Abstract
Over winter, alpine plants are protected from low-temperature extremes by a blanket of snow. Climate change predictions indicate an overall reduction in snowpack and an earlier thaw; a situation which could expose the tips of shrubs which extend above the snowpack to freezing events in early spring, and cause foliar frost damage during the onset of physiological activity. We assessed the photosynthetic responses of freezing-damaged shrub leaves from an assay of freezing temperatures in the Snowy Mountains in south-eastern Australia, using chlorophyll fluorometery ex situ. We sampled leaves that were exposed early during the spring thaw and leaves that were buried in snow for up to two extra weeks, from four evergreen shrub species at monthly intervals following the period of snowmelt. Freezing resistance (estimated from LT50) was poorest at the earliest spring sampling time, in both exposed above-snow and protected below-snow foliage in all species. Protected foliage in early spring had lower freezing resistance than exposed foliage, but not significantly so. By the third sampling time, freezing resistance was significantly better in the lower protected foliage (LT50 of − 14) compared with the upper exposed foliage (LT50 of − 10) in one species. Over the course of spring, freezing resistance improved significantly in all species, with LT50 values of between − 10 and − 15 °C by the third sampling time, which is lower than the minimum air temperatures recorded at that time (> − 5 °C). The results indicate that the dominant evergreen shrub species in this area may only be susceptible to freezing events very early in spring, before a period of frost-hardening occurs after snowmelt. Later in spring, these alpine shrubs appear frost hardy, thus further perpetuating the positive feedbacks surrounding shrub expansion in alpine areas.
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Acknowledgements
We thank the New South Wales National Parks and Wildlife Service for providing the research laboratory space and equipment at Waste Point, Jindabyne. We thank John Morgan at La Trobe University for use of the chlorophyll fluorometer. Janice Lord made many useful suggestions on the techniques employed and edited an early version of the manuscript. We also thank two anonymous reviewers who helped to substantially improve the manuscript.
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Communicated by Bradley J. Butterfield.
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Venn, S.E., Green, K. Evergreen alpine shrubs have high freezing resistance in spring, irrespective of snowmelt timing and exposure to frost: an investigation from the Snowy Mountains, Australia. Plant Ecol 219, 209–216 (2018). https://doi.org/10.1007/s11258-017-0789-8
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DOI: https://doi.org/10.1007/s11258-017-0789-8