Multidrug Resistant Mycobacterium tuberculosis: A Retrospective katG and rpoB Mutation Profile Analysis in Isolates from a Reference Center in Brazil

Background Multidrug resistance is a critical factor in tuberculosis control. To gain better understanding of multidrug resistant tuberculosis in Brazil, a retrospective study was performed to compare genotypic diversity and drug resistance associated mutations in Mycobacterium tuberculosis isolates from a national reference center. Methods and Findings Ninety-nine multidrug resistant isolates from 12 Brazilian states were studied. Drug-resistance patterns were determined and the rpoB and katG genes were screened for mutations. Genotypic diversity was investigated by IS6110-RFLP and Luminex 47 spoligotyping. Mutations in rpoB and katG were seen in 91% and 93% of the isolates, respectively. Codon 315 katG mutations occurred in 82.8% of the isolates with a predominance of the Ser315Thr substitution. Twenty-five isolates were clustered in 11 groups with identical IS6110-RFLP patterns while 74 showed unique patterns with no association between mutation frequencies or susceptibility profiles. The most prevalent spoligotyping lineages were LAM (47%), T (17%) and Haarlen (12%). The Haarlen lineage showed a higher frequency of codon 516 rpoB mutations while codon 531 mutations prevailed in the other isolates. Conclusions Our data suggest that there were no major multidrug resistant M. tuberculosis strains transmitted among patients referred to the reference center, indicating an independent acquisition of resistance. In addition, drug resistance associated mutation profiles were well established among the main spoligotyping lineages found in these Brazilian multidrug resistant isolates, providing useful data for patient management and treatment.


Introduction
Tuberculosis (TB) is an infectious disease caused by bacteria of the Mycobacterium tuberculosis complex. In general, its clinical form is characterized by lung impairment, however, this disease may also affect other anatomical sites or occur in a disseminated form. TB is currently one of the main causes of morbidity and mortality affecting the main vulnerable groups (young adults, children and people with HIV) [1]. Multidrug resistant (MDR) M. tuberculosis strains are highly pathogenic and show great dissemination capacity. The global average of MDR-TB estimated for newly reported TB cases in 2012 was 3.6%, being slightly higher in high MDR-TB burden countries with 4.2% [1].
According to the World Health Organization (WHO), in 2012 there were an estimated 8.6 million new TB cases in the world representing a burden of 1.3 million deaths (including 320,000 deaths among HIV-positive patients). TB, therefore, is a highly relevant public health issue in Brazil, being the third cause of death from infectious diseases. Brazil is one of the 22 countries that account for 82% of all TB cases in the world [1]. In 2012, there were 82,000 new TB cases in this country with an incidence of 46/ 100,000 inhabitants and a mortality rate of 2.5/100,000. In 2012, of a total of 900 cases tested for MDR-TB in Brazil, 684 cases were laboratory confirmed as MDR.
The high TB prevalence is assumed to result from poverty, the HIV epidemic and inadequate diagnosis and treatment [2,3]. Isoniazid (INH) and rifampin (RMP) are still the most important drugs available for TB treatment. Multidrug resistance (MDR), defined as resistance to at least RMP and INH, is another critical factor involved in TB control as MDR M. tuberculosis strains are highly pathogenic and have the potential for great dissemination. While the standard treatment requires six months of chemotherapy the regimen for most MDR-TB patients takes 20 months. In 2012, an estimated 450,000 people developed MDR-TB worldwide with 170,000 deaths [1]. Most cases in 2012 were in South-East Asian (29%), African (27%) and Western Pacific (19%) regions [1].
Global data collected in 2012 from MDR surveys and continuous surveillance among notified TB cases suggest that 3.6% of newly diagnosed TB cases and 20% of those previously treated for TB showed MDR-TB. The highest levels of MDR-TB are found in Eastern Europe and Central Asia where in some countries more than 20% of new TB cases and more than 50% of those previously treated for TB are MDR. In 2012, of a total of 94,000 TB patients eligible for MDR-TB treatment, 84,000 cases were confirmed. This represented a 42% increase in MDR cases compared with 2011 [1].
Gene mutations are typically associated with resistance to specific drugs in M. tuberculosis. RMP has been the most important drug available for TB treatment. It inhibits gene transcription by binding to the beta subunit of the DNA dependent RNA polymerase, encoded by the rpoB gene. Most rpoB mutations occur in a 81 bp region known as RRDR (RMP resistance determining region), located between codons 507 and 533 [4].
Several genes can be involved in INH resistance (katG, inhA, KasA, ndh, the oxyR-ahpC intergenic region, fabG, fadE24, inhA promoter, iniA and the mabA-inhA operon) [5,6]. The katG gene encodes the catalase-peroxidase enzyme that is involved in the activation of the pro-drug INH. The loss or reduction of enzyme activity by mutations prevents this process, allowing survival in the presence of INH [7,8]. katG gene mutations are present in most INH resistant M. tuberculosis clinical isolates where alterations in codon 315 predominate [9,10]. Mutations located at the mabA-inhA operon can also lead to INH resistance and are present in 8-30% of the resistant strains [6]. Mutations in the other genes are rare and usually coexist with other hotspot mutations in katG and mabA-inhA [6].
Molecular techniques that differentiate M. tuberculosis strains are important tools in public health issues such as TB outbreaks and to unravel transmission patterns. The RFLP (restriction fragment length polymorphism) analysis of the IS6110 insertion element (IS6110-RFLP), when performed under standardized conditions, is highly reproducible and effective in transmission studies in a specific region or place or between populations, providing better ways to understand and control disease transmission [11,12].
The basis for spoligotyping (spacer oligonucleotide typing) lies in the determination of the direct repeat number present in a specific region of the M. tuberculosis genome [13]. Alone or in conjunction with other techniques, spoligotyping can be used to establish strain/isolate relationships, investigate circulating strains, transmission dynamics and the natural history of TB [14][15][16][17][18].
Here we present a retrospective analysis of katG and rpoB mutation profiles and the genotypic diversity by IS6110-RFLP and spoligotyping of 99 MDR M. tuberculosis isolates obtained at a MDR-TB national reference center in Rio de Janeiro. Our goals were to determine correlations between genotypes and katG and rpoB mutations and evaluate relationships within these isolates and the main global circulating M. tuberculosis strains. This information could be useful for TB care and control as Brazil has a considerable incidence of primary resistance which is, typically, 6% and 1.5% for INH and RMP, respectively [19].

Mycobacterium tuberculosis isolates
Ninety-nine MDR M. tuberculosis isolates were provided by the National Tuberculosis Reference Center for Multidrug Resistance Prof. Hélio Fraga, in Rio de Janeiro, Brazil. According to international standards, MDR is defined as resistance to at least INH and RMP. These M. tuberculosis isolates were obtained from patients with pulmonary TB who were referred to the Center between 1995 and 2003. Fifty-three isolates were from patients that resided in Rio de Janeiro State and 46 isolates were from patients living in 12 other Brazilian States (Amazonas: 3; Pará: 5; Maranhão: 4; Ceará: 2; Paraíba: 3; Pernambuco: 5; Bahia: 2; Goiás: 3; Minas Gerais: 4; São Paulo: 6; Paraná: 7 and Rio Grande do Sul: 2) ( Figure S1). Isolates were selected according to two different criteria: one group (20 isolates) belonged to a National Survey on Drug Resistant Tuberculosis performed in Brazil between 1995 and 1997. This survey was undertaken by the Brazilian TB control program to detect the magnitude of drug resistance in TB treatment. Unfortunately, clinical data collection was not prioritized in the survey so it was available only for few patients. Among the 5,586 patients with pulmonary TB enrolled in the National Survey, 2% (123 patients) were MDR. Clinical data was available for only one of these patients therefore the other 19 isolates from this MDR group were randomly selected. The remaining 79 isolates were from MDR-TB patients referred to the Reference Center Professor Helio Fraga for treatment. Patietnts were referred to the center by State Clinics who characterized resistance to TB treatment. We tried to select patients for whom clinical data were available and who were admitted for treatment between 2002 and 2003 to match the last years of the survey. Clinical data was available for 36 of these patients due to the destruction of patient records during a flood in the Center. Strain isolation was achieved from sputum samples by cultivation in Löwenstein-Jensen (LJ) medium.

Drug susceptibility tests
Drug resistance patterns were determined on LJ medium using the proportions method at critical concentrations and critical proportions of the population indicating bacterial resistance. The concentrations and proportions were 40 mg/L and 1.0% for RMP, 0.2 mg/L and 1.0% for INH, 100 mg/L and 10% for pirazinamid (PZA), 4 mg/L and 10% for streptomycin (St) and 2.0 mg/L and 1.0% for ethambutol (EMB) [20].

DNA extraction
M. tuberculosis isolates were cultured for three to four weeks at 37uC in LJ medium. Genomic DNA was prepared by a CTAB protocol as described by van Soolingen et al. (1991) [21]. Genomic DNA was inspected by agarose gel electrophoresis and quantified on a spectrophotometer (Nanoview, GE Healthcare, Brazil).

Genotyping by IS6110-RFLP
DNA fingerprinting by IS6110 RFLP was performed on the isolates following standard procedures [22]. Briefly, extracted mycobacterial DNA was digested with PvuII, separated by electrophoresis, transferred to a Hybond N + membrane and hybridized with a horseradish peroxidase conjugated 245-bp PCR-amplified probe directed against the right arm of IS6110. Detection was performed with the ECL Direct Labeling and Detection System (GE Healthcare Life Sciences, Brazil). Autoradiograms were scanned at 190 dots/inch and IS6110 patterns were analyzed using Bionumerics (Windows version 4.0, Applied Maths). The position of IS6110 containing fragments was normalized against the internal markers and the accuracy of the procedure was verified by comparison of IS6110 banding patterns to those of strain Mt.14323 on different autoradiograms. Similarity matrices were constructed using the Dice band-based similarity coefficient using a band tolerance interval of 2.0% of the pattern length and dendrograms were generated by the hierarchic unweighted pair group method analysis (UPGMA) clustering algorithm.

Genotyping by Luminex spoligotyping
Spoligotyping was performed as described previously [23]. We used the Luminex 200 platform and spoligotype patterns were entered in the SITVIT2 proprietary database of the Institut Pasteur de la Guadeloupe, which is an updated version of the previously released SpolDB4 database (available online http:// www.pasteur-guadeloupe.fr:8081/SITVITDemo) [24]. Some samples were classified as new because they did not match any pattern of the Spoligotype International Type (SIT) that designates patterns shared by two or more patient isolates. Therefore, a new spoligotype pattern is one that has never been reported before. Some isolates were also classified as unknown, which means that they do have an SIT number but the lineage to which they belong is unknown.
katG and rpoB mutation analysis Mutation analysis of the katG gene (GenBank accession number U06258) was concentrated on two regions of interest. The first, extending from the first codon (GTG/valine) to codon 119, was PCR amplified using primers katG1 sense, 59-A CTTCGCGAT-CACATCCGTG-39 and katG1 antisense,59-GCGGCCGTCGT-GGATGCGGTA-39. The second region, from codon 267 to 504, was amplified with primers katG2 sense, 59-CGGCGGTCA-CACTTTCGGTA-39 and katG2 antisense 59-CCCGACTTG-TGGCTGCAGGC-39. The region comprehending codons 445 to 560 of the rpoB gene (GenBank accession number L27989) was PCR amplified with primers rpoB sense 59-CATCGACCAC-TTCGGCAACCG-39 and rpoB antisense 59-TTTCGATCGGG-CACATCCGGC-39. All PCR reactions were performed using Platinum Taq High Fidelity (Invitrogen, Brazil), 1.5 mM of MgCl 2 , 15 pmol of each primer, 0.2 mM of dNTPs, 1X PCR buffer (provided by the manufacturer) and 40 ng of genomic DNA. PCR parameters were as follows: denaturation at 95uC for 5 min, followed by 35 cycles at 95uC for 45 s, 56uC (for rpoB) and 63uC (for katG) for 45 s and 72uC for 1 min, and a final extension time of 10 min at 72uC. Amplicons were analyzed by agarose gel electrophoresis, purified by the Illustra GFX PCR DNA and Gel Band Purification kit (GE Healthcare, Brazil), sequenced directly with the DYEnamic ET terminator cycle sequencing kit (GE Healthcare) and analyzed on a MegaBACE 1000 automated DNA sequencer platform (GE Healthcare). Several reactions in both directions were done for each amplicon to ensure accurate sequencing. Chromatograms were analyzed using Chromas software (version 2.22, Technelysium Pty Ltd, Australia). The consensus sequences of each sample were compared to the wildtype M. tuberculosis katG and rpoB gene sequences in order to identify the mutations. Blast searches against Genbank were performed for nucleotide comparisons.

Statistical analysis
Data was analyzed with GraphPad Prism 5.0 software (GraphPad Software Inc. La Jolla, CA, USA). Associations between categorical variables were assessed using the Chi-square test or Fisher's exact test. A P value of ,0.05 was considered statistically significant. Ninety-five percent confidence intervals of all proportions were calculated by Wald's equation: p~# of 00 successes 00 #of 00 events 00~S N

Results and Discussion
As described above, clinical data was available for only 37 patients and is shown in Table S1. Among them, 15 were women and 22 were men. Globally, most TB cases and deaths occur in men but this disease remains among the top three killers of women [1]. The median age at the diagnosis of MDR was 33 years. The main type of resistance was acquired resistance (89%; CI = 82.7-95.1) and almost 50% of the patients died after two years of follow up.
All of the 99 MDR isolates analyzed were resistant to INH and RMP, 52 were resistant to EMB and 35 to streptomycin ST (Table 1). Drug susceptibility results for some of the isolates could not be determined due to intrinsic difficulties of the method. Susceptibility patterns for all samples are shown in Table S2.
Mutations in the 81-bp RRDR region of the rpoB gene were present in 90 isolates. A total of 51, 23 and 11 isolates carried mutations at codons 531, 526 and 516, respectively, confirming this segment of the gene as a hotspot region, as observed worldwide [10,[25][26][27][28][29][30][31][32]. The other five isolates had mutations  distributed among other codons (Table 2). Furthermore, eight isolates that had mutations in codon 531, 526 or 516, also had mutations in other codons. Therefore, 82 isolates exhibited single changes but seven presented double mutations, always in conjunction with the altered codons 531, 526 or 516. One isolate had point mutations in three separate codons (531, 522 and 539).
We found four new alleles for the rpoB gene in codons 475, 539, 545 and 471. Three of them occurred as double mutations involving always one of the most frequently mutated codons. Three of these alleles were from isolates from Rio de Janeiro state while the one in codon 471 was from a Pernambuco isolate. It is possible that these double mutations are related to compensatory mutations. Several studies have demonstrated that drug resistance  mutations in essential genes may have a negative impact on key physiological functions. Drug resistance incurs a fitness cost and compensatory mutations in target or related genes can help to reduce it [33]. We previously reported katG mutation profiles for 64 of the isolates included in this study [34] and now the remaining 35 samples were analyzed. Two regions of this gene were sequenced, katG1 and katG2, the latter containing codon 315, the most commonly mutated one [10,25,26,[35][36][37][38]. katG mutations were found in 92 isolates with seven of them showing mutations only in katG1. Among these 92 isolates, 82 had changes in codon 315 and 5 showed double mutations in katG2 in codons 463, 399, 493 or 485 that were always accompanied by codon 315 alterations and are probably compensatory mutations ( Table 2). Although amino acid changes in codon 431 have already been described [39], we also found a new single nucleotide (G) deletion in this codon. Within katG1, 30 isolates showed mutations in which 26 were deletions in codon 4. The remaining 4 isolates showed insertions, deletions and base substitutions in this region ( Table 2). The full results of the mutation screening for the rpoB and katG genes can be seen in Table S3.
Three MDR isolates had no katG and rpoB mutations and 6 others were RMP resistant but also had no rpoB mutations. Curiously, although most samples in this study were from Rio de Janeiro state, only one of these 6 isolates was from this state. Additionally, 4 other isolates were INH resistant but had no katG mutations. It is possible that some of these isolates possess an efflux mechanism of drug resistance, extruding structurally and functionally unrelated compounds by transporter pumps. This mechanism can be responsible for intrinsic and acquired drug resistance in prokaryotic and eukaryotic cells [40].
Moreover, especially regarding resistance to INH, mutations in other genes can be involved. We also investigated through multiplex allele-specific polymerase chain reaction (MAS-PCR), mutations in the mabA-15 region in the 8 INH resistant isolates that carried the wild type katG gene and found that only one had a mutation in this region (data not shown).
This investigation not only confirms data observed in other studies analyzing the resistance and mutation profiles of Brazilian MDR isolates but also describes new mutations in isolates that were collected over an eight-year period from different Brazilian states. Furthermore, the mutation profiles described in our data could help in the design of rapid diagnostic tests that simultaneously detect TB and MDR by new strategies such as high resolution melting analysis in qPCR.
To evaluate whether mutation frequencies could be influenced by clustered isolates, their possible genetic relationships were investigated through IS6110-RFLP (Table 3). The number of IS6110 copies detected ranged from 2 to 18 with an average number of 10. Twenty-five isolates were clustered in 11 groups comprising 2 or 3 isolates with identical RFLP patterns. The remaining 74 isolates showed unique IS6110 patterns and there was no association between mutation frequencies at each mutated codon or susceptibility profiles.
Two RFLP clusters (cluster 4 and cluster 5) with 2 isolates each showed similar resistance profiles and carried single rpoB and katG mutations at codon 531 and 315, respectively. However, in cluster 5 the resistance profile was different for each isolate concerning EMB and ST. The transmission of the same MDR isolate between the patients of these 2 clusters may have happened, as suggested by the fact that all isolates in these clusters came from Rio de Janeiro state and showed similar drug resistance patters and identical rpoB and katG mutations.
Regarding the other nine clusters, no apparent mutation or resistance profile relationships were detected. Their rpoB and katG mutations were somewhat different with some showing distinct amino acid changes (clusters 6 and 7) or different mutations at the same gene (rpoB mutations in clusters 1, 3,6,8,9,10). Interestingly, in several clusters a katG codon 4 deletion was found in one of the isolates belonging to the same cluster (clusters 1, 2, 6, 7, 8, 10, 11) ( Table 3). This indicates that transmission of the same isolate happened before the MDR phenotype was established, suggesting an independent acquisition of antibiotic resistance. Moreover, clusters 1, 3, 7 and 9 exhibited isolates that were from different states, indicating that the same strain may have circulated freely between different Brazilian regions. Seven clusters showed different mutation profiles for the rpoB or katG gene. These data suggest that there were no major MDR strains transmitted between patients in Brazil between the years 1995 and 2003.
We observed a high rate of IS6110-RFLP polymorphisms among the 99 MDR isolates that is again indicative of independent acquisition of resistance. This is not surprising since secondary resistance was the main mode of MDR development in our samples. The opposite was observed for MDR isolates from Rio Grande do Sul by Perizzolo et al. (2012) [30], who had a large level of genotype clustering and concluded that these came mostly from strains that had been transmitted in the last few years.
Spoligotyping was also performed for all samples ( Figure 1A). An updated version of the SpolDB4 database, the SITVIT2 proprietary database of the Institut Pasteur de la Guadeloupe, was used to identify all spoligotype patterns. Eighty-two isolates were classified into 5 distinct lineages ( Figure 1A). Forty-six were assigned to the Latin-America and Mediterranean (LAM) family, 17 to T super-family 12 to Haarlen (H), 6 to X2 and 1 to the East African Indian (EAI) families. Recently, a large spoligotyping analysis reported that LAM, T and H lineages are the most frequently observed ones in Brazilian M. tuberculosis isolates [31]. Our study corroborates with these findings as we found very similar frequencies for these lineages in our MDR isolates.
Of the other 17 isolates, 9 were classified as new and 8 as unknown. No statistically significant differences in lineage frequencies were found between samples from Rio de Janeiro and those from other states (Chi-square test, p = 0.43). This indicates that our data is general enough and could be useful for the development of diagnostic tests for MDR-TB in Brazil (Table 4). Lineage distribution among the 37 patients for whom clinical data was available was not statistically different from the whole set (Chi-square test, p = 0.77) Isolates of LAM and T families were distributed into 8 and 5 sublineages, respectively ( Figure 1B and 1C). In LAM family, 20 isolates were assigned to LAM9 and 9 to LAM4 sublineages while for the T family, T1 was the major sublineage with 12 isolates. Haarlem family isolates were also subdivided into H1 and H3 sublineages with 2 and 10 isolates, respectively (data not shown).
IS6110-RFLP and spoligotyping patterns, octal number, SIT and lineage for each isolate can be observed in Table S4. Curiously, the EAI lineage, that shows a phylogeographic distribution in South-East Asia, India and East-Africa, was represented by one isolate from Parana state. This raises the question of whether transmission from other continents may have happened.
IS6110-RFLP clusters were compared with spoligotyping data ( Table 5). As expected, isolates belonging to the same RFLP cluster were of similar spoligotype lineages. Our data allowed us, through a paired analysis, to discriminate some IS6110-RFLP clusters by spoligotyping. Some isolates within the same IS6110-RFLP and spoligotyping cluster had different mutation profiles and came from various Brazilian states. This reinforces the idea of independent acquisition of drug resistance in these clusters. We can also note that for RFLP clusters 10 and 11, isolates were assigned as new profiles in LAM sublineage. Both isolates in cluster 11 showed identical RFLP patterns and octal numbers and were tentatively identified as LAM3 sublineage members.
A relationship, although not statistically significant (Fischer test, p = 0.17), between the absence of katG codon 4 deletions with lineage X2 was observed (Table 6). Although codon 4 deletions were common in isolates from all lineages, X2 was the only clustered lineage that did not have them. More isolates belonging to this lineage should be analyzed to try to reach statistical significance and confirm this hypothesis. However, we suggest that in countries where this lineage is common, MDR patient care should take into account that these patients may carry this mutation. Considering the H lineage, rpoB gene mutations were atypical, with codon 516 being the most frequently altered followed by 526 and 531 (Chi-square test, p,0.0001). However, for the other lineages the most commonly mutated codons were those normally seen in RMP resistant isolates worldwide (codons 531, 526 and 516).
A comparative analysis of our data with a study that analyzed 217 MDR M. tuberculosis isolates from Russia in a similar way showed that 46%, 10% and 2% of them belonged to the LAM, H and T lineages, respectively [32]. While only 4 T lineage isolates were observed in the Russian samples, we had 17 (17.1%; CI = 9.7-24.6). Another major difference was seen for rpoB codon 531 that was the most frequently mutated one in our study while no mutations were found in the Russian samples. Russian LAM isolates showed rpoB mutations in codon 516 (75%) and 531 (7%) and also in katG at codon 315 (99%). Similarly, 46.4% (CI = 36.6-56.3) of our MDR isolates also belonged to LAM lineage with a high frequency of codon 315 mutations (82.6%; CI = 71.7-93.6). However, we observed a much higher frequency (60.9%; CI = 46.8-75) of codon 531 rpoB mutations, with only 2% (CI = 0-6.4) in codon 516.
In H lineage Russian isolates, 43% had no katG mutations against 16.7% (CI = 0-37.8) in our study. For rpoB, mutations were absent in 48% of them against only 8.3% (CI = 0-24) in ours. Additionally, mutations in rpoB codon 516 were the most frequent ones in our H lineage isolates while the same was not observed for the Russian samples. However, our results are similar to another study in Brazil with 121 MDR isolates from Rio Grande do Sul state [30], in which 20% had no katG and 12% no rpoB mutations. These observations suggest that the frequencies of certain mutations in particular genotypic lineages are dependent on the geographical region of the isolates.
Perizzolo et al. (2012) [30] also observed that only 4% of their samples from Rio Grande do Sul state belonged to the H lineage while we had 12% (CI = 5.7-18.6) among all samples, which suggests that this difference may be occurring only when Rio  Grande do Sul state is analyzed separately from other Brazilian states. They also observed that the largest sublineage was LAM5 (15%), one that is rarely observed among drug susceptible samples in this region. In our study, the frequency of the LAM5 sublineage was low (3%; CI = 0-6.4), which is similar to what was found in drug susceptible samples from Rio Grande do Sul and reinforces the idea that Perizzolo et al. (2012) [30] analyzed samples from a specific MDR outbreak. Concerning the type of mutations found  in LAM5, both studies showed similar findings, with one isolate that had no mutations and several with mutations in codons 531 (rpoB) and 315 (katG). The mutation profile in this sublineage seems to be very similar in Brazilian isolates. The two main spoligotyping lineages found in our study, LAM and T, were compared with their respective mutation profiles (Table 7). There were some associations between katG1 alterations and the sublineages. LAM6 and LAM9 carry a higher number of katG1 deletions than the other LAM sublineages (Chi-square test, p = 0,008). Furthermore, all isolates belonging to lineages LAM and T also had mutations in katG2 codon 315. Another interesting observation, although not statistically significant, is that the T lineage shows much lower mutation diversity in both rpoB (Chi-square test, p = 0.50) and katG (Chi-square test, p = 1.00) than LAM.
MDR-TB is one of the most important threats for TB control. Sensitivity tests of first line drugs strongly influence patient care and the utilization of resources before the treatment. In this work, a correlation of drug resistance profiles with IS6110 fingerprinting clusters and rpoB and katG mutations was attempted in order to determine possible associations. We found that isolates belonging to the same cluster did not necessarily show the same resistance or mutation profile, indicating that genotyping to strain level cannot predict resistance in this set of samples. This type of investigation could be optimized by a new Luminex based method, the Spoligoriftyping that allows the simultaneous assessment of the main rpoB mutation SNPs (codons 516, 526 and 531), the main mutations in genes related to INH resistance (katG 315, inhA 215) and spoligotyping [41].
Although most isolates came from Rio de Janeiro, we also analyzed isolates from other 11 Brazilian states, as shown in Table 4. Thus, we were able to draw an idea of rpoB and katG mutations throughout the Brazilian territory. Even though alterations in at least three genes (katG, inhA and ahpC) are associated with INH resistance, our analysis, as confirmed in other studies, shows that katG mutations are good predictors of resistance as 93% (CI = 87.9-98) of our INH resistant isolates carried mutations in this gene. Among these, 89% (CI = 82.8-95.5) had codon 315 mutations with a predominance of the Ser315Thr substitution. This profile is consistent with findings from other countries [25,26,36,37,38] and also with previous studies of Brazilian MDR isolates [10,39]. In spite of that, one study with INH resistant Brazilian isolates from Goiás state [42] found a lower prevalence of codon 315 katG mutations (6 of 17), raising the question of whether geographical strain differences could be responsible for this variation.
According to Costa et al. (2009) [43], there is an association between the katG 315 mutation and the H lineage in strains from South America (Brazil, Peru and Argentina) but there is none with the LAM lineage. In contrast, we had a high number of codon 315 mutations in these two lineages. Although the Ser315Thr mutation results in an enzyme incapable of activating INH, it retains approximately 50% of the catalase-peroxidase activity [44]. Therefore, this altered enzyme provides high-level resistance to INH while still keeping a level of oxidative protection that creates a clear advantage for the isolates that carry it.
In the present study, we correlated data from resistance and mutation profiles with spoligotyping and IS6110-RFLP cluster analysis. Such data are highly relevant for the study of global TB transmission. One study with 99 MDR isolates from Portugal, for example, showed that IS6110-RFLP in association with rpoB mutation analysis can be useful to unambiguously confirm isolate identities and to propose epidemiological links [45]. Another study with 114 isolates recovered from patients of a Russian prison [46] determined the active transmission of MDR isolates between prisoners through the high rate of MDR and the identical RFLP patterns, spoligotypes and rpoB mutations among new cases. The high proportion of clustered isolates (79.8%) in this prison clearly indicates an active and recent disease transmission.
Regarding the 37 isolates from patients who had clinical data available, no significant associations between spoligotype lineages and the following variables were found: sex, presence of comorbidities, patient outcome, presence of cavitation and pulmonary bilateral involvement (Chi-square test, p always.0.05).
In spite of being a high TB and HIV burden country, there is scarce data comparing rpoB and katG gene mutations with IS6110-RFLP and spoligotype fingerprints in MDR isolates in  Brazil. Our data are useful to enhance our understanding of the mechanisms of resistance and their relationship with specific lineages. Furthermore, resistance profiles were well established in the present study among the main lineages found in Brazilian isolates (LAM and T), thus providing useful data for patient management and treatment in this country. Additionally, the characterization of these MDR isolates could aid in the development of diagnostic tools as well as guide new strategies to fight MDR-TB in Brazil.