Authors' Affiliations

Morad Malek, Department of Biology, College of Arts and Sciences, East Tennessee State University, East Tennessee State University, Johnson City, TN. Dr. Lev Yamplosky, College of Arts and Sciences, Department of Biology, East Tennessee State University,East Tennessee State University, Johnson City, TN.

Location

Culp Room 210

Start Date

4-6-2022 9:30 AM

End Date

4-6-2022 9:45 AM

Faculty Sponsor’s Department

Biological Sciences

Name of Project's Faculty Sponsor

Lev Yampolsky

Classification of First Author

Undergraduate Student

Competition Type

Non-Competitive

Type

Boland Symposium

Project's Category

Biological and Chemical Sciences, Ecology

Abstract or Artist's Statement

Hypoxia has become a subject of interest among the many environmental stressors as its role in biology is complex and diverse. Hypoxia is a significant low oxygen condition that causes many pathologies and adaptive responses in organisms. It can lead to a moderate or dangerous loss of respiration and can be an indication of tumorigenesis as many tumors lack adequate blood supply. Organisms possess adaptive responses to hypoxia that include hypoxia-inducible factors (HIFs) that activate several downstream pathways that are responsible for altering metabolism and maintaining homeostasis. Within aquatic organisms, hypoxia is an important ecological constraint as oxygen availability within bodies of water can vary greatly over time and space. Therefore, adaptation to hypoxia is likely pervasive, especially in genotypes originating from bodies of water that are prone to hypoxia. Here we report the transcriptional response to acute hypoxia in the clonal freshwater crustacean Daphnia magna. Daphnia were subjected to 1mg/O2 for 12 hours. Then, RNA was extracted, reverse transcribed, and sequenced using Oxford Nanopore MinION. We find that severe hypoxia significantly up-regulates key enzymes in the gluconeogenesis pathway. Additionally, we report genotype-by-environment interactions showing that Daphnia clones from habitats that are hypoxia prone survive better in hypoxia.

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Apr 6th, 9:30 AM Apr 6th, 9:45 AM

Severe Hypoxia Alters Metabolism in Daphnia by Inducing Gluconeogenesis

Culp Room 210

Hypoxia has become a subject of interest among the many environmental stressors as its role in biology is complex and diverse. Hypoxia is a significant low oxygen condition that causes many pathologies and adaptive responses in organisms. It can lead to a moderate or dangerous loss of respiration and can be an indication of tumorigenesis as many tumors lack adequate blood supply. Organisms possess adaptive responses to hypoxia that include hypoxia-inducible factors (HIFs) that activate several downstream pathways that are responsible for altering metabolism and maintaining homeostasis. Within aquatic organisms, hypoxia is an important ecological constraint as oxygen availability within bodies of water can vary greatly over time and space. Therefore, adaptation to hypoxia is likely pervasive, especially in genotypes originating from bodies of water that are prone to hypoxia. Here we report the transcriptional response to acute hypoxia in the clonal freshwater crustacean Daphnia magna. Daphnia were subjected to 1mg/O2 for 12 hours. Then, RNA was extracted, reverse transcribed, and sequenced using Oxford Nanopore MinION. We find that severe hypoxia significantly up-regulates key enzymes in the gluconeogenesis pathway. Additionally, we report genotype-by-environment interactions showing that Daphnia clones from habitats that are hypoxia prone survive better in hypoxia.