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Fourteen degrees of latitude and a continent apart: comparison of lichen activity over two years at continental and maritime Antarctic sites

Published online by Cambridge University Press:  17 September 2010

Burkhard Schroeter
Affiliation:
Botanisches Institut, Christian-Albrechts-Universität, D-24098 Kiel, Germany
T.G. Allan Green*
Affiliation:
Biological Sciences, University of Waikato, Private Bag 3105, Hamilton, New Zealand Biologia Vegetal II, Farmacia Facultad, Universidad Computense, 28040 Madrid, Spain
Stefan Pannewitz
Affiliation:
Botanisches Institut, Christian-Albrechts-Universität, D-24098 Kiel, Germany
Mark Schlensog
Affiliation:
Botanisches Institut, Christian-Albrechts-Universität, D-24098 Kiel, Germany
Leopoldo G. Sancho
Affiliation:
Biologia Vegetal II, Farmacia Facultad, Universidad Computense, 28040 Madrid, Spain

Abstract

There are marked declines in precipitation, mean temperatures and the number of lichen species with increasing latitude in Antarctica. However, it is not known which factors are the predominant controllers of biodiversity changes. Results are presented from over two years of almost continuous monitoring of both microclimate and activity in lichens at Livingston Island, South Shetland Islands, 62°S, and Botany Bay, Ross Sea region, 77°S. Lichen activity was evident over a much longer period at Livingston Island, (3694 versus 897 hours) and could occur in any month whereas it was almost completely confined to the period November–February at Botany Bay. Mean air temperatures were much lower at Botany Bay (-18° compared to -1.5°C at Livingston Island), but the temperatures at which the lichens were active were almost identical at around 2°C at both sites. When the lichens were active incident light at Botany Bay was very much higher. The differences are related to the availability of meltwater which only occurs at times of high light and warm temperatures at Botany Bay. Temperature as a direct effect does not seem to explain the differences in biodiversity between the sites, but an indirect effect through active hours is much more probable. In addition there are negative effects of stresses such as high light and extreme winter cold at Botany Bay.

Type
Research Article
Copyright
Copyright © Antarctic Science Ltd 2010

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Footnotes

Present address: Leibniz Institute for Science and Mathematics Education, University of Kiel, Olshausenstr. 62, D-24098 Kiel, Germany

References

Dietz, S., Büdel, B., Lange, O.L. Bilger, W. 2000. Transmittance of light through the cortex of lichens from contrasting habitats. New Aspects in Cryptogamic Research. Contributions in Honour of Ludger Kappen. Bibliotheca Lichenologica, 75, 171182.Google Scholar
Friedmann, E.I. Ocampo, R. 1986. Endolithic blue-green algae in the dry valleys: primary producers in the Antarctic desert ecosystem. Science, 193, 12471249.CrossRefGoogle Scholar
Gaio-Oliveira, G., Dahlman, L., Maguas, C. Palmqvist, K. 2004. Growth in relation to microclimate conditions and physiological characteristics of four Lobaria pulmonaria populations in two contrasting sites. Ecography, 27, 1328.CrossRefGoogle Scholar
Gauslaa, Y. Solhaug, K.A. 2001. Fungal melanins as a sun screen for symbiotic green algae in the lichen Lobaria pulmonaria. Oecologia, 126, 462471.CrossRefGoogle ScholarPubMed
Green, T.G.A., Schroeter, B. Sancho, L.G. 2007. Plant life in Antarctica. In Pugnaire, F.I. & Valladares, F., eds. Functional plant ecology, 2nd ed. Baton Rota, FL: CRC Press, 389433.CrossRefGoogle Scholar
Green, T.G.A., Schroeter, B. Seppelt, R.D. 2000. Effect of temperature, light and ambient UV on the photosynthesis of the moss Bryum argenteum Hedw. in continental Antarctica. In Davison, W., Howard-Williams, C. & Broady, P., eds. Antarctic ecosystems: models of wider ecological understanding. Christchurch, New Zealand: Caxton Press, 165170.Google Scholar
Green, T.G.A., Schlensog, M., Sancho, L.G., Winkler, J., Broom, F.D. Schroeter, B. 2002. The photobiont determines the pattern of photosynthetic activity within a lichen thallus containing cyanobacterial and green algal sectors (photosymbiodeme). Oecologia, 130, 191198.CrossRefGoogle ScholarPubMed
Hill, D.J. Woolhouse, H.W. 1966. Aspects of the autecology of Xanthoria parietina agg. Lichenologist, 3, 207214.CrossRefGoogle Scholar
Hills, S.F., Stevens, M.I. Gemmill, C.E.C. 2010. Molecular support for Pleistocene persistence of the continental Antarctic moss Bryum argenteum. Antarctic Science, 21, 10.1017/S0954102010000453.Google Scholar
Kappen, L. 1993. Lichens in the Antarctic region. In Friedmann, E.I., ed. Antarctic microbiology. New York: Wiley-Liss, 433490.Google Scholar
Kappen, L. Schroeter, B. 2002. Plants and lichens in the Antarctic, their way of life and their relevance to soil formation. In Beyer, L. & Bölter, M., eds. Geoecology of Antarctic ice-free coastal landscapes. Berlin: Springer, 327373.CrossRefGoogle Scholar
Kappen, L., Schroeter, B., Green, T.G.A. Seppelt, R.D. 1998. Chlorophyll a fluorescence and CO2 exchange of Umbilicaria aprina under extreme light stress in the cold. Oecologia, 113, 325331.CrossRefGoogle ScholarPubMed
Kennedy, A.D. 1995. Antarctic terrestrial ecosystem response to global environmental change. Annual Review of Ecology and Systematics, 26, 683704.CrossRefGoogle Scholar
Lange, O.L. 2003a. Photosynthetic productivity of the epilithic lichen Lecanora muralis: long-term field monitoring of CO2 exchange and its physiological interpretation. II. Diel and seasonal patterns of net photosynthesis and respiration. Flora, 198, 5570.Google Scholar
Lange, O.L. 2003b. Photosynthetic productivity of the epilithic lichen Lecanora muralis: long-term field monitoring of CO2 exchange and its physiological interpretation. III. Diel, seasonal, and annual carbon budgets. Flora, 198, 277292.Google Scholar
Longton, R.E. 1988. Biology of polar bryophytes and lichens. Cambridge: Cambridge University Press, 391 pp.CrossRefGoogle Scholar
Longton, R.E. MacIver, M.A. 1977. Climatic relationships in Antarctic and Northern Hemisphere populations of a cosmopolitan moss, Bryum argenteum Hedw. In Llano, G.A., ed. Adaptations within Antarctic ecosystems. Proceedings of the Third SCAR Symposium on Antarctic Biology. Washington, DC: Smithsonian Institution, 899919.Google Scholar
McGaughran, A., Convey, P., Redding, G.P. Stevens, M.I. 2010. Temporal and spatial metabolic rate variation in an Antarctic springtail. Journal of Insect Physiology, 56, 5764.CrossRefGoogle Scholar
Moldaenke, C. 1989. Bau eines Chlorophyll-Fluoreszenzmeflgerates und Untersuchung seiner Anwendungsmoglichkeit im Feldeinsatz und in der Systemidentifikation. Diplomarbeit, Universitat Kiel.Google Scholar
Nybakken, L., Asplund, J., Solhaug, K.A. Gauslaa, Y. 2007. Forest successional stage affects the cortical secondary chemistry of three old forest lichens. Journal of Chemical Ecology, 33, 16071618.CrossRefGoogle ScholarPubMed
Ochyra, R., Lewis Smith, R.I. Bednarek-Ochyra, H. 2008. The illustrated moss flora of Antarctica. Cambridge: Cambridge University Press, 704 pp.Google Scholar
Øvstedal, D.O. Lewis Smith, R.I. 2001. Lichens of Antarctica and South Georgia: a guide to their identification and ecology. Cambridge: Cambridge University Press, 411 pp.Google Scholar
Pannewitz, S., Schlensog, M., Green, T.G.A., Sancho, L.G. Schroeter, B. 2003. Are lichens active under snow in continental Antarctica? Oecologia, 135, 3038.CrossRefGoogle Scholar
Pannewitz, S., Green, T.G.A., Maysek, K., Schlensog, M., Seppelt, R.D., Sancho, L.G., Türk, R. Schroeter, B. 2005. Photosynthetic responses of three common mosses from continental Antarctica. Antarctic Science, 17, 341352.CrossRefGoogle Scholar
Peat, H.J., Clarke, A. Convey, P. 2007. Diversity and biogeography of the Antarctic flora. Journal of Biogeography, 34, 132146.CrossRefGoogle Scholar
Ramos, M. Vieira, G. 2009. Evaluation of the ground surface Enthalpy balance from bedrock temperatures (Livingston Island, maritime Antarctic). The Cryosphere, 3, 133145.CrossRefGoogle Scholar
Robinson, S.A., Wasley, J., Popp, M. Lovelock, C.E. 2000. Desiccation tolerance of three moss species from continental Antarctica. Australian Journal of Plant Physiology, 27, 379388.Google Scholar
Sancho, L.G., Green, T.G.A. Pintado, A. 2007. Slowest to fastest: extreme range in lichen growth rates supports their use as an indicator of climate change in Antarctica. Flora, 202, 667673.CrossRefGoogle Scholar
Sancho, L.G., Schulz, F., Schroeter, B. Kappen, L. 1999. Bryophyte and lichen flora of South Bay (Livingston Island, South Shetland Islands, Antarctica). Nova Hedwigia, 68, 301337.CrossRefGoogle Scholar
Sancho, L.G., Pintado, A., Green, T.G.A., Pannewitz, S. Schroeter, B. 2003. Photosynthetic and morphological variation within and among populations of the Antarctic lichen Umbilicaria aprina: implications of thallus size. Bibliotheca Lichenologica, 86, 299311.Google Scholar
Schreiber, U., Bilger, W. Neubauer, C. 1994. Chlorophyll fluorescence as a nonintrusive indicator for rapid assessment of in vivo photosynthesis. In Schulze, E.D. & Caldwell, M.M., eds. Ecophysiology of photosynthesis. Berlin: Springer, 4970.Google Scholar
Schroeter, B. 1997. Grundlagen der Stoffproduktion von Kryptogamen unter besonderer Berücksichtigung der Flechten. Habilitation thesis, Universität Kiel. [Unpublished].Google Scholar
Schroeter, B., Kappen, L. Moldaenke, C. 1991. Continuous in situ recording of the photosynthetic activity of Antarctic lichens - established methods and a new approach. Lichenologist, 23, 253265.CrossRefGoogle Scholar
Schroeter, B., Green, T.G.A., Seppelt, R.D. Kappen, L. 1992. Monitoring photosynthetic activity of crustose lichens using PAM-2000 fluorescence system. Oecologia, 92, 457462.CrossRefGoogle ScholarPubMed
Schroeter, B., Kappen, L., Green, T.G.A. Seppelt, R.D. 1997. Lichens and the Antarctic environment; effects of temperature and water availability of photosynthesis. In Lyons, W.B., Howard-Williams, C. & Hawes, I., eds. Ecosystem processes in Antarctic ice-free landscapes. Rotterdam: A.A. Balkema, 103117.Google Scholar
Schroeter, B., Kappen, L., Schulz, F. Sancho, L.G. 2000. Seasonal variation in the carbon balance of lichens in the maritime Antarctic: long-term measurements of photosynthetic activity in Usnea aurantiaco-atra. In Davison, W., Howard-Williams, C. & Broady, P., eds. Antarctic ecosystems: model for wider ecological understanding. Christchurch: Caxton Press, 220224.Google Scholar
Schroeter, B., Green, T.G.A., Pannewitz, S., Schlensog, M. Sancho, L.G. 2010. Summer variability, winter dormancy: lichen activity over 3 years at Botany Bay, 77°S latitude, continental Antarctica. Polar Biology, 33, 10.1007/s00300-010-0851-7.Google Scholar
Seppelt, R.D., Tuerk, R., Green, T.G.A., Moser, G., Pannewitz, S., Sancho, L.G. Schroeter, B. 2010. Lichen and moss communities of Botany Bay, Granite Harbour, Ross Sea, Antarctica. Antarctic Science, 10.1017/S0954102010000568.CrossRefGoogle Scholar
Smith, R.I.L. 1994. Vascular plants as bioindicators of regional warming in the Antarctic. Oecologia, 99, 322328.CrossRefGoogle Scholar
Smith, R.I.L. 1999. Biological and environmental characteristics of three cosmopolitan mosses dominant in continental Antarctica. Journal of Vegetation Science, 10, 231242.CrossRefGoogle Scholar
Thomas, E.R., Marshall, G.J. McConnell, J.R. 2008. A doubling in snow accumulation in the western Antarctic Peninsula since 1850. Geophysical Research Letters, 35, 10.1029/2007GL032529.CrossRefGoogle Scholar
Winkler, J.B. Schulz, F. 2000. Seasonal variation of snowcover: a new, inexpensive method for automatically measuring snow depth. New Aspects in Cryptogamic Research. Contributions in Honour of Ludger Kappen. Bibliotheca Lichenologica, 75, 381388.Google Scholar