Figures
Abstract
Background
Rapid molecular diagnostics for detecting multidrug-resistant and extensively drug-resistant tuberculosis (M/XDR-TB) primarily identify mutations in Mycobacterium tuberculosis (Mtb) genes associated with drug resistance. Their accuracy, however, is dependent largely on the strength of the association between a specific mutation and the phenotypic resistance of the isolate with that mutation, which is not always 100%. While this relationship is well established and reliable for first-line anti-TB drugs, rifampin and isoniazid, it is less well-studied and understood for second-line, injectable drugs, amikacin (AMK), kanamycin (KAN) and capreomycin (CAP).
Methodology/Principal Findings
We conducted a systematic review of all published studies evaluating Mtb mutations associated with resistance to AMK, KAN, CAP in order to characterize the diversity and frequency of mutations as well as describe the strength of the association between specific mutations and phenotypic resistance in global populations. Our objective was to determine the potential utility and reliability of these mutations as diagnostic markers for detecting AMK, KAN and CAP resistance. Mutation data was reviewed for 1,585 unique clinical isolates from four continents and over 18 countries. Mutations in the rrs, tlyA, eis promoter and gidB genes were associated with AMK, KAN and/or CAP resistance.
Conclusions/Significance
The rrs A1401G mutation was present in the majority of AMK, KAN and CAP resistant Mtb strains reviewed, but was also found in 7% of CAP susceptible strains. The 1401 mutation alone, however, was not found with sufficient frequency to detect more than 70–80% of global Mtb strains resistant to AMK and CAP, and 60% of strains resistant to KAN. Additional mutations in the rrs, eis promoter, tlyA and gidB genes appear to be associated with resistance and could improve sensitivity and specificity of future diagnostics.
Citation: Georghiou SB, Magana M, Garfein RS, Catanzaro DG, Catanzaro A, Rodwell TC (2012) Evaluation of Genetic Mutations Associated with Mycobacterium tuberculosis Resistance to Amikacin, Kanamycin and Capreomycin: A Systematic Review. PLoS ONE 7(3): e33275. https://doi.org/10.1371/journal.pone.0033275
Editor: Laura Ellen Via, National Institute of Allergy and Infectious Disease, United States of America
Received: December 16, 2011; Accepted: February 12, 2012; Published: March 29, 2012
Copyright: © 2012 Georghiou et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by NIAID grants #K01AI083784 to Dr. Timothy Rodwell and #U01AI082229 to Dr. Antonio Catanzaro, Dr. Marisa Magana, Dr. Richard Garfein, and Dr. Donald Catanzaro. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
In 2010, 8.8 million new cases of tuberculosis (TB) and 1.4 million TB-related deaths were reported worldwide [1]. While the global incidence of TB appears to be decreasing, the emergence of multidrug-resistant TB (MDR-TB) and extensively drug-resistant TB (XDR-TB) has significantly complicated TB eradication efforts. MDR-TB strains, as defined by World Health Organization (WHO), are Mycobacterium tuberculosis (Mtb) strains resistant to the most effective “first-line” TB medications: isoniazid (INH) and rifampin (RIF). XDR-TB strains are characterized by resistance to INH, RIF (ie MDR-TB) plus any fluoroquinolone (e.g., moxifloxacin), and at least one of the three “injectable” anti-TB drugs: amikacin (AMK), kanamycin (KAN), and capreomycin (CAP) [2]. At an estimated 5% of all tuberculosis cases globally, the incidence of MDR-TB recently reported by the WHO is the highest ever recorded [3], and XDR-TB cases have been confirmed in 58 countries to date [4].
Appropriate use of the “second-line” injectable drugs, AMK, KAN and/or CAP is critical to the effective treatment of MDR-TB and to the prevention of XDR-TB. It is therefore imperative that the MDR-TB strains in patients starting second-line drug treatment are first tested for sensitivity to these drugs to ensure appropriate treatment choices are made and that resistance is not further amplified [5]. Conventional diagnosis of drug-resistance in Mtb strains relies heavily upon mycobacterial culture and drug susceptibility testing in liquid or solid media. While this method is effective for detecting INH and RIF resistance, detecting resistance to AMK, KAN and CAP is more complicated and less reliable [6]. Additionally, results are only obtained after weeks to months of incubation and many developing countries lack the resources to establish the stringent laboratory conditions needed for these growth-based methods. From a clinical perspective, the existing growth-based diagnostics also reveal too little, too late, as patients undergoing treatment with drugs to which they are resistant, remain contagious, and those with XDR-TB and HIV often die before they are even diagnosed [7]. Rapid molecular diagnostic tests that do not rely upon the culture of this slow-growing pathogen are essential to the future management of M/XDR-TB.
Molecular diagnostics, which focus on the detection of mutations in pathogen genes that have been associated with drug resistance, have shown the most promise for rapid diagnosis of M/XDR-TB [8]–[10]. Their accuracy, however, is dependent largely on the strength of the association between a specific Mtb gene mutation and the phenotypic resistance of the isolate with that mutation, which is not always 100%. This relationship between mutation and phenotypic resistance is well established and consistent for the first-line drug RIF [11], [12], and to a lesser extent INH [13], [14], but it is less well-studied and understood for the injectable drugs.
To date, the primary genes associated with injectable drug resistance in Mtb have been identified based on an understanding of the mechanisms of action of the aminoglycosides (AMK, KAN) and cyclic peptides (CAP) against Mtb. Both AMK and KAN bind to the 16S rRNA in the 30S ribosomal subunit and inhibit protein synthesis [15]. The mechanism of action of CAP in Mtb is not well understood, but it appears to interfere with translation and inhibit phenylalanine synthesis in mycobacterial ribosomes [16]. Mutations in Mtb, mostly non-synonymous, single nucleotide polymorphisms (SNPs), that prevent the binding of the injectable drugs to their pathogen gene targets or that change the mechanism of action of the drugs, have been associated with drug resistance to AMK, KAN and CAP [17], [18]. The most well-studied gene mutations believed to confer resistance to the injectable drugs lie in the rrs and tlyA genes. The rrs gene encodes 16S rRNA [19] and tlyA encodes a 2′-O-methyltransferase that modifies nucleotide C1409 in helix 44 of 16S rRNA and nucleotide C1920 in helix 69 of 23S rRNA [20]. The mutations most commonly reported to cause resistance to the injectable drugs include: A1401G, C1402T, and G1484T in the rrs gene [9], [10], [18], [21]–[38]. More recently, the eis promoter, which has been demonstrated to enhance the intracellular survival of a related bacterium—Mycobacterium smegmatis—has also been considered for its utility as a marker for resistance to KAN when mutated [39]. Other resistance-associated mutations in these genes and other genes have been proposed [32], but their utility as accurate predictors of resistance has yet to be demonstrated. Consequently, current molecular detection tests for XDR-TB are considered inferior to those used for MDR-TB due to insufficient knowledge about the key mutations responsible for conferring resistance to AMK, KAN and CAP.
We therefore conducted a systematic review of all published studies evaluating Mtb mutations associated with resistance to AMK, KAN, CAP in order to characterize the diversity and frequency of mutations as well as describe the strength of the association between specific mutations and phenotypic resistance in global populations. The objective of our study was to determine the potential utility and reliability of these mutations as diagnostic markers for detecting AMK, KAN and CAP resistance in Mtb.
Methods
Literature Search
A Medline search was conducted of all publications evaluating mutations associated with resistance to AMK, KAN and CAP in Mtb. The search was restricted to studies published from 1959 through September 10th, 2011, including those studies available online prior to publication. MEDLINE/PubMed key search terms used were: (second-line OR kanamycin OR capreomycin OR amikacin) AND (resistance OR resistant) AND tuberculosis AND (mutation OR sequence OR gene).
Study Selection Criteria
Studies were included if they met the following predetermined criteria: i) published in English; ii) presented original data; and iii) assessed drug resistance mutations in clinical Mtb strains that were resistant to AMK, KAN and/or CAP (in vitro studies were excluded as laboratory generated mutations have been frequently observed to be different from those found in clinical isolates [40]). Studies were also excluded if they did not perform or describe phenotypic drug susceptibility testing (DST), did not perform sequencing as a method for determining drug resistance mutations, or did not report specific mutation data. We included studies that used both liquid and solid-based media for DST as long as they reported clearly defined drug concentration cutoffs for determining resistance. These criteria were intended to select the broadest range of studies with the highest quality of specific data for mutation analysis.
Data Extraction and Entry
From each publication, we extracted the following information: authors, publication year, geographic origin of clinical strains, reference strain(s) utilized to evaluate mutations, testing method for phenotypic drug susceptibility and drug concentrations used for defining resistance, methods used to detect genotypic mutations, genes sequenced, and loci of genes sequenced. The following mutation information was also recorded: specific gene mutation(s) found, injectable drug utilized for selection, number of resistant and susceptible isolates tested, and number of resistant and susceptible isolates demonstrating mutation. Data were recorded and compiled using Excel and Access software (Microsoft, Redmond, WA).
Data Collation and Cumulative Mutation Frequency Calculations
Mutations associated with resistance to AMK, KAN, and CAP were grouped by genes and stratified by the drug resistance phenotype associated with the mutation. Data was examined for evidence of individual as well as multiple mutations within a gene. Each mutation reported in a resistant Mtb isolate was considered independent of all others within and between studies (except where otherwise noted for multiple mutations in the same gene), and recorded as one instance of the mutation in the numerator of our cumulative frequency calculations. Cumulative mutation frequency in resistant isolates was calculated as the number of resistant isolates in which the mutation was found, divided by the total number of phenotypically resistant isolates tested across studies. Cumulative mutation frequency in susceptible isolates was calculated as the number of susceptible isolates in which the mutation was found, divided by the total number of susceptible isolates tested across studies. As not all studies examined all mutations or all genes associated with resistance, an isolate was only included in the denominator of a cumulative frequency calculation for a particular mutation if that mutation could have been detected in that isolate (i.e. the study sequenced the appropriate section of the gene).
While all mutations identified in the review were evaluated, the cumulative mutation frequency tables presented in this review represent only the mutations that reached a frequency threshold as described below. Isolates with rrs and gidB gene mutations were included if their frequency among resistant isolates was at least 1% for any one of the injectable drugs tested, and when that frequency was not higher among susceptible isolates than resistant isolates for two or more injectable drugs. The isolates with tlyA gene, eis promoter, and multiple rrs mutations were included in the tables if the mutation frequency among resistant isolates was at least 1% for any one of the injectable drugs tested. Mutations were excluded from the tables when the frequencies of the mutation were equal in resistant and susceptible strains (ie not likely to be associated with resistance).
Quality Assessment and Consistency
Throughout this review mutation co-ordinates are referred to in accordance with the numbering in the Mtb H37Rv complete genome, accession number NC_000962, National Center for Biotechnology Information [41]. Mutations identified in earlier publications that did not use this co-ordinate system [21], [22], [25] were updated to this numbering system. The H37Rv strain was the assumed template for mutation analysis in all publications, even when not explicitly stated within a given study, as is standard practice [9], [10], [18], [25], [26], [30].
In publications that did not examine the whole gene and did not report the specific area of the gene sequenced, the reported SNPs were substituted as the outer limits for the gene region under study (e.g. if only rrs mutations A1401G and G1484T were reported within a publication, the sequence from 1401–1484 was considered to be the section of rrs analyzed for mutations). In publications evaluating the MTBDRsl line probe assay (Hain Life Sciences, Tübingen, Germany), in which resistance-associated genes were sequenced, but sequence data was only provided for regions hybridized to the line probes, only those SNPs tested via hybridization strips were considered sequenced.
In one publication, mutation data was reported for “probable-resistant” and “probable-susceptible” clinical isolates [33]. A “probable-susceptible” strain was defined as an Mtb strain isolated prior to initiation of any treatment with a given drug, while a “probable-resistant” strain was defined as a strain isolated from patients after at least six months of treatment with the given drug. For the purposes of this review, we assumed the probable-resistant and probable-susceptible isolates were resistant and susceptible based on the DST methodology described in the manuscript.
Sensitivity and Specificity of Mutations
In order to comment on the potential predictive value of the reported resistance-related mutations in a molecular diagnostic test, we described a mutation as potentially “very sensitive” when its cumulative frequency was 75% or more in the resistant strains evaluated and “moderately sensitive” if it occurred in 50% to 74% of the resistant strains reported. A resistance-related mutation was defined as “very specific” if it was reported in 5% or less of susceptible strains evaluated and “moderately specific” if it was reported in 6% to 10% of the susceptible strains evaluated.
Results
Description of Included Studies
Figure 1 (Figure S1) illustrates the study selection and exclusion process utilized for this review. Initial search parameters identified 135 studies published from November, 1959 through September, 2011. Twenty-two publications met all eligibility criteria and were included in the review [6]–[27].
Of the 22 studies included, the earliest was published in 1998 and 17 (77%) were published in the last three years (Table 1). Altogether, mutation data was provided for 1,585 unique clinical isolates with various phenotypic resistance profiles to AMK, KAN, and/or CAP. The reported geographic origins of these strains were diverse, covering four continents and over 18 countries.
Mutations in the rrs, tlyA, eis promoter and gidB genes were associated with Mtb resistance to AMK, KAN and/or CAP in the examined literature. A total of 94 unique mutations were reported relative to the reference H37Rv genome: rrs (37 unique mutations), tlyA (30 unique mutations), eis (12 unique mutations) and gidB (15 unique mutations). Eighty-two of these mutations (87%) were SNPs, six were deletions (one in rrs, two in tlyA and three in gidB), and six were insertions (two in rrs and four in tlyA). As resistance determination for the strains was crucial to our analysis, we evaluated the DST methods and drug-concentration cutoffs used in each study to define whether a strain was resistant or not. Table 2 shows the method of DST and cutoff concentrations used in each study as well as whether or not they conformed to published standards. The drug concentrations used in all but three studies [10], [26], [36] conformed to at least one national or international published standard. As DST standards are somewhat controversial and variable between countries, and the three studies in question were all conducted by national reference laboratories, we assumed their DST definition of resistance was correct for this review. A PRISMA checklist is provided as befitting a systematic review, to ensure integrity of the data (Table S1).
rrs Mutations Associated with Injectable Drug Resistance
Among the genes considered in the 22 papers reviewed, rrs was the most extensively studied, but only eight papers (36%), representing a total of 442 tested isolates (32% of the total), included sequence data on the entire rrs gene. Figure 2 shows the rrs studies as a heatmap of the number of isolates evaluated in each study as well as the locations of the major mutations found. The most commonly examined mutations were the A1401G mutation, reported in all 21 papers with rrs mutations, and the G1484T mutation, reported in 7/21 papers.
Graphic shows the region of the rrs gene studied, the number of isolates tested in each study and the locations of the mutations found. The X-axis (nucleotide position) has a 25 base pair resolution. The numbers of isolates varies from 314 (black) to 10 (lightest grey). Red indicates that a mutation has been found in that 25 base pair region.
Table 3 shows the cumulative frequencies of the most commonly reported mutations in the rrs gene. The A1401G SNP was found in 387/493 (78%) of AMK-resistant (AMKR) strains and it was never observed in AMK-susceptible (AMKS) strains. It is notable that while 367/483 (76%) CAP-resistant (CAPR) isolates studied had the A1401G mutation, it was also found in 45/678 (7%) of CAP-susceptible (CAPS) strains tested across 7 studies. However only 354/637 (56%) KAN-resistant (KANR) isolates studied had the A1401G mutation, and it was never reported in KAN-susceptible (KANS) strains. These studies indicate that the A1401G mutation has potentially moderate sensitivity for predicting resistance to all three drugs and the potential to be a highly specific predictor for AMK and KAN resistance, but less so for CAP.
Other notable rrs mutations included the A514C and C517T SNPs, which were found in only 7%–10% and 4%–7% of resistant strains, respectively. However, both mutations were also found in 2%–6% of isolates defined as susceptible to the injectable drugs. Surprisingly, while the G1484T and C1402T mutations are commonly cited as being strongly and commonly associated with resistance, our review found that out of over 400 injectable drug resistant strains evaluated, only 1% or less had these mutations. The C1402T appears to occur as frequently in AMKS and KANS strains as it does in AMKR and KANR strains suggesting it would be a poor marker of resistance. The rrs mutation G1158T, while studied in less than 300 injectable drug resistant strains, appears to be at least as frequent in resistant strains as the 1484 and 1402 rrs mutations, and has never been observed in the almost 150 strains susceptible to AMK, KAN and/or CAP, suggesting it might be at least as sensitive as 1484 and 1402 mutations and a more specific predictor for injectable drug resistance.
tlyA Mutations Associated with Injectable Drug Resistance
Sequence data for the tlyA gene was provided in only 8 of the 22 publications reviewed [18], [24], [28], [31], [33], [35], [37], [38]. Mutations of the tlyA gene have been most well-studied in CAPR and CAPS Mtb strains (n = 366 and 559, respectively), and have been evaluated in less than 260 KANR or AMKR strains (Table 4). Mutations in the tlyA gene associated with CAPR were reported to be rare in the surveyed literature (found in ∼1–3% of resistant strains). However, when reported, they were not found in any CAPS strains, making them potentially highly specific markers of CAP resistance. Of the 559 total CAPS isolates reported in 7 studies [18], [24], [28], [31], [33], [35], [37], [38], none had any mutations within the tlyA gene. A GT insertion at position 755 of the tlyA gene was the only mutation that was found in more than 1% of CAPR strains (3% of strains had this mutation).
eis Promoter Mutations Associated with Injectable Drug Resistance
Mutations within the eis promoter region of Mtb have only been evaluated in a few hundred injectable drug resistant strains (Table 5) and were reported to be largely associated with KAN resistance [37], [39]. The most frequently reported eis promoter SNP (G-10A) was found in 66/296 (22%) of the KANR strains studied—second only to the frequency of the rrs A1401G mutation in injectable drug resistant strains—and was found in only 2/266 (1%) of KANS strains. The C-14T SNP was reported in modest frequency in both KANR and AMKR strains (11% and 9% respectively) and was not found in susceptible strains. eis promoter mutations were also reported in up to (9%) CAPR strains. Aside from the C-12T SNP, however, which was reported in 5/93 (5%) of CAPR strains and 1/93 (<1%) of CAPS strains, these mutations appear to be non-specific markers of resistance, occurring in up to 29% of CAPS strains.
gidB Mutations Associated with Injectable Drug Resistance
The reported gidB mutations associated with injectable drug resistance have only been evaluated in 20 strains resistant to AMK, KAN and/or CAP (Table 6), producing what are likely unreliable cumulative frequencies. The G102 deletion appeared with a high frequency among resistant isolates (17–20%), and was only found in one susceptible isolate examined. The T230C, C286T, and T104G SNPs were each reported in one injectable drug resistant strain and did not appear to occur in strains susceptible to AMK, KAN and/or CAP.
Double Mutations in the rrs Gene Associated with Injectable Drug Resistance
Only a small number of the surveyed publications described specific mutations at more than one site in any of the genes evaluated, limiting our ability to calculate cumulative frequencies of such “multiple mutations” in injectable drug resistant strains. We therefore report here only specific double mutations within the most commonly described gene (rrs). The most common double mutations reported always included the A1401G mutation (Table 7). While the cumulative frequency of double mutations did not exceed 5% in injectable drug resistant strains, an A1401G mutation together with A514C, A513C or A1338C SNP occurred only in resistant strains and was not reported to occur in any strains susceptible to AMK, KAN and/or CAP, whereas the A1401G mutation alone was found to occur in up to 7% of CAPS strains (Table 3). This suggests that multiple rrs mutations might be a highly specific predictor of injectable drug resistance when detected (i.e., never observed in susceptible strains).
Discussion
It is clear from the literature reviewed that Mtb mutations associated with injectable drug resistance are understudied compared to the mutations associated with resistance to first-line drugs [42]. Only the 1401 and 1484 positions of the rrs gene have been evaluated to any extent in injectable drug resistant isolates (n>600), while the remainder of the rrs and other resistance-associated genes (tlyA and the eis promoter) have each been evaluated in less than 400 drug resistant Mtb isolates. Only 20 injectable drug resistant isolates have been examined for gidB mutations. This review uncovered evidence to suggest that certain mutations outside the commonly-observed A1401G SNP, alone or in conjunction with rrs mutations, could help to detect some of the 25%–40% of AMK, KAN, and CAP resistant Mtb strains that do not appear to have an rrs mutation.
Future studies of Mtb resistant to AMK, KAN and CAP should always include a comprehensive sequence analysis of at least the entire four genes examined here, if not the entire Mtb genome. Additionally, a suitable number of injectable drug susceptible strains should be included in each study to build data on the potential specificity of each mutation. As the sensitivity of any mutation-based molecular diagnostic will be determined by both the strength of the association between mutation and phenotypic resistance and the frequency of the specific resistance-related mutation in the population, it is also crucial to establish both regional and global frequencies of these mutations to predict where and how to develop the most effective molecular diagnostics.
Mutations as Markers of Phenotypic Resistance to the Injectable Drugs
Certain rrs, tlyA, eis promoter and gidB gene mutations with the potential to be both sensitive and specific predictors of phenotypic drug resistance were found frequently in drug-resistant strains and infrequently, or never, in drug-susceptible strains. Compared to INH-resistant Mtb strains (∼85% of which have katG and/or inhA promoter mutations) [43] and RIF resistant strains (∼97% of which have rpoB mutations) [44], phenotypic resistance to AMK, KAN and/or CAP was associated with a larger diversity of genes, each with lower cumulative frequencies.
The rrs A1401G SNP was reported in about 75% of CAPR and AMKR strains, and in less than 60% of KANR strains, and it was only found in 7% of strains susceptible to CAP, suggesting this mutation would be a very sensitive and specific marker for phenotypic resistance to AMK, a very sensitive but moderately specific marker for phenotypic resistance to CAP, and a moderately sensitive but very specific marker for resistance to KAN.
It appears that a single mutation, or even a set of mutations in a single gene, does not adequately predict phenotypic resistance to AMK, KAN and CAP. It is likely that a combination of different gene mutations for each injectable drug will be needed to best predict phenotypic resistance, as has been reported for the molecular detection of INH resistance [45].
Based on the published mutation frequencies we report here, KANR strains might be predicted with highest sensitivity and specificity using a combination of rrs mutations (e.g. A1401G and C517T) and eis promoter mutations (e.g. G-10A and C-14). Since eis promoter mutations reportedly occur almost exclusively in KANR strains with no 1401 rrs mutation [37], [39] it is likely that this approach will be considerably more sensitive than using the rrs 1401 mutation alone. CAPR strains, on the other hand, appear to be best predicted by mutations in rrs gene (i.e., A1401G, C1402T, G1158T) possibly together with mutations such as C-12T in the eis promoter, which was reported in 5% of CAPR strains and only 1% of CAPS strains. Another useful marker might be the insertion at position 755 of the tlyA gene; however, future studies will be needed to confirm the frequency of this, and other, mutations in CAPR strains worldwide. For AMKR strains, a combination of the A1401G rrs SNP together with the eis promoter mutations C-14T or C-12T (reported in 9% and 6% of AMKR strains) could increase sensitivity of resistance detection without decreasing specificity. There was not sufficient data to evaluate the potential role of double rrs mutations, but given that they were never reported in injectable drug susceptible Mtb strains, these mutations could significantly increase the positive predictive value of rapid diagnostics when found.
It is important to note that resistance to streptomycin (SM), an aminoglycoside with a similar mechanism to AMK and KAN [46], was not evaluated in this review as it is not as well-studied as the XDR-TB defining drugs. It is possible this exclusion may have confounded some of our findings regarding mutations in gidB and rrs. As SM is often administered together with AMK, KAN or CAP, and SM resistance has been associated with mutations in gidB [47] and the 500 region of rrs [48], that are not thought to cross-react with AMK, KAN or CAP resistance; it is possible that the associations we observed in these gene regions are a reflection of underlying, but unevaluated SM resistance rather than true associations with AMK, KAN and CAP resistance. Further study of these mutations in the absence of SM resistance could shed important light on the value of these mutations.
Improving the Detection of AMK, KAN and/or CAP Resistance with Existing Molecular Diagnostics
In considering the implications of our findings, we focus upon three commercially available molecular diagnostics employed to detect resistance-related mutations in Mtb clinical isolates [49]: hybridization-based tests, pyrosequencing, and molecular beacon testing. Hybridization tests, such as the MTBDRplus and MTBDRsl line probe assays (LPAs) (Hain Life Sciences, Tübingen, Germany), are based on the hybridization of specific mutations in clinical strains to a probe that is complimentary to the mutated DNA. The MTBDRplus/sl assays are the only commercially available rapid molecular diagnostics currently in broad use for the detection of both MDR-TB and XDR-TB. They have shown great promise in field studies for the detection of MDR-TB [8], [50]–[60], but variable sensitivity (40%–100% depending on the number of strains examined) for detection of injectable drug resistance [9], [10], [29], [36], [61]. As the MTBDRsl LPA detects only mutations in the 1401, 1402 and 1484 positions of the rrs gene, the varying sensitivity of the test is in agreement with the apparent cumulative frequency of these mutations in the published literature. It would also seem from the very low cumulative frequencies of the rrs 1402 and 1484 mutations reported, that their inclusion in the MTBDRsl LPA as the only mutations outside of rrs 1401, might be limiting the potential sensitivity of this test for the detecting AMK, KAN and CAP resistance. Adding or replacing probes could potentially increase MTBDRsl sensitivity by as much as 10% without significantly decreasing specificity. In a recent evaluation study of the MTBDRsl test, the inclusion of mutations from a second gene, the eis promoter, increased field sensitivity for KANR detection by about 30% [36].
Pyrosequencing is a rapid sequencing method used to detect genetic mutations based on “sequencing by synthesis”. It has been established as a valid rapid method for detecting resistance-associated SNPs in MDR-TB strains [62]–[66], but only one small study reported on its use for XDR-TB detection [59]. A large, multinational field study of suspected M/XDR-TB patients in India, Moldova and South Africa [67] is currently evaluating the effectiveness of pyrosequencing for detecting resistance to AMK, KAN and CAP based on detection of mutations in the rrs gene between base pair 1397 through 1406. Increasing the number of mutations and genes currently being detected by pyrosequencing in this study could significantly improve the next iteration of the assay.
Beacon-type sequencing, or SNP genotyping, has shown excellent utility in the field [68]–[71] and is the basis of the GeneXpert assay that was recently endorsed by WHO for detecting RIF resistance in Mtb [72]. Unfortunately, this technology is still being developed for XDR-TB detection, and there is a risk that detection of second-line drug resistance may fall behind unless the study of the appropriate mutations is accelerated. Beacon technology is based on detection of short stretches of genes that are different from the wild type genome, rather than detecting point mutations like an LPA. Nonetheless, it could similarly be developed to detect a variety of mutations in short regions of the rrs, eis promoter, tlyA, and gidB genes if the limitations in beacon development for these regions can be overcome.
Limitations
The cumulative frequencies we calculated were based on several assumptions, but the two we describe here are the most important. First, we assumed that all the mutations reported were independent of each other. If some isolates were misclassified as independent when they were in fact not, this could have caused an overestimation in our cumulative frequencies of that specific mutation. Every effort was made to ensure that the isolates and the mutations presented in one study were not also reported in another study. All manuscripts were carefully examined to identify isolates that were used in more than one study (e.g., same isolate origin, same authors or organization, etc.) and to the best of our knowledge, all isolates reported here are unique. A second potential source of misclassification error was in our use of the DST results as reported. For example, if an isolate was misclassified as resistant based on faulty DST data, when it was in fact susceptible, and it did not have the expected mutation, then we would have underestimated the cumulative frequency of that mutation among resistant isolates. To minimize the chances of such misclassification, we excluded manuscripts without explicit descriptions of their DST methods and clear definitions of what constituted a resistant or susceptible isolate using accepted DST drug concentrations and methodologies.
Conclusion
It is clear that the rrs 1401 mutation alone was not found with sufficient frequency to detect more than 70–80% of global Mtb strains resistant to AMK and CAP, and 60% of strains resistant to KAN. While this is likely sufficient for a rapid screening test, future molecular diagnostics will need to include more mutations in more genes in order to accurately and sensitively detect resistance and cross-resistance to AMK, KAN and CAP for clinical decision-making purposes.
Other SNPs in the rrs, eis promoter, tlyA and gidB appear to be very promising markers for improving both sensitivity and specificity of detection of AMK, KAN and CAP resistance and cross-resistance, but it is likely that each drug will need to be considered independently (with independent mutation profiles) to maximize the diagnostic and clinical utility of future molecular diagnostics for these drugs.
Supporting Information
Figure S1.
PRISMA flowchart for systematic review.
https://doi.org/10.1371/journal.pone.0033275.s001
(DOC)
Table S1.
PRISMA checklist for systematic review.
https://doi.org/10.1371/journal.pone.0033275.s002
(DOC)
Acknowledgments
The authors would like to acknowledge Dr. Ed Desmond, Grace Lin and Elizabeth Kim who provided comments and advice on an early draft of this manuscript.
Author Contributions
Conceived and designed the experiments: TCR SG RSG AC. Analyzed the data: SG MM TCR DGC. Contributed reagents/materials/analysis tools: TCR RSG DGC AC SG. Wrote the paper: SG TCR. Literature searching and data abstraction: SG MM TCR. Statistical analysis: SG TCR MM DGC.
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