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Notes: The medically significant, obligate intracellular pathogen Chlamydia trachomatis replicates within vacuoles termed inclusions. A developmental cycle is initiated after entry into a host cell and is manifested by the transformation of infectious elementary bodies (EBs) to larger, non-infectious reticulate bodies (RBs). Analysis of the C. trachomatis genome has revealed that chlamydiae possess genes that may encode a type III secretion apparatus. In other Gram-negative pathogens, the type III secretion mechanism is used to target virulence factors directly to the host cell cytoplasm and is essential for full virulence. To evaluate the possibility of a functional type III secretion mechanism in C. trachomatis, we initially focused on a locus containing genes encoding products with similarity to chaperones (Scc1), secretion pore components (Cds1 and Cds2) and secreted proteins (CopN) from other type III systems. Gene expression was tested by reverse transcriptase–polymerase chain reaction (RT–PCR) of total RNA extracted from infected HeLa cell monolayers at 2, 6, 12 and 20 h after infection and normalized for the number of C. trachomatis genomes present. Message was detected for Scc1 at all times, whereas message for all other tested genes was detected in significant amounts at 12 h and 20 h. Immunoblot analysis with Scc1- and CopN-specific antibodies revealed that CopN and Scc1 were present in EBs, RBs and whole-culture extracts harvested 20 h after infection. CopN is homologous to the secreted protein YopN of Yersinia sp., and analysis of monolayers 20 h after infection via indirect immunofluorescence showed specific labelling of inclusion membranes when probed with CopN-specific antibodies but not with Scc1-specific antibodies. His-tagged CopN and a chlamydial cytoplasmic control protein (NrdB) were expressed in Yersinia enterocolitica containing or lacking the virulence plasmid pYV. CopN, but not NrdB, was secreted by Y. enterocolitica in a Ca2+- and pYV-dependent fashion. These data indicate that components of the putative type III apparatus of C. trachomatis are expressed and that at least one of these products is secreted by chlamydiae to the inclusion membrane. The observation that CopN is also secreted by the Yersinia type III apparatus provides support for the notion that chlamydiae secrete proteins via a type III mechanism.

Notes: The obligate intracellular bacterium Chlamydia trachomatis has a unique developmental cycle that involves functionally and morphologically distinct cell types adapted for extracellular survival and intracellular multiplication. Infection is initiated by an environmentally resistant cell type called an elementary body (EB). Over the first several hours of infection, EBs differentiate into a larger replicative form, termed the reticulate body (RB). Late in the infectious process, RBs asynchronously begin to differentiate back to EBs, which accumulate within the lumen of the inclusion until released from the host cell for subsequent rounds of infection. In an effort to characterize temporal gene expression in relation to the chlamydial developmental cycle, we have used quantitative–competitive polymerase chain reaction (QC-PCR) and reverse transcription (RT)-PCR techniques. These analyses demonstrate that C. trachomatis double their DNA content every 2–3 h, with synthesis beginning between 2 and 4 h after infection. We determined the onset of transcription of specific temporal classes of developmentally expressed genes. RT-PCR analysis was performed on several genes encoding key enzymes or components of essential biochemical pathways and functions. This comparison encompassed approximately 8% of open reading frames on the C. trachomatis genome. In analysis of total RNA samples harvested at 2, 6, 12 and 20 h after infection, using conditions under which a single chlamydial transcript per infected cell is detected, three major temporal classes of gene expression were resolved. Initiation of transcription appears to occur in three temporal classes which we have operationally defined as: early, which are detected by 2 h after infection during the germination of EBs to RBs; mid-cycle, which appear between 6 and 12 h after infection and represent transcripts expressed during the growth and multiplication of RBs; or late, which appear between 12 and 20 h after infection and represent those genes transcribed during the terminal differentiation of RBs to EBs. Collectively, the data suggest that chlamydial early gene functions are weighted toward initiation of macromolecular synthesis and the establishment of their intracellular niche by modification of the inclusion membrane. Surprisingly, representative enzymes of intermediary metabolism and structural proteins do not appear to be transcribed until 10–12 h after infection; coinciding with the onset of observed binary fission of RBs. Late gene functions appear to be predominately those associated with the terminal differentiation of RBs back to EBs.

Notes: The obligate intracellular bacterium Chlamydia trachomatis occupies a parasitophorous vacuole termed an inclusion. During its intracellular developmental cycle, C. trachomatis maintains this intracellular niche, presumably by expressing a type III secretion system, which deploys a set of host cell-interactive proteins including inclusion membrane-localized proteins termed Incs. Some Incs are expressed and secreted by 2 h (early cycle) after infection, whereas the expression of type III-specific genes is not detectable until 6–12 h (mid-cycle). To resolve this paradox, we investigated the presence of a type III apparatus on elementary bodies (EBs) that might function early in infection. We demonstrate the existence of the type III secretory apparatus by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) and immunoblot analyses of purified EB extracts. Immunoblots using polyclonal antibodies specific for the core apparatus component CdsJ identified this protein in both EB and reticulate body (RB) extracts. Furthermore, CdsJ-specific signals were detected by immunoblot of whole infected-culture extracts and by indirect immunofluorescence of infected monolayers at times before the detection of cdsJ-specific message. Finally, expression of IncC, expressed by 2 h after infection during C. trachomatis infections, in Yersinia pseudotuberculosis resulted in its secretion via the Yersinia type III apparatus. Based on these data, we propose a model in which type III secretion pores are present on EBs and mediate secretion of early Incs and possible additional effectors. Mid-cycle expression of type III genes would then replenish secretion apparatus on vegetative RBs and serve as a source of secretion pores for subsequently formed EBs.