Diversity, drivers and dispersal of East Antarctic soil microbiota

Microbes are the life support system of the biosphere. Their metabolic activities have been tightly linked to establishing and maintaining core ecosystem processes around the globe, including the polar deserts of terrestrial Antarctica. Shaped by the continent’s extreme abiotic constraints and physi...

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Bibliographic Details
Main Author: Zhang, Eden
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: UNSW Sydney 2021
Subjects:
Online Access:https://dx.doi.org/10.26190/unsworks/2044
http://hdl.handle.net/1959.4/100134
id ftdatacite:10.26190/unsworks/2044
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic Antarctica
Soil Microbiome
Microbial Ecology
Climate Change
4106 Soil sciences
310703 Microbial ecology
spellingShingle Antarctica
Soil Microbiome
Microbial Ecology
Climate Change
4106 Soil sciences
310703 Microbial ecology
Zhang, Eden
Diversity, drivers and dispersal of East Antarctic soil microbiota
topic_facet Antarctica
Soil Microbiome
Microbial Ecology
Climate Change
4106 Soil sciences
310703 Microbial ecology
description Microbes are the life support system of the biosphere. Their metabolic activities have been tightly linked to establishing and maintaining core ecosystem processes around the globe, including the polar deserts of terrestrial Antarctica. Shaped by the continent’s extreme abiotic constraints and physical isolation, core ecosystem processes such as primary production and geochemical cycling often involve unique taxa with novel functional traits thus emphasizing the high conservational value of endemic microbiota. Up till now, microorganisms were rarely considered in Antarctic conservation frameworks despite growing concerns about complex environmental change and our anthropogenic footprint. Major gaps in biodiversity surveys and a general lack of understanding in the basic ecological concepts (niche and neutral) underlying the assemblage of Antarctic soil microbial communities has led to their poor protection status and regional sampling bias. Systematic retrieval of baseline data across the continent is therefore much needed, especially in Eastern Antarctica. In support of bridging this gap, we combined a comprehensive amplicon survey (>700 soil samples) with multivariate analyses and high-end modelling approaches to discern biogeographic patterns of polar soil bacteria, micro-eukarya and archaea throughout two coastal regions in Eastern Antarctica – the Windmill Islands and hyperarid Vestfold Hills. This thesis entails three simple but important mission statements: (1) to unveil the diversity of East Antarctic soil microbiota using a multi-domain approach; (2) to identify key edaphic drivers and threshold tipping points by advancing methods for quantifying multispecies responses to change along environmental gradients; and (3) to explore the influence of wind-driven dispersal as a new initiative for monitoring ecosystem change using a combination of dust samples and particulate trajectory modelling with historical climate data. Soil biodiversity profiles and co-occurrence networks found bacteria, micro-eukarya and archaea likely to be jointly responsible for molding the microbial backbone of Antarctic polar desert ecosystems. Species co-existence is proposed to be linked to tradeoffs between niche (environmental filtering and competition) and neutral (dispersal, speciation and drift) processes. However, the scales weighing these processes are heavily tipped in favor of strong niche-partitioning, which is expected given the harsh abiotic constraints. Bacteria (average Chao1 = 1427.57), the most strongly niche-driven (wPLN = 1.000, wNB = <0.001), were found to be inherently more diverse than micro-eukarya (average Chao1 = 92.93) and archaea (average Chao1 = 45.60) in the same environments where they co-occurred. In comparison, neutrality played a larger role in the assemblage of micro-eukaryotic (wPLN = <0.001, wNB = 1.000) and archaeal (wPLN = 0.960, wNB = 0.040) communities – especially at the Vestfold Hills, which were identified as a potentially sensitive sink location for local windblown particles travelling westward from the Windmill Islands. Employment of a modified Gradient Forest model enabled us to explore non-linear relationships between biodiversity (>17, 000 sequence variants) and the environment (79 physiochemical variables), for the first time, on the hyperarid Vestfold Hills soil microbiome. Moisture availability was primarily responsible for shaping the regional microbiome. Highest rates of compositional turnover were observed for rarer lineages of bacteria and micro-eukarya within the 10 – 12 % moisture range. Often the most responsive were taxa with phototrophic or nutrient-cycling capacities such as Cyanobacteria, Chlorophyta and Ochrophyta, which were detected in relatively high amounts within soil at Old Wallow (OW) and Rookery Lake (RL). High dispersal propensity of Chlorophyta (>75 %), based on dust biodiversity profiles (n = 25), generated some insight on the potential implications of wind-driven dispersal upon current ecosystem dynamics as Antarctica warms up. In theory, habitat expansion for micro-algal blooms via aeolian processes may lead to increased phototrophic capacity thereby resulting in potential competition for dominance between primary production strategies across Eastern Antarctica. Cascading events from this hypothetical scenario would be especially pertinent if aeolian deposition occurred within the vicinity of bird and seal colonies, like those found at OW and RL in the Vestfold Hills. When also taking into account the distinctive soil micro-eukaryotic and bacterial components at these two East Antarctic sites, OW and RL were recommended as conservation targets for further sampling and protection. Escalation of consequences from climate change and human activities are major threats to Antarctica’s unique biodiversity. In the coming century, strengthening of links between science and governance will be key towards forming a solid basis for future conservation planning and management across Antarctica. Integration of microbial data has been identified as crucial to this action. This thesis tackles one part of the equation by bringing attention to the vastly understudied coastal regions of Eastern Antarctica. More baseline surveys and research, however, are needed to capture the full scope of biodiversity offered by the Antarctic soil microbiome. This enormous effort would require sustained funding, increased international cooperation and greater year-round access to all regions.
format Doctoral or Postdoctoral Thesis
author Zhang, Eden
author_facet Zhang, Eden
author_sort Zhang, Eden
title Diversity, drivers and dispersal of East Antarctic soil microbiota
title_short Diversity, drivers and dispersal of East Antarctic soil microbiota
title_full Diversity, drivers and dispersal of East Antarctic soil microbiota
title_fullStr Diversity, drivers and dispersal of East Antarctic soil microbiota
title_full_unstemmed Diversity, drivers and dispersal of East Antarctic soil microbiota
title_sort diversity, drivers and dispersal of east antarctic soil microbiota
publisher UNSW Sydney
publishDate 2021
url https://dx.doi.org/10.26190/unsworks/2044
http://hdl.handle.net/1959.4/100134
long_lat ENVELOPE(77.935,77.935,-68.600,-68.600)
ENVELOPE(78.073,78.073,-68.498,-68.498)
ENVELOPE(110.417,110.417,-66.350,-66.350)
geographic Antarctic
Old Wallow
Rookery Lake
The Antarctic
Vestfold
Vestfold Hills
Windmill Islands
geographic_facet Antarctic
Old Wallow
Rookery Lake
The Antarctic
Vestfold
Vestfold Hills
Windmill Islands
genre Antarc*
Antarctic
Antarctica
polar desert
Windmill Islands
genre_facet Antarc*
Antarctic
Antarctica
polar desert
Windmill Islands
op_rights Creative Commons Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/legalcode
cc-by-4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.26190/unsworks/2044
_version_ 1766251832975294464
spelling ftdatacite:10.26190/unsworks/2044 2023-05-15T13:49:35+02:00 Diversity, drivers and dispersal of East Antarctic soil microbiota Zhang, Eden 2021 https://dx.doi.org/10.26190/unsworks/2044 http://hdl.handle.net/1959.4/100134 en eng UNSW Sydney Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 CC-BY Antarctica Soil Microbiome Microbial Ecology Climate Change 4106 Soil sciences 310703 Microbial ecology Dissertation thesis Thesis doctoral thesis 2021 ftdatacite https://doi.org/10.26190/unsworks/2044 2022-04-01T18:42:29Z Microbes are the life support system of the biosphere. Their metabolic activities have been tightly linked to establishing and maintaining core ecosystem processes around the globe, including the polar deserts of terrestrial Antarctica. Shaped by the continent’s extreme abiotic constraints and physical isolation, core ecosystem processes such as primary production and geochemical cycling often involve unique taxa with novel functional traits thus emphasizing the high conservational value of endemic microbiota. Up till now, microorganisms were rarely considered in Antarctic conservation frameworks despite growing concerns about complex environmental change and our anthropogenic footprint. Major gaps in biodiversity surveys and a general lack of understanding in the basic ecological concepts (niche and neutral) underlying the assemblage of Antarctic soil microbial communities has led to their poor protection status and regional sampling bias. Systematic retrieval of baseline data across the continent is therefore much needed, especially in Eastern Antarctica. In support of bridging this gap, we combined a comprehensive amplicon survey (>700 soil samples) with multivariate analyses and high-end modelling approaches to discern biogeographic patterns of polar soil bacteria, micro-eukarya and archaea throughout two coastal regions in Eastern Antarctica – the Windmill Islands and hyperarid Vestfold Hills. This thesis entails three simple but important mission statements: (1) to unveil the diversity of East Antarctic soil microbiota using a multi-domain approach; (2) to identify key edaphic drivers and threshold tipping points by advancing methods for quantifying multispecies responses to change along environmental gradients; and (3) to explore the influence of wind-driven dispersal as a new initiative for monitoring ecosystem change using a combination of dust samples and particulate trajectory modelling with historical climate data. Soil biodiversity profiles and co-occurrence networks found bacteria, micro-eukarya and archaea likely to be jointly responsible for molding the microbial backbone of Antarctic polar desert ecosystems. Species co-existence is proposed to be linked to tradeoffs between niche (environmental filtering and competition) and neutral (dispersal, speciation and drift) processes. However, the scales weighing these processes are heavily tipped in favor of strong niche-partitioning, which is expected given the harsh abiotic constraints. Bacteria (average Chao1 = 1427.57), the most strongly niche-driven (wPLN = 1.000, wNB = <0.001), were found to be inherently more diverse than micro-eukarya (average Chao1 = 92.93) and archaea (average Chao1 = 45.60) in the same environments where they co-occurred. In comparison, neutrality played a larger role in the assemblage of micro-eukaryotic (wPLN = <0.001, wNB = 1.000) and archaeal (wPLN = 0.960, wNB = 0.040) communities – especially at the Vestfold Hills, which were identified as a potentially sensitive sink location for local windblown particles travelling westward from the Windmill Islands. Employment of a modified Gradient Forest model enabled us to explore non-linear relationships between biodiversity (>17, 000 sequence variants) and the environment (79 physiochemical variables), for the first time, on the hyperarid Vestfold Hills soil microbiome. Moisture availability was primarily responsible for shaping the regional microbiome. Highest rates of compositional turnover were observed for rarer lineages of bacteria and micro-eukarya within the 10 – 12 % moisture range. Often the most responsive were taxa with phototrophic or nutrient-cycling capacities such as Cyanobacteria, Chlorophyta and Ochrophyta, which were detected in relatively high amounts within soil at Old Wallow (OW) and Rookery Lake (RL). High dispersal propensity of Chlorophyta (>75 %), based on dust biodiversity profiles (n = 25), generated some insight on the potential implications of wind-driven dispersal upon current ecosystem dynamics as Antarctica warms up. In theory, habitat expansion for micro-algal blooms via aeolian processes may lead to increased phototrophic capacity thereby resulting in potential competition for dominance between primary production strategies across Eastern Antarctica. Cascading events from this hypothetical scenario would be especially pertinent if aeolian deposition occurred within the vicinity of bird and seal colonies, like those found at OW and RL in the Vestfold Hills. When also taking into account the distinctive soil micro-eukaryotic and bacterial components at these two East Antarctic sites, OW and RL were recommended as conservation targets for further sampling and protection. Escalation of consequences from climate change and human activities are major threats to Antarctica’s unique biodiversity. In the coming century, strengthening of links between science and governance will be key towards forming a solid basis for future conservation planning and management across Antarctica. Integration of microbial data has been identified as crucial to this action. This thesis tackles one part of the equation by bringing attention to the vastly understudied coastal regions of Eastern Antarctica. More baseline surveys and research, however, are needed to capture the full scope of biodiversity offered by the Antarctic soil microbiome. This enormous effort would require sustained funding, increased international cooperation and greater year-round access to all regions. Doctoral or Postdoctoral Thesis Antarc* Antarctic Antarctica polar desert Windmill Islands DataCite Metadata Store (German National Library of Science and Technology) Antarctic Old Wallow ENVELOPE(77.935,77.935,-68.600,-68.600) Rookery Lake ENVELOPE(78.073,78.073,-68.498,-68.498) The Antarctic Vestfold Vestfold Hills Windmill Islands ENVELOPE(110.417,110.417,-66.350,-66.350)