Activation of Raf/MEK/ERK/cPLA2 signaling pathway is essential for chlamydial acquisition of host glycerophospholipids

Chlamydiae, a diverse group of obligate intracellular pathogens replicating within cytoplasmic vacuoles of eukaryotic cells, are able to acquire lipids from host cells. Here we report that activation of the host Raf-MEK-ERK-cPLA2 signaling cascade is required for the chlamydial uptake of host glycerophospholipids. Both the MAP kinase pathway (Ras/Raf/MEK/ERK) and Ca(2+)-dependent cytosolic phospholipase A2 (cPLA2) were activated in chlamydia-infected cells. The inhibition of cPLA2 activity resulted in the blockade of the chlamydial uptake of host glycerophospholipids and impairment in chlamydial growth. Blocking either c-Raf-1 or MEK1/2 activity prevented the chlamydial activation of ERK1/2, leading to the suppression of both chlamydial activation of the host cPLA2 and uptake of glycerophospholipids from the host cells. The chlamydia-induced phosphorylation of cPLA2 was also blocked by a dominant negative ERK2. Furthermore, activation of both ERK1/2 and cPLA2 was dependent on chlamydial growth and restricted within chlamydia-infected cells, suggesting an active manipulation of the host ERK-cPLA2 signaling pathway by chlamydiae.     

A soluble 60 kilo Dalton antigen of Chlamydia spp. is a homologue of Escherichia coli GroEL

Two major 60 kD protein species can be separated by differential detergent extraction in Chlamydia spp. A Sarkosyl-soluble 60 kD protein is (i) structurally and antigenically distinct from the previously characterized 60 kD Omp2 outer membrane protein; and (ii) antigenically related to a bacterial common antigen of similar molecular weight which includes a 65 kD mycobacterial antigen and the GroEL heat-shock protein of Escherichia coli. Among GroEL homologues, the chlamydial protein (chl-GroEL) uniquely displays affinity towards immobilized thiol groups. The significance of this property is discussed with respect to the synthesis and assembly of the chlamydial disulphide-rich cell wall late in the growth cycle. Chl-GroEL is identical to the Triton X-100-soluble, ocular delayed-type hypersensitivity agent (Morrison et al., 1989), an essential component in the development of blinding trachoma. An autoimmune mechanism for chronic chlamydial diseases based on chl-GroEL homology to host proteins is hypothesized.     

Fluorescence lifetime imaging unravels C. trachomatis metabolism and its crosstalk with the host cell

Chlamydia trachomatis is an obligate intracellular bacterium that alternates between two metabolically different developmental forms. We performed fluorescence lifetime imaging (FLIM) of the metabolic coenzymes, reduced nicotinamide adenine dinucleotides [NAD(P)H], by two-photon microscopy for separate analysis of host and pathogen metabolism during intracellular chlamydial infections. NAD(P)H autofluorescence was detected inside the chlamydial inclusion and showed enhanced signal intensity on the inclusion membrane as demonstrated by the co-localization with the 14-3-3β host cell protein. An increase of the fluorescence lifetime of protein-bound NAD(P)H [τ₂-NAD(P)H] inside the chlamydial inclusion strongly correlated with enhanced metabolic activity of chlamydial reticulate bodies during the mid-phase of infection. Inhibition of host cell metabolism that resulted in aberrant intracellular chlamydial inclusion morphology completely abrogated the τ₂-NAD(P)H increase inside the chlamydial inclusion. τ₂-NAD(P)H also decreased inside chlamydial inclusions when the cells were treated with IFNγ reflecting the reduced metabolism of persistent chlamydiae. Furthermore, a significant increase in τ₂-NAD(P)H and a decrease in the relative amount of free NAD(P)H inside the host cell nucleus indicated cellular starvation during intracellular chlamydial infection. Using FLIM analysis by two-photon microscopy we could visualize for the first time metabolic pathogen-host interactions during intracellular Chlamydia trachomatis infections with high spatial and temporal resolution in living cells. Our findings suggest that intracellular chlamydial metabolism is directly linked to cellular NAD(P)H signaling pathways that are involved in host cell survival and longevity.     

Rottlerin Inhibits Chlamydial Intracellular Growth and Blocks Chlamydial Acquisition of Sphingolipids from Host Cells

We report that rottlerin, a plant-derived compound known to inhibit various mammalian kinases, profoundly inhibited chlamydial growth in cell culture with a minimal inhibition concentration of 1 μM. The inhibition was effective even when rottlerin was added as late as the middle stage of chlamydial infection cycle, against multiple Chlamydia species, and in different host cell lines. Pretreatment of host cells with rottlerin prior to infection also blocked chlamydial growth, suggesting that rottlerin targets host factors. Moreover, rottlerin did not alter the chlamydial infection rate and did not directly target chlamydial protein synthesis and secretion. The rottlerin-mediated inhibition of chlamydial replication and inclusion expansion correlated well with the rottlerin-induced blockade of host cell sphingolipid trafficking from the Golgi apparatus into chlamydial inclusions. These studies not only allowed us to identify a novel antimicrobial activity for rottlerin but also allowed us to uncover a potential mechanism for rottlerin inhibition of chlamydial growth.     

Extensive heterogeneity of the protein composition of Chlamydia trachomatis following serial passage in two different cell lines

To determine if the host-modulated adherence characteristics of the intracellular bacterial pathogen Chlamydia trachomatis were due to the acquisition of altered surface-exposed proteins, highly purified chlamydiae grown in two different host cells were analysed. Two serovars, L1 and E, were grown for multiple passages in both HeLa and McCoy host cells. Numerous protein differences in the chlamydial elementary bodies (EB) of each serovar grown in the two different hosts were detected by two-dimensional (2-D) gel electrophoresis and fluorography of radioactively labelled proteins. At least four to six serial passages in the alternative host were necessary before the changes were apparent. Iodination of suspensions of purified chlamydiae and 2-D electrophoresis revealed several surface proteins that were determined by the host cells in which the bacteria had replicated. These iodinated chlamydial proteins were removed by treatment of the iodinated EB with trypsin, indicating their location at the bacterial surface. Two of the major constituents of the outer-membrane complex, the cysteine- and methionine-rich 60 kDa and 40 kDa proteins, remained unchanged in both molecular mass and charge during the host adaptation. Several chlamydial proteins capable of binding iodinated host membrane preparations also exhibited host-dependent alterations. Immunoblotting experiments with a rabbit and a human polyclonal sera indicated that distinct host-specified chlamydial proteins were reactive with the two sera.     

Rottlerin-Mediated Inhibition of Chlamydia trachomatis Growth and Uptake of Sphingolipids Is Independent of p38-Regulated/Activated Protein Kinase (PRAK)

We previously found that rottlerin, a plant-derived small molecule compound, profoundly inhibited Chlamydia trachomatis growth and blocked sphingolipid trafficking from host cell Golgi into chlamydial inclusions. Since the p38-regulated/activated protein kinase (PRAK) is a known target of rottlerin and is activated in Chlamydia trachomatis-infected cells, we investigated the potential role of this kinase in rottlerin-mediated anti-chlamydial activity. However, we found that a PRAK-specific inhibitor failed to inhibit chlamydial growth, suggesting that the kinase activity of PRAK may not be required for chlamydial intracellular replication. This conclusion was supported by the observation that chlamydial organisms replicated equally well in mouse embryonic fibroblast cells with or without PRAK. Moreover, neither the PRAK inhibitor nor PRAK deficiency altered host sphingolipid trafficking into chlamydial inclusions. Finally, rottlerin maintained its anti-chlamydial activity in PRAK-deficient cells. Together, these observations have demonstrated that PRAK is not required for either the rottlerin-mediated anti-chlamydial activity or rottlerin inhibition of sphingolipid trafficking, suggesting that rottlerin may achieve its inhibitory role by targeting other host factors.     

Trafficking of chlamydial antigens to the endoplasmic reticulum of infected epithelial cells

Confinement of the obligate intracellular bacterium Chlamydia trachomatis to a membrane-bound vacuole, termed an inclusion, within infected epithelial cells neither prevents secretion of chlamydial antigens into the host cytosol nor protects chlamydiae from innate immune detection. However, the details leading to chlamydial antigen presentation are not clear. By immunoelectron microscopy of infected endometrial epithelial cells and in isolated cell secretory compartments, chlamydial major outer membrane protein (MOMP), lipopolysaccharide (LPS) and the inclusion membrane protein A (IncA) were localized to the endoplasmic reticulum (ER) and co-localized with multiple ER markers, but not with markers of the endosomes, lysosomes, Golgi nor mitochondria. Chlamydial LPS was also co-localized with CD1d in the ER. Since the chlamydial antigens, contained in everted inclusion membrane vesicles, were found within the host cell ER, these data raise additional implications for antigen processing by infected uterine epithelial cells for classical and non-classical T cell antigen presentation.     

Control mechanisms governing the infectivity of Chlamydia trachomatis for HeLa cells: the role of calmodulin

Adhesion of the obligate intracellular bacterium Chlamydia trachomatis to host cells is associated with a flux of Ca2+ across the cell membrane, and infection is enhanced by treatment of host cells with Ca2+ ionophore. The possibility that Ca2+ might interact with host cell Ca2+ regulatory proteins to promote chlamydial infection was investigated. Treatment of HeLa 229 cells with the calmodulin inhibitors pimozide, trifluoperazine, chlorpromazine, promethazine or haloperidol reduced chlamydial infectivity as measured by inclusion counting or the specific incorporation of [3H]threonine. The inhibitory effect was reversible, dose-related and shown to be associated with impairment of chlamydial adhesion and uptake by the host cells. This effect was clearly distinguished from the delayed maturation of chlamydiae due to continuous exposure to calmodulin inhibitors which may result from a decrease in the availability of high energy compounds from the host cells necessary for chlamydial growth. The possible mechanisms for calmodulin-mediated chlamydial endocytosis are discussed.     

An early event in the herpes simplex virus type-2 replication cycle is sufficient to induce Chlamydia trachomatis persistence

Epidemiological studies have demonstrated that co-infections of herpes simplex virus type 2 (HSV-2) and Chlamydia trachomatis occur in vivo. Data from a tissue culture model of C. trachomatis/HSV-2 co-infection indicate that viral co-infection stimulates the formation of persistent chlamydiae. Transmission electron microscopic (TEM) analyses demonstrated that in both HeLa and HEC-1B cells, co-infection caused developing chlamydiae to exhibit swollen, aberrantly shaped reticulate bodies (RBs), characteristically observed in persistence. Additionally, HSV-2 co-infection suppressed production of infectious chlamydial elementary bodies (EBs) in both host cell types. Co-infection with HSV type 1 (HSV-1) produced similar morphologic alterations and abrogated infectious EB production. These data indicate that virus-induced chlamydial persistence was neither host cell- nor virus strain-specific. Purification of crude HSV-2 stocks demonstrated that viral particles were required for coinfection-induced chlamydial persistence to occur. Finally, co-infection with either UV-inactivated, replication-incompetent virus or replication-competent HSV-2 in the presence of cyclohexamide reduced chlamydial infectivity without altering chlamydial genomic DNA accumulation. These data demonstrate that productive viral replication is not required for the induction of chlamydial persistence and suggest that HSV attachment and entry can provide the necessary stimulus to alter C. trachomatis development.     

Control mechanisms governing the infectivity of Chlamydia trachomatis for HeLa cells: mechanisms of endocytosis

The mechanism by which Chlamydia trachomatis is endocytosed by host cells is unclear. Studies of the kinetics of chlamydial attachment and uptake in the susceptible HeLa 229 cell line showed that chlamydial endocytosis was rapid and saturable but limited by the slow rate of chlamydial attachment. To overcome this limitation and to investigate the mechanism of endocytosis, chlamydiae were centrifuged onto the host cell surface in the cold to promote attachment. Endocytosis of the adherent chlamydiae was initiated synchronously by rapid warming to 36 degrees C. Electron micrographs of chlamydial uptake 5 min after onset showed that chlamydial ingestion involves movement of the host cell membrane, leading to interiorization in tight, endocytic vacuoles which were not clathrin coated. Chlamydial ingestion was not inhibited by monodansylcadaverine or amantadine, inhibitors of receptor-mediated endocytosis and chlamydiae failed to displace [3H]sucrose from micropinocytic vesicles. Chlamydial endocytosis was markedly inhibited by cytochalasin D, an inhibitor of host cell microfilament function, and by vincristine or vinblastine, inhibitors of host cell microtubules. Hyperimmune rabbit antibody prevented the ingestion of adherent chlamydiae, suggesting that endocytosis requires the circumferential binding of chlamydial and host cell surface ligands. These findings were incompatible with the suggestion that chlamydiae enter cells by taking advantage of the classic mechanism of receptor-mediated endocytosis into clathrin-coated vesicles, used by the host cell for the internalization of beta-lipoprotein and other macromolecules, but were consistent with the hypothesis that chlamydiae enter cells by a microfilament-dependent zipper mechanism.     

Apoptosis of host cells regulation by Chlamydia

In a study on the impact of chlamydial infection on host cell apoptosis, C. trachomatis were shown to protect host cell against staurosporin-induced apoptosis only at the middle stage of infection development (at 20 hours post infection), C. pneumoniae--at different stages of its growth cycle (from 2 to 7 day post infection). We found, that C. trachomatis elementary bodies fail to inhibit staurosporin-induced apoptotic stimuli. The clear antiapoptotic effect of cell lysate filtrate, infected with C. trachomatis, was demonstrated by cytometric analysis and luminescent microscopy. Our findings make it possible to use biochemical approach to identification of chlamydial antiapoptotic factors in future. Investigations directed at chlamydial antiapoptotic activities may aim to create the therapies of chronic chlamydial infection.     

Chlamydia trachomatis Tarp cooperates with the Arp2/3 complex to increase the rate of actin polymerization

Actin polymerization is required for Chlamydia trachomatis entry into nonphagocytic host cells. Host and chlamydial actin nucleators are essential for internalization of chlamydiae by eukaryotic cells. The host cell Arp2/3 complex and the chlamydial translocated actin recruiting phosphoprotein (Tarp) are both required for entry. Tarp and the Arp2/3 complex exhibit unique actin polymerization kinetics individually, but the molecular details of how these two actin nucleators cooperate to promote bacterial entry is not understood. In this study we provide biochemical evidence that the two actin nucleators act synergistically by co-opting the unique attributes of each to enhance the dynamics of actin filament formation. This process is independent of Tarp phosphorylation. We further demonstrate that Tarp colocalization with actin filaments is independent of the Tarp phosphorylation domain. The results are consistent with a model in which chlamydial and host cell actin nucleators cooperate to increase the rate of actin filament formation.     

Identification of Chlamydia trachomatis CT621, a protein delivered through the type III secretion system to the host cell cytoplasm and nucleus

Chlamydiae are obligate intracellular bacteria, developing inside host cells within chlamydial inclusions. From these inclusions, the chlamydiae secrete proteins into the host cell cytoplasm. A pathway through which secreted proteins can be delivered is the type III secretion system (T3SS). The T3SS is common to several gram-negative bacteria and the secreted proteins serve a variety of functions often related to the modulation of host signalling. To identify new potentially secreted proteins, the cytoplasm was extracted from Chlamydia trachomatis L2-infected HeLa cells, and two-dimensional polyacrylamide gel electrophoresis profiles of [³⁵S]-labelled chlamydial proteins from this extract were compared with profiles of chlamydial proteins from the lysate of infected cells. In this way, CT621 was identified. CT621 is a member of a family of proteins containing a domain of unknown function DUF582 that is only found within the genus Chlamydia . Immunofluorescence microscopy and immunoblotting demonstrated that CT621 is secreted late in the chlamydial developmental cycle and that it is the first chlamydial protein found to be localized within both the host cell cytoplasm and the nucleus. To determine whether CT621 is secreted through the T3SS, an inhibitor of this apparatus was added to the infection medium, resulting in retention of the protein inside the chlamydiae. Hence, the so far uncharacterized CT621 is a new type III secretion effector protein.     

Effect of 6-thioguanine on Chlamydia trachomatis growth in wild-type and hypoxanthine-guanine phosphoribosyltransferase-deficient cells.

Chlamydiae have evolved a biphasic life cycle to facilitate their survival in two discontinuous habitats. The unique growth cycle is represented by two alternating forms of the organism, the elementary body and the reticulate body. Chlamydiae have an absolute nutritional dependency on the host cell to provide ribonucleoside triphosphates and other essential intermediates of metabolism. This report describes the pleiotropic effects of the purine antimetabolite 6-thioguanine on chlamydial replication. In order to display cytotoxicity, 6-thioguanine must first be converted to the nucleotide level by the host cell enzyme hypoxanthine-guanine phosphoribosyltransferase. Our results show that 6-thioguanine is an effective inhibitor of chlamydial growth with either wild-type or hypoxanthine-guanine phosphoribosyltransferase-deficient cell lines as the host. Interestingly, the mechanism of 6-thioguanine-induced inhibition of chlamydial growth is different depending on which cell line is used. With wild-type cells as the host, the cytotoxic effects of 6-thioguanine on chlamydial growth are relatively fast and irreversible. Under these circumstances, cytotoxicity likely results from the combined effect of starving chlamydiae for purine ribonucleotides and incorporation of host-derived 6-thioguanine-containing nucleotides into chlamydial nucleic acids. With hypoxanthine-guanine phosphoribosyltransferase-deficient cells as the host, 6-thioguanine must be present at the start of the chlamydial infection cycle to be effective and the growth inhibition is reversible upon removal of the antimetabolite. These findings suggest that in hypoxanthine-guanine phosphoribosyltransferase-deficient cells, the free base 6-thioguanine may inhibit the differentiation of elementary bodies to reticulate bodies. With hypoxanthine-guanine phosphoribosyltransferase-deficient cells as the host, 6-thioguanine was used as a selective agent in culture to isolate a Chlamydia trachomatis isolate resistant to the effects of the drug. This drug resistant C. trachomatis isolate was completely resistant to 6-thioguanine in hypoxanthine-guanine phosphoribosyltransferase-deficient cells; however, it displayed wildtype sensitivity to 6-thioguanine when cultured in wild-type host cells.     

Control mechanisms governing the infectivity of Chlamydia trachomatis for hela cells: modulation by cyclic nucleotides, prostaglandins and calcium

Chlamydia trachomatis causes common infections of the eyes and genital tract in man. The mechanism by which this obligate intracellular bacterium is taken into epithelial cells is unclear. The results described here support the concept that chlamydial infections of HeLa cells is under bidirectional cyclic nucleotide control, with guanosine 3':5'-cyclic monophosphate (cGMP) acting as a stimulator, and adenosine 3':5'-cyclic monophosphate (cAMP) as an inhibitor. Treatment of the HeLa cells with the divalent cation ionophore A23187, with carbamoylcholine, or with prostaglandins known to increase the concentration of endogenous cGMP, also increased host cell susceptibility to chlamydial infection. Cyclic GMP was only effective if added at or before chlamydial inoculation, suggesting that its main effect was on chlamydial uptake. The stimulatory effect of cGMP, but nt antagonism, by cAMP, was abolished if the cells were first treated with any of four different inhibitors of prostaglandin synthesis, suggesting a critical role for endogenous prostaglandin synthesis. Centrifugation of chlamydiae on to host cells was followed by a rapid increase in the mobility of Ca2+ across the cell membrane. The interrelationships of these observations and the possibility that chlamydiae and other intracellular pathogens might evoke alterations in host cell prostaglandin and cyclic nucleotide concentrations to aid their own uptake are discussed.     

NF-kappa B activation is not required for Chlamydia trachomatis inhibition of host epithelial cell apoptosis

Chlamydia trachomatis, an obligate intracellular bacterial species, is known to inhibit host cell apoptosis. However, the chlamydial antiapoptotic mechanism is still not clear. Because NF-kappaB activation is antiapoptotic, we tested the potential role of NF-kappaB activation in chlamydial antiapoptotic activity in the current study. First, no obvious NF-kappaB activation was detected in the chlamydia-infected cells when these cells were resistant to apoptosis induced via either the intrinsic or extrinsic apoptosis pathways. Second, inhibition of NF-kappaB activation with pharmacologic reagents failed to block the chlamydial antiapoptotic activity. Finally, NF-kappaB p65 gene deletion did not prevent chlamydia from inhibiting host cell apoptosis. These observations together have demonstrated that NF-kappaB activation is not required for the chlamydial antiapoptotic activity.     

Ultrastructural analysis of chlamydial antigen-containing vesicles everting from the Chlamydia trachomatis inclusion

Several chlamydial antigens have been detected in the infected epithelial cell cytosol and on the host cell surface prior to their presumed natural release at the end of the 72-96 h developmental cycle. These extra-inclusion antigens are proposed to influence vital host cell functions, antigen trafficking and presentation and, ultimately, contribute to a prolonged inflammatory response. To begin to dissect the mechanisms for escape of these antigens from the chlamydial inclusion, which are enhanced on exposure to antibiotics, polarized endometrial epithelial cells (HEC-1B) were infected with Chlamydia trachomatis serovar E for 36 h or 48 h. Infected cells were then exposed to chemotactic human polymorphonuclear neutrophils not loaded or pre-loaded in vitro with the antibiotic azithromycin. Viewed by electron microscopy, the azithromycin-mediated killing of chlamydiae involved an increase in chlamydial outer membrane blebbing followed by the appearance of the blebs in larger vesicles (i) everting from but still associated with the inclusion as well as (ii) external to the inclusion. Evidence that the vesicles originated from the chlamydial inclusion membrane was shown by immuno-localization of inclusion membrane proteins A, F, and G on the vesicular membranes. Chlamydial heat shock protein 60 (chsp60) copies 2 and 3, but not copy 1, were released from RB and incorporated into the everted inclusion membrane vesicles and delivered to the infected cell surface. These data represent direct evidence for one mechanism of early antigen delivery, albeit membrane-bound, beyond the confines of the chlamydial inclusion.     

Initial characterization of a chlamydial receptor on mammalian cells

We have examined characteristics of the binding of eukaryotic cells to chlamydial elementary body (EB)-specific proteins. A wide variety of eukaryotic cell lines bound to representatives of both Chlamydia trachomatis lymphogranuloma venereum (LGV) and trachoma biovars and a C. psittaci strain meningopneumonitis (Mn) suggesting the presence of a common host cell receptor. Neither tunicamycin nor neuraminidase treatment of HeLa cells impaired binding to C. trachomatis EB, implying that host cell N-linked carbohydrate domains and sialic acid moieties, respectively, are not involved in attachment. However, trypsinized HeLa cells do not bind to EB, suggestive of a proteinaceous host cell receptor. The trypsin sensitivity of two EB-specific binding proteins Mr = 18,000 and 31,000) was also examined, and the finding that 125I-labeled HeLa cells bind both the 18,000 and 31,000-dalton proteins after chlamydial trypsinization corroborates our earlier observation that these EB binding proteins mediate attachment.