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ABSTRACT: During persistent infection, the intracellular bacterial pathogen Chlamydia trachomatis is viable but severely attenuates the production of new, infectious elementary bodies (EBs). To investigate the reasons for this lack of new EB output, we analysed the expression of chlamydial genes encoding products required for DNA replication and cell division, using in vitro models of active versus persistent infection and synovial tissue samples from patients with chronic Chlamydia-associated arthritis. Hep-2 cells were infected with K serovar C. trachomatis and harvested at t = 0-48 h post-infection (p.i; active). Human monocytes were infected similarly and harvested at t = 1-7 days p.i. (persistent). RNA preparations from infected/uninfected cells and patient samples were subjected to reverse transcription-polymerase chain reaction (RT-PCR) targeting polA, dnaA, mutS and parB mRNA, related to chlamydial DNA replication/segregation; these were expressed in infected Hep-2 cells from 11 to 48 h p.i; ftsK and ftsW, related to cell division, were expressed similarly. Real-time PCR analyses demonstrated that significant accumulation of chlamydial chromosome began at about 12 h p.i. in infected Hep-2 cells. In infected human monocytes, polA, dnaA, mutS and parB mRNA were produced from days 1-7 p.i. and were weakly expressed in patient samples. Real-time PCR indicated the continuing accumulation of chlamydial chromosome during the 7 day monocyte infection, although the rate of such accumulation was lower than that occurring during active growth. However, transcripts from ftsK and ftsW were detected only at 1 day p.i. in infected monocytes but not thereafter, and they were absent in all patient samples. Thus, genes whose products are required for chlamydial DNA replication are expressed during persistence, but transcription of genes whose products are required for cytokinesis is severely downregulated. These data explain, at least in part, the observed attenuation of new EB production during chlamydial persistence.
Molecular Microbiology 09/2001; 41(3):731-41. · 5.01 Impact Factor
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H C Gérard, Z Wang,
G F Wang,
H El-Gabalawy,
R Goldbach-Mansky,
Y Li,
W Majeed,
H Zhang,
N Ngai,
A P Hudson,
H R Schumacher
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ABSTRACT: We and others have reported the presence of Chlamydia and other bacterial species in joint specimens from patients with reactive arthritis (ReA). The present study was conducted to investigate whether bacteria other than those specified by diagnostic criteria for ReA could be identified in synovial fluid (SF) or tissue from patients with various arthritides, and whether the presence of such organisms corresponds to particular clinical characteristics in any patient set or subset.
DNA in synovial biopsy samples and SF obtained from 237 patients with various arthritides, including ReA, rheumatoid arthritis, and undifferentiated oligoarthritis, was assayed by polymerase chain reaction (PCR) using "panbacterial" primers; we chose only samples known to be PCR negative for Chlamydia, Borrelia, and Mycoplasma species. PCR products were cloned, and cloned amplicons from each sample were sequenced; DNA sequences were compared against all others in GenBank for identification of bacterial species involved.
Ten percent of patient samples were PCR positive in panbacterial screening assays. Bacterial species identified belonged to the genera Neisseria, Acinetobacter, Moraxella, Salmonella, Pseudomonas, and others. Thirty-five percent of PCR-positive patients showed the presence of DNA from more than a single bacterial species in synovium; overall, however, we could identify no clear relationship between specific single or multiple bacterial species in the synovium and any general clinical characteristics of any individual or group of patients.
This analysis provides the first systematic attempt to relate bacterial nucleic acids in the synovium to clinical characteristics, joint findings, and outcomes. Many patients with arthritis have bacterial DNA in the joint, and, in some cases, DNA from more than a single species is present. However, except for 1 case of a control patient with staphylococcal septic arthritis, it is not clear from the present study whether the synovial presence of such organisms is related to disease pathogenesis or evolution in any or all cases.
Arthritis & Rheumatism 08/2001; 44(7):1689-97. · 7.87 Impact Factor
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ABSTRACT: When the rabbit bladder outlet is partially obstructed, the relative amount of mitochondrial (mt) DNA per cell in bladder smooth muscle falls rapidly. In order to assess whether this loss of organellar genome results from attenuation of mt DNA replication, we cloned portions of rabbit genes specifying the single-strand binding (SSB) protein required for initiation of mt DNA replication, and the catalytic subunit of DNA polymerase gamma (pol gamma), the replication enzyme itself. We then designed primer-probe systems for real-time RT-PCR (TaqMan) analyses for each gene. These were used to assess mRNA in preparations from bladder smooth muscle and mucosa from rabbits subjected to surgical obstruction of the bladder outlet for up to 14 days. mRNA from the pol gamma gene remained essentially at control level in smooth muscle and mucosa in all samples. In mucosa, mRNA from the SSB protein gene remained virtually at control levels in all samples, as did mt genome copy number. In smooth muscle, however, levels of this mRNA declined by >95% within 3 days of obstruction and remained at that level through 14 days; this attenuation of SSB protein mRNA paralleled the loss of mt DNA in the same smooth muscle samples. Thus, lack of mt SSB protein, and consequently attenuated mt DNA replication, is a primary factor in the loss of mt genome copies in bladder smooth muscle after outlet obstruction in the rabbit model of benign bladder dysfunction.
Molecular Urology 01/2001; 5(3):99-104.
