Rapid and Simultaneous Detection of Mycobacterium Tuberculosis Complex and Beijing/W Genotype in Sputum by an Optimized DNA Extraction Protocol and a Novel Multiplex Real-time PCR

Overview

Journal J Clin Microbiol

Specialty Microbiology

Date 2011 May 20

PMID 21593264

Citations 10

Authors

Eric T Y Leung

L Zheng

Rity Y K Wong

Edward W C Chan

T K Au

Raphael C Y Chan

Grace Lui

Nelson Lee

Margaret Ip

Affiliations

Soon will be listed here.

Abstract

Rapid diagnosis and genotyping of Mycobacterium tuberculosis by molecular methods are often limited by the amount and purity of DNA extracted from body fluids. In this study, we evaluated 12 DNA extraction methods and developed a highly sensitive protocol for mycobacterial DNA extraction directly from sputa using surface-coated magnetic particles. We have also developed a novel multiplex real-time PCR for simultaneous identification of M. tuberculosis complex and the Beijing/W genotype (a hypervirulent sublineage of M. tuberculosis) by using multiple fluorogenic probes targeting both the M. tuberculosis IS6110 and the Rv0927c-pstS3 intergenic region. With reference strains and clinical isolates, our real-time PCR accurately identified 20 non-Beijing/W and 20 Beijing/W M. tuberculosis strains from 17 different species of nontuberculosis Mycobacterium (NTM). Further assessment of our DNA extraction protocol and real-time PCR with 335 nonduplicate sputum specimens correctly identified all 74 M. tuberculosis culture-positive specimens. In addition, 15 culture-negative specimens from patients with confirmed tuberculosis were also identified. No cross-reactivity was detected with NTM specimens (n = 31). The detection limit of the assay is 10 M. tuberculosis bacilli, as determined by endpoint dilution analysis. In conclusion, an optimized DNA extraction protocol coupled with a novel multiprobe multiplex real-time PCR for the direct detection of M. tuberculosis, including Beijing/W M. tuberculosis, was found to confer high sensitivity and specificity. The combined procedure has the potential to compensate for the drawbacks of conventional mycobacterial culture in routine clinical laboratory setting, such as the lengthy incubation period and the limitation to viable organisms.

Citing Articles

Laboratory validation of a simplified DNA extraction protocol followed by a portable qPCR detection of M. tuberculosis DNA suitable for point of care settings.

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Epidemiology and laboratory detection of non-tuberculous mycobacteria.

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Rv0927c Inhibits NF-κB Pathway by Downregulating the Phosphorylation Level of IκBα and Enhances Mycobacterial Survival.

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Preanalytical conditions can interfere with M. tuberculosis detection by PCR in respiratory samples.

Carnevale G, Vargas F, Caiaffa-Filho H, Acencio M, Marcal L, Sales R Clinics (Sao Paulo). 2018; 73:e410.

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Optimized Lysis-Extraction Method Combined With -Amplification for Detection of in Paucibacillary Sputum Specimens.

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