Detection of novel mutations associated with independent resistance and cross-resistance to isoniazid and prothionamide in Mycobacterium tuberculosis clinical isolates

ObjectivesProthionamide, a structural analogue of isoniazid, is used mainly for treating multidrug-resistant tuberculosis (MDR-TB). Both drugs have a common target InhA, so prothionamide can be ineffective against isoniazid-resistant (INH^R) Mycobacterium tuberculosis. We aimed to investigate the prevalence of mutations in katG, ethA, ndh, ethR, mshA, inhA and/or its promoter associated with independent resistance and cross-resistance to INH^R and/or prothionamide-resistant (PTO^R) M. tuberculosis isolates.MethodsWe sequenced the above genes in 206 M. tuberculosis isolates with susceptibility testing against ten drugs.ResultsOf the 173 INH^R PTO^R isolates, 170 (98.3%) harboured mutations in katG, 111 (64.2%) in ethA, 58 (33.5%) in inhA or its promoter, 5 (2.9%) in ndh, 3 (1.7 %) in ethR and 2 (1.2%) in mshA. Among the 18 INH^R PTO^S isolates, mutations in katG were found in all of them; one had a mutation in the inhA promoter and another in ndh. Of the five INH^S PTO^R isolates, four showed mutations in ethA and two in the inhA promoter. Notably, 55 novel non-synonymous mutations were found in them and 20.2% of the PTO^R M. tuberculosis isolates harboured no known mutations.ConclusionsThis is the first report to investigate cross-resistance between INH^R and/or PTO^R isolates. Among INH^R (94.4% MDR-TB) M. tuberculosis isolates, the high diversity of mutations for independent resistance and cross-resistance with prothionamide highlight the importance of both phenotypic susceptibility and genotypic diagnosis when using it to treat patients with INH^R-TB. The high proportion (one-fifth) of PTO^R M. tuberculosis isolates showed no known mutation related to PTO^R genes, so uncovered resistance mechanism(s) of prothionamide exist.     

Geographical Differences Associated with Single-Nucleotide Polymorphisms (SNPs) in Nine Gene Targets among Resistant Clinical Isolates of Mycobacterium tuberculosis

Alternative diagnostic methods, such as sequence-based techniques, are necessary for increasing the proportion of tuberculosis cases tested for drug resistance. Despite the abundance of data on drug resistance, isolates can display phenotypic resistance but lack any distinguishable markers. Furthermore, because resistance-conferring mutations develop under antibiotic pressure, different drug regimens could favor unique single-nucleotide polymorphisms (SNPs) in different geographical regions. A total of 407 isolates were collected from four geographical regions with a high prevalence of drug-resistant tuberculosis (India, Moldova, the Philippines, and South Africa). The “hot spot” or promoter sequences of nine genes (rpoB, gyrA, gyrB, katG, inhA promoter, ahpC promoter, eis promoter, rrs, and tlyA) associated with resistance to four types of antibiotics (rifampin, isoniazid, fluoroquinolones, and aminoglycosides) were analyzed for markers. Four genes contributed largely to resistance (rpoB, gyrA, rrs, and katG), two genes contributed moderately to resistance (the eis and inhA promoters), and three genes contributed little or no resistance (gyrB, tlyA, and the ahpC promoter) in clinical isolates. Several geographical differences were found, including a double mutation in rpoB found in 37.1% of isolates from South Africa, the C→T mutation at position −12 of the eis promoter found exclusively in 60.6% of isolates from Moldova, and the G→A mutation at position −46 of the ahpC promoter found only in India. These differences in polymorphism frequencies emphasize the uniqueness of isolates found in different geographical regions. The inclusion of several genes provided a moderate increase in sensitivity, and elimination of the examination of other genes might increase efficiency.     

Assessing capreomycin resistance on tlyA deficient and point mutation (G695A) Mycobacterium tuberculosis strains using multi-omics analysis

Capreomycin (CAP), a cyclic peptide antibiotic, is considered to be an ideal second-line drug for tuberculosis (TB). However, in the past few years, the emergence of more CAP-resistant (CAP^r) TB patients has limited its use. Although it has been reported that CAP resistance to Mycobacterium tuberculosis (Mtb) is associated with rrs or tlyA mutation, the exact mechanism of CAP^r Mtb strains, especially the mechanism associated with tlyA deficient or mutation, is not fully understood. Herein, we utilized a multi-omics (genome, proteome, and metabolome) approach to assess CAP resistance on tlyA deficient CAP^r Mtb strains (CAP^r1) and tlyA point mutation CAP^r Mtb strains (CAP^r2) that we established for the first time in vitro to investigate the CAP-resistant mechanism. Our results showed that the CAP^r1 strains (> 40 μg/ml) was more resistant to CAP than the CAP^r2 strains (G695A, 10 μg/ml). Furthermore, multi-omics analysis indicated that the CAP^r1 strains exhibited greater drug tolerance than the CAP^r2 strains may be associated with the weakening of S-adenosyl-L-methionine-dependent methyltransferase (AdoMet-MT) activity and abnormal membrane lipid metabolism such as suppression of fatty acid metabolism, promotion of glycolipid phospholipid and glycerolipid metabolism. As a result, these studies reveal a new mechanism for CAP resistance to tlyA deficient or mutation Mtb strains, and may be helpful in developing new therapeutic approaches to prevent Mtb resistance to CAP.     

High-Resolution Melting Curve Analysis for Rapid Detection of Rifampin and Isoniazid Resistance in Mycobacterium tuberculosis Clinical Isolates

We evaluated high-resolution melting (HRM) curve analysis as a tool for detecting rifampin (RIF) and isoniazid (INH) resistance in Mycobacterium tuberculosis in an accurate, affordable, and rapid manner. Two hundred seventeen M. tuberculosis clinical isolates of known resistance phenotype were used. Twenty-nine known rpoB mutant DNAs, including rare mutations, were also included. Four pairs of primers were designed: rpoB-F/R (for codons 516 to 539 of rpoB), rpoB-516F/R (for codons 508 to 536 of rpoB), katG-F/R (for the codon 315 region of katG), and inhA-F/R (for the nucleotide substitution of C to T at position −15 of inhA). An HRM curve was generated for each isolate after real-time PCR differentiated the mutant from the wild-type strains. DNA sequencing of the target regions was performed to confirm the results of the HRM curve analysis. All but one of the 73 RIF-resistant (RIF-R) strains and all 124 RIF-susceptible (RIF-S) isolates were correctly identified by HRM curve analysis of rpoB. Twenty-seven of 29 known rpoB mutants were detected. In HRM curve analysis of katG and inhA, 90 INH-R strains that harbored katG or inhA mutations, or both, and all INH-S strains were correctly identified. Ten phenotypically INH-R strains not harboring katG or inhA mutations were not detected. The HRM curve analysis will be a useful method for detection of RIF and INH resistance in M. tuberculosis in a rapid, accurate, simple, and cost-effective manner.The rates of mortality and morbidity from tuberculosis (TB) remain high, despite intense worldwide efforts. One of the major factors sustaining the current TB epidemic is the increasing drug resistance of Mycobacterium tuberculosis strains (2). In the early 1990s, multidrug-resistant (MDR) TB cases that were resistant to at least rifampin (RIF) plus isoniazid (INH) arose (6). When the frequency and distribution of extensively drug-resistant (XDR) TB cases were assessed in 2004 by the U.S. Centers for Disease Control and Prevention and the World Health Organization, several cases of drug-resistant tuberculosis consistent with an XDR phenotype were found (7). This study revealed that 20% of the isolates met the MDR criteria; 2% of those were classifiable as XDR; and 4%, 15%, and 19% of the XDR TB cases were from the United States, South Korea, and Latvia, respectively (7). Thus, it is crucial that rapid drug susceptibility tests be developed to prevent the spread of MDR and XDR TB.Although drug susceptibility testing (DST) is a prerequisite for accurate results, such testing requires much time and labor (3). Therefore, several molecular techniques have been applied to detect mutations related to drug resistance (5, 10). Resistance to RIF and INH, the mainstays of antituberculosis treatment, is mainly attributable to mutations in genes encoding the drug target or drug-converting enzymes (8). Early studies demonstrated that 95% of the resistance to RIF is associated with mutation of the RIF resistance-determining region of rpoB, whereas mutations in katG and the regulatory zone of inhA are most frequently associated with INH resistance (11).The oligonucleotide chip method and real-time PCR have been used for detection of drug-resistant M. tuberculosis (17, 21, 27, 29). A novel method of high-resolution melting (HRM) curve analysis is an accurate and simple technique for analyzing the genotype without the need for specific probes. The dye LC Green, SYTO9, or Eva Green saturates amplified DNA, unlike SYBR green dye, during homogeneous melting curve analysis. Also, HRM curve analysis generates a difference plot curve, which analyzes nucleic acid sequences with high accuracy. Application of genotyping by HRM curve analysis has followed (13, 19). The aim of the study described here was to develop a useful molecular tool for the identification of drug resistance in M. tuberculosis in an accurate, rapid, and cost-effective manner.     

Evaluation of GenoFlow DR-MTB Array Test for Detection of Rifampin and Isoniazid Resistance in Mycobacterium tuberculosis

The aim of this study was to evaluate the GenoFlow DR-MTB array test (DiagCor Bioscience, Hong Kong) on 70 cultured isolates and 50 sputum specimens. The GenoFlow array test showed good sensitivity and specificity compared to the phenotypic Bactec 460TB. This array accurately detected mutations in rpoB, katG, and inhA associated with resistance to rifampin and isoniazid.     

Rapid Detection of Isoniazid Resistance in Mycobacterium tuberculosis Isolates by Use of Real-Time-PCR-Based Melting Curve Analysis

The MeltPro TB/INH assay, recently approved by the Chinese Food and Drug Administration, is a closed-tube, dual-color, melting curve analysis-based, real-time PCR test specially designed to detect 30 isoniazid (INH) resistance mutations in katG position 315 (katG 315), the inhA promoter (positions −17 to −8), inhA position 94, and the ahpC promoter (positions −44 to −30 and −15 to 3) of Mycobacterium tuberculosis. Here we evaluated both the analytical performance and clinical performance of this assay. Analytical studies with corresponding panels demonstrated that the accuracy for detection of different mutation types (10 wild-type samples and 12 mutant type samples), the limit of detection (2 × 10³ to 2 × 10⁴ bacilli/ml), reproducibility (standard deviation [SD], <0.4°C), and the lowest heteroresistance level (40%) all met the parameters preset by the kit. The assay could be run on five types of real-time PCR machines, with the shortest running time (105 min) obtained with the LightCycler 480 II. Clinical studies enrolled 1,096 clinical isolates collected from three geographically different tuberculosis centers, including 437 INH-resistant isolates and 659 INH-susceptible isolates characterized by traditional drug susceptibility testing on Löwenstein-Jensen solid medium. The clinical sensitivity and specificity of the MeltPro TB/INH assay were 90.8% and 96.4%, respectively. DNA sequencing analysis showed that, except for the 5 mutants outside the detection range of the MeltPro assay, a concordance rate between the two methods of 99.1% (457/461) was obtained. Among the 26 mutation types detected, katG S315T (AGC→ACC), inhA −15C→T, katG S315N (AGC→AAC), and ahpC promoter −10C→T accounted for more than 90%. Overall, the MeltPro TB/INH assay represents a reliable and rapid tool for the detection of INH resistance in clinical isolates.     

Evaluation of the MTBDRsl Test for Detection of Second-Line-Drug Resistance in Mycobacterium tuberculosis

The MTBDRsl assay (Hain Lifescience GmbH, Germany) is a new line probe assay for the detection of extensively drug-resistant tuberculosis (XDR TB). The test simultaneously detects resistance to ethambutol, aminoglycosides/cyclic peptides, and fluoroquinolones through detection of mutations in the relevant genes. The assay format is identical to the MTBDR Hain assay. The assay was evaluated for the detection of second-line-drug resistance in Vietnamese isolates using two sample sets from the microbiology department of Pham Ngoc Thach Hospital, Ho Chi Minh City, Viet Nam, with existing conventional phenotypic drug susceptibility results for second-line drugs: 41 consecutive fluoroquinolone-resistant isolates and 21 consecutive multidrug-resistant but fluoroquinolone-sensitive isolates. The sensitivity for detection of fluoroquinolone resistance was 75.6% (31/41) (95% confidence interval [95% CI], 59.7% to 87.6%), and for kanamycin resistance, the sensitivity was 100% (5/5) (95% CI, 47.8% to 100%). The sensitivity of the test for detection of ethambutol resistance was low, consistent with previous reports, at 64.2% (34/53) (95% CI, 49.8% to 76.9%). The specificity of the test was 100% for all three drugs. These data suggest that the MTBDRsl assay is a rapid, specific test for the detection of XDR TB but should not be used exclusively to “rule out” second-line-drug resistance. Further operational evaluation is required and should be integrated with evaluations of the MTBDR test.The World Health Organization (WHO) has estimated that 5% of all tuberculosis (TB) cases globally are now multidrug-resistant tuberculosis (MDRTB) (resistance to at least rifampin [RIF] and isoniazid [INH]), based on data acquired since 2000 from more than 100 countries (14). Every year, an estimated 490,000 new cases of MDRTB occur, causing more than 130,000 deaths (14). In 2006, the documentation of a rapidly fatal TB outbreak among hospitalized HIV patients in Kwa Zulu Natal, South Africa (5) led to the definition of extensively drug-resistant tuberculosis (XDR TB) as TB resistant to a fluoroquinolone and injectable second-line drug (amikacin, capreomycin, or kanamycin) in addition to isoniazid and rifampin. XDR TB has subsequently been reported from over 50 countries by WHO (14). It is likely that the majority of XDR TB cases worldwide remain undetected due to the lack of second-line-drug testing in most high-burden settings. There are an estimated 40,000 new cases of extensively drug-resistant tuberculosis each year (15).The recognition of XDR TB worldwide has made timely identification of XDR TB cases to achieve effective disease management and to prevent their spread a priority (3, 8).Significant challenges exist; although standard protocols exist for second-line-drug susceptibility testing, strong evidence is lacking on many factors, such as the reproducibility and reliability of results, applicability of MIC to clinical outcomes, and intermethod variability. Proficiency testing for second-line-drug susceptibility testing has only recently been integrated into the supranational reference laboratory panel in an effort to improve standardization of second-line drugs across the WHO reference laboratory network.Conventional drug resistance testing takes more than 2 weeks to return a result even after a positive culture has been isolated. Rapid commercial liquid-based culture systems, such as Bactec MGIT 960 testing (Becton Dickinson), for second-line drugs are not yet formally FDA/WHO approved but are reported to be accurate, widely used in developed settings, and reduce turnaround times to approximately 8 days (7). In recent years, many second-line-drug susceptibility testing methods have been developed. The most rapid results are achieved by direct testing of patient specimens by molecular methods; however, in addition to the high cost of such tests, the sensitivity remains suboptimal, and rigorous contamination control is required to maintain accuracy. The majority of high-burden settings currently lack the resources to implement such tests effectively. Two commercial DNA strip assays, INNO-LiPA RifTB (Innogenetics, Zwijndrecht, Belgium) and MTBDRplus (Hain Lifescience GmbH, Germany), targeting the rpoB plus katG and inhA genes have been extensively evaluated for use with Mycobacterium tuberculosis culture and directly on sputum to identify MDR TB cases (2, 10). The Foundation for Innovative Diagnostics (FIND) demonstration projects in South Africa of the GenoType MTBDRplus assay resulted in the recommendation of commercial line probe assays for use in high-burden settings by WHO (16). This assay is based on a multiplex PCR in combination with reverse hybridization. Either the absence of wild-type bands or the appearance of bands targeting specific mutations indicates the presence of a resistant strain. MDR TB cases can be detected within 1 or 2 days of sputum sampling using this assay.In order to rapidly detect second-line-drug resistance, the MTBDRsl test (Hain Lifescience GmbH, Germany) has been developed. This assay can detect mutations in gyrA, rrs, and embB genes, detecting resistance to the fluoroquinolones (FQ), aminoglycosides/cyclic peptides, and ethambutol (EMB), respectively, with a single assay. A previous evaluation study in Germany showed that this assay has a high accuracy for FQ and amikacin-capreomycin resistance testing in clinical strains and sputum samples (6). EMB detection was specific (100%), but its sensitivity (69.2%) was low.The MTBDRsl assay contains 22 probes, including 16 probes for gene mutation detection and 6 probes for the control of the test procedure. The six control probes include a conjugate control (CC), an amplification control (AC), a Mycobacterium tuberculosis complex control (TUB), and three locus probes (gyrA, rrs, and embB) for gene amplification control. The remaining probes detect FQ resistance (gyrA), amikacin/capreomycin resistance (rrs), and ethambutol resistance (embB). The probes contained in the assay do not detect all mutations in these genes but are targeted to the most commonly occurring mutations.The aim of the present study was to determine the accuracy of this assay for detection of FQ, kanamycin, and ethambutol resistance against conventional phenotypic testing as the gold standard on Vietnamese isolates of M. tuberculosis.     

Tuberculosis-Spoligo-Rifampin-Isoniazid Typing: an All-in-One Assay Technique for Surveillance and Control of Multidrug-Resistant Tuberculosis on Luminex Devices

As a follow-up of the “spoligoriftyping” development, we present here an extension of this technique which includes the detection of isoniazid resistance-associated mutations in a new 59-plex assay, i.e., tuberculosis-spoligo-rifampin-isoniazid typing (TB-SPRINT), running on microbead-based multiplexed systems. This assay improves the synergy between clinical microbiology and epidemiology by providing (i) mutation-based prediction of drug resistance profiles for patient treatment and (ii) genotyping data for tuberculosis (TB) surveillance. This third-generation microbead-based high-throughput assay for TB runs on the Luminex 200 system and on the recently launched MagPix system (Luminex, Austin, TX). Spoligotyping patterns obtained by the TB-SPRINT method were 100% (n = 85 isolates; 3,655/3,655 spoligotype data points) concordant with those obtained by microbead-based and membrane-based spoligotyping. Genetic drug susceptibility typing provided by the TB-SPRINT method was 100% concordant with resistance locus sequencing (n = 162 for rpoB gene sequencing and n = 76 for katG and inhA sequencing). Considering phenotypic drug susceptibility testing (DST) as the reference method, the sensitivity and specificity of TB-SPRINT regarding Mycobacterium tuberculosis complex (n = 162 isolates) rifampin resistance were both 100%, and those for isoniazid resistance were 90.4% (95% confidence interval, 85 to 95%) and 100%, respectively. Used routinely in national TB reference and specialized laboratories, the TB-SPRINT assay should simultaneously improve personalized medicine and epidemiological surveillance of multidrug-resistant (MDR) TB. This assay is expected to play an emerging role in public health in countries with heavy burdens of MDR TB and/or HIV/TB coinfection. Application of this assay directly to biological samples, as well as development for extensively drug-resistant (XDR) TB detection by inclusion of second-line antituberculosis drug-associated mutations, is under development. With bioinformatical methods and data mining to reduce the number of targets to the most informative ones, locally adapted formats of this technique can easily be developed everywhere.     

Multidrug-Resistant Mycobacterium tuberculosis of the Latin American Mediterranean Lineage,Wrongly Identified as Mycobacterium pinnipedii (Spoligotype International Type 863 [SIT863]), Causing Active Tuberculosis in South Brazil

We recently detected the spoligotype patterns of strains of Mycobacterium pinnipedii, a species of the Mycobacterium tuberculosis complex, in sputum samples from nine cases with pulmonary tuberculosis residing in Porto Alegre, South Brazil. Because this species is rarely encountered in humans, we further characterized these nine isolates by additional genotyping techniques, including 24-locus mycobacterial interspersed repetitive-unit–variable-number tandem-repeat (MIRU-VNTR) typing, verification of the loci TbD1, RD9, pks15/1, RD^Rio, and fbpC, the insertion of IS6110 at a site specific to the M. tuberculosis Latin American Mediterranean (LAM) lineage, and whole-genome sequencing. The combined analysis of these markers revealed that the isolates are in fact M. tuberculosis and more specifically belong to the LAM genotype. Most of these isolates (n = 8) were shown to be multidrug resistant (MDR), which prompted us to perform partial sequencing of the rpoA, rpoB, rpoC, katG, and inhA genes. Seven isolates (77.8%) carried the S315T mutation in katG, and one of these (11%) also presented the C(−17)T single-nucleotide polymorphism (SNP) in inhA. Interestingly, six of the MDR isolates also presented an undescribed insertion of 12 nucleotides (CCA GAA CAA CCC) in codon 516 of rpoB. No putative compensatory mutation was found in either rpoA or rpoC. This is the first report of an M. tuberculosis LAM family strain with a convergent M. pinnipedii spoligotype. These spoligotypes are observed in genotype databases at a modest frequency, highlighting that care must be taken when identifying isolates in the M. tuberculosis complex on the basis of single genetic markers.     

Magnitude of Gene Mutations Conferring Drug Resistance in Mycobacterium Tuberculosis Isolates from Lymph Node Aspirates in Ethiopia

Objective: Resistance to drugs is due to particular genomic mutations in the specific genes of Mycobacterium tuberculosis. Timely genetic characterization will allow identification of resistance mutations that will optimize an effective antibiotic treatment regimen. We determine the magnitude of gene mutations conferring resistance to isoniazid (INH), rifampicin (RMP) and ethambutol (EMB) among tuberculosis (TB) lymphadenitis patients.Methods: A cross sectional prospective study was conducted among 226 M.tuberculosis isolates from culture positive lymph node aspirates collected from TB lymphadenitis patients between April 2012 and May 2012. Detection of mutations conferring resistance to drugs was carried out using GenoType^® MTBDRplus and GenoType® MTBDRsl assay.Results: Out of the 226 strains, mutations conferring resistance to INH, RMP, multidrug resistance tuberculosis (MDR-TB) and EMB were 8, 3, 2 and 2 isolates, respectively. There was no isolated strain that showed mutation in the inhA promoter region gene. All INH resistant strains had mutations in the katG gene at codon 315 with amino acid change of S315T1. Among rifampicin resistant strains, two isolates displayed mutations at codon 531 in the rpoB gene with amino acid change of S531L and one isolate was by omission of wild type probes at Q513L. According to mutations associated with ethambutol resistance, all of the isolates had mutations in the embB gene with aminoacid change of M306I. All isolates resistant to INH, RMP and MDR using BacT/AlerT 3D system were correctly identified by GenoType® MTBDRplus assay.Conclusion: We observed mutations conferring resistance to INH at S315T1 of the katG gene, RMP at S531L and Q513L in the rpoB genes and EMB at M306I of the embB gene. In the absence of conventional drug susceptibility testing, the effort to develop easy, rapid and cost effective molecular assays for drug resistance TB monitoring is definitely desirable and the GenoType® MTBDRplus assay was found to be a useful method for diagnosis of resistance to INH, RMP and MDR from lymph node aspirates. Further molecular cluster analysis to determine transmission dynamics of mutated strain is required.     

Rapid screening of rpoB and katG mutations in Mycobacterium tuberculosis isolates by high-resolution melting curve analysis

Background: Early detection of multidrug-resistant tuberculosis (MDR-TB) is essential to prevent its transmission in the community and initiate effective anti-TB treatment regimen. Materials and Methods: High-resolution melting curve (HRM) analysis was evaluated for rapid detection of resistance conferring mutations in rpoB and katG genes. We screened 95 Mycobacterium tuberculosis clinical isolates including 20 rifampin resistant (RIF-R), 21 isoniazid resistant (INH-R) and 54 fully susceptible (S) isolates determined by proportion method of drug susceptibility testing. Nineteen M. tuberculosis isolates with known drug susceptibility genotypes were used as references for the assay validation. The nucleotide sequences of the target regions rpoB and katG genes were determined to investigate the frequency and type of mutations and to confirm HRM results. Results: HRM analysis of a 129-bp fragment of rpoB allowed correct identification of 19 of the 20 phenotypically RIF-R and all RIF-S isolates. All INH-S isolates generated wild-type HRM curves and 18 out of 21 INH-R isolates harboured any mutation in 109-bp fragment of katG exhibited mutant type HRM curves. However, 1 RIF-R and 3 INH-R isolates were falsely identified as susceptible which were confirmed for having no mutation in their target regions by sequencing. The main mutations involved in RIF and INH resistance were found at codons rpoB531 (60% of RIF-R isolates) and katG315 (85.7% of INH-R isolates), respectively. Conclusion: HRM was found to be a reliable, rapid and low cost method to characterise drug susceptibility of clinical TB isolates in resource-limited settings.     

Unequal distribution of resistance-conferring mutations among Mycobacterium tuberculosis and Mycobacterium africanum strains from Ghana

Isoniazid (INH) and rifampicin (RMP) resistance in Mycobacterium tuberculosis complex (MTC) isolates are mainly based on mutations in a limited number of genes. However, mutation frequencies vary in different mycobacterial populations. In this work, we analyzed the distribution of resistance-associated mutations in M. tuberculosis and M. africanum strains from Ghana, West Africa. The distribution of mutations in katG, fabG1-inhA, ahpC, and rpoB was determined by DNA sequencing in 217 INH-resistant (INH^r) and 45 multidrug-resistant (MDR) MTC strains isolated in Ghana from 2001 to 2004. A total of 247 out of 262 strains investigated (94.3%) carried a mutation in katG (72.5%), fabG1-inhA (25.1%), or ahpC (6.5%), respectively. M. tuberculosis strains mainly had katG 315 mutations (80.1%), whereas this proportion was significantly lower in M. africanum West-African 1 (WA1) strains (43.1%; p < 0.05). In contrast, WA1 strains showed more mutations in the fabG1-inhA region (39.2%, p < 0.05) compared to M. tuberculosis strains (20.9%). In 44 of 45 MDR strains (97.8%) mutations in the 81-bp core region of the rpoB gene could be verified. Additionally, DNA sequencing revealed that 5 RMP-susceptible strains also showed mutations in the rpoB hotspot region. In conclusion, although principally the same genes were affected in INH^rM. tuberculosis and M. africanum strains, disequilibrium in the distribution of mutations conferring resistance was verified that might influence the efficiency of molecular tests for determination of resistance.     

Pyrosequencing for Rapid Detection of Extensively Drug-Resistant Mycobacterium tuberculosis in Clinical Isolates and Clinical Specimens

Treating extensively drug-resistant (XDR) tuberculosis (TB) is a serious challenge. Culture-based drug susceptibility testing (DST) may take 4 weeks or longer from specimen collection to the availability of results. We developed a pyrosequencing (PSQ) assay including eight subassays for the rapid identification of Mycobacterium tuberculosis complex (MTBC) and concurrent detection of mutations associated with resistance to drugs defining XDR TB. The entire procedure, from DNA extraction to the availability of results, was accomplished within 6 h. The assay was validated for testing clinical isolates and clinical specimens, which improves the turnaround time for molecular DST and maximizes the benefit of using molecular testing. A total of 130 clinical isolates and 129 clinical specimens were studied. The correlations between the PSQ results and the phenotypic DST results were 94.3% for isoniazid, 98.7% for rifampin, 97.6% for quinolones (ofloxacin, levofloxacin, or moxifloxacin), 99.2% for amikacin, 99.2% for capreomycin, and 96.4% for kanamycin. For testing clinical specimens, the PSQ assay yielded a 98.4% sensitivity for detecting MTBC and a 95.8% sensitivity for generating complete sequencing results from all subassays. The PSQ assay was able to rapidly and accurately detect drug resistance mutations with the sequence information provided, which allows further study of the association of drug resistance or susceptibility with each mutation and the accumulation of such knowledge for future interpretation of results. Thus, reporting of false resistance for mutations known not to confer resistance can be prevented, which is a significant benefit of the assay over existing molecular diagnostic methods endorsed by the World Health Organization.     

Rapid and accurate detection of rifampin and isoniazid-resistant Mycobacterium tuberculosis using an oligonucleotide array

To rapidly detect rifampin, isoniazid and multidrug resistance in Mycobacterium tuberculosis isolates, a new system (BluePoint MtbDR, Bio Concept Inc., Taichung, Taiwan) including an oligonucleotide array and an automatic reader was evaluated. The array simultaneously identifies M. tuberculosis and predominant mutations in the rpoB, katG and inhA upstream regulatory region (inhA-r) genes. The system was assessed with 324 clinical M. tuberculosis isolates, including 210 multidrug-resistant, 41 rifampin mono-resistant, 34 isoniazid mono-resistant and 39 fully susceptible isolates. The results were compared with those obtained using the GenoType MTBDRplus test, drug-resistant gene sequencing and conventional drug susceptibility testing. The detection limit of the array was 25 pg DNA. The array and the GenoType MTBDRplus test detected 179 (85.2%) and 182 (86.7%) multidrug-resistant M. tuberculosis strains, respectively. The sensitivities of the array for detecting rifampin and isoniazid resistance were 98.4% and 87.7%, respectively, whereas the sensitivities of the GenoType MTBDRplus test for detecting rifampin and isoniazid resistance were 98.8% and 88.9%, respectively. No significant difference was found between the tests with respect to their sensitivities to detect multidrug resistance (p 0.66), rifampin resistance (p 0.69) or isoniazid resistance (p 0.68). The discrepancies were mainly attributed to rare mutations in inhA-r, which were not included in the array. The array can directly reveal transmission-associated mutations, which are useful for epidemiological investigations. The turnaround time of the array test was 6–7 h. This study confirms the feasibility of using this system for rapid and accurate diagnosis of isoniazid and rifampin resistance in M. tuberculosis.     

Detection of rpoB,katG and inhA gene mutations in Mycobacterium tuberculosis clinical isolates from Chongqing as determined by microarray

The emergence of multidrug-resistance Mycobacterium tuberculosis is an increasing threat to tuberculosis control programmes. Susceptibility testing of Mycobacterium tuberculosis complex isolates by traditional methods requires a minimum of 14 days. This can be reduced significantly if molecular analysis is used. DNA sequencing is a good method for detecting mutation, but cannot be used routinely because of its relatively high cost. A sensitive and specific microarray has been designed to detect mutations in the rifampin resistance determining region of rpoB and loci in katG and inhA associated with isoniazid (INH) resistance. A panel of Mycobacterium tuberculosis isolates containing 13 different rpoB genotypes, two mutation genotypes within codon 315 of katG and one mutation genotypes at inhA was used to validate the microarray. The results obtained indicate that 100% of rifampicin-resistant M. tuberculosis strains isolated in Chongqing had rpoB mutations, with 531-Ser and 526-His being the most common positions substituted. Of the total 50 INH resistant isolates, 82% had a katG315 mutation and 18% had an inhA mutation. All the mutations detected by the microarray method were also confirmed by conventional DNA sequencing. It is demonstrated that the microarray is an efficient, specialized technique and can be used as a rapid method for detecting rifampin and isoniazid resistance.     

Assessment of three commercially available serologic assays for detection of antibodies to Mycobacterium tuberculosis and identification of active tuberculosis

Tuberculosis (TB) caused by Mycobacterium tuberculosis remains a major world disease, with approximately 9 million new cases each year. Identification and treatment of active disease are essential for TB control. Serology may offer increased detection of active disease in patients with a positive tuberculin skin test (TST) or QuantiFERON-TB (QFT-G). The InBios Active TbDetect immunoglobulin G (IgG) enzyme-linked immunosorbent assay (ELISA), IBL M. tuberculosis IgG ELISA, and Anda Biologics TB ELISAs were evaluated for the ability to detect M. tuberculosis antibodies in patients with active disease. Agreement, sensitivity, and specificity for each ELISA were determined and compared to those for culture or amplified direct detection and M. tuberculosis low-risk control patients. The InBios Active TbDetect ELISA had an agreement of 96.2%, a sensitivity of 83.3%, and a specificity of 98.9%. The IBL M. tuberculosis ELISA had an agreement of 84.0%, a sensitivity of 5.6%, and a specificity of 100.0%. The agreement, sensitivity, and specificity of the Anda Biologics TB ELISA were 74.2%, 83.3%, and 72.0%, respectively. The sensitivity for detecting M. tuberculosis antibodies in human immunodeficiency virus-associated TB was 50% for both the InBios Active TbDetect ELISA and the Anda Biologics TB ELISA and 0% for the IBL M. tuberculosis ELISA. The positivity rates for InBios Active TbDetect ELISA, IBL M. tuberculosis ELISA, and Anda Biologics TB ELISA in latently infected individuals positive by TST and/or QFT-G were 5.1%, 0.0%, and 30.8%, respectively. It can be concluded that the InBios Active TbDetect IgG ELISA is superior to the other ELISAs in accurately detecting active TB.     

Rapid Detection of Multidrug-Resistant Mycobacterium tuberculosis by Use of Real-Time PCR and High-Resolution Melt Analysis

The current study describes the development of a unique real-time PCR assay for the detection of mutations conferring drug resistance in Mycobacterium tuberculosis. The rifampicin resistance determinant region (RRDR) of rpoB and specific regions of katG and the inhA promoter were targeted for the detection of rifampin (RIF) and isoniazid (INH) resistance, respectively. Additionally, this assay was multiplexed to discriminate Mycobacterium tuberculosis complex (MTC) strains from nontuberculous Mycobacteria (NTM) strains by targeting the IS6110 insertion element. High-resolution melting (HRM) analysis following real-time PCR was used to identify M. tuberculosis strains containing mutations at the targeted loci, and locked nucleic acid (LNA) probes were used to enhance the detection of strains containing specific single-nucleotide polymorphism (SNP) transversion mutations. This method was used to screen 252 M. tuberculosis clinical isolates, including 154 RIF-resistant strains and 174 INH-resistant strains based on the agar proportion method of drug susceptibility testing (DST). Of the 154 RIF-resistant strains, 148 were also resistant to INH and therefore classified as multidrug resistant (MDR). The assay demonstrated sensitivity and specificity of 91% and 98%, respectively, for the detection of RIF resistance and 87% and 100% for the detection of INH resistance. Overall, this assay showed a sensitivity of 85% and a specificity of 98% for the detection of MDR strains. This method provides a rapid, robust, and inexpensive way to detect the dominant mutations known to confer MDR in M. tuberculosis strains and offers several advantages over current molecular and culture-based techniques.The World Health Organization (WHO) estimates that approximately one-third of the world''s population is infected with Mycobacterium tuberculosis, with an estimated 9.27 million new cases reported in 2007 (20). In that year alone, an estimated 1.77 million people died from this treatable disease. Despite this significant burden, only a limited number of tests have been developed and implemented for the rapid diagnosis of tuberculosis (TB). Further, since the majority of TB disease burden occurs in underdeveloped and resource-limited settings, the need for a cost-efficient method is paramount.The emergence of drug-resistant strains of M. tuberculosis is one of the most critical issues facing TB researchers and clinicians today. Multidrug-resistant (MDR) M. tuberculosis is defined as being resistant to the two best first-line drugs used to treat TB: rifampin (RIF) and isoniazid (INH). Extensively drug-resistant (XDR) M. tuberculosis is defined as having additional resistance to a fluoroquinolone (ciprofloxacin, moxifloxicin, etc.) and an injectable drug (kanamycin, capreomycin, or amakacin), the two best classes of second-line drugs. The WHO estimates that 5% of new TB cases are MDR, with approximately 10% of those actually being XDR (20). Compounding this problem is the fact that no new drugs have been developed and approved for the treatment of TB in the past 30 years (16). The limited number of antibiotics available to treat TB necessitates rapid diagnosis not only to reduce the spread of drug-resistant strains but also to monitor and limit the emergence of newly resistant strains.While RIF and INH are very effective in the treatment of susceptible strains of M. tuberculosis, drug resistance can emerge quickly, in part due to patient nonadherence to the multidrug regimen or noncontinuous treatment. The molecular basis of resistance to these drugs is well documented. The target of RIF is the β-subunit of bacterial DNA-dependent RNA polymerase, which is encoded by the rpoB gene. At the genetic level, the majority of RIF resistance is due to the accumulation of mutations within an 81-bp region of rpoB, termed the rifampicin resistance determinant region (RRDR). Mutations within this region account for up to 98% of the RIF resistance observed (15). The strong correlation between genotypic changes in this region resulting in phenotypic resistance makes the RRDR an optimal target for the design of rapid molecular diagnostics.There are two described mechanisms that account for the majority of INH resistance. The most common mechanism involves mutations within the katG gene, which encodes a catalase peroxidase whose activity is required for the activation of INH (9). Nucleotide changes resulting in amino acid substitutions at codon 315 of katG account for up to 50% of the clinical resistance to INH (15). Another less common mutation occurs in the promoter region of the inhA gene, which encodes enoyl-ACP reductase, which is required for mycolic acid biosynthesis (18). Mutations at this locus account for up to 34% of the clinical INH resistance observed and are typically found in combination with additional mutations in katG (15).The vast majority of mutations that occur within rpoB, katG, and the inhA promoter regions are due to accumulation of single-nucleotide polymorphisms (SNPs), of which there are four classes (8). Class I SNPs, also called transitions, are changes in which a purine is exchanged for a purine (A/G→G/A) or a pyrimidine is exchanged for a pyrimidine (C/T→T/C) (8). Class II, III, and IV SNP changes are collectively referred to as transversions, and all involve the change of a purine to a pyrimidine, or vice versa (17). Class II changes result in A/C→C/A or T/G→G/T transversions, class III changes result in C/G→G/C transversions, and class IV changes result in A/T→T/A changes (8). These genetic mutations often result in phenotypic changes, such as RIF and INH resistance observed in M. tuberculosis, and are excellent targets for rapid molecular diagnostics.A significant obstacle in controlling TB is the amount of time required to reach a diagnosis. Due to the slow growth rate of M. tuberculosis, the initial diagnosis can take up to 6 weeks, with up to an additional 12 weeks to obtain drug susceptibility profiles for clinical isolates, depending on the techniques available to the laboratory. These labor-intensive methods can cause significant delays in identifying MDR or XDR cases, adjusting treatment regimens, and initiating epidemiological investigations. Recently, attention has shifted toward the development of dependable, molecular-based assays that can rapidly detect drug resistance. The development of new methodologies could potentially reduce the time required to diagnose drug resistance so that effective treatment regimens can be established. Direct sequencing of genes known to have a role in antibiotic resistance is one method that is currently used. However, while reliable, it is costly and may not be readily available. Another rapid method, the GenoType MTBDRplus assay (Hain Lifescience GmbH, Nehren, Germany), has made substantial contributions to the area of rapid diagnostics but still requires approximately 8 h to complete the assay and additional training to ensure that results are interpreted correctly (7). High-resolution melt (HRM) analysis is a molecular technique that can be used for detecting subtle genetic changes, such as SNPs conferring drug resistance in M. tuberculosis. By slowly melting the DNA amplicon products of a real-time PCR assay, slight genetic differences can be visualized by changes in dissociation profiles.The current study describes the use of multiple real-time PCR chemistries and HRM technology to detect RIF, INH, and more importantly, MDR strains of M. tuberculosis. This novel assay design is also capable of distinguishing M. tuberculosis complex bacteria (MTC) from nontuberculous mycobacterium (NTM) strains. This assay provides a rapid, robust, and inexpensive way to identify MDR TB that could result in numerous advantages over current molecular and culture-based techniques.     

Simplified Microarray System for Simultaneously Detecting Rifampin,Isoniazid, Ethambutol,and Streptomycin Resistance Markers in Mycobacterium tuberculosis

We developed a simplified microarray test for detecting and identifying mutations in rpoB, katG, inhA, embB, and rpsL and compared the analytical performance of the test to that of phenotypic drug susceptibility testing (DST). The analytical sensitivity was estimated to be at least 110 genome copies per amplification reaction. The microarray test correctly detected 95.2% of mutations for which there was a sequence-specific probe on the microarray and 100% of 96 wild-type sequences. In a blinded analysis of 153 clinical isolates, microarray sensitivity for first-line drugs relative to phenotypic DST (true resistance) was 100% for rifampin (RIF) (14/14), 90.0% for isoniazid (INH) (36/40), 70% for ethambutol (EMB) (7/10), and 89.1% (57/64) combined. Microarray specificity (true susceptibility) for first-line agents was 95.0% for RIF (132/139), 98.2% for INH (111/113), and 98.6% for EMB (141/143). Overall microarray specificity for RIF, INH, and EMB combined was 97.2% (384/395). The overall positive and negative predictive values for RIF, INH, and EMB combined were 84.9% and 98.3%, respectively. For the second-line drug streptomycin (STR), overall concordance between the agar proportion method and microarray analysis was 89.5% (137/153). Sensitivity was 34.8% (8/23) because of limited microarray coverage for STR-conferring mutations, and specificity was 99.2% (129/130). All false-susceptible discrepant results were a consequence of DNA mutations that are not represented by a specific microarray probe. There were zero invalid results from 220 total tests. The simplified microarray system is suitable for detecting resistance-conferring mutations in clinical M. tuberculosis isolates and can now be used for prospective trials or integrated into an all-in-one, closed-amplicon consumable.     

Phenotypic and genotypic characterization of pyrazinamide resistance among multidrug-resistant Mycobacterium tuberculosis clinical isolates in Hangzhou,China

ObjectivesPyrazinamide (PZA) is a crucial first-line tuberculosis (TB) drug recommended for both drug-susceptible and multidrug-resistant Mycobacterium tuberculosis. This study aimed to evaluate the performance of the sequencing method of pncA, rpsA and panD mutations in detecting PZA resistance in multidrug-resistant (MDR) TB isolates.MethodsWe sequenced the pncA, rpsA and panD genes and performed PZA susceptibility tests across 291 MDR-TB isolates to evaluate the performance of the sequencing method of these genes in detecting PZA resistance.ResultsResults showed that 145 (90.0%) of 161 PZA phenotypic resistant isolates had mutations in pncA. Among the 16 isolates (10.0%) which did not have mutations in pncA, ten and three isolates had mutations in rpsA and panD, respectively. The sequencing method for detecting mutations in pncA alone had 90.1% (95% confidence interval (CI), 84.4–94.2) sensitivity and 92.3% (95% CI, 86.3–96.3) specificity. The combination of all three genes increased the sensitivity from 90.1% (95% CI, 84.4–94.2) to 98.1% (95% CI, 94.7–99.6) (p < 0.001) while the specificity remained unchanged. In 120 PZA-susceptible and 16 PZA-resistant isolates without pncA mutations, rpsA/panD mutations were correlated with PZA resistance.ConclusionsPZA resistance was largely associated with mutations in pncA. Mutations in rpsA and panD were also associated with PZA resistance in MDR isolates expressing wild-type pncA. The detection of mutations in pncA, rpsA and panD can be useful for the determination of PZA resistance.