Christopher C. Thompson scite author profile

Iron is an essential cofactor in a number of critical biochemical reactions, and as such, its acquisition, storage, and metabolism is highly regulated in most organisms. The obligate intracellular bacterium, Chlamydia trachomatis experiences a developmental arrest when iron within the host is depleted. The nature of the iron starvation response in Chlamydia is relatively uncharacterized because of the likely inefficient method of iron depletion, which currently relies on the compound deferoxamine mesylate (DFO). Inefficient induction of the iron starvation response precludes the identification of iron-regulated genes. This report evaluated DFO with another iron chelator, 2,2′-bipyridyl (Bpdl) and presented a systematic comparison of the two across a range of criteria. We demonstrate that the membrane permeable Bpdl was superior to DFO in the inhibition of chlamydia development, the induction of aberrant morphology, and the induction of an iron starvation transcriptional response in both host and bacteria. Furthermore, iron starvation using Bpdl identified the periplasmic iron-binding protein-encoding ytgA gene as iron-responsive. Overall, the data present a compelling argument for the use of Bpdl, rather than DFO, in future iron starvation studies of chlamydia and other intracellular bacteria.

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The Rsb Phosphoregulatory Network Controls Availability of the Primary Sigma Factor in Chlamydia trachomatis and Influences the Kinetics of Growth and Development

Thompson

Griffiths

Nicod

et al. 2015

PLoS Pathog

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Chlamydia trachomatis is an obligate intracellular human pathogen that exhibits stage-specific gene transcription throughout a biphasic developmental cycle. The mechanisms that control modulation in transcription and associated phenotypic changes are poorly understood. This study provides evidence that a switch-protein kinase regulatory network controls availability of σ66 , the main sigma subunit for transcription in Chlamydia. In vitro analysis revealed that a putative switch-protein kinase regulator, RsbW, is capable of interacting directly with σ66, as well as phosphorylating its own antagonist, RsbV1, rendering it inactive. Conversely, the putative PP2C-like phosphatase domain of chlamydial RsbU was capable of reverting RsbV1 into its active state. Recent advances in genetic manipulation of Chlamydia were employed to inactivate rsbV1, as well as to increase the expression levels of rsbW or rsbV1, in vivo. Representative σ66-dependent gene transcription was repressed in the absence of rsbV1 or upon increased expression of RsbW, and increased upon elevated expression of RsbV1. These effects on housekeeping transcription were also correlated to several measures of growth and development. A model is proposed where the relative levels of active antagonist (RsbV1) and switch-protein anti-sigma factor (RsbW) control the availability of σ66 and subsequently act as a molecular 'throttle' for Chlamydia growth and development.

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Multidimensional modular microfluidic system

et al. 2009

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Cleavage of a putative metal permease in Chlamydia trachomatis yields an iron-dependent transcriptional repressor

Thompson

Nicod

Malcolm

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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The regulation of iron homeostasis is essential for most organisms, because iron is required for a variety of conserved biochemical processes, yet can be toxic at high concentrations. Upon experiencing iron starvation in vitro, the obligate intracellular human pathogen Chlamydia trachomatis exhibits elevated expression of a putative iron-transport system encoded by the ytg operon. The third component of the ytg operon, CT069 (YtgCR), encodes a protein with two distinct domains: a membrane-anchored metal ion permease and a diphtheria toxin repressor (DtxR)-like transcriptional repressor. In this report, we demonstrate that the C-terminal domain of CT069 (YtgR) serves as an iron-dependent autorepressor of the ytg operon. Moreover, the nascent full-length metal permease-transcriptional repressor protein was processed during the course of infection, and heterologously when expressed in Escherichia coli. The products produced by heterologous cleavage in E. coli were functional in the repression of a reporter gene downstream of a putative YtgR operator. We report a bona fide mechanism of iron-dependent regulation of transcription in Chlamydia. Moreover, the unusual membrane permease-DNA-binding polypeptide fusion configuration was found in several bacteria. Therefore, the DNA-binding capability and liberation of the YtgR domain from a membrane-anchored permease in C. trachomatis could represent a previously uncharacterized mechanism for prokaryotic regulation of iron-homeostasis.ron is an essential micronutrient for nearly all organisms, with its redox capability being both beneficial and harmful to the organism, because of iron readily catalyzing the formation of toxic free radicals via the Haber-Weiss reaction (1). Thus, both eukaryotes and prokaryotes, alike, have evolved regulatory networks for the tight control of intracellular iron homeostasis.In prokaryotes, these regulatory networks are usually controlled through metal-dependent DNA-binding proteins. Two of the best-characterized metal-dependent transcriptional regulators are ferric uptake regulator (Fur) in Escherichia coli and diphtheria toxin repressor (DtxR) in Corynebacterium diphtheriae. Although nonhomologous and structurally distinct, both families of transcriptional repressors function similarly, in that the presence of a cognate metal cofactor activates DNA-binding activity (2). Homodimers of the metal-activated proteins recognize specific cis-regulatory elements that are often located proximally to the promoter operating regions of the regulated gene, effectively blocking RNA polymerase initiation of transcription (3, 4).Chlamydia trachomatis is an obligate, intracellular human pathogen that is responsible for the leading cause of bacterial sexually transmitted infection (5, 6) and infection-derived blindness (7) worldwide. The chlamydial requirement for iron is well established, because iron restriction forces Chlamydia into an alternative persistent growth mode distinguished by abnormal morphology (8-10) and altered transcriptional profile of hall...

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