Location
Culp Center Ballroom
Start Date
4-25-2023 9:00 AM
End Date
4-25-2023 11:00 AM
Poster Number
122
Faculty Sponsor’s Department
Health Sciences
Name of Project's Faculty Sponsor
Sean Fox
Competition Type
Competitive
Type
Poster Presentation
Project's Category
Biological and Chemical Sciences
Abstract or Artist's Statement
Antibiotic resistance occurs when bacteria change in response to selective pressures induced by antibiotics, which has become a major concern worldwide and one of the biggest threats to global health. Antibiotic resistance can occur naturally, but the misuse and overuse of antibiotics is accelerating the process. One way to combat this process is to understand the different relationships between microbes, also known as polymicrobial interactions. Bacteria can interact with one another synergistically or antagonistically and understanding the mechanisms behind these interactions can lead to the discovery of new therapeutics or targets to fight and kill pathogenic microbes. The rarely pathogenic Gram-negative bacterium, Alcaligenes faecalis, has previously been shown in our lab as playing an important role in potentially fighting antibiotic and antifungal resistance due to its competitiveness during polymicrobial interaction. Our research has found that A. faecalis kills Bacillus cereus, Staphylococcus aureus, and Candida albicans. This is a unique characteristic as these targets encompass both prokaryotic (bacteria) and eukaryotic (fungi) microbes. These three species are known to cause numerous infections in humans and have increased cases of antibiotic and antifungal resistance. In the present study, we investigated the genetic elements A. faecalis utilizes to inhibit growth when interacting with B. cereus, S. aureus, and C. albicans. Transposon mutagenesis was performed to create a genetic library of A. faecalis loss-of-function mutants. These strains were then screened against all three microorganisms to determine which mutants no longer inhibited growth. The mutants that lacked zones-of-inhibition were sequenced to determine the gene that had been interrupted. BLAST analysis of these sequences identified a MFS transporter, a 2FE-2S iron sulfur binding protein, a mechanosensitive ion channel, and a glucose-6-phosphate isomerase as instrumental in this inhibitory mechanism. Results from this research study can be used to further study polymicrobial interactions and potentially discover new therapeutics to combat antimicrobial resistance.
Transposon Mutagenesis Identification of Polymicrobial Interaction Mechanisms Between Prokaryotic and Eukaryotic Microorganisms
Culp Center Ballroom
Antibiotic resistance occurs when bacteria change in response to selective pressures induced by antibiotics, which has become a major concern worldwide and one of the biggest threats to global health. Antibiotic resistance can occur naturally, but the misuse and overuse of antibiotics is accelerating the process. One way to combat this process is to understand the different relationships between microbes, also known as polymicrobial interactions. Bacteria can interact with one another synergistically or antagonistically and understanding the mechanisms behind these interactions can lead to the discovery of new therapeutics or targets to fight and kill pathogenic microbes. The rarely pathogenic Gram-negative bacterium, Alcaligenes faecalis, has previously been shown in our lab as playing an important role in potentially fighting antibiotic and antifungal resistance due to its competitiveness during polymicrobial interaction. Our research has found that A. faecalis kills Bacillus cereus, Staphylococcus aureus, and Candida albicans. This is a unique characteristic as these targets encompass both prokaryotic (bacteria) and eukaryotic (fungi) microbes. These three species are known to cause numerous infections in humans and have increased cases of antibiotic and antifungal resistance. In the present study, we investigated the genetic elements A. faecalis utilizes to inhibit growth when interacting with B. cereus, S. aureus, and C. albicans. Transposon mutagenesis was performed to create a genetic library of A. faecalis loss-of-function mutants. These strains were then screened against all three microorganisms to determine which mutants no longer inhibited growth. The mutants that lacked zones-of-inhibition were sequenced to determine the gene that had been interrupted. BLAST analysis of these sequences identified a MFS transporter, a 2FE-2S iron sulfur binding protein, a mechanosensitive ion channel, and a glucose-6-phosphate isomerase as instrumental in this inhibitory mechanism. Results from this research study can be used to further study polymicrobial interactions and potentially discover new therapeutics to combat antimicrobial resistance.