Photosynthetic responses of three common mosses from continental Antarctica

STEFAN PANNEWITZ; T.G. ALLAN GREEN; KADMIEL MAYSEK; MARK SCHLENSOG; ROD SEPPELT; LEOPOLDO G. SANCHO; ROMAN TÜRK; BURKHARD SCHROETER

doi:10.1017/S0954102005002774

Abstract

Predicting the effects of climate change on Antarctic terrestrial vegetation requires a better knowledge of the ecophysiology of common moss species. In this paper we provide a comprehensive matrix for photosynthesis and major environmental parameters for three dominant Antarctic moss species (Bryum subrotundifolium, B. pseudotriquetrum and Ceratodon purpureus). Using locations in southern Victoria Land, (Granite Harbour, 77°S) and northern Victoria Land (Cape Hallett, 72°S) we determined the responses of net photosynthesis and dark respiration to thallus water content, thallus temperature, photosynthetic photon flux densities and CO2 concentration over several summer seasons. The studies also included microclimate recordings at all sites where the research was carried out in field laboratories. Plant temperature was influenced predominantly by the water regime at the site with dry mosses being warmer. Optimal temperatures for net photosynthesis were 13.7°C, 12.0°C and 6.6°C for B. subrotundifolium, B. pseudotriquetrum and C. purpureus, respectively and fall within the known range for Antarctic mosses. Maximal net photosynthesis at 10°C ranked as B. subrotundifolium > B. pseudotriquetrum > C. purpureus. Net photosynthesis was strongly depressed at subzero temperatures but was substantial at 0°C. Net photosynthesis of the mosses was not saturated by light at optimal water content and thallus temperature. Response of net photosynthesis to increase in water content was as expected for mosses although B. subrotundifolium showed a large depression (60%) at the highest hydrations. Net photosynthesis of both B. subrotundifolium and B. pseudotriquetrum showed a large response to increase in CO2 concentration and this rose with increase in temperature; saturation was not reached for B. pseudotriquetrum at 20°C. There was a high level of variability for species at the same sites in different years and between different locations. This was substantial enough to make prediction of the effects of climate change very difficult at the moment.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Barrett, J.E. Virginia, R.A. Hopkins, D.W. Aislabie, J. Bargagli, R. Bockheim, J.G. Campbell, I.B. Lyons, W.B. Moorhead, D.L. Nkem, J.N. Sletten, R.S. Steltzer, H. Wall, D.H. and Wallenstein, M.D. 2006. Terrestrial ecosystem processes of Victoria Land, Antarctica. Soil Biology and Biochemistry, Vol. 38, Issue. 10, p. 3019.

Hopkins, D.W Sparrow, A.D Novis, P.M Gregorich, E.G Elberling, B and Greenfield, L.G 2006. Controls on the distribution of productivity and organic resources in Antarctic Dry Valley soils. Proceedings of the Royal Society B: Biological Sciences, Vol. 273, Issue. 1602, p. 2687.

Adams, Byron J. Bardgett, Richard D. Ayres, Edward Wall, Diana H. Aislabie, Jackie Bamforth, Stuart Bargagli, Roberto Cary, Craig Cavacini, Paolo Connell, Laurie Convey, Peter Fell, Jack W. Frati, Francesco Hogg, Ian D. Newsham, Kevin K. O’Donnell, Anthony Russell, Nicholas Seppelt, Rodney D. and Stevens, Mark I. 2006. Diversity and distribution of Victoria Land biota. Soil Biology and Biochemistry, Vol. 38, Issue. 10, p. 3003.

Buck, William R. Allen, Bruce and Pursell, Ronald A. 2006. Recent literature on bryophytes—109(2). The Bryologist, Vol. 109, Issue. 2, p. 276.

Schroeter, Burkhard Sancho, Leopoldo and Allan Green, T 2007. Functional Plant Ecology, Second Edition. Vol. 20073278, Issue. ,

Hopkins, D.W. Sparrow, A.D. Shillam, L.L. English, L.C. Dennis, P.G. Novis, P. Elberling, B. Gregorich, E.G. and Greenfield, L.G. 2008. Enzymatic activities and microbial communities in an Antarctic dry valley soil: Responses to C and N supplementation. Soil Biology and Biochemistry, Vol. 40, Issue. 9, p. 2130.

Hopkins, D.W. Sparrow, A.D. Gregorich, E.G. Novis, P. Elberling, B. and Greenfield, L.G. 2008. Redistributed lacustrine detritus as a spatial subsidy of biological resources for soils in an Antarctic dry valley. Geoderma, Vol. 144, Issue. 1-2, p. 86.

Hopkins, D. W. Sparrow, A. D. Gregorich, E. G. Elberling, B. Novis, P. Fraser, F. Scrimgeour, C. Dennis, P. G. Meier‐Augenstein, W. and Greenfield, L. G. 2009. Isotopic evidence for the provenance and turnover of organic carbon by soil microorganisms in the Antarctic dry valleys. Environmental Microbiology, Vol. 11, Issue. 3, p. 597.

Hájek, J. Váczi, P. Barták, M. Smejkal, L. and Lipavská, H. 2009. Cryoproective role of ribitol in Xanthoparmelia somloensis. Biologia plantarum, Vol. 53, Issue. 4, p. 677.

Waite, Mashuri and Sack, Lawren 2010. How does moss photosynthesis relate to leaf and canopy structure? Trait relationships for 10 Hawaiian species of contrasting light habitats. New Phytologist, Vol. 185, Issue. 1, p. 156.

Schroeter, Burkhard Green, T.G. Allan Pannewitz, Stefan Schlensog, Mark and Sancho, Leopoldo G. 2010. Fourteen degrees of latitude and a continent apart: comparison of lichen activity over two years at continental and maritime Antarctic sites. Antarctic Science, Vol. 22, Issue. 6, p. 681.

Ruprecht, Ulrike Lumbsch, H. Thorsten Brunauer, Georg Green, T.G. Allan and Türk, Roman 2010. Diversity ofLecidea(Lecideaceae, Ascomycota) species revealed by molecular data and morphological characters. Antarctic Science, Vol. 22, Issue. 6, p. 727.

Seppelt, Rodney D. 2011. Bryophyte Ecology and Climate Change. p. 251.

Singh, Shiv M. Singh, Purnima and Ravindra, Rasik 2011. Screening of antioxidant potential of Arctic lichens. Polar Biology, Vol. 34, Issue. 11, p. 1775.

Schroeter, Burkhard Green, T. G. Allan Pannewitz, Stefan Schlensog, Mark and Sancho, Leopoldo G. 2011. Summer variability, winter dormancy: lichen activity over 3 years at Botany Bay, 77°S latitude, continental Antarctica. Polar Biology, Vol. 34, Issue. 1, p. 13.

Green, T. G. Allan Sancho, Leopoldo G. Pintado, Ana and Schroeter, Burkhard 2011. Functional and spatial pressures on terrestrial vegetation in Antarctica forced by global warming. Polar Biology, Vol. 34, Issue. 11, p. 1643.

Ötvös, Edit and Jócsák, Ildikó 2011. Bryophyte Ecology and Climate Change. p. 55.

Barták, Miloš Váczi, Peter and Hájek, Josef 2012. Photosynthetic activity in three vascular species of Spitsbergen vegetation during summer season in response to microclimate. Polish Polar Research, Vol. 33, Issue. 4, p. 443.

Cannone, Nicoletta Binelli, Giorgio Worland, M. Roger Convey, Peter and Guglielmin, Mauro 2012. CO2 fluxes among different vegetation types during the growing season in Marguerite Bay (Antarctic Peninsula). Geoderma, Vol. 189-190, Issue. , p. 595.

RUPRECHT, Ulrike BRUNAUER, Georg and PRINTZEN, Christian 2012. Genetic diversity of photobionts in Antarctic lecideoid lichens from an ecological view point. The Lichenologist, Vol. 44, Issue. 5, p. 661.

Download full list

Article contents

Photosynthetic responses of three common mosses from continental Antarctica

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Photosynthetic responses of three common mosses from continental Antarctica

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests