The endogenous antiseptic N-chlorotaurine irreversibly inactivates Chlamydia pneumoniae and Chlamydia trachomatis.

PURPOSE: The antimicrobial activity of N-chlorotaurine (NCT), an endogenous long-lived oxidant applied topically, was tested against Chlamydiae in vitro. METHODOLOGY: Elementary bodies of Chlamydia pneumoniae strain CV-6 and Chlamydia trachomatis serovars A and D were incubated in 0.01, 0.1 and 1 % (w/v) NCT solution at pH 7.1 and 37 °C. After different incubation times, aliquots were removed and grown in cell culture. The number of inclusion forming units was quantified by immunofluorescence and real-time qPCR.Results/Key findings.Chlamydia pneumoniae and Chlamydia trachomatis were inactivated by 1 and 0.1 % NCT within 1 min. Moreover, 0.025-0.1 % NCT significantly reduced the number of intracellularly growing C. pneumoniae within 30 min. CONCLUSIONS: This is the first study demonstrating the antimicrobial activity of NCT against Chlamydiae. Clinical implications of these findings have to be investigated in further trials.

Chlamydia pneumoniae infection acts as an endothelial stressor with the potential to initiate the earliest heat shock protein 60-dependent inflammatory stage of atherosclerosis.

We identified increased expression and redistribution of the intracellular protein 60-kDa human heat shock protein (hHSP60) (HSPD1) to the cell surface in human endothelial cells subjected to classical atherosclerosis risk factors and subsequent immunologic cross-reactivity against this highly conserved molecule, as key events occurring early in the process of atherosclerosis. The present study aimed at investigating the role of infectious pathogens as stress factors for vascular endothelial cells and, as such, contributors to early atherosclerotic lesion formation. Using primary donor-matched arterial and venous human endothelial cells, we show that infection with Chlamydia pneumoniae leads to marked upregulation and surface expression of hHSP60 and adhesion molecules. Moreover, we provide evidence for an increased susceptibility of arterial endothelial cells for redistribution of hHSP60 to the cellular membrane in response to C. pneumoniae infection as compared to autologous venous endothelial cells. We also show that oxidative stress has a central role to play in endothelial cell activation in response to chlamydial infection. These data provide evidence for a role of C. pneumoniae as a potent primary endothelial stressor for arterial endothelial cells leading to enrichment of hHSP60 on the cellular membrane and, as such, a potential initiator of atherosclerosis.

Sequence homologies between Mycoplasma and Chlamydia spp. lead to false-positive results in chlamydial cell cultures tested for mycoplasma contamination with a commercial PCR assay.

Mycoplasma contamination is a frequent problem in chlamydial cell culture. After obtaining contradictory contamination results, we compared three commercial PCR kits for mycoplasma detection. One kit signaled contamination in mycoplasma-free Chlamydia pneumoniae cultures. Sequencing of cloned PCR products revealed primer homology with the chlamydial genome as the basis of this false-positive result.

Inhibitory effect of the natural product betulin and its derivatives against the intracellular bacterium Chlamydia pneumoniae.

Chlamydia pneumoniae is a universal pathogen that has been indicated to play a part in the development of asthma, atherosclerosis and lung cancer. The complete eradication of this intracellular bacterium is in practice impossible with the antibiotics that are currently in use and studies on new antichlamydial compounds is challenging because Chlamydia research lacks the tools required for the genetic modification of this bacterium. Betulin is a natural lupane-class triterpene derived from plants with a wide variety of biological activities. This compound group thus has wide medical potentials, and in fact has been shown to be active against intracellular pathogens. For this reason, betulin and its derivatives were selected to be assayed against C. pneumoniae in the present study. Thirty-two betulin derivatives were assayed against C. pneumoniae using an acute infection model in vitro. Five promising compounds with potential lead compound characteristics were identified. Compound 24 (betulin dioxime) gave a minimal inhibitory concentration (MIC) of 1 microM against strain CWL-029 and showed activity in nanomolar concentrations, as 50% inhibition was achieved at 290 nM. The antichlamydial effect of 24 was confirmed with a clinical isolate CV-6, showing a MIC of 2.2 microM. Previous research on betulin and its derivatives has not identified such a remarkable inhibition of Gram-negative bacterial growth. Furthermore, we also demonstrated that this antichlamydial activity was not due to PLA(2) (EC 3.1.1.4) inhibition caused by the betulin derivatives.

Chlamydia pneumoniae adversely modulates vascular cell properties by direct interaction with signalling cascades.

Due to its dependence on intracellular development Chlamydia pneumoniae has developed numerous strategies to create an adequate environment within its host cells ensuring both chlamydial reproduction and target cell survival. The bacterium that has been related to atherogenesis due to its presence in vascular tissue is able to enter a persistent state of chronic infection in the vasculature that escapes antibiotic targeting. Ingestion of the bacterium results in severe modifications and reprogramming of signalling pathways and the metabolism of the host cell. Processes range from the prevention of direct lysosomal destruction of chlamydial inclusions to the inhibition of host cell apoptosis and an enhanced cellular glucose uptake to maintain energy-consuming mechanisms. Furthermore, infection regularly causes the development of a proinflammatory and proproliferative phenotype in the host cell in vitro, ex vivo and in vivo and own new findings suggest a detrimental proliferative loop within vascular cells upon a modified endothelin-1 axis demonstrating a potential for proatherosclerotic processes in early and progressed atherosclerosis. This review displays crucial mechanisms of Chlamydia pneumoniae-induced interactions with vascular host cell signalling cascades with an emphasis on mitogenic and inflammatory processes as well as target cell activation.

Proliferative stimulation of the vascular Endothelin-1 axis in vitro and ex vivo by infection with Chlamydia pneumoniae.

Endothelin-1 (ET-1) is a vasoactive peptide that modifies vascular function via the G-protein coupled transmembrane receptors, Endothelin-A receptor (ETAR) and Endothelin-B receptor (ETBR). Dysregulation of the ET-1 axis plays a role in atherosclerotic development as it triggers cell proliferation, inflammation, and vasoconstriction. The respiratory pathogen Chlamydia pneumoniae (Cp) has been recovered from atherosclerotic lesions, and related to atherogenesis, via activation of vascular small GTPases and leukocyte recruitment. Cp effectively reprograms host cell signalling and is able to enter an intracellular persistent state in vascular cells that is refractory to antibiotics. Upon chlamydial infection, vascular smooth muscle cells, which do not produce significant ET-1 under physiological conditions were switched into a fundamental source of ET-1 mRNA and protein in a p38-MAP-kinase-dependent pathway. Endothelial cells did not overproduce ET-1 but showed upregulation of mitogenic ETAR mRNA and protein while the counterbalancing ETBR, which regulates ET-1 clearance, remained unaffected. This disruption of the ET-1 axis was confirmed in an ex vivo mouse aortic ring model, and resulted in endothelial cell proliferation that could be abrogated by ETAR-siRNA and the selective ETAR-antagonist BQ-123. Chronic chlamydial infection of the vascular wall might represent a permanent noxious stimulus linked to the endothelial cell proliferation characteristic of early atherosclerosis. Suppression of this deleterious paracrine loop by ETAR antagonism opens up a new option of preventing possible vascular sequelae of otherwise untreatable chronic chlamydial infection. In conclusion, this is the first study to demonstrate infection to dysregulate the ET-1 axis towards inducing a proatherogenic proliferative phenotype.

Chlamydia pneumoniae-induced pathological signaling in the vasculature.

Since its description in 1986, Chlamydia pneumoniae has remained one of the most enigmatic pathogens. This intracellular bacterium is highly seroprevalent, but rarely recovered from cell culture, it can genetically switch between a proliferative and a nonreplicative state and has been linked to a vast number of chronic diseases, most notably to atherosclerosis, as it can be found in the plaques. It has become quite clear that persistent bacteria in atherosclerotic lesions cannot be eradicated by currently available antibiotic treatments and that attempts to do so without a better understanding of the pathobiology of chlamydial persistence are futile. However, there is growing knowledge on how vascular chlamydial infection may lead to the pathological reprogramming of the host cell signaling pathways. Chlamydia pneumoniae is now well known to induce, at least in vitro, the two pathogenetic main events that define atherosclerosis: angiogenesis and inflammation. In vivo a contribution of chlamydial infection to the progression of atherosclerosis remains unproven. This minireview provides a brief overview on the proproliferative and proinflammatory effects of vascular C. pneumoniae infection and their potential link to atherogenesis.