Is this project an undergraduate, graduate, or faculty project?
Undergraduate
group
What campus are you from?
Daytona Beach
Authors' Class Standing
Olivia Siu, Senior Mitchell Villafania, Sophomore Alba Chavez, Faculty Mentor Hugo Castillo, Faculty Mentor
Lead Presenter's Name
Olivia Siu
Faculty Mentor Name
Alba Chavez
Abstract
Changes in environmental conditions represent a challenge for all terrestrial organisms, including the organisms involved in mutualistic associations (when both organisms obtain a benefit from each other). Changes in environment might include fluctuations in in gravity and microgravity which represents a new frontier for space biology research. In this study we utilized Vibrio fischeri, a beneficial symbiotic bacterium of squids and monocentrid fishes. First, Vibrio fischeri was grown under gravity and microgravity conditions using a 2D clinostat design, after 24 and 48 hours of growth, we examined crucial phenotypic changes that might affect bacterial physiology and phenotypic changes involved in host colonization, mutualism and virulence. We will conduct an initial study of microbial colonies (known as biofilms) and antibiotic resistance profiles (relevant to host colonization and virulence). Additionally, we will perform a transcriptomic analysis in order to identify the relevant genes responsible for genotypic changes that occur under modeled microgravity. This study will provide a window to the adaptative bacterial changes and responses in an effort to shed light into understanding microbiome changes and adaptations in space.
Did this research project receive funding support from the Office of Undergraduate Research.
No
Effects of Microgravity on Mutualistic Bacteria
Changes in environmental conditions represent a challenge for all terrestrial organisms, including the organisms involved in mutualistic associations (when both organisms obtain a benefit from each other). Changes in environment might include fluctuations in in gravity and microgravity which represents a new frontier for space biology research. In this study we utilized Vibrio fischeri, a beneficial symbiotic bacterium of squids and monocentrid fishes. First, Vibrio fischeri was grown under gravity and microgravity conditions using a 2D clinostat design, after 24 and 48 hours of growth, we examined crucial phenotypic changes that might affect bacterial physiology and phenotypic changes involved in host colonization, mutualism and virulence. We will conduct an initial study of microbial colonies (known as biofilms) and antibiotic resistance profiles (relevant to host colonization and virulence). Additionally, we will perform a transcriptomic analysis in order to identify the relevant genes responsible for genotypic changes that occur under modeled microgravity. This study will provide a window to the adaptative bacterial changes and responses in an effort to shed light into understanding microbiome changes and adaptations in space.