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http://hdl.handle.net/11375/28498
Title: | UNDERSTANDING AND OVERCOMING INDUCIBLE RIFAMYCIN RESISTANCE |
Authors: | Surette, Matthew |
Advisor: | Wright, Gerard |
Department: | Biochemistry and Biomedical Sciences |
Keywords: | Antibiotic Resistance;Rifamycins |
Publication Date: | 2023 |
Abstract: | Antibiotics are one of the most important advances in medical science, but today, antibiotic-resistant bacteria threaten this legacy. We risk losing our ability to treat acute infections, perform invasive surgeries, and exploit immunosuppressive therapies like transplantation and cancer chemotherapy. The antibiotics we use today have ancient roots and have been produced by microbial denizens of the soil for millions of years before we adopted them in the 20th century. This history has modern consequences, as strategies to resist these compounds have evolved in concert for millions of years. The result is a vast reservoir of antimicrobial resistance that exists in environmental bacteria, which have the potential to be mobilized into human pathogens and cripple our antibiotic arsenal. Here, I set out to deepen our understanding of the environmental resistome, focusing on the rifamycin antibiotics. These compounds inhibit bacterial RNA polymerase and are frontline agents for treating tuberculosis. Environmental bacteria from the phylum Actinobacteria induce the production of resistance enzymes in response to these compounds. Although mechanistic questions remain, we demonstrate that this induction stems from the inhibition of RNA polymerase by rifamycins. The induction process is known to require a specific DNA motif; here, I identify additional sequences as part of this motif and use this information to map inducible rifamycin resistance across the entire phylum. The most common rifamycin-inducible gene was an uncharacterized family of proteins annotated as DNA helicases. I investigated these proteins and discovered that they bind to RNA polymerase and displace rifamycin antibiotics, a novel mechanism of rifamycin resistance. Lastly, we repurposed this inducible system to develop an assay to screen for novel RNA polymerase inhibitors. From this screen, we identified a rifamycin immune to a common environmental resistance enzyme and a new family of rifamycin antibiotics. |
URI: | http://hdl.handle.net/11375/28498 |
Appears in Collections: | Open Access Dissertations and Theses |
Files in This Item:
File | Description | Size | Format | |
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Surette_Matthew_D_2023-04_PhD.pdf | 13.33 MB | Adobe PDF | View/Open |
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