic of Antarctic than of sub-

Antarctic waters (Palma et al. 2008) and this might

explain the overall lower pigment concentration and

ratios in Desmarestia from sub-Antarctic sites than in those

from Antarctica. An increase in global temperatures, with

its consequent increase in glacial inflows, reduced salinity

and increased water turbidity, may alter depth distribu-

tion patterns*and therefore productivity*of macroalgal
communities, especially in high-latitude regions.

Though salinity barely differed between sites in both

study regions, macroalgal pigment composition and con-

centration may also vary according to life history stage and

thallus morphology (Gómez et al. 1997; Wiencke, Clayton

et al. 2006). Early stages of D. menziesii would be better

adapted to low light intensities than adult stages because

they have more pigment composition per unit of biomass

and therefore more investment in light-harvesting me-

chanisms (Gómez 2001). Alternatively, the Desmarestia

species we examined have filamentous and laminar thalli,

which directly affect the efficiency of light absorption

(Ramus 1978; Peckol & Ramus 1988; Johansson & Snoeijs

2002). Thinner species have increased photosynthetic

tissue per unit biomass. In D. menziesii, the content of chl

a, c and Fucox in cultured samples increased with thallus

biomass (Gómez & Wiencke 1997). The pigment composi-

tion of D. confervoides, of cylindrical and branched thalli

morphology, showed a photosynthetic capacity between

that of fleshy and laminar thalli with few cell layers

(Rautenberger et al. 2009). This morphology is typical of

sub-Antarctic species. Therefore, the greatest concentra-

tion of Fucox in D. ligulata subsp. muelleri (and D. antarctica,

similar morphology) may be due to the laminar thallus

morphology potentially influencing pigment concen-

trations (Eggert et al. 2006; Navarro et al. 2009) in these

sub-Antarctic algae.

In the sub-Antarctic species, no clear pattern in pigment

composition was observed from Saint Ana Point to Paula

Bay near Cape Horn (Drake Passage; Fig. 1). The sub-

Antarctic marine habitats are exposed to the unique

confluence of three ocean influences (Reid 1989) where

heavy precipitation, for instance, may set a subtle but

important difference among study regions (Table 1), in

addition to fluvial run off often rare in sites of the Antarctic

Peninsula. This may explain the lower water salinity and

higher temperatures registered in general in the physico-

chemically heterogeneous sub-Antarctic environment.

The greater variation in, and generally lower, pigment

concentration among the sub-Antarctic Desmarestiales

studied may result from low ice or cloud cover, decreased

water turbidity from glacial run off, longer daylength in

winter or large heterogeneity in the physico-chemical

environment (e.g., the advance and retreat of ice [Silva &

Calvete 2002]).

We found differences in pigment concentration, espe-

cially in chl a, between our study sites along the Antarctic

Peninsula (Fildes, Prat, Deception, Spring, Argentine,

Rothera and Carvajal), although the concentrations of

Fucox barely changed among sites. This might be ex-

plained by the fact that accessory pigments (carotenoids)

are generally less sensitive to severe environments com-

pared with chl a (Häder & Häder 1989). Antarctic macro-

algae may be better acclimated than other algae to

withstand environmental extremes (irradiance, photo-

period, temperature, salinity, nutrients) that affect the

photosynthetic efficiency and pigment composition in

high latitudes (Gómez et al. 1997; Gómez 2001; Wiencke,

Roleda et al. 2006).

Though we did not measure directly all possible abiotic

conditions (cloud cover, transient ice), in other studies,

reduced availability of PAR due to increased water

turbidity from glacial influence and depth in coastal

Antarctica led to decreased macroalgal vertical distribu-

tion, photosynthetic parameters (Rautenberger et al.

2013) and metabolic carbon balance (Deregibus et al.

2015). Similar works reveal that the duration of daily

exposure, rather than the intensity of light, is most

significant for macroalgal productivity and photosynthetic

efficiency in coastal areas (Gómez et al. 1997; Zacher et al.

2009). That is, the increased pigment concentration in

Antarctic algae during the summer may be a strategy to

increase light-harvesting efficiency in an environment

with significantly less annual solar radiation than that in

temperate to tropical regions (Ramus 1981; Kirst &

Wiencke 1995; Wiencke, Roleda et al. 2006).

In contrast, lower pigment content could protect

individuals in regions (e.g., sub-Antarctic) with less-

intense light regime (though available over longer time,

that is, months per year, daylength in winter) than the

short-and-intense Antarctic light regime in the summer

(e.g., Gómez et al. 1997; Gómez 2001). Similar patterns

have been found in a number of seaweeds from a high

Arctic site (Aguilera et al. 2002). Samples were only

collected in summer and therefore we were unable to test

this potential strategy. In addition, photoperiod is sug-

gested to influence the concentration of accessory pig-

ments in Antarctic waters to a greater degree than it

A. Mansilla et al. Pigment composition in Desmarestia species

Citation: Polar Research 2016, 35, 29383, http://dx.doi.org/10.3402/polar.v35.29383 7
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http://dx.doi.org/10.3402/polar.v35.29383


influences chl a (Yokoya et al. 2007). But, under field

conditions, the effects of photoperiod and irradiance are

difficult to disentangle, and thus further studies under

controlled laboratory conditions are recommended. It is

likely that changes occur in pigment composition of the

photosynthetic antenna in sub-Antarctic Desmarestia

(e.g., decrease in chl a with increased light availability

in summer; our unpubl. data), but its physiological

response must be further studied.

In conclusion, despite the environmental extremes of

polar waters, macroalgae show physiological adaptations

(Wiencke 1990). These adaptations can be seen in the

photosynthetic apparatus and pigment composition

(Kirst & Wiencke 1995). Amid the cumulative global

and environmental changes, including increases in aver-

age temperatures*and consequent changes in salinity,
light intensity and availability*there is a growing need
for basic research to guide applied studies (e.g., biotech-

nology) using algae and their mechanisms of adaptation,

survival and irradiance protection as model machinery.

Acknowledgements

This research was funded by Chile’s National Council for

Research in Science and Technology (CONICYT) Program

FONDECYT, project 1140940, the Millennium Scientific

Initiative (grant P05-002 ICM, Chile) and the Basal

Financing Program of the (grant PFB-23, Chile). We

thank the resources and support offered by the Chilean

Navy Ships AP-46 ƒAlmirante Óscar Viel, and AP�41 Aquiles
during field expeditions. We are thankful for the graduate

scholarships by the Institute of Ecology and Biodiversity

granted to FM (ICM, P05-002) and JPR (ICM, P05-002)

and to JM (PFB-23-2008) and SR (ICM P05-002).

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