Molecular Investigations of Protein Assemblies Involved in Prokaryotic Virulence

Mancl, Jordan Michael

15 August 2019

Protein complexes mediate a diverse range of behavior in prokaryotic cells, yet the exact molecular mechanisms explaining how many of these complexes assemble and function remain unknown. This work focuses on understanding the molecular mechanisms of two different protein assemblies responsible for regulating virulence in the opportunistic pathogen Pseudomonas aeruginosa. P. aeruginosa utilizes type IV pili (T4P) to adhere to, and move along, surfaces. Assembly of T4P is powered by a dedicated cytoplasmic ATPase, PilB. The structural study of PilB from a related system (chapter 2) resulted in the formulation of the first model describing the mechanism of force generation resulting from ATP hydrolysis, which explains how T4P are assembled. Chapter 3 focuses on the RetS/GacS interaction, which is responsible for globally regulating virulence in P. aeruginosa. A comprehensive structural study reveals a dynamics of a novel regulatory interaction and the discovery of a potentially universal transmembrane signaling mechanism. / Doctor of Philosophy / Bacteria have threatened human health since the beginning of recorded history. With the development of antibiotics in the early twentieth century, the threat posed by bacterial infection was greatly lessened. However, decades of antibiotic mismanagement has led to the evolution of bacteria which are no longer vulnerable to these antibiotics. In order to combat this rising threat of resistant bacteria, we require a deeper understanding of how bacteria function and cause disease. Proteins play a crucial role in the diseases caused by bacteria, either by directly damaging host cells or regulating the expression of these damaging factors. By increasing our knowledge of the roles played by protein during bacterial infections, it will be possible to create new antibiotics while minimizing the risk of resistance. The work presented here grants a deeper understanding into how proteins work together to allow bacteria to survive inside the human body.

Protein Assemblies

Virulence Regulation

Structural Biology

Small RNAs of <i>Shigella dysenteriae</i>

Broach, William H.

22 September 2014

No description available.

Biology

Microbiology

Molecular Biology

Ribo-regulation

Gene regulation

Virulence regulation

Shigella

Shigella dysenteriae

Small RNAs

sRNAs

RyhB

RyfA

VirB

Virulence regulation

Generation and characterization of an attenuated mutant in a response-regulator gene of Francisella tularensis live vaccine strain (LVS)

Sammons, Wendy L

01 June 2007

Francisella tularensis is a zoonotic bacterium that must exist in diverse environments ranging from arthropod vectors to mammalian hosts. To better understand how genes are regulated in these different environments, a transcriptional response- regulator gene (genome locus FTL0552) was deleted in F. tularensis live vaccine strain (LVS). The FTL0552 deletion mutant exhibited slightly reduced rates of extracellular growth but was unable to replicate or survive in mouse macrophages and was avirulent in the mouse model using either BALB/c or C57BL/6 mice. Mice infected with the FTL0552 mutant produced reduced levels of inflammatory cytokines, exhibited reduced histopathology and cleared the bacteria quicker than mice infected with LVS. Mice that survived infection with the FTL0552 mutant were afforded partial protection when challenged with a lethal dose of the virulent Schu S4 strain (4 of 10 survivors, day 21 post infection) when compared to naïve mice (0 of 10 survivors by day 7 post infection). Microarray experiments indicate that 148 genes are regulated in the FTL0552 mutant. Most of the genes are down regulated, indicating that FTL0552 controls transcription of genes in a positive manner. The list of down regulated genes includes genes located within the Francisella Pathogenicity Island (FPI) that are essential for intracellular survival and virulence of Francisella tularensis. Furthermore, a mutant in FTL0552 or the comparable locus in Schu S4 (FTT1557c) may be an alternative candidate vaccine for tularemia.

Tularemia

Rabbit fever

Two-component signal transduction system

Intracellular survival

Virulence regulation

American Studies

Arts and Humanities

Transcriptional Regulation of Virulence Genes in Enterotoxigenic Escherichia coli and Shigella flexneri by Members of the AraC/XylS Family

Pilonieta, Maria Carolina

03 June 2008

Pathogenesis of enterotoxigenic Escherichia coli (ETEC) and Shigella flexneri relies predominantly on members of the AraC/XylS family of transcriptional regulators, Rns (or its homolog, CfaD) and MxiE, respectively. Rns/CfaD regulate the expression of pili, which allow the bacteria to attach to the intestinal epithelium. Better understanding of the role Rns plays in virulence was attained by expanding our knowledge of the Rns regulon, revealing that it functions as an activator of cexE, a previously uncharacterized gene. By in vitro DNase I footprinting two Rns-binding sites were identified upstream of cexEp, both of which are required for full activation of cexE. The amino terminus of CexE also contains a secretory signal peptide that is removed during translocation to the periplasm. Though the function of CexE remains unknown, these studies suggest that CexE is a novel ETEC virulence factor since it is regulated by Rns/CfaD. In Shigella flexneri, the expression of a subset of virulence genes (including, ipaH9.8 and ospE2) is dependent upon the activator MxiE and a cytoplasmic chaperone IpgC. To define the molecular mechanism of transcriptional activation by this chaperone-activator pair, an in vitro pull down assay was performed revealing that MxiE specifically interacts with IpgC in a complex. Additionally, IpgC recognizes three polypeptide regions in MxiE: within MxiE(1-46), MxiE(46-110) and MxiE(196-216). Furthermore, it seems that MxiE and IpgC regulate transcription of ipaH9.8 and ospE2 promoters differently. In the bacterium, the formation of the MxiE-IpgC complex is initially prevented because IpgC is sequestered in individual complexes with effector proteins, IpaB and IpaC. Upon contact with an eukaryotic host cell the effector proteins are secreted, thereby freeing IpgC to form a complex with MxiE and activate the expression of virulence genes. This new characterization of the role of Rns and MxiE in virulence gene regulation in ETEC and S. flexneri, respectively will give new insights into the pathogenesis of the regulators.