Transmission Electron Microscopy of XDR Mycobacterium tuberculosis Isolates Grown on High Dose of Ofloxacin.

The aim of the study was to investigate behavior of resistant Mycobacterium tuberculosis (MTB) isolates under a high dose of ofloxacin and its morphological changes. 19 extensively drug resistant (XDR) clinical isolates of MTB were grown on Löwenstein-Jensen medium containing progressively increasing concentrations of ofloxacin (2, 4, 8, 16, 32 mg/L). Ultra-structure analyses of resistant isolates grown on ofloxacin were conducted by transmission electron microscopy (TEM). Fixation was carried out by 4% glutaraldehyde in 0.1 M sodium cacodylate buffer on 300 mesh carbon formvar copper grid. The samples were negatively stained with uranium acetate suspension. All19XDRMTBisolatesweregrownandformedcoloniessuccessfullyon2,4,8mg/L,sevenisolates on16mg/L,andfourisolateson32mg/Lofloxacin. Morphologicalchangesandunusualformswere detected in 8, 16 and 32 mg/L ofloxacin at 43%, 76.5% and 81% of cells, respectively. Swollen form (protoplast like), ghost-like cell, degraded forms, and in a few cases, detached cytoplasm from cell wall were clearly detected in high drug concentrations in comparison to control. Changes in morphology were increased with increasing ofloxacin concentrations (p < 0.05). Some XDR isolates could be successfully grown on high doses of ofloxacin (32 mg/L), but with changes in morphology. It was concluded that several magnitudes of the drug doses could not prevent growth of drug resistant forms.

Molecular detection of fluoroquinolone resistance-associated gyrA mutations in ofloxacin-resistant clinical isolates of Mycobacterium tuberculosis from Iran and Belarus.

OBJECTIVE/BACKGROUND: Detection of mutations in the quinolone resistance-determining region (QRDR) of the gyrA gene could determine resistance to fluoroquinolone antituberculosis drugs. The aim of this study was to detect mutations in QRDRs. METHODS: From 184 clinical isolates of Mycobacterium tuberculosis, ofloxacin resistance was proven in 42 isolates using the proportion method. The molecular basis of resistance to ofloxacin were investigated by the determination of mutations in the QRDR region of the gyrA gene. Extracted DNA fragments of 194bp from the gyrA gene were amplified and an automatic DNA sequencer was used for the sequencing process. RESULTS: Molecular genetic analysis of 42 resistant M. tuberculosis strains demonstrated that they belong to Principal Genetic Group (PGG) 1 in 19 cases (45.2±10.9%), to PGG2 in 15 cases (35.7±10.5%), and to PGG3 in eight cases (19.0±8.4%). Isolates from PGG1 were dominant among resistant isolates (P<.05). It was found that 24 (57%) resistant isolates carried mutations at codon 94 with five different amino acid changes: D94A (n=11), D94G (n=3), D94T (n=4), D94A (n=4), and D94Y (n=2). The remaining 18 (43%) isolates had mutations in codon A90V (GCG→GTG) and S91P (TCG→CCG). Five isolates had two mutations in codons 90 and 94. There was no difference between mutations at these two codons in resistant isolates of the two countries (P<.001). There was no polymorphism observed in codon 95 in any of the ofloxacin-susceptible isolates. CONCLUSION: It was concluded that the determination of nucleotide sequences of QRDRs can be used as a molecular test for the rapid detection of ofloxacin resistance. Furthermore, frequencies in gyrA codons in Belarus and Iran were similar, therefore it is not of geographical concern for the two countries.