Hydrogenosomes of Laboratory‐Induced Metronidazole‐Resistant Trichomonas vaginalis Lines are Downsized While Those from Clinically Metronidazole‐Resistant Isolates Are Not

ABSTRACT. Trichomonas vaginalis is the most common sexually transmitted protozoan in the world and its resistance to metronidazole is increasing. The purpose of this study was to demonstrate that clinical metronidazole resistance in T. vaginalis does not occur via the same mechanism as laboratory‐induced metronidazole resistance—that is, via hydrogenosome down sizing. Ultrathin sections of this parasite were examined using transmission electron microscopy and the size and area of the cell and hydrogenosomes were compared between drug‐resistant laboratory lines and clinically resistant isolates. Clinical metronidazole‐resistant T. vaginalis had similar‐sized hydrogenosomes as a metronidazole‐sensitive isolate. Inducing metronidazole resistance in both of these isolates caused down sizing of hydrogenosomes. Inducing toyocamycin resistance did not cause any ultrastructural changes to the cell or to the hydrogenosome. No correlation between hydrogenosome number and the drug‐resistant status of T. vaginalis isolates and lines was observed. This report demonstrates that clinical metronidazole resistance is not associated with down‐sized hydrogenosomes, thus indicating that an alternative resistance mechanism is used by T. vaginalis.

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