Soil biota sensitivity to hydroclimate variability in a polar desert ecosystem

Soil biota sensitivity to hydroclimate variability in a polar desert ecosystem

An anomalous warm weather event in the Antarctic McMurdo Dry Valleys on 18 March 2022 created an opportunity to characterize soil biota communities most sensitive to freeze–thaw stress. This event caused unseasonal melt within Taylor Valley, activating stream water and microbial mats around Canada S...

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Bibliographic Details
Main Authors: Meredith D. Snyder, Byron J. Adams, Abigail Borgmeier, Jesse Jorna, Sarah N. Power, Mark R. Salvatore, John. E. Barrett
Format: Article
Language:English
Published: Taylor & Francis Group 2025-12-01
Series:Arctic, Antarctic, and Alpine Research
Subjects:
Climate variation
extreme weather
soil invertebrates
McMurdo Dry Valleys
microbial community
Online Access:https://www.tandfonline.com/doi/10.1080/15230430.2025.2485283
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Summary:An anomalous warm weather event in the Antarctic McMurdo Dry Valleys on 18 March 2022 created an opportunity to characterize soil biota communities most sensitive to freeze–thaw stress. This event caused unseasonal melt within Taylor Valley, activating stream water and microbial mats around Canada Stream. Liquid water availability in this polar desert is a driver of soil biota distribution and activity. Because climate change impacts hydrological regimes, we aimed to determine the effect on soil communities. We sampled soils identified from this event that experienced thaw, nearby hyper-arid areas, and wetted areas that did not experience thaw to compare soil bacterial and invertebrate communities. Areas that exhibited evidence of freeze–thaw supported the highest live and dead nematode counts and were composed of soil taxa from hyper-arid landscapes and wetted areas. They received water inputs from snowpacks, hyporheic water, or glacial melt, contributing to community differences associated with organic matter and salinity gradients. Inundated soils had higher organic matter and lower conductivity (p < .02) and hosted the most diverse microbial and invertebrate communities on average. Our findings suggest that as liquid water becomes more available under predicted climate change, soil communities adapted to the hyper-arid landscape will shift toward diverse, wetted soil communities.
ISSN:1523-0430
1938-4246

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