Thermal ecotypes of amphi-Atlantic algae. I. Algae of Arctic to cold-temperate distribution (Chaetomorpha melagonium, Devaleraea ramentacea andPhycodrys rubens)

Novaczek, Irené; Lubbers, GW; Breeman, Anneke M.

doi:10.1007/bf02365480

Cited by 33 publications

(20 citation statements)

References 19 publications

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“…The capability of a single species to exist under a wide range of environmental parameters and over a broad geographical range has been reported for many macroalgae (Bolton, 1983;Karsten et al, 1994). The wide biogeographic occurrence of S. hookeri may be explained by the existence of temperature ecotypes with genetically fixed growth optima for specific temperatures in a specific habitat, as has been demonstrated for the brown alga Ectocarpus siliculosus (Bolton, 1983) and the green alga Chaetomorpha melagonium (Novaczeck et al, 1990). Although in this study ecotypic differentiation has been demonstrated in principle for S. hookeri, caution is necessary since only single isolates from each population were physiologically characterized.…”

Section: Discussionmentioning

confidence: 82%

Physiological responses of the eulittoral macroalgaStictosiphonia hookeri(Rhodomelaceae, Rhodophyta) from Argentina and Chile: salinity, light and temperature acclimation

Karsten

Koch

West

et al. 1996

European Journal of Phycology

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The marine red alga Stictosiphonia hookeri was isolated from three locations in cold-temperate Chile and Argentina, and the comparative ecophysiology of the isolates was studied. The growth response in relation to various salinity, light and temperature conditions was investigated and photosynthesis-irradiance curves were determined. The effect of increasing salinity on the intracellular concentration of the sugar alcohol sorbitol, and the accumulation/degradation kinetics of this compound, were studied. All isolates are characterized as euryhaline, eurythermal and low-light-adapted organisms because of the growth and photosynthesis response patterns. With increasing salinities the macroalgae accumulated high concentrations of sorbitol, which acts as an organic osmolyte and compatible solute. However, this process requires more than 24 h, and hence is too slow to contribute to osmotic acclimation within a tidal cycle. The geographic distribution and the growth versus temperature data indicate infraspecific differences which are interpreted as a stage in the development of different (physiological) ecotypes.Key words: growth, osmotic acclimation, photosynthesis, salt stress, sorbitol, temperature ecotypes IntroductionThe marine red alga Stictosiphonia hookeri (Harvey) J. D. Hooker et Harvey is widely distributed in the SouthernHemisphere from temperate (about 30 ° S) to cold (about 55 ° S) waters (King & Puttock, 1989). It preferentially grows on shaded rocks in the upper littoral zone of sheltered to exposed coastlines and less frequently as an epiphyte on the pneumatophores and trunks of mangrove trees in south-eastern Australia and New Zealand (King & Puttock, 1989). In the latter habitat S. hookeri occurs intermixed with other red algae of the so-called Bostrychia-CaIoglossa association (Post, 1936), a group of algae which are considered characteristic of mangrove communities. In both habitats S. hookeri is subject to alternating emersion-immersion cycles because of the tides. Under these conditions it may be exposed to wide salinity and temperature fluctuations.The genus Stictosiphonia was segregated from the genus Bostrych& (Ceramiales) on the basis of some morphological features (King & Puttock, 1989). There are also biogeographic differences between these closely related genera. While Bostrychia species typically dominate the macroalgal flora in the eulittoral zone of tropical mangrove and temperature salt marsh communities, several Stictosiphonia species occur mainly in cold-temperate and subantarctic regions. This is particularly interesting since these algae are thought to originate from the tropical Indo-Pacific region (Post, 1968), but during evolution Stictosiphonia has occupied locations in much higher latitudes (30°S to 55°S) than has Bostrychia. This is well documented by the present geographic distribution of four of the six known Stictosiphonia species (including S. hookeri) (King & Puttock, 1989).Recent investigations of Bostrychia species consider the physiological and biochemical capabilit...

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Section: Discussionmentioning

confidence: 82%

Physiological responses of the eulittoral macroalgaStictosiphonia hookeri(Rhodomelaceae, Rhodophyta) from Argentina and Chile: salinity, light and temperature acclimation

Karsten

Koch

West

et al. 1996

European Journal of Phycology

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“…The red alga Devaleraea ramentacea, which is distributed from the Arctic to the cold temperate North Atlantic region, grows at up to 10°C with an optimum at 0°C and exhibits an UST of 18-20°C and an LST of £-5°C. The ULG of this species is 8°C (Novaczek et al 1990;Bischoff and Wiencke 1993). Macrothalli of species with a prominent distribution in both, the Arctic and the cold-temperate region, grow at up to 15 or 20 (to 25)°C with optima between 5 and 15 (to 20)°C and exhibit USTs between 17 and 25 (to 26)°C.…”

Section: Temperature Demands and Geographical Distributionmentioning

confidence: 95%

“…In particular red and brown algal species from both polar regions exhibit temperature growth optima at 0-5°C or even at -2°C tom Dieck 1989, 1990;Novaczek et al 1990;Bischoff and Wiencke 1993;Bischoff-Bä smann and Wiencke 1996;Eggert and Wiencke 2000;McKamey and Amsler 2006). Some species like Georgiella confluens, Gigartina skottsbergii and Plocamium cartilagineum from the Antarctic grow only at 0°C, the lowest temperature tested, but not at 5°C (Bischoff-Bä smann and Wiencke 1996).…”

Section: Temperature Demands and Geographical Distributionmentioning

confidence: 99%

Life strategy, ecophysiology and ecology of seaweeds in polar waters

Wiencke

Clayton

Gómez

et al. 2006

Rev Environ Sci Biotechnol

137

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Polar seaweeds are strongly adapted to the low temperatures of their environment, Antarctic species more strongly than Arctic species due to the longer cold water history of the Antarctic region. By reason of the strong isolation of the Southern Ocean the Antarctic marine flora is characterized by a high degree of endemism, whereas in the Arctic only few endemic species have been found so far. All polar species are strongly shade adapted and their phenology is finely tuned to the strong seasonal changes of the light conditions. The paper summarises the present knowledge of seaweeds from both polar regions with regard to the following topics: the history of seaweed research in polar regions; the environment of seaweeds in polar waters; biodiversity, biogeographical relationships and vertical distribution of Arctic and Antarctic seaweeds; life histories and physiological thallus anatomy; temperature demands and geographical distribution; light demands and depth zonation; the effect of salinity, temperature and desiccation on supraand eulittoral seaweeds; seasonality of reproduction and the physiological characteristics of C. Wiencke (&) AE U. H. Lü der

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“…We have found ecotypic variation with respect to high-temperature tolerance in one pan-Arctic species (Devaleraea ramentacea) whereas 2 other species (Chaetomorpha melagonium and Phycodrys rubens) were more homogeneous (Novaczek et al, 1990). In the latter species, differences occurred in growth rates and in resistance to sublethal temperatures but not in absolute tolerance limits.…”

Section: Introductionmentioning

confidence: 74%

“…Algal species currently occupying both sides of the North Atlantic Ocean may have evolved in the Arctic or Atlantic; they may also have been introduced either from the North Pacific via the Arctic Ocean, or from the south Pacific via either the Caribbean or Tethys Seas (Novaczek et al, 1990). For some millions of years, thermal regimes of the eastern and western coasts of the North Atlantic have differed to a relatively large degree.…”

Section: Introductionmentioning

confidence: 99%

Thermal ecotypes of amphi-Atlantic algae. II. Cold-temperate species (Furcellaria lumbricalis andPolyides rotundus)

Novaczek

Breeman

1990

Helgolander Meeresunters

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Two species of cold-temperate algae from the North Atlantic Ocean, Polyides rotundus and Furceflaria lumbricalis, were tested for growth and survival over a temperature range of -5 to 30 ~ In comparisons of eastern and western isolates, both F. lumbricalis, a North Atlantic endemic, and P. rotundus, a species having related populations in the North Pacific, were quite homogeneous. F. lumbricalis tolerated -5 to 25 ~ and grew well from 0 to 25 ~ with optimal growth at 10-15 ~ P. rotundus tolerated -5 to 27 ~ grew well from 5 to 25 ~ and had a broad optimal range of 10-25 ~ Both species tolerated 3 months in darkness at 0 ~ In neither case could any geographic boundary be explained in terms of lethal seasonal temperatures, suggesting that these species are restricted in distribution by strict thermal and/or daylength requirements for reproduction. The hypothesis that northern species are more homogeneous than southern taxa in terms of thermal tolerance was supported. A second hypothesis, that disjunct cold-temperate species should be more variable than pan-Arctic species, was not supported.

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Thermal ecotypes of amphi-Atlantic algae. I. Algae of Arctic to cold-temperate distribution (Chaetomorpha melagonium, Devaleraea ramentacea andPhycodrys rubens)

Cited by 33 publications

References 19 publications

Physiological responses of the eulittoral macroalgaStictosiphonia hookeri(Rhodomelaceae, Rhodophyta) from Argentina and Chile: salinity, light and temperature acclimation

Physiological responses of the eulittoral macroalgaStictosiphonia hookeri(Rhodomelaceae, Rhodophyta) from Argentina and Chile: salinity, light and temperature acclimation

Life strategy, ecophysiology and ecology of seaweeds in polar waters

Thermal ecotypes of amphi-Atlantic algae. II. Cold-temperate species (Furcellaria lumbricalis andPolyides rotundus)

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