Mycobacterium tuberculosis complex differentiation by genomic deletion patterns with multiplex polymerase chain reaction and melting analysis.

Differentiation of Mycobacterium tuberculosis complex (MTC) species is important for patient management. We developed a genomic deletion assay based on multiplex polymerase chain reaction with melting temperature analysis that correctly identified 124 (96%) of 129 MTC isolates. This assay is a fast single-tube method to differentiate members of MTC.

"Mycobacterium canettii" isolated from a human immunodeficiency virus-positive patient: first case recognized in the United States.

We report the first case of tuberculosis caused by "Mycobacterium canettii" recognized in the United States. The pathogen was isolated from the cerebrospinal fluid of a 30-year-old Sudanese refugee.

Direct comparison of the genotype MTBC and genomic deletion assays in terms of ability to distinguish between members of the Mycobacterium tuberculosis complex in clinical isolates and in clinical specimens.

The automated GenoType MTBC assay was evaluated for the ability to detect and identify members of the Mycobacterium tuberculosis complex. In addition to 35 reference strains and 157 clinical isolates, performance of this assay was tested directly on 79 smear-positive clinical specimens. The assay proved as accurate as the reference deletion analysis for all 192 isolates and detected and identified M. tuberculosis complex members in 93.2% of the specimens containing the M. tuberculosis complex.

Discrepant results between pyrazinamide susceptibility testing by the reference BACTEC 460TB method and pncA DNA sequencing in patients infected with multidrug-resistant W-Beijing Mycobacterium tuberculosis strains.

BACKGROUND: Mycobacterium tuberculosis strains belonging to the W-Beijing family have received broad clinical and public health attention because of their rapid worldwide spread and their frequent association with outbreaks, multidrug resistance, and treatment failures and relapses. METHODS: The present study examined a large number of multidrug-resistant strain-W isolates (isolates of 29 patients) by susceptibility testing for pyrazinamide (PZA) using the reference BACTEC 460TB method (Becton Dickinson Diagnostic Instrument Systems; Sparks, MD) and also by DNA sequencing of the pncA gene. RESULTS: We found that despite of the presence of a strain W-specific Thr47Ala in the pncA gene, all strains showed susceptibility to PZA in the reference BACTEC 460TB system due to their higher minimum inhibitory concentrations (relative to BACTEC 460TB PZA-susceptible strains). CONCLUSIONS: Our results suggest that the current radiometric reference method cannot reproducibly detect PZA resistance in patients infected with W-Beijing strains. Therefore, PZA susceptibility testing should instead be based on analysis of the pncA gene for resistance-associated mutations.

Sequencing of the pncA gene in members of the Mycobacterium tuberculosis complex has important diagnostic applications: Identification of a species-specific pncA mutation in "Mycobacterium canettii" and the reliable and rapid predictor of pyrazinamide resistance.

Testing for susceptibility to pyrazinamide (PZA) and analysis of the pncA gene sequences of 423 Mycobacterium tuberculosis complex isolates have revealed a unique silent nucleotide substitution that enables the rapid identification of "M. canettii" (proposed name). Moreover, the lack of a defined mutation within the pncA gene strongly suggests that an alternative mechanism is responsible for PZA resistance. Our results indicate that DNA sequencing of the pncA gene has the potential to shorten the turnaround time and increase the accuracy of PZA susceptibility testing of the M. tuberculosis complex.

Use of smear-positive samples to assess the PCR-based genotype MTBDR assay for rapid, direct detection of the Mycobacterium tuberculosis complex as well as its resistance to isoniazid and rifampin.

Isoniazid (INH) and rifampin (RIF) are two of the most important antituberculosis drugs, and resistance to both of these drugs can often result in treatment failure and fatal clinical outcome. Resistance to these two first-line drugs is most often attributed to mutations in the katG, inhA, and rpoB genes. Historically, the identification and testing of the susceptibility of Mycobacterium tuberculosis complex (MTBC) strains takes weeks to complete. Rapid detection of resistance using the PCR-based Genotype MTBDR assay (Hain Lifescience GmbH, Nehren, Germany) has the potential to significantly shorten the turnaround time from specimen receipt to reporting of results of susceptibility testing. Therefore, the aim of the present study was to determine (i) the sensitivity and accuracy of the Genotype MTBDR assay for the detection of MTBC strains and (ii) the ability of the assay to detect the presence of INH and RIF resistance-associated mutations in katG and rpoB from samples taken directly from smear-positive clinical specimens. The results were compared with those obtained with the reference BACTEC 460TB system combined with standard DNA sequencing analysis methods for katG, inhA, and rpoB. A total of 92 drug-resistant and 51 pansusceptible smear-positive specimens were included in the study. The Genotype MTBDR assay accurately and rapidly detected MTBC strains in 94.4% of the 143 specimens and showed a sensitivity of 94.4% for katG and 90.9% for rpoB when used directly on smear-positive specimens. The assay correctly identified INH resistance in 48 (84.2%) of the 57 specimens containing strains with resistance to high levels of INH (0.4 microg/ml) and RIF resistance in 25 (96.2%) of the 26 specimens containing RIF-resistant strains.

Phenotypic and molecular characterization of Mycobacterium tuberculosis isolates resistant to both isoniazid and ethambutol.

In performing radiometric susceptibility testing on over 2,000 patient isolates of Mycobacterium tuberculosis during the past 6 years, we found that resistance to 7.5 microg/ml ethambutol (EMB) occurred only in isolates that are also resistant to 0.4 microg/ml isoniazid (INH). Using 157 selected isolates in the present study, we performed radiometric and agar proportion susceptibility tests and DNA sequencing of genetic regions associated with resistance to these two drugs. The goal was to study the occurrence of the common mutations associated with resistance to each drug and also to determine whether any particular INH-resistance-associated mutation occurred more often in combination with any particular EMB-resistance-associated mutation. In an analysis of 128 isolates resistant to 0.4 microg/ml INH, we found that a mutation at katG Ser315 was more common in isolates also resistant to 7.5 microg/ml EMB (61 of 67=91.0%) than in isolates either susceptible to EMB or resistant to 2.5 microg/ml EMB (39 of 60=65.0%). These observations suggest that INH-resistant strains with a mutation at katG Ser315 are more likely to acquire resistance to 7.5 microg/ml EMB than are isolates with INH-resistance-associated mutations at other sites. In addition, we found that 64 of 67 (95.5%) isolates resistant to 7.5 microg/ml EMB contained a mutation in either codon 306 or codon 406 of embB. Met306Val was the most common embB mutation, present in 52 (77.6%) of the 67 isolates. Most occurrences of this mutation (49 of 52=94.2%) were found in isolates that also contained the katG Ser315Thr mutation. Finally, sequencing this region of embB appears to be sufficiently sensitive for use as a rapid screening tool for detection of high-level resistance to EMB.