Biology Department Theses and Dissertations

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Browsing Biology Department Theses and Dissertations by Author "Anderson, Gregory"

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    Alternative Assembly Pathways of the 20S Proteasome and Non-canonical Complexes
    (2018-12) Panfair, Dilrajkaur; Balakrishnan, Lata; Kusmierczyk, Andrew; Randall, Stephen; Rubenstein, Eric; Anderson, Gregory
    The 20S proteasome, a multi-subunit protease complex, present in all domains of life and some orders of bacteria, is involved in degradation of the majority of cellular proteins. Structurally, it is made of α and β subunits arranged in four heptameric rings, with inner two β-rings sandwiched between outer two α-rings. The 20S proteasome in prokaryotes usually has one type of α and one type of β subunits, whereas eukaryotes have seven distinct types of α and seven distinct types of β subunits. Unlike the highly conserved structure of proteasome, its assembly pathway is different across the domains. In archaea and eukaryotes, proteasome assembly begins with α subunit interactions leading to the α-ring formation. By contrast, bacterial proteasome assembly pathway bypasses the α-ring formation step by initiating assembly through an α and β subunit interaction first. These early interactions are not well understood due to their highly rapid and dynamic nature. This dissertation focused on understanding the early events in proteasome assembly and contributed three significant findings. First, the archaeal proteasome assembly can also begin without formation of α-rings, demonstrating the coexistence of a bacterial-like assembly pathway. Second, a novel assembly intermediate was identified in yeast, and its composition argues for the presence of a similar α-ring independent assembly pathway. Third, the assembly chaperone Pba3-Pba4 prevents the formation of high molecular weight complexes arising from spontaneous and non-productive interactions among the α subunits. These findings provide a broader understanding of proteasome biogenesis and suggest considering proteasome assembly event as a network of interactions rather than a linear pathway. The results also shed light on assembly chaperone’s contribution in increasing the efficiency of proteasome assembly by streamlining the productive interactions.
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    Biofilm and Virulence Regulation of the Cystic Fibrosis Associated Pathogens, Stenotrophomonas maltophilia and Pseudomonas aeruginosa
    (2020-05) Ramos-Hegazy, Layla; Anderson, Gregory; Perrin, Benjamin; Slayback-Barry, Denise
    Cystic fibrosis (CF) is a fatal, incurable genetic disease that affects over 30,000 people in the United States alone. People with this disease have a homozygous mutation in the cystic fibrosis transmembrane conductance regulator (CFTR) which causes defects in chloride transport and leads to build up of mucus in the lungs and disruption of function in various organs. CF patients often suffer from chronic bacterial infections within the lungs, wherein the bacteria persist as a biofilm, leading to poor prognosis. Two of these pathogens, Stenotrophomonas maltophilia and Pseudomonas aeruginosa, are often found in the lungs of patients with CF and are an increasing medical concerns due to their intrinsic antimicrobial resistance. Both species can readily form biofilms on biotic and abiotic surfaces such as intravascular devices, glass, plastic, and host tissue. Biofilm formation starts with bacterial attachment to a surface and/or adjacent cells, initiating the acute infection stage. Chronic, long-term infection involves subsequent or concurrent altered genetic regulation, including a downregulation of virulence factors, resulting in the bacteria committing to a sessile lifestyle, markedly different from the planktonic one. Many of these genetic switches from an acute to chronic lifestyle are due to pressures from the host immune system and lead to permanently mutated strains, most likely an adaptive strategy to evade host immune responses. Biofilms are extremely problematic in a clinical setting because they lead to nosocomial infections and persist inside the host causing long-term chronic infections due to their heightened tolerance to almost all antibiotics. Understanding the genetic networks governing biofilm initiation and maintenance would greatly reduce consequences for CF and other biofilm-related infections and could lead to the development of treatments and cures for affected patients. This study showed that in S. maltophilia, isogenic deletion of phosphoglycerate mutase (gpmA) and two chaperone-usher pilin subunits, S. maltophilia fimbrae-1 (smf-1) and cblA, lead to defects in attachment on abiotic surfaces and cystic fibrosis derived bronchial epithelial cells (CFBE). Furthermore, Δsmf-1 and ΔcblA showed defects in long-term biofilm formation, mimicking that of a chronic infection lifestyle, on abiotic surfaces and CFBE as well as stimulating less of an immune response through TNF-α production. This study also showed that in P. aeruginosa, the Type III secretion system (T3SS), an important virulence factor activated during the acute stage of infection, is downregulated when polB, a stress-induced alternate DNA polymerase, is overexpressed. This downregulation is due to post-transcriptional inhibition of the master regulatory protein, ExsA. Taken together, this project highlights important genes involved in the acute and chronic infection lifestyle and biofilm formation in S. maltophilia and genetic switches during the acute infection lifestyle in P. aeruginosa.
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    Role of Stenotrophomonas Maltophilia Pili Iin Biofilm And Virulence
    (2024-08) Bhaumik, Radhika; Marrs, Kathleen; Anderson, Gregory; Berbari, Nicolas; Marrs, James A.; Gregory, Richard L.
    Stenotrophomonas maltophilia is an emerging multidrug-resistant, Gram-negative opportunistic pathogen. It causes many hospital-acquired infections such as sepsis, endocarditis, meningitis, and catheter-related urinary tract infections. It also affects individuals with cystic fibrosis, exacerbating their lung condition. S. maltophilia often causes pathogenesis through the formation of biofilms. However, the molecular mechanisms S. maltophilia uses to carry out these pathogenic steps are unclear. The SMF-1 chaperone/usher pilus has been thought to mediate S. maltophilia attachment. To confirm this role, we created an isogenic deletion of the smf-1 pilin gene and observed a defect in biofilm compared to wild type. We also discovered 2 additional chaperone/usher pilus operons, mutation of which also caused attenuation in biofilm levels. Analysis of S. maltophilia clinical strains and S. maltophilia complete genomes listed in NCBI showed that these three pili are prevalent and highly conserved, suggesting a vital role in infection. Intriguingly, through TEM studies, we found that the mutation of one pilus is not phenotypically compensated by another. Infection of Galleria mellonella larvae revealed increased virulence of the pilus mutants. Additionally, we also demonstrated a relationship between pilus and flagella contributing to the overall biofilm development of S. maltophilia. Understanding their activity may help identify therapeutic targets for this pathogen.