Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals

Human population growth and global industrial development are driving potentially irreversible anthropogenic impacts on the natural world, including altering global climate and ocean conditions and exposing oceanic environments to a wide range of pollutants. While there are numerous studies highligh...

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Main Authors: Weinnig, Alexis, orcid:0000-0001-8858-4837
Other Authors: Cordes, Erik E., Sanders, Robert W., Kulathinal, Rob J, Morrison, Cheryl L
Format: Thesis
Language:English
Published: Temple University. Libraries 2020
Subjects:
Biological oceanography
Genetics
Bioinformatics
Deep-sea
Deepwater Horizon
Dispersant
Gulf of Mexico
Lophelia pertusa
Transcriptomics
Online Access:https://hdl.handle.net/20.500.12613/4751
id fttempleuniv:oai:scholarshare.temple.edu:20.500.12613/4751
record_format openpolar
institution Open Polar
collection TUScholarShare (Temple University)
op_collection_id fttempleuniv
language English
topic Biological oceanography
Genetics
Bioinformatics
Deep-sea
Deepwater Horizon
Dispersant
Gulf of Mexico
Lophelia pertusa
Transcriptomics
spellingShingle Biological oceanography
Genetics
Bioinformatics
Deep-sea
Deepwater Horizon
Dispersant
Gulf of Mexico
Lophelia pertusa
Transcriptomics
Weinnig, Alexis
orcid:0000-0001-8858-4837
Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals
topic_facet Biological oceanography
Genetics
Bioinformatics
Deep-sea
Deepwater Horizon
Dispersant
Gulf of Mexico
Lophelia pertusa
Transcriptomics
description Human population growth and global industrial development are driving potentially irreversible anthropogenic impacts on the natural world, including altering global climate and ocean conditions and exposing oceanic environments to a wide range of pollutants. While there are numerous studies highlighting the variable effects of climate change and pollution on marine organisms independently, there are very few studies focusing on the potential interactive effects of these stressors. The deep-sea is under increasing threat from these anthropogenic stressors, especially cold-water coral (CWC) communities which contribute to nutrient and carbon cycling, as well as providing biogenic habitats, feeding grounds, and nurseries for many fishes and invertebrates. The primary goals of this dissertation are to assess the vulnerability of CWCs to independent and interacting anthropogenic stressors in their environment; including natural hydrocarbon seepage, hydrocarbon and dispersant concentrations released during an accidental oil spill (i.e. Deepwater Horizon), and the interacting effects of climate change-related factors and hydrocarbon/dispersant exposure. To address these goals, multiple stressor experiments were implemented to assess the effects of current and future conditions [(a) temp: 8C and pH: 7.9; (b) temp: 8C and pH: 7.6; (c) temp: 12C and pH: 7.9; (d) temp: 12C and pH: 7.6] and oil spill exposure (oil, dispersant, oil + dispersant combined) on coral health using the CWC Lophelia pertusa. Phenotypic response was assessed through observations of diagnostic characteristics that were combined into an average health rating at four points during exposure and recovery. Regardless of environmental condition, average health significantly declined during 24-hour exposure to dispersant alone and increased temperature resulted in a delay in recovery (72 hours) from dispersant exposure. The overall gene expression patterns varied by coral colony, but the dispersant exposure elicited the strongest response. Gene ontology (GO) enrichment analysis revealed that L. pertusa likely experienced varying stages of the cellular stress response (CSR) during exposure to oil, dispersant, and a decrease in pH. The most severe responses were associated with the dispersant exposure including GO terms related to apoptosis, the immune system, wound healing, and stress-related responses. However, the oil exposure induced an upregulation of metabolic pathways and energy transfer but a downregulation of cell growth and development, indicating that the coral nubbins could have been reallocating resources and reducing growth to maintain cellular homeostasis. The decrease in seawater pH elicited a similar response to oil through the enrichment of terms associated with a reduction in the cell cycle and development. Interestingly, the increase in temperature did not elicit a CSR that was detectable in the gene expression data. To further investigate the influence of hydrocarbon exposure on CWCs, comparisons of gene expression profiles were conducted using Callogorgia delta colonies that live in close proximity to active hydrocarbon seepage (“seep”) areas with no current active seepage (“non-seep”) at two different sites in the Gulf of Mexico. There were fewer differentially expressed genes in the “seep” versus “non-seep” comparison (n=21) than the site comparison (n=118) but both analyses revealed GO terms indicating slight alterations in natural biological housekeeping processes, as opposed to a CSR. Our results indicate that distinct stages of the CSR are induced depending on the intensity of stress. This bolsters the idea that there is a stress response shared by all corals in response to a variety of stressors. These data provide evidence that CWCs can be more negatively impacted, both on the phenotypic and molecular levels, by exposure to chemical dispersants than to hydrocarbons alone. Gaining an understanding of how these communities respond, not only to independent stressors, but the combination of these stressors, provides vital information about how CWC communities will fair in current and future conditions. Biology
author2 Cordes, Erik E.
Sanders, Robert W.
Kulathinal, Rob J
Morrison, Cheryl L
format Thesis
author Weinnig, Alexis
orcid:0000-0001-8858-4837
author_facet Weinnig, Alexis
orcid:0000-0001-8858-4837
author_sort Weinnig, Alexis
title Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals
title_short Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals
title_full Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals
title_fullStr Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals
title_full_unstemmed Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals
title_sort independent and interacting effects of multiple anthropogenic stressors on cold-water corals
publisher Temple University. Libraries
publishDate 2020
url https://hdl.handle.net/20.500.12613/4751
genre Lophelia pertusa
genre_facet Lophelia pertusa
op_relation http://dx.doi.org/10.34944/dspace/4733
Theses and Dissertations
14334
http://hdl.handle.net/20.500.12613/4751
op_rights IN COPYRIGHT- This Rights Statement can be used for an Item that is in copyright. Using this statement implies that the organization making this Item available has determined that the Item is in copyright and either is the rights-holder, has obtained permission from the rights-holder(s) to make their Work(s) available, or makes the Item available under an exception or limitation to copyright (including Fair Use) that entitles it to make the Item available.
http://rightsstatements.org/vocab/InC/1.0/
op_doi https://doi.org/20.500.12613/4751
https://doi.org/10.34944/dspace/4733
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spelling fttempleuniv:oai:scholarshare.temple.edu:20.500.12613/4751 2023-05-15T17:08:47+02:00 Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals Weinnig, Alexis orcid:0000-0001-8858-4837 Cordes, Erik E. Sanders, Robert W. Kulathinal, Rob J Morrison, Cheryl L 2020 233 pages https://hdl.handle.net/20.500.12613/4751 eng eng Temple University. Libraries http://dx.doi.org/10.34944/dspace/4733 Theses and Dissertations 14334 http://hdl.handle.net/20.500.12613/4751 IN COPYRIGHT- This Rights Statement can be used for an Item that is in copyright. Using this statement implies that the organization making this Item available has determined that the Item is in copyright and either is the rights-holder, has obtained permission from the rights-holder(s) to make their Work(s) available, or makes the Item available under an exception or limitation to copyright (including Fair Use) that entitles it to make the Item available. http://rightsstatements.org/vocab/InC/1.0/ Biological oceanography Genetics Bioinformatics Deep-sea Deepwater Horizon Dispersant Gulf of Mexico Lophelia pertusa Transcriptomics Thesis/Dissertation Text 2020 fttempleuniv https://doi.org/20.500.12613/4751 https://doi.org/10.34944/dspace/4733 2021-08-26T18:59:43Z Human population growth and global industrial development are driving potentially irreversible anthropogenic impacts on the natural world, including altering global climate and ocean conditions and exposing oceanic environments to a wide range of pollutants. While there are numerous studies highlighting the variable effects of climate change and pollution on marine organisms independently, there are very few studies focusing on the potential interactive effects of these stressors. The deep-sea is under increasing threat from these anthropogenic stressors, especially cold-water coral (CWC) communities which contribute to nutrient and carbon cycling, as well as providing biogenic habitats, feeding grounds, and nurseries for many fishes and invertebrates. The primary goals of this dissertation are to assess the vulnerability of CWCs to independent and interacting anthropogenic stressors in their environment; including natural hydrocarbon seepage, hydrocarbon and dispersant concentrations released during an accidental oil spill (i.e. Deepwater Horizon), and the interacting effects of climate change-related factors and hydrocarbon/dispersant exposure. To address these goals, multiple stressor experiments were implemented to assess the effects of current and future conditions [(a) temp: 8C and pH: 7.9; (b) temp: 8C and pH: 7.6; (c) temp: 12C and pH: 7.9; (d) temp: 12C and pH: 7.6] and oil spill exposure (oil, dispersant, oil + dispersant combined) on coral health using the CWC Lophelia pertusa. Phenotypic response was assessed through observations of diagnostic characteristics that were combined into an average health rating at four points during exposure and recovery. Regardless of environmental condition, average health significantly declined during 24-hour exposure to dispersant alone and increased temperature resulted in a delay in recovery (72 hours) from dispersant exposure. The overall gene expression patterns varied by coral colony, but the dispersant exposure elicited the strongest response. Gene ontology (GO) enrichment analysis revealed that L. pertusa likely experienced varying stages of the cellular stress response (CSR) during exposure to oil, dispersant, and a decrease in pH. The most severe responses were associated with the dispersant exposure including GO terms related to apoptosis, the immune system, wound healing, and stress-related responses. However, the oil exposure induced an upregulation of metabolic pathways and energy transfer but a downregulation of cell growth and development, indicating that the coral nubbins could have been reallocating resources and reducing growth to maintain cellular homeostasis. The decrease in seawater pH elicited a similar response to oil through the enrichment of terms associated with a reduction in the cell cycle and development. Interestingly, the increase in temperature did not elicit a CSR that was detectable in the gene expression data. To further investigate the influence of hydrocarbon exposure on CWCs, comparisons of gene expression profiles were conducted using Callogorgia delta colonies that live in close proximity to active hydrocarbon seepage (“seep”) areas with no current active seepage (“non-seep”) at two different sites in the Gulf of Mexico. There were fewer differentially expressed genes in the “seep” versus “non-seep” comparison (n=21) than the site comparison (n=118) but both analyses revealed GO terms indicating slight alterations in natural biological housekeeping processes, as opposed to a CSR. Our results indicate that distinct stages of the CSR are induced depending on the intensity of stress. This bolsters the idea that there is a stress response shared by all corals in response to a variety of stressors. These data provide evidence that CWCs can be more negatively impacted, both on the phenotypic and molecular levels, by exposure to chemical dispersants than to hydrocarbons alone. Gaining an understanding of how these communities respond, not only to independent stressors, but the combination of these stressors, provides vital information about how CWC communities will fair in current and future conditions. Biology Thesis Lophelia pertusa TUScholarShare (Temple University)

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