Improved Detection by Next-Generation Sequencing of Pyrazinamide Resistance in Mycobacterium tuberculosis Isolates.

The technical limitations of common tests used for detecting pyrazinamide (PZA) resistance in Mycobacterium tuberculosis isolates pose challenges for comprehensive and accurate descriptions of drug resistance in patients with multidrug-resistant tuberculosis (MDR-TB). In this study, a 606-bp fragment (comprising the pncA coding region plus the promoter) was sequenced using Ion Torrent next-generation sequencing (NGS) to detect associated PZA resistance mutations in 88 recultured MDR-TB isolates from an archived series collected in 2001. These 88 isolates were previously Sanger sequenced, with 55 (61%) designated as carrying the wild-type pncA gene and 33 (37%) showing mutations. PZA susceptibility of the isolates was also determined using the Bactec 460 TB system and the Wayne test. In this study, isolates were recultured and susceptibility testing was performed in Bactec 960 MGIT. Concordance between NGS and MGIT results was 93% (n = 88), and concordance values between the Bactec 460, the Wayne test, or pncA gene Sanger sequencing and NGS results were 82% (n = 88), 83% (n = 88), and 89% (n = 88), respectively. NGS confirmed the majority of pncA mutations detected by Sanger sequencing but revealed several new and mixed-strain mutations that resolved discordancy in other phenotypic results. Importantly, in 53% (18/34) of these isolates, pncA mutations were located in the 151 to 360 region and warrant further exploration. In these isolates, with their known resistance to rifampin, NGS of pncA improved PZA resistance detection sensitivity to 97% and specificity to 94% using NGS as the gold standard and helped to resolve discordant results from conventional methodologies.

Surgical face masks worn by patients with multidrug-resistant tuberculosis: impact on infectivity of air on a hospital ward.

RATIONALE: Drug-resistant tuberculosis transmission in hospitals threatens staff and patient health. Surgical face masks used by patients with tuberculosis (TB) are believed to reduce transmission but have not been rigorously tested. OBJECTIVES: We sought to quantify the efficacy of surgical face masks when worn by patients with multidrug-resistant TB (MDR-TB). METHODS: Over 3 months, 17 patients with pulmonary MDR-TB occupied an MDR-TB ward in South Africa and wore face masks on alternate days. Ward air was exhausted to two identical chambers, each housing 90 pathogen-free guinea pigs that breathed ward air either when patients wore surgical face masks (intervention group) or when patients did not wear masks (control group). Efficacy was based on differences in guinea pig infections in each chamber. MEASUREMENTS AND MAIN RESULTS: Sixty-nine of 90 control guinea pigs (76.6%; 95% confidence interval [CI], 68-85%) became infected, compared with 36 of 90 intervention guinea pigs (40%; 95% CI, 31-51%), representing a 56% (95% CI, 33-70.5%) decreased risk of TB transmission when patients used masks. CONCLUSIONS: Surgical face masks on patients with MDR-TB significantly reduced transmission and offer an adjunct measure for reducing TB transmission from infectious patients.

Molecular characterization and second-line antituberculosis drug resistance patterns of multidrug-resistant Mycobacterium tuberculosis isolates from the northern region of South Africa.

Despite South Africa being one of the high-burden multidrug-resistant tuberculosis (MDR-TB) countries, information regarding the population structure of drug-resistant Mycobacterium tuberculosis strains is limited from many regions of South Africa. This study investigated the population structure and transmission patterns of drug-resistant M. tuberculosis isolates in a high-burden setting of South Africa as well as the possible association of genotypes with drug resistance and demographic characteristics. A total of 336 consecutive MDR-TB isolates from four provinces of South Africa were genotyped using spoligotyping and mycobacterial interspersed repetitive-unit-variable number tandem repeat (MIRU-VNTR) typing. Drug susceptibility testing for ofloxacin, kanamycin, and capreomycin was performed using the agar proportion method. The results showed that 4.8% of MDR-TB isolates were resistant to ofloxacin, 2.7% were resistant to kanamycin, and 4.5% were resistant to capreomycin, while 7.1% were extensively drug resistant (XDR), and the remaining 83.6% were susceptible to all of the second-line drugs tested. Spoligotyping grouped 90.8% of the isolates into 25 clusters, while 9.2% isolates were unclustered. Ninety-one percent of the 336 isolates were assigned to 21 previously described shared types, with the Beijing family being the predominant genotype in the North-West and Limpopo Provinces, while the EAI1_SOM family was the predominant genotype in the Gauteng and Mpumalanga Provinces. No association was found between genotypes and specific drug resistance patterns or demographic information. The high level of diversity and the geographical distribution of the drug-resistant M. tuberculosis isolates in this study suggest that the transmission of TB in the study settings is not caused by the clonal spread of a specific M. tuberculosis strain.

High diversity of Mycobacterium tuberculosis genotypes in South Africa and preponderance of mixed infections among ST53 isolates.

The reemergence of tuberculosis (TB) has become a major health problem worldwide, especially in Asia and Africa. Failure to combat this disease due to nonadherence or inappropriate drug regimens has selected for the emergence of multiple-drug-resistant (MDR) TB. The development of new molecular genotyping techniques has revealed the presence of mixed Mycobacterium tuberculosis infections, which may accelerate the emergence of drug-resistant strains. There are some studies describing the local distribution of circulating strains in South Africa, but to date, reports describing the frequency and distribution of M. tuberculosis genotypes, and specifically MDR genotypes, across the different provinces are limited. Thus, 252 isolates (of which 109 were MDR) from eight of the nine provinces of South Africa were analyzed by spoligotyping. Spoligotyping showed 10 different lineages, and ST53 (11.1%) and ST1 (10.3%) were the most frequent genotypes. Of the 75 different spoligopatterns observed, 20 (7.9%) were previously unreported. Analysis of the mycobacterial interspersed repetitive units of variable-number tandem repeats of the ST53 and ST1 isolates revealed that approximately 54% of the ST53 isolates were of mixed M. tuberculosis subpopulations. Drug resistance (defined as resistance to at least isoniazid and/or rifampin) could only be linked to a history of previous anti-TB treatment (adjusted odds ratio, 4.0; 95% confidence interval, 2.27 to 7.10; P = <0.0001). This study describes a high diversity of circulating genotypes in South Africa in addition to a high frequency of mixed M. tuberculosis subpopulations among the ST53 isolates. MDR TB in South Africa could not be attributed to the spread of any single lineage.

Pyrazinamide resistance among South African multidrug-resistant Mycobacterium tuberculosis isolates.

Pyrazinamide is important in tuberculosis treatment, as it is bactericidal to semidormant mycobacteria not killed by other antituberculosis drugs. Pyrazinamide is also one of the cornerstone drugs retained in the treatment of multidrug-resistant tuberculosis (MDR-TB). However, due to technical difficulties, routine drug susceptibility testing of Mycobacterium tuberculosis for pyrazinamide is, in many laboratories, not performed. The objective of our study was to generate information on pyrazinamide susceptibility among South African MDR and susceptible M. tuberculosis isolates from pulmonary tuberculosis patients. Seventy-one MDR and 59 fully susceptible M. tuberculosis isolates collected during the national surveillance study (2001 to 2002, by the Medical Research Council, South Africa) were examined for pyrazinamide susceptibility by the radiometric Bactec 460 TB system, pyrazinamidase activity (by Wayne's assay), and sequencing of the pncA gene. The frequency of pyrazinamide resistance (by the Bactec system) among the MDR M. tuberculosis isolates was 37 of 71 (52.1%) and 6 of 59 (10.2%) among fully sensitive isolates. A total of 25 unique mutations in the pncA gene were detected. The majority of these were point mutations that resulted in amino acid substitutions. Twenty-eight isolates had identical mutations in the pncA gene, but could be differentiated from each other by a combination of the spoligotype patterns and 12 mycobacterial interspersed repetitive-unit loci. A high proportion of South African MDR M. tuberculosis isolates were resistant to pyrazinamide, suggesting an evaluation of its role in patients treated previously for tuberculosis as well as its role in the treatment of MDR-TB.

Natural infection of guinea pigs exposed to patients with highly drug-resistant tuberculosis.

A natural TB infection model using guinea pigs may provide useful information for investigating differences in transmission efficiency and establishment of active disease by clinical TB strains in a highly susceptible host under controlled environmental conditions. We sought to examine the capacity of naturally transmitted multidrug-resistant Mycobacterium tuberculosis to establish infection and produce active disease in guinea pigs. Guinea pigs were continuously exposed for 4 months to the exhaust air of a 6-bed multidrug-resistant tuberculosis inpatient hospital ward in South Africa. Serial tuberculin skin test reactions were measured to determine infection. All animals were subsequently evaluated for histologic disease progression at necropsy. Although 75% of the 362 exposed guinea pigs had positive skin test reactions [≥6 mm], only 12% had histopathologic evidence of active disease. Reversions (≥6 mm change) in skin test reactivity were seen in 22% of animals, exclusively among those with reactions of 6-13 mm. Only two of 86 guinea pigs with reversion had histological evidence of disease compared to 47% (31/66) of guinea pigs with large, non-reverting reactions. Immunosuppression of half the guinea pigs across all skin test categories did not significantly accelerate disease progression. In guinea pigs that reverted a skin test, a second positive reaction in 27 (33%) of them strongly suggested re-infection due to ongoing exposure. These results show that a large majority of guinea pigs naturally exposed to human-source strains of multidrug-resistant tuberculosis became infected, but that many resolved their infection and a large majority failed to progress to detectable disease.