Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife

A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Marine Biology. Estuarine ecosystems can experience extended periods of salinity and temperature stress. In the South Texas region of the northwest Gulf of Mexico (GoM), climate models and c...

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Main Author: Bachand, Paxton Turner
Other Authors: Turner, Jeffrey W., Labonte, Jessica M., Sterba-Boatwright, Blair, Walther, Benjamin D.
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: 2023
Subjects:
climate change
community dynamics
disturbance
ecology
eutrophication
microbiology
environmental science
Baffin Bay
Online Access:https://hdl.handle.net/1969.6/97963
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spelling fttexasamucorpus:oai:tamucc-ir.tdl.org:1969.6/97963 2024-04-28T08:13:57+00:00 Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife Bachand, Paxton Turner Turner, Jeffrey W. Labonte, Jessica M. Sterba-Boatwright, Blair Walther, Benjamin D. 2023-12 139 pages application/pdf https://hdl.handle.net/1969.6/97963 en_US eng https://hdl.handle.net/1969.6/97963 This material is made available for use in research, teaching, and private study, pursuant to U.S. Copyright law. The user assumes full responsibility for any use of the materials, including but not limited to, infringement of copyright and publication rights of reproduced materials. Any materials used should be fully credited with its source. All rights are reserved and retained regardless of current or future development or laws that may apply to fair use standards. Permission for publication of this material, in part or in full, must be secured with the author and/or publisher. climate change community dynamics disturbance ecology eutrophication microbiology environmental science Text Dissertation 2023 fttexasamucorpus 2024-04-08T00:05:46Z A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Marine Biology. Estuarine ecosystems can experience extended periods of salinity and temperature stress. In the South Texas region of the northwest Gulf of Mexico (GoM), climate models and current trends support increased temperatures, prolonged droughts, and increased storm severity. It is therefore imperative to assess how climate stress will impact South Texas estuarine ecosystems. Coastal lagoons are particularly vulnerable to disturbance, and the hypersaline Baffin Bay and Upper Laguna Madre Complex is a ‘hotspot’ of environmental change. In this dissertation, factors contributing to hypersaline microbial community dynamics in a hypersaline creek were assessed in three stand-alone research projects: 1) a short-term 2-month study of microbial community dynamics following a flood event, 2) a long-term 18-month study of microbial community dynamics that included flood and freeze events, and 3) a targeted study of wildlife connectivity (Mexican free-tailed bats) to microbial community dynamics and eutrophication. The short-term study revealed that flood events are disturbance events that cause pronounced shifts in microbial community structure. The long-term study revealed the hypersaline community was resilient to flood and freeze events. Additionally, whole genome sequencing of halophilic bacteria uncovered mechanisms of osmoregulation and heavy metal resistance. The targeted study revealed that bat guano is a source of dissolved organic carbon and potentially pathogenic bacteria. Severe heat coupled with severe flooding is anticipated to alter salinity regimes, increase osmotic stress, adversely impact ecosystem stability, and potentially restructure natural communities between drought and flood events. Climate stress will also affect the quality of riparian buffers and the wildlife inhabiting those buffers. A better understanding of microbial drought and flood resilience is critical to predicting ... Doctoral or Postdoctoral Thesis Baffin Bay Texas A&M University - Corpus Christi: DSpace Repository
institution Open Polar
collection Texas A&M University - Corpus Christi: DSpace Repository
op_collection_id fttexasamucorpus
language English
topic climate change
community dynamics
disturbance
ecology
eutrophication
microbiology
environmental science
spellingShingle climate change
community dynamics
disturbance
ecology
eutrophication
microbiology
environmental science
Bachand, Paxton Turner
Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife
topic_facet climate change
community dynamics
disturbance
ecology
eutrophication
microbiology
environmental science
description A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Marine Biology. Estuarine ecosystems can experience extended periods of salinity and temperature stress. In the South Texas region of the northwest Gulf of Mexico (GoM), climate models and current trends support increased temperatures, prolonged droughts, and increased storm severity. It is therefore imperative to assess how climate stress will impact South Texas estuarine ecosystems. Coastal lagoons are particularly vulnerable to disturbance, and the hypersaline Baffin Bay and Upper Laguna Madre Complex is a ‘hotspot’ of environmental change. In this dissertation, factors contributing to hypersaline microbial community dynamics in a hypersaline creek were assessed in three stand-alone research projects: 1) a short-term 2-month study of microbial community dynamics following a flood event, 2) a long-term 18-month study of microbial community dynamics that included flood and freeze events, and 3) a targeted study of wildlife connectivity (Mexican free-tailed bats) to microbial community dynamics and eutrophication. The short-term study revealed that flood events are disturbance events that cause pronounced shifts in microbial community structure. The long-term study revealed the hypersaline community was resilient to flood and freeze events. Additionally, whole genome sequencing of halophilic bacteria uncovered mechanisms of osmoregulation and heavy metal resistance. The targeted study revealed that bat guano is a source of dissolved organic carbon and potentially pathogenic bacteria. Severe heat coupled with severe flooding is anticipated to alter salinity regimes, increase osmotic stress, adversely impact ecosystem stability, and potentially restructure natural communities between drought and flood events. Climate stress will also affect the quality of riparian buffers and the wildlife inhabiting those buffers. A better understanding of microbial drought and flood resilience is critical to predicting ...
author2 Turner, Jeffrey W.
Labonte, Jessica M.
Sterba-Boatwright, Blair
Walther, Benjamin D.
format Doctoral or Postdoctoral Thesis
author Bachand, Paxton Turner
author_facet Bachand, Paxton Turner
author_sort Bachand, Paxton Turner
title Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife
title_short Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife
title_full Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife
title_fullStr Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife
title_full_unstemmed Microbial dynamics of a hypersaline creek: Community response to disturbance and connectivity to wildlife
title_sort microbial dynamics of a hypersaline creek: community response to disturbance and connectivity to wildlife
publishDate 2023
url https://hdl.handle.net/1969.6/97963
genre Baffin Bay
genre_facet Baffin Bay
op_relation https://hdl.handle.net/1969.6/97963
op_rights This material is made available for use in research, teaching, and private study, pursuant to U.S. Copyright law. The user assumes full responsibility for any use of the materials, including but not limited to, infringement of copyright and publication rights of reproduced materials. Any materials used should be fully credited with its source. All rights are reserved and retained regardless of current or future development or laws that may apply to fair use standards. Permission for publication of this material, in part or in full, must be secured with the author and/or publisher.
_version_ 1797580238834630656

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