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Determination of the Relationship Between Bacterial Coculturing, Antibiotic Resistance and Bacterial GrowthLeszcynski, Robert A. 29 June 2020 (has links)
No description available.
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The role of type VI secretion systems in the competitive ability of Escherichia coli strain D12Cekol, Ana January 2024 (has links)
No description available.
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MECHANISMS OF BACTERIAL CONFLICT: MOLECULAR INSIGHTS INTO BACTERIAL COMPETITION AND ANTIPHAGE DEFENCEBullen, Nathan 08 1900 (has links)
Many bacteria inhabit polymicrobial communities where competition for resources is fierce. To survive, they employ sophisticated systems to outcompete rivals and defend against threats. Here, I present three studies exploring the molecular mechanisms underlying unique aspects of microbial conflict, including interbacterial competition and defence against phage predation. This work highlights the complex and often nefarious strategies bacteria and their viruses (bacteriophages) use to succeed in their habitats.
First, I characterize the effector repertoire of the H2 type VI secretion system of Pseudomonas aeruginosa, showing that this protein export pathway delivers at least six toxins directly into competing bacterial cells. I further show that one of these toxins, termed RhsP2, functions as an ADP-ribosyltransferase that elicits cell death through the modification of diverse non-coding RNAs, including tRNA and RNase P. These findings reveal a new mechanism of interbacterial antagonism and describe the first physiological role for the ADP-ribosylation of RNA.
Second, with the help of collaborators, I explore how the pathogenic bacterium Enterococcus faecalis defends against bacteriophage predation. Using forward genetics, we identify one antiphage defence mechanism involving a type IV restriction enzyme (TIV-RE) encoded within a plasmid of the model strain V583. By isolating bacteriophage that can circumvent this defence, we also discover a novel family of anti-TIV-RE inhibitor proteins encoded by enterococcal phages.
Finally, I explore the physiology of MuF toxins, a widespread family of polymorphic protein toxins encoded within prophages. I demonstrate that MuF toxins are antibacterial, inhibiting processes such as protein synthesis and cell division. Furthermore, I show that these toxins are trafficked into the phage capsid via their N-terminal MuF domains, poising them for delivery into host cells at the onset of infection. Although their precise role remains to be determined, this study lays the groundwork needed to fully characterize this intriguing family of antibacterial toxins. / Dissertation / Doctor of Philosophy (PhD) / Bacteria inhabit environments rife with conflict, competing for limited resources against diverse microorganisms, including other bacteria, fungi, protists, and viruses. This thesis explores the mechanisms bacteria use to navigate and survive in these challenging environments, focusing on the antagonistic and protective strategies used during microbial competition and viral infection, respectively. It starts by outlining our current understanding of the molecular weapons used during microbial conflicts, then presents three detailed studies exploring novel mechanisms used during these processes, including the identification of a protein toxin with unique biochemical activities that mediates interbacterial competition, the discovery of a novel phage-encoded counter-defence mechanism, and the characterization of a newly discovered family of bacterial toxins that I hypothesize have been repurposed by viruses to support their own survival. This work aims to deepen our molecular understanding of microbial conflict and sets the stage for further research into the complex dynamics of microbial competition.
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