Rapid detection of isoniazid, rifampin, and ofloxacin resistance in Mycobacterium tuberculosis clinical isolates using high-resolution melting analysis

Abstract

A high-resolution melting analysis (HRMA) assay was developed to detect isoniazid, rifampin, and ofloxacin resistance in Mycobacterium tuberculosis by targeting resistance-associated mutations in the katG, mabA-inhA promoter, rpoB, and gyrA genes. A set of 28 (17 drug-resistant and 11 fully susceptible) clinical M. tuberculosis isolates was selected for development and evaluation of HRMA. PCR amplicons from the katG, mabA-inhA promoter, rpoB, and gyrA genes of all 28 isolates were sequenced. HRMA results matched well with 18 mutations, identified by sequencing, in 17 drug-resistant isolates and the absence of mutations in 11 susceptible isolates. Among 87 additional isolates with known resistance phenotypes, HRMA identified katG and/or mabA-inhA promoter mutations in 66 of 69 (95.7%) isoniazid-resistant isolates, rpoB mutations in 51 of 54 (94.4%) rifampin-resistant isolates, and gyrA mutations in all of 41 (100%) ofloxacin-resistant isolates. All mutations within the HRMA primer target regions were detected as variant HRMA profiles. The corresponding specificities were 97.8%, 100%, and 98.6%, respectively. Most false-positive results were due to synonymous mutations, which did not affect susceptibility. HRMA is a rapid, sensitive method for detection of drug resistance in M. tuberculosis which could be used routinely for screening isolates in countries with a high prevalence of tuberculosis and drug resistance or in individual isolates when drug resistance is suspected.

Fig. 1.

Normalized and temperature-shifted difference plots for mutant discrimination by HRMA in katG (A and a, respectively), mabA-inhA promoter (B and b, respectively), rpoB (C and c, respectively), and gyrA (D and d, respectively). Wild-type profiles are shown in black, and variant profiles are shown in color. Numbers in parentheses are numbers of isolates tested.