Subsoontorn Lab:Research: Difference between revisions
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Revision as of 21:40, 9 May 2017
Current Research
Our ability to study and utilise microbiota is limited by the lack of tools for precisely perturbing and modulating microbial subpopulations of interest within a heterogenous population. Recently, CRISPR/Cas technology was used for creating antimicrobials with a programmable spectrum of activities.This strategy exploits the fact that CRISPR/Cas system can be designed to break a specific DNA sequence. In a prokaryotic cell without efficient DNA repair, such genomic cleavage often results in cell death. By delivering the designed CRISPR/Cas system to a microbial population one could selectively knockdown a subpopulation whose genomic DNA is targeted. Previous works demonstrated sequence-specific elimination of Escherichia coli and Staphylococcus aureus in mixed populations. Here, we are applying this strategy for targeted elimination of Vibrio harveyi, a pathogenic bacteria in black tiger shrimp and Pacific white shrimp. This project is under collaboration with Dr. Wanilada Rungrassamee (BIOTEC) and Prof. Jim Haseloff (University of Cambridge, UK)
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Past Research
DNA transfer via conjugation plays a major role in the dissemination of antibiotic resistance among medically significant bacterial species. In this study, we developed a technique for visualising spatial distribution of conjugating bacterial population on a solid surface. Populations of donor, recipient and transconjugant cells can be distinguished using three different fluorescent reporters. We show that the fractal dimension of the interface between donor and recipient populations determines population-level conjugation efficiency. Additionally, competition for nutrients available at colony borders results in stochastic loss of cell diversity and increases variability of observed conjugation frequencies across different colonies. Our ability to monitor the dynamics of conjugation especially in the context of growth and competition within bacterial population would lead to better understanding of how antibiotic resistance spreads and how we might prevent it. This project was conducted at the laboratory of Prof. Jim Haseloff (University of Cambridge, UK)
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DNA transfer via conjugation plays a major role in the dissemination of antibiotic resistance among medically significant bacterial species. In this study, we developed a technique for visualising spatial distribution of conjugating bacterial population on a solid surface. Populations of donor, recipient and transconjugant cells can be distinguished using three different fluorescent reporters. We show that the fractal dimension of the interface between donor and recipient populations determines population-level conjugation efficiency. Additionally, competition for nutrients available at colony borders results in stochastic loss of cell diversity and increases variability of observed conjugation frequencies across different colonies. Our ability to monitor the dynamics of conjugation especially in the context of growth and competition within bacterial population would lead to better understanding of how antibiotic resistance spreads and how we might prevent it. This project was conducted at the laboratory of Prof. Jim Haseloff (University of Cambridge, UK)
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