In vitro susceptibility testing was performed on strains of Chlamydia trachomatis, Chlamydia pneumoniae, and Chlamydia psittaci under various conditions, including the cell line utilized, the time between infection and the addition of an antimicrobial, the concentration of inoculum, and the effect of multiple passage on the minimal chlamydicidal concentrations for the antibiotics doxycycline, azithromycin, erythromycin, ofloxacin, and tetracycline. With macrolides, the MIC varied depending upon the cell line utilized. With all antimicrobials, the MIC was related to the time at which the antimicrobial was added after infection. By an optimized cell culture passage method, all strains of chlamydia tested demonstrated survival after exposure to high levels (>100 times the MIC) of antimicrobials. Furthermore, upon retest, these surviving organisms did not demonstrate increased MICs. Thus, this phenomenon does not reflect selection of antimicrobial-resistant mutants but rather survival of some organisms in high antimicrobial concentrations (heterotypic survival). An additional 44 clinical isolates of C. trachomatis from patients with single-incident infections were tested against those from patients with recurrent or persistent infections, and heterotypic survival was seen in all isolates tested; hence, in vitro resistance did not correlate with the patient's apparent clinical outcome.
There are no examples of stable tetracycline resistance in clinical strains of Chlamydia trachomatis. However, the swine pathogen Chlamydia suis is commonly tetracycline resistant, both in America and in Europe. In tested U.S. strains, this resistance is mediated by a genomic island carrying a tet(C) allele. In the present study, the ability of C. suis to mobilize tet(C) into other chlamydial species was examined. Differently antibiotic resistant strains of C. suis, C. trachomatis, and Chlamydia muridarum were used in coculture experiments to select for multiply antibiotic resistant progeny. Coinfection of mammalian cells with a naturally occurring tetracyclineresistant strain of C. suis and a C. muridarum or C. trachomatis strain containing selected mutations encoding rifampin (rifampicin) or ofloxacin resistance readily produced doubly resistant recombinant clones that demonstrated the acquisition of tetracycline resistance. The resistance phenotype in the progeny from a C. trachomatis L2/ofl R -C. suis R19/tet R cross resulted from integration of a 40-kb fragment into a single ribosomal operon of a recipient, leading to a merodiploid structure containing three rRNA operons. In contrast, a cross between C. suis R19/tet R and C. muridarum MoPn/ofl R led to a classical double-crossover event transferring 99 kb of DNA from C. suis R19/tet R into C. muridarum MoPn/ofl R . Tetracycline resistance was also transferred to recent clinical strains of C. trachomatis. Successful crosses were not obtained when a rifampin-resistant Chlamydophila caviae strain was used as a recipient for crosses with C. suis or C. trachomatis. These findings provide a platform for further exploration of the biology of horizontal gene transfer in Chlamydia while bringing to light potential public health concerns generated by the possibility of acquisition of tetracycline resistance by human chlamydial pathogens.
The chlamydiae are obligate intracellular pathogens that occupy a nonacidified vacuole, termed an inclusion, throughout their developmenal cycle. When an epithelial cell is infected with multiple Chlamydia trachomatis elementary bodies, they are internalized by endocytosis into individual phagosomal vacuoles that eventually fuse to form a single inclusion. In the course of large-scale serotyping studies in which fluorescent antibody staining of infected cells was used, a minority of strains that had an alternate inclusion morphology were identified. These variants formed multiple nonfusogenic inclusions in infected cells, with the number of independent inclusions per cell varying directly with the multiplicity of infection. Overall the nonfusogenic phenotype was found in 1.5% (176 of 11,440) of independent isolates. Nonfusing variants were seen in C.
Recurrent Chlamydia trachomatis infections are common among sexually active women. Although recurrences with a new chlamydial serovar indicate reinfection, same-serovar recurrences may be due to persistence. Because persistence has important implications for pathogenesis and patient management, we identified 552 women with >3 recurrences over 2 years. Among these, 130 women (24%) had same-serovar recurrences; 58 (45%) were C class serovars (odds ratio, 2.4; 95% confidence interval, 1.7-3.5; P<.0001). Forty-five isolates from 7 women with 3-10 repeated, same-serovar infections over 2-5 years were studied. As determined by omp1 genotyping, 4 women had identical genotypes at each recurrence; 2 women had 1 or 2 amino acid changes following treatment, and one was persistently infected with a unique genotype, Ja. Many intervening culture-negative samples were positive when tested by ligase chain reaction, which suggests persistence. These data demonstrate that cervical infections with C class serovars can persist for years and may have specific biologic properties that allow for modulation of the major outer membrane protein in response to immune selection.
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