David J. Mead scite author profile

The obligate intracellular bacterium Chlamydia trachomatis rapidly induces its own entry into host cells. Initial attachment is mediated by electrostatic interactions to heparan sulfate moieties on the host cell, followed by irreversible binding to an unknown secondary receptor. This secondary binding leads to the recruitment of actin to the site of attachment, formation of an actin-rich, pedestallike structure, and finally internalization of the bacteria. How chlamydiae induce this process is unknown. We have identified a high-molecular-mass tyrosine-phosphorylated protein that is rapidly phosphorylated on attachment to the host cell. Immunoelectron microscopy studies revealed that this tyrosine-phosphorylated protein is localized to the cytoplasmic face of the plasma membrane at the site of attachment of surface-associated chlamydiae. The phosphoprotein was isolated by immunoprecipitation with the antiphosphotyrosine antibody 4G10 and identified as the chlamydial protein CT456, a hypothetical protein with unknown function. The chlamydial protein (Tarp) appears to be translocated into the host cell by type III secretion because it is exported in a Yersinia heterologous expression assay. Phosphotyrosine signaling across the plasma membrane preceded the recruitment of actin to the site of chlamydial attachment and may represent the initial signal transduced from pathogen to the host cell. These results suggest that C. trachomatis internalization is mediated by a chlamydial type III-secreted effector protein. Chlamydia trachomatis is a Gram-negative obligate intracellular bacterium that is a leading cause of sexually transmitted diseases and blindness worldwide (1). Chlamydiae have a biphasic developmental cycle characterized by an infectious but metabolically inactive extracellular form, called the elementary body (EB), that initiates infection by attaching to and inducing uptake by the host cell. Once internalized, chlamydiae remain within a membrane-bound vacuole termed an inclusion, where the organism differentiates into the larger, metabolically active reticulate body. Reticulate bodies replicate and differentiate back to EBs before release at the end of the developmental cycle.EBs attach to and enter cultured eukaryotic cells so efficiently that the process has been termed parasite-specified phagocytosis (2). Despite the importance of this event to chlamydial pathogenesis, little consensus exists regarding the identity of the chlamydial ligands and respective host receptors (for a review, see ref.3). Considerable evidence suggests that electrostatic interactions mediate attachment with heparan sulfate-like proteoglycans involved in an initial, reversible interaction with the eukaryotic host cell for many, but not all, strains and species of chlamydiae (4 -9). Recent studies using chemically mutagenized cell lines distinguished a subsequent, irreversible secondary binding step in the entry process, although the receptor was not identified (8, 10). Entry of C. trachomatis requires participation of the actin cy...

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Temporal Analysis of Coxiella burnetii Morphological Differentiation

Coleman

et al. 2004

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Coxiella burnetii undergoes a poorly defined developmental cycle that generates morphologically distinct small-cell variants (SCV) and large-cell variants (LCV). We developed a model to study C. burnetii morphogenesis that uses Vero cells synchronously infected with homogeneous SCV (Nine Mile strain in phase II) harvested from aged infected cell cultures. A time course transmission electron microscopic analysis over 8 days of intracellular growth was evaluated in conjunction with one-step growth curves to correlate morphological differentiations with growth cycle phase. Lag phase occurred during the first 2 days postinfection (p.i.) and was primarily composed of SCV-to-LCV morphogenesis. LCV forms predominated over the next 4 days, during which exponential growth was observed. Calculated generation times during exponential phase were 10.2 h (by quantitative PCR assay) and 11.7 h (by replating fluorescent focus-forming unit assay). Stationary phase began at approximately 6 days p.i. and coincided with the reappearance of SCV, which increased in number at 8 days p.i. Quantitative reverse transcriptase-PCR demonstrated maximal expression of scvA, which encodes an SCV-specific protein, at 8 days p.i., while immunogold transmission electron microscopy revealed degradation of ScvA throughout lag and exponential phases, with increased expression observed at the onset of stationary phase. Collectively, these results indicate that the overall growth cycle of C. burnetii is characteristic of a closed bacterial system and that the replicative form of the organism is the LCV. The experimental model described in this report will allow a global transcriptome and proteome analysis of C. burnetii developmental forms.

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Inhibition of a Mycobacterium tuberculosis β-Ketoacyl ACP Synthase by Isoniazid

Mdluli

Slayden

Zhu

et al. 1998

Science

376

305

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Although isoniazid (isonicotinic acid hydrazide, INH) is widely used for the treatment of tuberculosis, its molecular target has remained elusive. In response to INH treatment, saturated hexacosanoic acid (C26:0) accumulated on a 12-kilodalton acyl carrier protein (AcpM) that normally carried mycolic acid precursors as long as C50. A protein species purified from INH-treated Mycobacterium tuberculosis was shown to consist of a covalent complex of INH, AcpM, and a beta-ketoacyl acyl carrier protein synthase, KasA. Amino acid-altering mutations in the KasA protein were identified in INH-resistant patient isolates that lacked other mutations associated with resistance to this drug.

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David J. Mead

A chlamydial type III translocated protein is tyrosine-phosphorylated at the site of entry and associated with recruitment of actin

Temporal Analysis of Coxiella burnetii Morphological Differentiation

Inhibition of a Mycobacterium tuberculosis β-Ketoacyl ACP Synthase by Isoniazid

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