Optimization and Clinical Evaluation of an Automated Commercial Analyte-Specific Reagent Assay for Mycoplasmoides genitalium Macrolide Resistance Detection in Primary Clinical Specimens.

Abstract

With improvement in laboratory diagnosis of Mycoplasmoides genitalium infection through molecular diagnostics, macrolide resistance determination within M. genitalium-positive patients is necessary. In this study, we report baseline parameters for an analyte-specific reagent (ASR) macrolide resistance real-time reverse transcriptase PCR on an open access analyzer and evaluated detection of macrolide resistance-mediated mutation (MRM) within 23S rRNA in a clinical specimen set. Initial use of 1.2 μM M. genitalium primer and 0.8 μM M. genitalium detection probe concentrations yielded an 80% false-positive detection rate when challenged with 10,000 copies of wild-type RNA. Optimization experiments showed that lowering primer/detection probe and MgCl2 concentrations minimized these false-detections of wild-type 23S rRNA, while higher levels of KCl increased rates of MRM detection with concomitant lower cycle threshold values and higher fluorescence emission. Lower limit of A2058G mutation detection was 5000 copies/mL (180 copies/reaction; 20/20 detections). Utilization of a baseline correction slope limit of 250 units further mitigated false-detection from wild-type 23S rRNA at challenges up to 3.3 billion copies/mL. MRM was detected in 583/866 (67.3%) clinical specimens initially positive for M. genitalium by commercial transcription-mediated amplification. These data included 392/564 detections (69.5%) from M. genitalium-positive swab specimens and 191/302 (63.2%) from M. genitalium-positive-positive first-void urine specimens (P = 0.06). Overall resistance detection rates did not vary by gender (P = 0.76). Specificity of the M. genitalium macrolide resistance ASR was 100% (141 urogenital determinations). MRM detection by the ASR was confirmed at a concordance rate of 90.9% by Sanger sequencing of a clinical specimen subset.