Browsing by Author "Casanova-Katny, A"

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    Antarctic mosses reveal high resolution records of local microclimates
    (Australian Nuclear Science and Technology Organisation, 2021-11-17) Waterman, MJ; Bramley-Alves, J; Casanova-Katny, A; Zúñiga, GE; Hua, Q; Robinson, SA
    Introduction Life in Antarctica is living in the extreme. To survive there, life must be resilient to sub-zero temperatures, high levels of damaging ultraviolet and solar radiation, strong winds and waterlimiting environments. In this harsh continent where water is locked up as snow and ice for most of the year, mosses are the dominant plant form. Like many living things, these small plants rely on liquid water to survive. The amount of potential water that is available to drive growth, distribution and survival of Antarctic flora is strongly influenced by the changing climate, especially temperature, precipitation and winds. However, meteorological climate records in most of the biologically diverse regions in Antarctica are sparse and limited to a few decades or less. In these areas, there is an increasing need for local climate proxies. We show that Antarctic moss species can be used as living proxies for local water availability through preserved stable carbon isotopes captured in cellulose. Methods and Results Using accelerator and isotope ratio mass spectrometry techniques, we obtained radiocarbon ages and δ¹³C signatures along 26 cores of long shoots of moss collected from the Windmill Islands, East Antarctica and South Shetland Islands in the Maritime Antarctic. AMS radiocarbon results showed that these once living cores are up to 500 years old. The five moss species studied grew at different rates; the slowest species grew at less than 1 mm/year while the fastest achieved 8 mm/year. These moss cores provide a high-resolution record, at annual to decadal scales, of their microclimate. Our results also reveal that growth patterns of these Antarctic plants are dependent on local moisture environments. Trends in δ¹³C signatures indicate microclimates in these regions are drying. Conclusion This work suggests that mosses have considerable potential as climate proxies by providing a temporal and spatial history of microclimate in Antarctica. Applying these measures will allow us to determine which terrestrial sites are at risk of the negative impacts of climate change in order to inform critical conservation efforts in a rapidly changing environment. © The Authors
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    Ecology of the past: old-growth mosses as potential biological proxies for past Antarctic climate
    (Scientific Committee on Antarctic Research, 2017-07-10) Waterman, MJ; Hua, Q; Casanova-Katny, A; Zúñiga, GE; Robinson, SA
    Climate changes in temperature, stratospheric ozone levels, wind speed and precipitation have strong implications on the bryophyte-dominated terrestrial vegetation of Antarctica. The reduction in stratospheric ozone substantially impacts wind, precipitation and radiation patterns over the southern continent potentially leading to dramatic shifts in species diversity, location and abundance. Thus, monitoring regional climates is becoming increasingly important. However, there is a substantial need for climate proxies, e.g. biomarkers, given the sparse distribution, limitations and short record of Antarctic meteorological stations. Bryophytes (mosses, liverworts), non-vascular plants that are crucial components to Antarctic terrestrial life, have unique abilities to show rapid and long-term changes in their biochemical signatures and ecophysiology in response to their surrounding environment. Therefore, we aim to develop and use Antarctic mosses as biological proxies for climate around the Antarctic coast. This included analysing pigments (photosynthetic and photoprotective), stable isotopes (δ13C), hormones and sugars of a range of Continental and Maritime mosses that have been dated using the radiocarbon bomb-pulse method. In some East Antarctic moss species, the δ13C signature in cellulose can be an accurate and preserved way to detect past water environments. Therefore, long-term regional climate records, such as moss water availability and ozone levels, could be locked away as chemical signatures within ancient moss shoots of up to 420 years old. We show, however, that this is likely to be species specific and so we discuss the potential of various moss species, including Ceratodon purpureus, Schistidium antarctici, Chorisodontium aciphyllym, Polytrichastrum alpinum and Bryum pseudotriquetrum, as biomarkers. In addition, we show how important it is to evaluate the abilities of specific species to record and preserve past local environments in order to determine the scale of which these miniature plants can provide regional climate records. We explain that there are complications and that various species as well as environmental factors need to be considered when using biomarkers in the Antarctic.