Bryophyte species composition over moisture gradients in the Windmill Islands, East Antarctica: development of a baseline for monitoring climate change impacts

Extreme environmental conditions prevail on the Antarctic continent and limit plant diversity to cryptogamic communities, dominated by bryophytes and lichens. Even small abiotic shifts, associated with climate change, are likely to have pronounced impacts on these communities that currently exist at their physiological limit of survival. Changes to moisture availability, due to precipitation shifts or alterations to permanent snow reserves, will most likely cause greatest impact. In order to establish a baseline for determining the effect of climate change on continental Antarctic terrestrial communities and to better understand bryophyte species distributions in relation to moisture in a floristically important Antarctic region, this study surveyed finescale bryophyte patterns and turf water and nutrient contents along community gradients in the Windmill Islands, East Antarctica. The survey found that the Antarctic endemic, Schistidium antarctici, dominated the wettest habitats, Bryum pseudotriquetrum distribution spanned the gradient, whilst Ceratodon purpureus and Cephaloziella varians were restricted to the driest habitats. These patterns, along with knowledge of these species relative physiology, suggest the endemic Schistidium antarctici will be negatively impacted under a drying trend. This study provides a model for quantitative finescale analysis of bryophyte distributions in cryptogamic communities and forms an important reference site for monitoring impacts of climate change in Antarctica.

[1]  K. Newsham The biology and ecology of the liverwort Cephaloziella varians in Antarctica , 2009, Antarctic Science.

[2]  J. Shaw,et al.  Subantarctic Macquarie Island – a model ecosystem for studying animal-derived nitrogen sources using 15N natural abundance , 1998, Oecologia.

[3]  Ė. Galimov,et al.  Carbon isotope composition of Antarctic plants , 2000 .

[4]  D. Takezawa,et al.  Rapid degradation of starch in chloroplasts and concomitant accumulation of soluble sugars associated with ABA-induced freezing tolerance in the moss Physcomitrella patens. , 2005, Journal of plant physiology.

[5]  H. Lim,et al.  Carbon and nitrogen isotope composition of vegetation on King George Island, maritime Antarctic , 2009, Polar Biology.

[6]  Sharon A. Robinson,et al.  Ultraviolet B screening potential is higher in two cosmopolitan moss species than in a co‐occurring Antarctic endemic moss: implications of continuing ozone depletion , 2006 .

[7]  J. Wasley The effect of climate change on Antarctic terrestrial flora , 2004 .

[8]  R. Seppelt,et al.  Exposure and Nutrients As Delimiters of Lichen Communities in Continental Antarctica , 1995, The Lichenologist.

[9]  R. Smith,et al.  Classification and ordination of cryptogamic communities in Wilkes Land, Continental Antarctica , 1988, Vegetatio.

[10]  P. Hietz,et al.  Stable isotopic composition of carbon and nitrogen and nitrogen content in vascular epiphytes along an altitudinal transect , 1999 .

[11]  S. Robinson,et al.  Desiccation tolerance of three moss species from continental Antarctica , 2000 .

[12]  Sharon A. Robinson,et al.  Some like it wet - biological characteristics underpinning tolerance of extreme water stress events in Antarctic bryophytes. , 2006, Functional plant biology : FPB.

[13]  D. Robinson δ15N as an integrator of the nitrogen cycle , 2001 .

[14]  J. Kirkpatrick,et al.  Bryophyte relationships with environmental and structural variables in Tasmanian old-growth mixed eucalypt forest , 2006 .

[15]  J. Raven,et al.  Stable carbon isotope discrimination measurements in Sphagnum and other bryophytes: physiological and ecological implications , 1992 .

[16]  M. Sakurai,et al.  Accumulation of theanderose in association with development of freezing tolerance in the moss Physcomitrella patens. , 2006, Phytochemistry.

[17]  G. Gebauer,et al.  Nitrogen nutrition and isotope differences among life forms at the northern treeline of Alaska , 1994, Oecologia.

[18]  M. Hovenden Seasonal Trends in Nitrogen Status of Antarctic Lichens , 2000 .

[19]  P. Convey,et al.  External nutrient inputs into terrestrial ecosystems of the Falkland Islands and the Maritime Antarctic region , 2007, Polar Biology.

[20]  P. Convey,et al.  Climate change effects on organic matter decomposition rates in ecosystems from the Maritime Antarctic and Falkland Islands , 2007 .

[21]  H. U. Ling,et al.  Polyol and sugar content of terrestrial plants from continental Antarctica , 1992, Antarctic Science.

[22]  R. Smith Biological and environmental characteristics of three cosmopolitan mosses dominant in continental Antarctica , 1999 .

[23]  L. Rejtõ,et al.  Resolving environmental drivers of microbial community structure in Antarctic soils , 2010, Antarctic Science.

[24]  A. Huiskes,et al.  Stable Isotope Ratios as a Tool for Assessing Changes in Carbon and Nutrient Sources in Antarctic Terrestrial Ecosystems , 2006, Plant Ecology.

[25]  I. Goodwin Holocene Deglaciation, Sea-Level Change, and the Emergence of the Windmill Islands, Budd Coast, Antarctica , 1993, Quaternary Research.

[26]  S. Hills,et al.  Phantom hitch-hikers mislead estimates of genetic variation in Antarctic mosses , 2007, Plant Systematics and Evolution.

[27]  N. Smirnoff The carbohydrates of bryophytes in relation to desiccation tolerance , 1992 .

[28]  T. Green,et al.  Lichen and moss communities of Botany Bay, Granite Harbour, Ross Sea, Antarctica , 2010, Antarctic Science.

[29]  Eric J. Woehler,et al.  A 9000-year record of Adélie penguin occupation and diet in the Windmill Islands, East Antarctica , 2005, Antarctic Science.

[30]  D. R. Melick,et al.  Phytogeography of bryophyte and lichen vegetation in the Windmill Islands, Wilkes Land, Continental Antarctica , 2004, Vegetatio.

[31]  Sharon A. Robinson,et al.  Climate change manipulations show Antarctic flora is more strongly affected by elevated nutrients than water , 2006 .

[32]  W. Stock,et al.  On the uptake of ornithogenic products by plants on the inland mountains of Dronning Maud Land, Antarctica, using stable isotopes , 1998, Polar Biology.

[33]  Quantitative community analysis and bryophyte ecology on Signy Island , 1967, Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences.

[34]  R. Seppelt,et al.  Vegetation Patterns in Relation to Climatic and Endogenous Changes in Wilkes Land, Continental Antarctica , 1997 .

[35]  D. Read,et al.  Widespread association between the ericoid mycorrhizal fungus Rhizoscyphus ericae and a leafy liverwort in the maritime and sub-Antarctic. , 2007, The New phytologist.

[36]  Andreas Richter,et al.  1d-1-O-methyl-muco-inositol in Viscum album and members of the rhizophoraceae , 1990 .

[37]  Lewis Smith,et al.  Vegetation of the South Orkney Islands with particular reference to Signy Island , 1972 .

[38]  T. Green,et al.  Slowest to fastest: Extreme range in lichen growth rates supports their use as an indicator of climate change in Antarctica , 2007 .

[39]  Sharon A. Robinson,et al.  Living on the edge – plants and global change in continental and maritime Antarctica , 2003 .

[40]  D. Wall,et al.  Invertebrate Biodiversity in Antarctic Dry Valley Soils and Sediments , 1999, Ecosystems.

[41]  Sharon A. Robinson,et al.  Radiocarbon bomb spike reveals biological effects of Antarctic climate change , 2012 .

[42]  S. K. Rice,et al.  The influence of water content and leaf anatomy on carbon isotope discrimination and photosynthesis in Sphagnum , 1996 .

[43]  Hua Xu,et al.  Nutrient compositions and potential greenhouse gas production in penguin guano, ornithogenic soils and seal colony soils in coastal Antarctica , 2009, Antarctic Science.

[44]  J. Bowman,et al.  Freezing and desiccation tolerance in the moss Physcomitrella patens: an in situ Fourier transform infrared spectroscopic study. , 2006, Biochimica et biophysica acta.