Graduation Date

Winter 12-20-2024

Document Type

Dissertation

Degree Name

Doctor of Philosophy (PhD)

Programs

Immunology, Pathology & Infectious Disease

First Advisor

Scot P. Ouellette

Abstract

Chlamydia trachomatis is an obligate intracellular pathogen responsible for the most common bacterial sexually transmitted infections and the leading cause of preventable infectious blindness worldwide. Despite its highly reduced genome, Chlamydia undergoes a complex biphasic developmental cycle, transitioning between two distinct forms: the infectious, non-replicative elementary body (EB) and the non-infectious, replicative reticulate body (RB). The EB initiates infection by binding to and inducing endocytosis into a host cell and forming a host derived vesicle termed the inclusion, where it undergoes primary differentiation into an RB. This RB will rapidly replicate to form a population of RBs. Midway through the developmental cycle, a signal triggers secondary differentiation, converting RBs into EBs, a process that continues irreversibly once initiated. Unlike bacterial differentiation that occurs in parallel with cell division, which involves redistributing intracellular proteins, this organism differentiates through processes that likely depend on targeted protein turnover. We hypothesize that the Clp protease system, particularly the ClpC unfoldase, plays a critical role in Chlamydia’s developmental cycle by facilitating the degradation of key proteins during differentiation. ClpC is an ATP-dependent unfoldase typically found in Gram-positive bacteria and mycobacteria; however, the Gram-negative Chlamydia trachomatis has uniquely retained ClpC, suggesting an essential role in its physiology. Through a combination of in vitro and cell culture approaches, we demonstrated that ClpC forms a functional protease complex with ClpP1P2, which can degrade arginine-phosphorylated substrates—a process crucial for regulating protein homeostasis and turnover. Overexpression of ClpC accelerates EB formation by promoting earlier expression of EB-associated genes, driving the RB-to-EB differentiation prematurely. Conversely, mutations in the N-terminal phosphoarginine (pArg) binding domain of ClpC, which is necessary for substrate recognition, lead to significant growth defects and abnormal bacterial morphology, highlighting the critical role of pArg substrates in secondary differentiation. Disruption of ClpC’s ATPase activity further delays this differentiation, underscoring the importance of ClpC in regulating chlamydial development. Our findings provide the first mechanistic insights into the ClpC-mediated initiation of secondary differentiation in Chlamydia trachomatis and suggest that the unique retention of ClpC in this Gram-negative bacterium may serve as a novel target for narrow spectrum therapeutic intervention.

Comments

2024 Copyright, the authors

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