Molecular characterization of pre-extensive drug resistant <i>Mycobacterium tuberculosis</i> in Northeast Brazil

Campelo, Thales Alves; Lima, Luana Nepomuceno Costa; Lima, Karla Valéria Batista; Silva, Caroliny Soares; Conceição, Marília Lima da; Barreto, José Antonio Pereira; Mota, Aquiles Paulino Peres; Sancho, Soraya de Oliveira; Frota, Cristiane Cunha

doi:10.1590/S1678-9946202062004

ABSTRACT

In Fortaleza, the capital of Ceara State, Brazil, the detection rate of tuberculosis (TB) in 2018 was 65.5/100,000 inhabitants with a cure rate of 59.1%, which is higher than the country average. This study investigated the risk factors associated with drug-resistant tuberculosis (DR-TB) and identified the drug-resistance phenotype and resistance-conferring mutations. The geographic distribution of DR-TB in Fortaleza, Brazil, was also determined. From March 2017 to February 2018, 41 DR-TB isolates and 69 drug-susceptible pulmonary TB isolates were obtained from patients seen at a referral hospital in Fortaleza, Brazil. Samples were subjected to phenotypic and genetic analysis of resistance; the spatial distribution of the participants was also analyzed. Primary resistance was high (50.9%) among participants. The following risk factors for DR were identified: being female ( p = 0.03), having diabetes ( p < 0.01), history of previous TB disease ( p < 0.01), and the number of intra-domiciliary contacts ( p < 0.01). Analysis by multiplex allele-specific polymerase chain reaction detected mutations in the genes katG (65.8%) , rpoB (43.9%), inhA promoter (14.6%), and gyrA (9.8%). Sequencing identified mutations in the the genes katG (75.6%), inhA promoter (19.5%), rpoB (85.4%), and gyrA (100%). There was no mutation in the rrs gene. Spatial analysis showed DR-TB isolates distributed in areas of low socioeconomic status in the city of Fortaleza. Our results emphasized the importance of detecting resistance to TB drugs. The resistance found in the gene gyrA is of concern due to the high number of pre-extensive DR-TB cases in Fortaleza.

Mycobacterium tuberculosis; Multidrug-resistant TB; Primary resistance; Pre-extensively drug-resistant TB; Risk factors

INTRODUCTION

Brazil ranks 20 ^th among the 30 countries responsible for 87% of new cases of tuberculosis (TB) globally ¹1. World Health Organization . Global tuberculosis report 2019 . Geneva : WHO ; 2019 . [ cited 2019 Apr 22 ]. Available from: http://www.who.int/tb/publications/global_report/en/
http://www.who.int/tb/publications/globa... . In 2018, there were 72,788 new cases of TB with a case detection rate (CDR) of 34.8/100,000 inhabitants ²2. Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Brasil livre da tuberculose: evolução dos cenários epidemiológicos e operacionais da doença . Bol Epidemiol . 2019 ; 50 : 1 - 18 . [ cited 2019 Apr 22 ]. Available from: http://portalms.saude.gov.br/images/pdf/2019/marco/22/2019-009.pdf
http://portalms.saude.gov.br/images/pdf/... . The World Health Organization (WHO) aims to reduce the TB CDR to less than 10.0/100,000 ¹1. World Health Organization . Global tuberculosis report 2019 . Geneva : WHO ; 2019 . [ cited 2019 Apr 22 ]. Available from: http://www.who.int/tb/publications/global_report/en/
http://www.who.int/tb/publications/globa... . Ceara State, located in the Northeastern region of the country, presented a CDR of 41.8/100,000 inhabitants, ranking 11 ^th in the number of new cases among Brazilian states. In Ceara, new cases of TB mainly occur in Fortaleza, the State capital, including 61% of drug-resistant (DR)-TB cases, with an average cure rate of 70.3%, lower than the recommended rate of 85% worldwide ¹1. World Health Organization . Global tuberculosis report 2019 . Geneva : WHO ; 2019 . [ cited 2019 Apr 22 ]. Available from: http://www.who.int/tb/publications/global_report/en/
http://www.who.int/tb/publications/globa... , ³3. Ceará . Secretaria de Saúde . Boletim epidemiológico tuberculose . [ cited 2019 Apr 19 ]. Available from: https: file:///C:/Users/biblioteca/Downloads/boletim_tuberculose_21_03_2019.pdf
https: file:///C:/Users/biblioteca/Downl... . Fortaleza is the fifth largest city in the country, administratively divided into six regions, with a population of approximately 2.6 million people ⁴4. Instituto Brasileiro de Geografia e Estatística . Brasil/Ceará/Fortaleza: panorama . [ cited 2019 Apr 22 ]. Available from: https://cidades.ibge.gov.br/brasil/ce/fortaleza/panorama
https://cidades.ibge.gov.br/brasil/ce/fo... . In 2010, the Human Development Index of Fortaleza was 0.754, ranking 467 ^th among the Brazilian municipalities ⁵5. Programa das Nações Unidas para o Desenvolvimento . Atlas de desenvolvimento humano do Brasil: Fortaleza, CE . [ cited 2019 Apr 22 ]. Available from: http://atlasbrasil.org.br/2013/pt/perfil_m/fortaleza_ce
http://atlasbrasil.org.br/2013/pt/perfil... .

In 2017, the Brazilian Ministry of Health developed a national plan to combat TB as a public health problem, aiming at eradicating the disease and reducing the incidence to less than 10.0/100,000 inhabitants by 2035 ⁶6. Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Departamento de Vigilância das Doenças Transmissíveis . Brasil livre da tuberculose: plano nacional pelo fim da tuberculose como problema de saúde pública . Brasília : Ministério da Saúde ; 2017 . [ cited 2019 Nov 6 ]. Available from: http://bvsms.saude.gov.br/bvs/publicacoes/brasil_livre_tuberculose_plano_nacional.pdf
http://bvsms.saude.gov.br/bvs/publicacoe... . Brazil has characteristics that favor the transmission of the disease, such as a great social inequality and a high rate of urbanization. Thus, in order to reduce the number of cases of TB, especially the transmission of primary resistant species, it is necessary to promote early diagnosis, identify socioeconomic and epidemiologic indicators, and identify the spatial distribution of clusters of cases. There are no reports on the characterization of resistance-related mutations against anti-TB drugs in Fortaleza, and also on the spatial distribution of cases of DR-TB.

Resistance to anti- Mycobacterium tuberculosis drugs is mainly caused by spontaneous mutations in drug-directed chromosomal genes or drug-modifying enzyme-related genes. Genetic studies have shown the presence of specific mutations in the genes responsible for conferring resistance to routine first-line and second-line anti-TB drugs. Mutations in katG and in the regulatory region of inhA ( inhA -15) account for 42% to 95% and 6% to 43% of isoniazid (INH) resistance cases, respectively. For rifampicin (RMP), the most common mutation is in the resistance-determining region (RDR) of rpoB , with a 95% frequency, whereas for streptomycin (STR), most mutations (76%) occur in the 16S rRNA gene and the rpsL (52%-59%) genes. For quinolones, mutations are found in the genes gyrA and gyrB (75-94%). Resistance to ethambutol (EMB) is often associated with simultaneous resistance to INH, RMP and STR, and mutations in the embCAB gene ⁷7. Zhang Y , Yew WW . Mechanisms of drug resistance in Mycobacterium tuberculosis: update 2015 . Int J Tuberc Lung Dis . 2015 ; 19 : 1276 - 89 . .

Rapid diagnosis is required for DR-TB surveillance and control. Ideally, we should have a sensitive, rapid, and reasonably economical technique that does not require complex methods, as most cases of resistance occur in underdeveloped countries with limited economic resources. Thus, molecular techniques, such as allele-specific polymerase chain reaction (PCR) and sequencing, have been used in the detection of these mutations and to overcome the limitations of phenotypic testing ⁸8. Miotto P , Tessema B , Tagliani E , Chindelevitch L , Starks AM , Emerson C , et al . A standardised method for interpreting the association between mutations and phenotypic drug resistance in Mycobacterium tuberculosis . Eur Respir J . 2017 ; 50 : 1701354 . .

The main objective of this study was to identify resistance-related mutations to the main first-line and second-line anti-TB drugs in Fortaleza and to compare phenotypic tests results (BACTEC Mycobacterial Growth Indicator Tube [MGIT] 960) with allele-specific PCR and sequencing. We have also investigated the risk factors associated with DR-TB and the geographic distribution of the study participants.

MATERIALS AND METHODS

This prospective case-control study was conducted from March 2017 to February 2018 in Fortaleza, Northeast Brazil. The study participants were recruited at the Messejana Hospital Dr. Carlos Alberto Studart Gomes, which is a reference center for the treatment of DR-TB. This is a 349-bed teaching hospital in Northeast Brazil, a leading hospital for treating patients with lung diseases, including DR-TB. On average, Messejana Hospital cares for 2,500 patients with DR-TB per year, and about 165 patients per month.

For the sample calculation, it was observed that 83 cases of multidrug-resistant (MDR)-TB were reported in 2013, 95 in 2014, 75 in 2015, and 45 cases in 2016. Regarding pre-extensively drug-resistant (XDR)-TB, 10 cases were reported in 2013, 21 in 2014, 5 in 2015, and 3 cases in 2016. The sample size for a finite population of at least 37 participants with DR-TB was estimated using a 95% confidence level (α = 0.05), 50% of the population, and an error rate of 5%. The equation for the sample size calculation was n = [ N × z ² × p × (1 − p )]/[ d ² × ( N − 1) + z ² × p × (1 − p )], where N is the total number of new smear-positive cases registered during one year at the hospital; the z value corresponds to the desired confidence level ( z = 1.95); d is the absolute precision and p is the expected proportion of drug resistance in the target population ⁹9. World Health Organization . Guidelines for surveillance of drug resistance in tuberculosis . 5th ed. Geneva : WHO ; 2015 . [ cited 2019 Apr 22 ]. Available from: https://www.who.int/tb/publications/2015/drs_guidelines/en/
https://www.who.int/tb/publications/2015... . The calculated sample size was increased by 20% to compensate for expected losses. Participants presented respiratory symptoms or chest radiography results suggesting pulmonary TB, confirmed by a clinical physician ¹⁰10. Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Departamento de Vigilância das Doenças Transmissíveis . Manual de recomendações para o controle da tuberculose no Brasil . 2ª ed atual. Brasil : Ministério da Saúde ; 2019 . [ cited 2019 Nov 6 ]. Available from: http://bvsms.saude.gov.br/bvs/publicacoes/manual_recomendacoes_controle_tuberculose_brasil_2_ed.pdf
http://bvsms.saude.gov.br/bvs/publicacoe... . During the nursing appointment and after the laboratory confirmation of a new case of TB, participants were invited to take part in the study and to answer the questionnaire, which included demographic, socioeconomic, clinical, and behavioral data.

Patients with pulmonary TB who signed the informed consent and were at least 16 years old were included in the study. In the case of participants under the age of 18, parental or legal guardian consent was also obtained. The inclusion criterion of cases was resistance to at least one anti-TB drug confirmed by mycobacterial culture. Control patients were those with TB susceptible to treatment, as confirmed by a negative laboratory result according to the national TB program guidelines. The final sample size was 110 (41 cases and 69 controls). Patients infected with HIV, presenting extra-pulmonary TB and those without a fixed residence were excluded from the study.

This project was approved by the Ethics Committee of the Federal University of Ceara, Fortaleza, Ceara State, Brazil (protocol Nº 1.956.894). All participants (and/or legal guardians) signed an informed consent form and authorized the sample collections.

Sputum samples were subjected to microscopic examination and culture in Löwenstein-Jensen medium. M . tuberculosis isolates were tested for susceptibility to first-line anti-TB drugs (STR, INH, RMP, and EMB) in an automated system (BACTEC MGIT 960) ¹¹11. Adami AG , Gallo JF , Pinhata JM , Martins MC , Giampaglia CM , Oliveira RS . Modified protocol for drug susceptibility testing of MGIT cultures of Mycobacterium tuberculosis by the MGIT 960 . Diagn Microbiol Infect Dis . 2017 ; 87 : 108 - 11 . . The critical concentrations of drugs in the medium were as follows: STR 1 µg/mL, INH 0.1 µg/mL, RMP 1 µg/mL, and EMB 5 µg/mL according to WHO guidelines ⁹9. World Health Organization . Guidelines for surveillance of drug resistance in tuberculosis . 5th ed. Geneva : WHO ; 2015 . [ cited 2019 Apr 22 ]. Available from: https://www.who.int/tb/publications/2015/drs_guidelines/en/
https://www.who.int/tb/publications/2015... . Samples were incubated until they became positive or for a maximum of 42 days to deliver a negative result. For DNA extraction, samples considered positive were removed from the equipment, and sub-cultured in Löwenstein-Jensen medium. The sub-cultures were incubated for up to 20 days at 37 °C to evaluate possible contaminants. DNA extraction was performed as described earlier ¹²12. van Helden PD , Victor TC , Warren RM , van Helden EG . Isolation of DNA from Mycobacterium tuberculosis . In: Parish T , Stoker NG , editors . Mycobacterium tuberculosis protocols . Totowa : Humana ; 2001 . p. 19 - 30 . .

The multiplex allele-specific (MAS)-PCR protocol and primer sequences for the katG315 , inhA -15 ( inhA promoter), rrs A1401G, rpoB codons 516, 526 and 531 as well as gyrA D94G were used as described previously ¹³13. Siu GK , Tam YH , Ho PL , Lee AS , Que TL , Tse CW , et al . Direct detection of isoniazid-resistant Mycobacterium tuberculosis in respiratory specimens by multiplex allele-specific polymerase chain reaction . Diagn Microbiol Infect Dis . 2011 ; 69 : 51 - 8 .

14. Kumari R , Banerjee T , Anupurba S . Molecular detection of drug resistance to ofloxacin and kanamycin in Mycobacterium tuberculosis by using multiplex allele-specific PCR . J Infect Public Health . 2018 ; 11 : 54 - 8 .

15. Yang Z , Durmaz R , Yang D , Gunal S , Zhang L , Foxman B , et al . Simultaneous detection of isoniazid, rifampin, and ethambutol resistance of Mycobacterium tuberculosis by a single multiplex allele-specific polymerase chain reaction (PCR) assay . Diagn Microbiol Infect Dis . 2005 ; 53 : 201 - 8 . - ¹⁶16. Vadwai V , Shetty A , Rodrigues C . Multiplex allele specific PCR for rapid detection of extensively drug resistant tuberculosis . Tuberculosis ( Edinb ). 2012 ; 92 : 236 - 42 . . Each assay, for each of the genes involved three primers: an external forward primer, an external reverse primer and an allele-specific internal reverse primer, with the exception of the protocol described for the simultaneous analysis of rpoB codons 516, 526 and 531, which used a set of four primers. All allele-specific primers target the reference strain M . tuberculosis H37Rv allele. After amplification, PCR products were electrophoresed in 3% agarose gels in Tris-borate EDTA buffer at 120 V for 40 min, and visualized under ultraviolet light.

The oligonucleotides for Sanger sequencing were designed by the authors using the Primer3Plus program based on the genomic region of M . tuberculosis H37Rv, deposited in GenBank (NCBI: txid83332) ¹⁷17. Ye J , Coulouris G , Zaretskaya I , Cutcutache I , Rozen S , Madden TL . Primer-BLAST: a tool to design target-specific primers for polymerase chain reaction . BMC Bioinformatics . 2012 ; 13 : 134 . . Table 1 shows the primer sequences used for amplification in each of the five sequencing assays. PCR products were purified using a BigDye Xterminator Purification Kit (Applied Biosystems, Thermo Fisher Scientific, Waltham, MA, USA) before sequencing in an Applied Biosystems DNA Sequencer. Sequences were analyzed using SecScape software v.2.7 (Applied Biosystems) and the BioEdit Sequence Alignment Editor version 7.2.5 (BioEdit, Carlsbad, CA, USA). M. tuberculosis strain H37Rv sequence was used as to prototype to align and analyze the obtained sequences.

Thumbnail

Table 1
Primer sequences used in individual sequencing assays, melting temperature and molecular weight of products.

The addresses of all the participants were geo-referenced using MyGeoPosition.com ¹⁸18. MyGeoPosition.com . [ cited 2019 Jul 20 ]. Available from: http://en.mygeoposition.com/
http://en.mygeoposition.com/... . The coordinates were entered into a Microsoft Excel 2013 datasheet and transferred to the ArcGIS 9.3 program (Environmental Systems Research Institute, Redlands, CA, USA) for mapping and illustration of case contact networks. The ArcMap application provided information on maps showing the distribution of geo-referenced cases in Fortaleza according to drug resistance. We used a search radius of 10 km and grid size of 2.5 km.

A bivariate analysis was performed for all the variables of interest, for the cases and controls. SSPS v10.0 and Epi-info v6.04d were used for analyses. The chi-squared test was used to compare the proportions and differences, which were considered significant at p ≤ 0.05. The Student’s t test was used to compare the averages of continuous variables. The Mann-Whitney U test was used to compare data with high asymmetry.

RESULTS

The average age of the participants in this study was 40.5 years (the participants in the control group were younger), and almost half of the participants had not been previously treated for TB (56/110 or 50.9%). Table 2 presents a descriptive statistical analysis of the main characteristics of the participants. Diabetes ( p < 0.01; odds ratio [OR], 7.4; 95% confidence interval [CI], 2.4-22.4), history of previous disease ( p < 0.01; OR, 6.2; 95% CI, 2.6-14.8), and a high number of intra-domiciliary contacts ( p < 0.01; OR, 3.1; 95% CI, 1.4-6.8) were the most frequent variables in the case group. Female gender was also more frequent among the cases (51.2%; p = 0.03). There were no differences between cases and controls considering age, occupation, schooling, alcohol consumption, use of illicit drugs, psychiatric disorder and chronic obstructive pulmonary disease.

Thumbnail

Table 2
Demographic and clinical characteristics of the study participants in the city of Fortaleza, from March 2017 to February 2018.

From the total of 41 isolates included in the study, 12 (29.3%) were resistant to only one drug, 14 (34.1%) were resistant to two drugs and 15 (36.6%) were resistant to three or more drugs. Simultaneous resistance to RMP and INH and to all first-line tested drugs (RMP, INH, EMB, and STR) were the most frequent (26.8% and 24.4%, respectively).

The frequencies of mutations detected by sequencing of genes related to INH, RMP, STR, and fluoroquinolone (FQ) resistance are shown in Table 3 . In relation to INH, eight C→T mutations (21.6%, 8/37) were found at position 15 of the inhA promoter region in the resistant profile samples in the BACTEC system, and six were positive in MAS-PCR. Regarding the gene katG , the presence of an S315T mutation was found in 31 isolates (75.6%). Three isolates with an S315T mutation presented a susceptible profile in BACTEC system, and 27 of the isolates with the same mutation were positive in MAS-PCR.

Thumbnail

Table 3
Mutations observed in inhA -15, rpoB , katG , rrs and gyrA genes, phenotypic resistance and MAS-PCR positivity in 41 resistant isolates of M. tuberculosis.

Mutations in the RDR were found in 35 isolates, of which 4 (9.7%) had a susceptible profile in the BACTEC system and 18 (43.9%) were positive in MAS-PCR. The most frequent mutation was at codon 531 in 17 isolates (48.9%), followed by codon 516 in 15 isolates (42.8%) with mutations at gAc→gTc (53.4%) and Gac→Tac (46.6%). Mutations in codon 531 were found in two isolates with susceptible phenotypes.

No mutations were found at positions 1009 and 1787 of the rrs gene, and no mutations were detected in the samples analyzed by MAS-PCR. However, 43.9% (18/41) of these isolates were resistant to STR in the BACTEC system. Regarding FQ, mutations associated with a resistant phenotype were found in all the samples. Mutations were detected at codons 89 (D89A), 90 (A90E and A90V), 94 (D94G and D94N) and 95 (S95T). Mutations in codon 95 were the most frequent (29/41; 70.7%), followed by codon 90 (10/41; 24.4%), codon 94 (6/41; 14.6%) and codon 89 (1/41; 2.4%). MAS-PCR was positive in four of the six isolates with mutation in codon 94.

A total of 41 samples were analyzed for RMP and INH resistance in the BACTEC system and MAS-PCR ( Table 4 ). Twenty-eight isolates (75.6%) showed resistance to RMP and were positive in MAS-PCR ( p < 0.03). Of 41 samples subjected to rpoB gene sequencing, 94.3% (33/35) were resistant according to the BACTEC system and were positive by sequencing ( p = 1.0). In relation to INH, we verified that 97.3% (36/37) of the clinical isolates presented resistance in the BACTEC system and were positive in MAS-PCR ( p < 0.56) corresponding to a sensitivity of 97.3%. In addition, we verified that 88.9% (32/36) of the samples were positive in the BACTEC system and by sequencing ( p = 0.71).

Thumbnail

Table 4
Contingency analysis between BACTEC MGIT 960 positivity, MAS-PCR assay and genetic sequencing.

Forty-three of the isolates were from participants living in Fortaleza city; the remaining (n = 6) were from the countryside of Ceara State. The spatial analysis ( Figure 1 ) showed that DR-TB cases were spread throughout the city, predominantly in the Western region. Most of the cases were located within administrative regions 1, 5, and 6, with 11, 10, and 9 participants with DR-TB, respectively. The other administrative regions (2, 3, and 4) had a total of eight DR-TB cases.

Figure 1
- Geographic distribution of the drug-resistant tuberculosis isolates in the city of Fortaleza, from March 2017 to February 2018. (

) resistance to ≥ 3 anti-TB drugs; (•) resistance to ≤ 2 anti-TB drugs.

DISCUSSION

This study showed that most of the drug-resistant participants have not been previously treated (75.6%), and all the isolates presented mutation in the gyrA gene. The frequency of primary resistance was high in relation to that found in Brazil, in Ethiopia and Serbia ¹⁹19. Luiz RS , Suffys P , Barroso EC , Kerr LR , Duarte CR , Freitas MV , et al . Genotyping and drug resistance patterns of Mycobacterium tuberculosis strains observed in a tuberculosis high-burden municipality in Northeast, Brazil . Braz J Infect Dis . 2013 ; 17 : 338 - 45 .

20. Hamusse SD , Teshome D , Hussen MS , Demissie M , Lindtjorn B . Primary and secondary anti-tuberculosis drug resistance in Hitossa District of Arsi Zone, Oromia Regional State, Central Ethiopia . BMC Public Health . 2016 ; 16 : 593 . - ²¹21. Stosic M , Vukovic D , Babic D , Antonijevic G , Foley KL , Vujcic I , et al . Risk factors for multidrug-resistant tuberculosis among tuberculosis patients in Serbia: a case-control study . BMC Public Health . 2018 ; 18 : 1114 . and lower than the one found in Bangladesh ²²22. Rifat M , Milton AH , Hall J , Oldmeadow C , Islam MA , Husain A , et al . Development of multidrug resistant tuberculosis in Bangladesh: a case-control study on risk factors . PloS One . 2014 ; 9 : e105214 . . The cases of DR-TB were spread throughout the city, raising concern about the increase in the number of cases bearing primary resistant M. tuberculosis .

Regarding the number of intra-domiciliary contacts, drug resistance was more frequent among those who reported having four or more intra-domiciliary contacts. It has already been reported in Amazonas State, Brazil, that DR-TB patients have an average of five family contacts ²³23. Silva Garrido M , Ramasawmy R , Perez-Porcuna T , Zaranza E , Chrusciak Talhari A , Martinez-Espinosa F , et al . Primary drug resistance among pulmonary treatment-naïve tuberculosis patients in Amazonas State, Brazil . Int J Tuberc Lung Dis . 2014 ; 18 : 559 - 63 . . However, a cohort study conducted in 2015 in Lima, Peru, found that crowding was associated with a greater incidence of secondary cases of TB disease among household contacts of drug-susceptible TB patients ²⁴24. Grandjean L , Gilman RH , Martin L , Soto E , Castro B , Lopez S , et al . Transmission of multidrug-resistant and drug-susceptible tuberculosis within households: a prospective cohort study . PLoS Med . 2015 ; 12 : e1001843 . . We have found that women are at a higher risk of resistance than men. A study conducted in Sokobanja, Serbia, found no differences in gender between TB-susceptible and DR-TB ²¹21. Stosic M , Vukovic D , Babic D , Antonijevic G , Foley KL , Vujcic I , et al . Risk factors for multidrug-resistant tuberculosis among tuberculosis patients in Serbia: a case-control study . BMC Public Health . 2018 ; 18 : 1114 . , whereas others found that males were at higher risk ²⁵25. Barroso EC , Mota RM , Santos RO , Sousa AL , Barroso JB , Rodrigues JL . Risk factors for acquired multidrug-resistant tuberculosis . J Pneumol . 2003 ; 29 : 89 - 97 . , ²⁶26. Ferreira KR , Cavalcante EG , De-La-Torre-Ugarte-Guanilo MC , Berti RA , Bertolozzi MR . Portadores de tuberculose multirresistente em um centro de referência: perfil sócio-demográfico e clínico-epidemiológico . Rev Esc Enferm USP . 2011 ; 45 N. Esp : 1685 - 9 . .

We found that diabetes was a comorbidity associated with resistance to anti-TB drugs. Data point out to the impact of diabetes on the immune system, favoring the bacillus survival ²⁷27. Vance J , Santos A , Sadofsky L , Morice A , Cervantes J . Effect of high glucose on human alveolar macrophage phenotype and phagocytosis of mycobacteria . Lung . 2019 ; 197 : 89 - 94 . . Diabetes causes increased susceptibility to TB through several mechanisms, including hyperglycemia and cellular insulinopenia, which have indirect effects on macrophage and lymphocyte function ²⁷27. Vance J , Santos A , Sadofsky L , Morice A , Cervantes J . Effect of high glucose on human alveolar macrophage phenotype and phagocytosis of mycobacteria . Lung . 2019 ; 197 : 89 - 94 . , ²⁸28. Silva DR , Muñoz-Torrico M , Duarte R , Galvão T , Bonini EH , Arbex FF , et al . Risk factors for tuberculosis: diabetes, smoking, alcohol use, and the use of other drugs . J Bras Pneumol . 2018 ; 44 : 145 - 52 . . Diabetes is associated with delays in Mycobacterium TB clearance during treatment, treatment failures, death, relapse and re-infection. Similar to other studies ²²22. Rifat M , Milton AH , Hall J , Oldmeadow C , Islam MA , Husain A , et al . Development of multidrug resistant tuberculosis in Bangladesh: a case-control study on risk factors . PloS One . 2014 ; 9 : e105214 . , ²⁹29. Sharma P , Lalwani J , Pandey P , Thakur A . Factors associated with the development of secondary multidrug-resistant tuberculosis . Int J Prev Med . 2019 ; 10 : 67 . , we have found a 7.4 times higher risk of MDR-TB among diabetic patients with TB.

Mutations in the gyrA gene were also found in all the 41 samples, constituting the main mechanism of resistance to FQ, with specific mutations at codons 89, 90, 94 and 95. The identification of mutations in molecular markers of resistance characterizes these isolates as XDR-TB, with resistance to RMP, INH and at least one FQ drug or a second-line injectable drug ³⁰30. Chen J , Peng P , Du Y , Ren Y , Chen L , Rao Y , et al . Early detection of multidrug- and pre-extensively drug-resistant tuberculosis from smear-positive sputum by direct sequencing . BMC Infect Dis . 2017 ; 17 : 300 . . Mutation at the S95T position of the gyrA gene was the most frequent mutation in our samples, followed by the A90V mutation. Other studies in China and the United States have reported the D94G codon mutation as the most common, ranging from 17.8% to 47.6% ³¹31. Avalos E , Catanzaro D , Catanzaro A , Ganiats T , Brodine S , Alcaraz J , et al . Frequency and geographic distribution of gyrA and gyrB mutations associated with fluoroquinolone resistance in clinical Mycobacterium tuberculosis isolates: a systematic review . PloS One . 2015 ; 10 : e0120470 .

32. Lau RW , Ho PL , Kao RY , Yew WW , Lau TC , Cheng VC , et al . Molecular characterization of fluoroquinolone resistance in Mycobacterium tuberculosis: functional analysis of gyrA mutation at position 74 . Antimicrob Agents Chemother . 2011 ; 55 : 608 - 14 . - ³³33. Farhat MR , Jacobson KR , Franke MF , Kaur D , Sloutsky A , Mitnick CD , et al . Gyrase mutations are associated with variable levels of fluoroquinolone resistance in mycobacterium tuberculosis . J Clin Microbiol . 2016 ; 54 : 727 - 33 . . Mutations in A90E and S95T codons are not associated with resistance to FQs ³³33. Farhat MR , Jacobson KR , Franke MF , Kaur D , Sloutsky A , Mitnick CD , et al . Gyrase mutations are associated with variable levels of fluoroquinolone resistance in mycobacterium tuberculosis . J Clin Microbiol . 2016 ; 54 : 727 - 33 . . The S95T mutation has been described as a natural polymorphism (G284C). Identification of mutation in the gyrA gene is relevant for establishing FQ therapy, as specific mutations differ with respect to the minimal inhibitory concentration of ofloxacin and moxifloxacin ³³33. Farhat MR , Jacobson KR , Franke MF , Kaur D , Sloutsky A , Mitnick CD , et al . Gyrase mutations are associated with variable levels of fluoroquinolone resistance in mycobacterium tuberculosis . J Clin Microbiol . 2016 ; 54 : 727 - 33 . .

Regarding aminoglycosides, no mutations were found at codon 1401 of the rrs gene with 43.9% of isolates resistant to STR in the BACTEC system. However, mutations have also been described in other genes, such as rpsL and gidB ⁷7. Zhang Y , Yew WW . Mechanisms of drug resistance in Mycobacterium tuberculosis: update 2015 . Int J Tuberc Lung Dis . 2015 ; 19 : 1276 - 89 . , and other genes related to efflux pumps ³⁴34. Cloete R , Kapp E , Joubert J , Christoffels A , Malan SF . Molecular modelling and simulation studies of the Mycobacterium tuberculosis multidrug efflux pump protein Rv1258c . PloS One . 2018 ; 13 : e0207605 . .

Our sequencing results showed that the resistant phenotype for INH and RMP obtained by the BACTEC system could be accurately predicted. These findings are useful for estimating the sensitivity of sequencing, as well as of MAS-PCR, compared with the phenotypic test used in the BACTEC automated system, still considered the gold standard. However, as phenotypic tests of FQ resistance in Ceara State are not available, only the sensitivity values related to INH and RMP were calculated. Differences between phenotypic test results and molecular tests are explained by the presence of different mutations in uninvestigated genomic regions. Therefore, all discordant data were re-tested and sequencing data were reviewed. Other studies have also reported these disagreements between the phenotypic test (gold standard) and the molecular ones and have reinforced that phenotypic data should be interpreted cautiously in cases of therapeutic failure ⁸8. Miotto P , Tessema B , Tagliani E , Chindelevitch L , Starks AM , Emerson C , et al . A standardised method for interpreting the association between mutations and phenotypic drug resistance in Mycobacterium tuberculosis . Eur Respir J . 2017 ; 50 : 1701354 . , ³⁵35. Zignol M , Cabibbe AM , Dean AS , Glaziou P , Alikhanova N , Ama C , et al . Genetic sequencing for surveillance of drug resistance in tuberculosis in highly endemic countries: a multi-country population-based surveillance study . Lancet Infect Dis . 2018 ; 18 : 675 - 83 . .

In our study, MAS-PCR had a sensitivity of 75.7% and 97.3% to detect mutations in isolates with resistance phenotype to RMP and INH, respectively. The approach is cost-effective and is a sensitive PCR-based technique to identify main mutations. However, it fails to detect mutations outside the RDR in rpoB gene and in other genes related to drug resistance. Sensitivity can be maximized by exploring the other possible targets associated with resistance. Although sequencing is a costly and laborious process to confirm results, it can be used to diagnose drug-resistant isolates with high specificity and efficiency. Sequencing can also identify silent mutations that are not always related to phenotypic resistance.

Several limitations of this study should be considered in the interpretation of results. Firstly, only the Sanger sequencing platform was used, which has low genomic coverage. Secondly, the EMB-related gene ( embB ) and other alternative genes related to aminoglycoside, INH and FQ resistance were not investigated. As resistance to EMB is often associated with MDR and XDR resistance, these mutations were not investigated. In our study, 11 cases of DR-TB were resistant to EMB, and ten isolates had simultaneous resistance to INH, RIF and STR, and one isolate to INH. Thirdly, the number of patients studied was restrict to allow conclusive evidence regarding the sensitivity of the tests. In addition, in our study, the patients were recruited from only one hospital in Fortaleza that is a reference hospital for DR-TB treatment. Despite these limitations, the risk factors associated with DR-TB provide important information for health policy makers, and the molecular diagnosis has proved to be important for monitoring resistance in TB, especially in the detection of mutations considered as resistance markers.

Regarding the distribution of DR-TB cases, the concentration of participants domiciled in the Western part of city, in administrative regions 1, 5, and 6, is explained by the higher population density in these regions where poverty is common. Regions 1, 5, and 6 have the lowest average monthly income per person (from USD 121.98 to USD 178.8) in Fortaleza ³⁶36. Menezes AS , Medeiros CN , organizadores . Perfil socioeconômico de Fortaleza . 2ª ed. Fortaleza : Governo do Estado do Ceará ; 2012 . [ cited 2019 Jul 20 ]. Available from: https://www.ipece.ce.gov.br/wp-content/uploads/sites/45/2015/02/Perfil-Socioeconomico-Fortaleza-final-email.pdf
https://www.ipece.ce.gov.br/wp-content/u... . The richest neighborhoods in the city have average monthly incomes between USD 520.51 and USD 952.41. These poor regions in the city have also a high incidence of violence ³⁷37. Oliveira VH , Medeiros CN , Carvalho JR . Violence and local development in Fortaleza, Brazil: a spatial regression analysis . Appl Spat Anal Policy . 2019 ; 12 : 147 - 66 . . Fortaleza had an average incidence of 69.4 violent crimes per 100,000 inhabitants in 2015. The high rate of violent crime was associated with low economic development, limited population’s access to infrastructure and health services ³⁷37. Oliveira VH , Medeiros CN , Carvalho JR . Violence and local development in Fortaleza, Brazil: a spatial regression analysis . Appl Spat Anal Policy . 2019 ; 12 : 147 - 66 . . Another study, also conducted in Fortaleza, reported a concentration of TB cases in insecure regions with low socioeconomic status ³⁸38. Harling G , Lima Neto AS , Sousa GS , Machado MM , Castro MC . Determinants of tuberculosis transmission and treatment abandonment in Fortaleza, Brazil . BMC Public Health . 2017 ; 17 : 508 . . Other studies conducted in Brazil have also associated a low Human Development Index with TB cases ³⁹39. Vieira RC , Prado TN , Siqueira MG , Dietze R , Maciel EL . Distribuição espacial dos casos novos de tuberculose em Vitória, Estado do Espírito Santo, no período entre 2000 e 2005 . Rev Soc Bras Med Trop . 2008 ; 41 : 82 - 6 . , ⁴⁰40. Hino P , Villa TC , Cunha TN , Santos CB . Distribuição espacial de doenças endêmicas no município de Ribeirão Preto (SP) . Cien Saude Coletiva . 2011 ; 16 Suppl 1 : 1289 - 94 . .

CONCLUSION

Our study showed a high prevalence of pre-XDR-TB in patients with no history of previous treatment in Fortaleza, presenting simultaneous resistance to various drugs. We have also shown the presence of pre-XDR-TB in geographic regions of the city that are associated with poverty and violence. We found that genetic sequencing is a useful tool for anti-TB drug-resistance surveillance, and molecular data should be routinely shared with public health agencies and used in conjunction with spatial analyses for the effective disease transmission control.

ACKNOWLEDGMENTS

We thank the Fortaleza municipal health secretariat for providing access to the data used in this study and the support of the staff of Hospital de Messejana Dr. Carlos Alberto Studart Gomes, Fortaleza, CE, Brazil.

REFERENCES

¹
World Health Organization . Global tuberculosis report 2019 . Geneva : WHO ; 2019 . [ cited 2019 Apr 22 ]. Available from: http://www.who.int/tb/publications/global_report/en/
» http://www.who.int/tb/publications/global_report/en/
²
Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Brasil livre da tuberculose: evolução dos cenários epidemiológicos e operacionais da doença . Bol Epidemiol . 2019 ; 50 : 1 - 18 . [ cited 2019 Apr 22 ]. Available from: http://portalms.saude.gov.br/images/pdf/2019/marco/22/2019-009.pdf
» http://portalms.saude.gov.br/images/pdf/2019/marco/22/2019-009.pdf
³
Ceará . Secretaria de Saúde . Boletim epidemiológico tuberculose . [ cited 2019 Apr 19 ]. Available from: https: file:///C:/Users/biblioteca/Downloads/boletim_tuberculose_21_03_2019.pdf
» https: file:///C:/Users/biblioteca/Downloads/boletim_tuberculose_21_03_2019.pdf
⁴
Instituto Brasileiro de Geografia e Estatística . Brasil/Ceará/Fortaleza: panorama . [ cited 2019 Apr 22 ]. Available from: https://cidades.ibge.gov.br/brasil/ce/fortaleza/panorama
» https://cidades.ibge.gov.br/brasil/ce/fortaleza/panorama
⁵
Programa das Nações Unidas para o Desenvolvimento . Atlas de desenvolvimento humano do Brasil: Fortaleza, CE . [ cited 2019 Apr 22 ]. Available from: http://atlasbrasil.org.br/2013/pt/perfil_m/fortaleza_ce
» http://atlasbrasil.org.br/2013/pt/perfil_m/fortaleza_ce
⁶
Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Departamento de Vigilância das Doenças Transmissíveis . Brasil livre da tuberculose: plano nacional pelo fim da tuberculose como problema de saúde pública . Brasília : Ministério da Saúde ; 2017 . [ cited 2019 Nov 6 ]. Available from: http://bvsms.saude.gov.br/bvs/publicacoes/brasil_livre_tuberculose_plano_nacional.pdf
» http://bvsms.saude.gov.br/bvs/publicacoes/brasil_livre_tuberculose_plano_nacional.pdf
⁷
Zhang Y , Yew WW . Mechanisms of drug resistance in Mycobacterium tuberculosis: update 2015 . Int J Tuberc Lung Dis . 2015 ; 19 : 1276 - 89 .
⁸
Miotto P , Tessema B , Tagliani E , Chindelevitch L , Starks AM , Emerson C , et al . A standardised method for interpreting the association between mutations and phenotypic drug resistance in Mycobacterium tuberculosis . Eur Respir J . 2017 ; 50 : 1701354 .
⁹
World Health Organization . Guidelines for surveillance of drug resistance in tuberculosis . 5th ed. Geneva : WHO ; 2015 . [ cited 2019 Apr 22 ]. Available from: https://www.who.int/tb/publications/2015/drs_guidelines/en/
» https://www.who.int/tb/publications/2015/drs_guidelines/en/
¹⁰
Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Departamento de Vigilância das Doenças Transmissíveis . Manual de recomendações para o controle da tuberculose no Brasil . 2ª ed atual. Brasil : Ministério da Saúde ; 2019 . [ cited 2019 Nov 6 ]. Available from: http://bvsms.saude.gov.br/bvs/publicacoes/manual_recomendacoes_controle_tuberculose_brasil_2_ed.pdf
» http://bvsms.saude.gov.br/bvs/publicacoes/manual_recomendacoes_controle_tuberculose_brasil_2_ed.pdf
¹¹
Adami AG , Gallo JF , Pinhata JM , Martins MC , Giampaglia CM , Oliveira RS . Modified protocol for drug susceptibility testing of MGIT cultures of Mycobacterium tuberculosis by the MGIT 960 . Diagn Microbiol Infect Dis . 2017 ; 87 : 108 - 11 .
¹²
van Helden PD , Victor TC , Warren RM , van Helden EG . Isolation of DNA from Mycobacterium tuberculosis . In: Parish T , Stoker NG , editors . Mycobacterium tuberculosis protocols . Totowa : Humana ; 2001 . p. 19 - 30 .
¹³
Siu GK , Tam YH , Ho PL , Lee AS , Que TL , Tse CW , et al . Direct detection of isoniazid-resistant Mycobacterium tuberculosis in respiratory specimens by multiplex allele-specific polymerase chain reaction . Diagn Microbiol Infect Dis . 2011 ; 69 : 51 - 8 .
¹⁴
Kumari R , Banerjee T , Anupurba S . Molecular detection of drug resistance to ofloxacin and kanamycin in Mycobacterium tuberculosis by using multiplex allele-specific PCR . J Infect Public Health . 2018 ; 11 : 54 - 8 .
¹⁵
Yang Z , Durmaz R , Yang D , Gunal S , Zhang L , Foxman B , et al . Simultaneous detection of isoniazid, rifampin, and ethambutol resistance of Mycobacterium tuberculosis by a single multiplex allele-specific polymerase chain reaction (PCR) assay . Diagn Microbiol Infect Dis . 2005 ; 53 : 201 - 8 .
¹⁶
Vadwai V , Shetty A , Rodrigues C . Multiplex allele specific PCR for rapid detection of extensively drug resistant tuberculosis . Tuberculosis ( Edinb ). 2012 ; 92 : 236 - 42 .
¹⁷
Ye J , Coulouris G , Zaretskaya I , Cutcutache I , Rozen S , Madden TL . Primer-BLAST: a tool to design target-specific primers for polymerase chain reaction . BMC Bioinformatics . 2012 ; 13 : 134 .
¹⁸
MyGeoPosition.com . [ cited 2019 Jul 20 ]. Available from: http://en.mygeoposition.com/
» http://en.mygeoposition.com/
¹⁹
Luiz RS , Suffys P , Barroso EC , Kerr LR , Duarte CR , Freitas MV , et al . Genotyping and drug resistance patterns of Mycobacterium tuberculosis strains observed in a tuberculosis high-burden municipality in Northeast, Brazil . Braz J Infect Dis . 2013 ; 17 : 338 - 45 .
²⁰
Hamusse SD , Teshome D , Hussen MS , Demissie M , Lindtjorn B . Primary and secondary anti-tuberculosis drug resistance in Hitossa District of Arsi Zone, Oromia Regional State, Central Ethiopia . BMC Public Health . 2016 ; 16 : 593 .
²¹
Stosic M , Vukovic D , Babic D , Antonijevic G , Foley KL , Vujcic I , et al . Risk factors for multidrug-resistant tuberculosis among tuberculosis patients in Serbia: a case-control study . BMC Public Health . 2018 ; 18 : 1114 .
²²
Rifat M , Milton AH , Hall J , Oldmeadow C , Islam MA , Husain A , et al . Development of multidrug resistant tuberculosis in Bangladesh: a case-control study on risk factors . PloS One . 2014 ; 9 : e105214 .
²³
Silva Garrido M , Ramasawmy R , Perez-Porcuna T , Zaranza E , Chrusciak Talhari A , Martinez-Espinosa F , et al . Primary drug resistance among pulmonary treatment-naïve tuberculosis patients in Amazonas State, Brazil . Int J Tuberc Lung Dis . 2014 ; 18 : 559 - 63 .
²⁴
Grandjean L , Gilman RH , Martin L , Soto E , Castro B , Lopez S , et al . Transmission of multidrug-resistant and drug-susceptible tuberculosis within households: a prospective cohort study . PLoS Med . 2015 ; 12 : e1001843 .
²⁵
Barroso EC , Mota RM , Santos RO , Sousa AL , Barroso JB , Rodrigues JL . Risk factors for acquired multidrug-resistant tuberculosis . J Pneumol . 2003 ; 29 : 89 - 97 .
²⁶
Ferreira KR , Cavalcante EG , De-La-Torre-Ugarte-Guanilo MC , Berti RA , Bertolozzi MR . Portadores de tuberculose multirresistente em um centro de referência: perfil sócio-demográfico e clínico-epidemiológico . Rev Esc Enferm USP . 2011 ; 45 N. Esp : 1685 - 9 .
²⁷
Vance J , Santos A , Sadofsky L , Morice A , Cervantes J . Effect of high glucose on human alveolar macrophage phenotype and phagocytosis of mycobacteria . Lung . 2019 ; 197 : 89 - 94 .
²⁸
Silva DR , Muñoz-Torrico M , Duarte R , Galvão T , Bonini EH , Arbex FF , et al . Risk factors for tuberculosis: diabetes, smoking, alcohol use, and the use of other drugs . J Bras Pneumol . 2018 ; 44 : 145 - 52 .
²⁹
Sharma P , Lalwani J , Pandey P , Thakur A . Factors associated with the development of secondary multidrug-resistant tuberculosis . Int J Prev Med . 2019 ; 10 : 67 .
³⁰
Chen J , Peng P , Du Y , Ren Y , Chen L , Rao Y , et al . Early detection of multidrug- and pre-extensively drug-resistant tuberculosis from smear-positive sputum by direct sequencing . BMC Infect Dis . 2017 ; 17 : 300 .
³¹
Avalos E , Catanzaro D , Catanzaro A , Ganiats T , Brodine S , Alcaraz J , et al . Frequency and geographic distribution of gyrA and gyrB mutations associated with fluoroquinolone resistance in clinical Mycobacterium tuberculosis isolates: a systematic review . PloS One . 2015 ; 10 : e0120470 .
³²
Lau RW , Ho PL , Kao RY , Yew WW , Lau TC , Cheng VC , et al . Molecular characterization of fluoroquinolone resistance in Mycobacterium tuberculosis: functional analysis of gyrA mutation at position 74 . Antimicrob Agents Chemother . 2011 ; 55 : 608 - 14 .
³³
Farhat MR , Jacobson KR , Franke MF , Kaur D , Sloutsky A , Mitnick CD , et al . Gyrase mutations are associated with variable levels of fluoroquinolone resistance in mycobacterium tuberculosis . J Clin Microbiol . 2016 ; 54 : 727 - 33 .
³⁴
Cloete R , Kapp E , Joubert J , Christoffels A , Malan SF . Molecular modelling and simulation studies of the Mycobacterium tuberculosis multidrug efflux pump protein Rv1258c . PloS One . 2018 ; 13 : e0207605 .
³⁵
Zignol M , Cabibbe AM , Dean AS , Glaziou P , Alikhanova N , Ama C , et al . Genetic sequencing for surveillance of drug resistance in tuberculosis in highly endemic countries: a multi-country population-based surveillance study . Lancet Infect Dis . 2018 ; 18 : 675 - 83 .
³⁶
Menezes AS , Medeiros CN , organizadores . Perfil socioeconômico de Fortaleza . 2ª ed. Fortaleza : Governo do Estado do Ceará ; 2012 . [ cited 2019 Jul 20 ]. Available from: https://www.ipece.ce.gov.br/wp-content/uploads/sites/45/2015/02/Perfil-Socioeconomico-Fortaleza-final-email.pdf
» https://www.ipece.ce.gov.br/wp-content/uploads/sites/45/2015/02/Perfil-Socioeconomico-Fortaleza-final-email.pdf
³⁷
Oliveira VH , Medeiros CN , Carvalho JR . Violence and local development in Fortaleza, Brazil: a spatial regression analysis . Appl Spat Anal Policy . 2019 ; 12 : 147 - 66 .
³⁸
Harling G , Lima Neto AS , Sousa GS , Machado MM , Castro MC . Determinants of tuberculosis transmission and treatment abandonment in Fortaleza, Brazil . BMC Public Health . 2017 ; 17 : 508 .
³⁹
Vieira RC , Prado TN , Siqueira MG , Dietze R , Maciel EL . Distribuição espacial dos casos novos de tuberculose em Vitória, Estado do Espírito Santo, no período entre 2000 e 2005 . Rev Soc Bras Med Trop . 2008 ; 41 : 82 - 6 .
⁴⁰
Hino P , Villa TC , Cunha TN , Santos CB . Distribuição espacial de doenças endêmicas no município de Ribeirão Preto (SP) . Cien Saude Coletiva . 2011 ; 16 Suppl 1 : 1289 - 94 .

FUNDING

This work was supported by Fundação Cearense de Apoio ao Desenvolvimento Científico e Tecnológico - FUNCAP (grant Nº 178638234); and the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001.

Publication Dates

Publication in this collection
07 Feb 2020
Date of issue
2020

History

Received
13 June 2019
Accepted
14 Oct 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
World Health Organization . Global tuberculosis report 2019 . Geneva : WHO ; 2019 . [ cited 2019 Apr 22 ]. Available from: http://www.who.int/tb/publications/global_report/en/
» http://www.who.int/tb/publications/global_report/en/

[2] ²
Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Brasil livre da tuberculose: evolução dos cenários epidemiológicos e operacionais da doença . Bol Epidemiol . 2019 ; 50 : 1 - 18 . [ cited 2019 Apr 22 ]. Available from: http://portalms.saude.gov.br/images/pdf/2019/marco/22/2019-009.pdf
» http://portalms.saude.gov.br/images/pdf/2019/marco/22/2019-009.pdf

[3] ³
Ceará . Secretaria de Saúde . Boletim epidemiológico tuberculose . [ cited 2019 Apr 19 ]. Available from: https: file:///C:/Users/biblioteca/Downloads/boletim_tuberculose_21_03_2019.pdf
» https: file:///C:/Users/biblioteca/Downloads/boletim_tuberculose_21_03_2019.pdf

[4] ⁴
Instituto Brasileiro de Geografia e Estatística . Brasil/Ceará/Fortaleza: panorama . [ cited 2019 Apr 22 ]. Available from: https://cidades.ibge.gov.br/brasil/ce/fortaleza/panorama
» https://cidades.ibge.gov.br/brasil/ce/fortaleza/panorama

[5] ⁵
Programa das Nações Unidas para o Desenvolvimento . Atlas de desenvolvimento humano do Brasil: Fortaleza, CE . [ cited 2019 Apr 22 ]. Available from: http://atlasbrasil.org.br/2013/pt/perfil_m/fortaleza_ce
» http://atlasbrasil.org.br/2013/pt/perfil_m/fortaleza_ce

[6] ⁶
Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Departamento de Vigilância das Doenças Transmissíveis . Brasil livre da tuberculose: plano nacional pelo fim da tuberculose como problema de saúde pública . Brasília : Ministério da Saúde ; 2017 . [ cited 2019 Nov 6 ]. Available from: http://bvsms.saude.gov.br/bvs/publicacoes/brasil_livre_tuberculose_plano_nacional.pdf
» http://bvsms.saude.gov.br/bvs/publicacoes/brasil_livre_tuberculose_plano_nacional.pdf

[7] ⁷
Zhang Y , Yew WW . Mechanisms of drug resistance in Mycobacterium tuberculosis: update 2015 . Int J Tuberc Lung Dis . 2015 ; 19 : 1276 - 89 .

[8] ⁸
Miotto P , Tessema B , Tagliani E , Chindelevitch L , Starks AM , Emerson C , et al . A standardised method for interpreting the association between mutations and phenotypic drug resistance in Mycobacterium tuberculosis . Eur Respir J . 2017 ; 50 : 1701354 .

[9] ⁹
World Health Organization . Guidelines for surveillance of drug resistance in tuberculosis . 5th ed. Geneva : WHO ; 2015 . [ cited 2019 Apr 22 ]. Available from: https://www.who.int/tb/publications/2015/drs_guidelines/en/
» https://www.who.int/tb/publications/2015/drs_guidelines/en/

[10] ¹⁰
Brasil . Ministério da Saúde . Secretaria de Vigilância em Saúde . Departamento de Vigilância das Doenças Transmissíveis . Manual de recomendações para o controle da tuberculose no Brasil . 2ª ed atual. Brasil : Ministério da Saúde ; 2019 . [ cited 2019 Nov 6 ]. Available from: http://bvsms.saude.gov.br/bvs/publicacoes/manual_recomendacoes_controle_tuberculose_brasil_2_ed.pdf
» http://bvsms.saude.gov.br/bvs/publicacoes/manual_recomendacoes_controle_tuberculose_brasil_2_ed.pdf

[11] ¹¹
Adami AG , Gallo JF , Pinhata JM , Martins MC , Giampaglia CM , Oliveira RS . Modified protocol for drug susceptibility testing of MGIT cultures of Mycobacterium tuberculosis by the MGIT 960 . Diagn Microbiol Infect Dis . 2017 ; 87 : 108 - 11 .

[12] ¹²
van Helden PD , Victor TC , Warren RM , van Helden EG . Isolation of DNA from Mycobacterium tuberculosis . In: Parish T , Stoker NG , editors . Mycobacterium tuberculosis protocols . Totowa : Humana ; 2001 . p. 19 - 30 .

[13] ¹³
Siu GK , Tam YH , Ho PL , Lee AS , Que TL , Tse CW , et al . Direct detection of isoniazid-resistant Mycobacterium tuberculosis in respiratory specimens by multiplex allele-specific polymerase chain reaction . Diagn Microbiol Infect Dis . 2011 ; 69 : 51 - 8 .

[14] ¹⁴
Kumari R , Banerjee T , Anupurba S . Molecular detection of drug resistance to ofloxacin and kanamycin in Mycobacterium tuberculosis by using multiplex allele-specific PCR . J Infect Public Health . 2018 ; 11 : 54 - 8 .

[15] ¹⁵
Yang Z , Durmaz R , Yang D , Gunal S , Zhang L , Foxman B , et al . Simultaneous detection of isoniazid, rifampin, and ethambutol resistance of Mycobacterium tuberculosis by a single multiplex allele-specific polymerase chain reaction (PCR) assay . Diagn Microbiol Infect Dis . 2005 ; 53 : 201 - 8 .

[16] ¹⁶
Vadwai V , Shetty A , Rodrigues C . Multiplex allele specific PCR for rapid detection of extensively drug resistant tuberculosis . Tuberculosis ( Edinb ). 2012 ; 92 : 236 - 42 .

[17] ¹⁷
Ye J , Coulouris G , Zaretskaya I , Cutcutache I , Rozen S , Madden TL . Primer-BLAST: a tool to design target-specific primers for polymerase chain reaction . BMC Bioinformatics . 2012 ; 13 : 134 .

[18] ¹⁸
MyGeoPosition.com . [ cited 2019 Jul 20 ]. Available from: http://en.mygeoposition.com/
» http://en.mygeoposition.com/

[19] ¹⁹
Luiz RS , Suffys P , Barroso EC , Kerr LR , Duarte CR , Freitas MV , et al . Genotyping and drug resistance patterns of Mycobacterium tuberculosis strains observed in a tuberculosis high-burden municipality in Northeast, Brazil . Braz J Infect Dis . 2013 ; 17 : 338 - 45 .

[20] ²⁰
Hamusse SD , Teshome D , Hussen MS , Demissie M , Lindtjorn B . Primary and secondary anti-tuberculosis drug resistance in Hitossa District of Arsi Zone, Oromia Regional State, Central Ethiopia . BMC Public Health . 2016 ; 16 : 593 .

[21] ²¹
Stosic M , Vukovic D , Babic D , Antonijevic G , Foley KL , Vujcic I , et al . Risk factors for multidrug-resistant tuberculosis among tuberculosis patients in Serbia: a case-control study . BMC Public Health . 2018 ; 18 : 1114 .

[22] ²²
Rifat M , Milton AH , Hall J , Oldmeadow C , Islam MA , Husain A , et al . Development of multidrug resistant tuberculosis in Bangladesh: a case-control study on risk factors . PloS One . 2014 ; 9 : e105214 .

[23] ²³
Silva Garrido M , Ramasawmy R , Perez-Porcuna T , Zaranza E , Chrusciak Talhari A , Martinez-Espinosa F , et al . Primary drug resistance among pulmonary treatment-naïve tuberculosis patients in Amazonas State, Brazil . Int J Tuberc Lung Dis . 2014 ; 18 : 559 - 63 .

[24] ²⁴
Grandjean L , Gilman RH , Martin L , Soto E , Castro B , Lopez S , et al . Transmission of multidrug-resistant and drug-susceptible tuberculosis within households: a prospective cohort study . PLoS Med . 2015 ; 12 : e1001843 .

[25] ²⁵
Barroso EC , Mota RM , Santos RO , Sousa AL , Barroso JB , Rodrigues JL . Risk factors for acquired multidrug-resistant tuberculosis . J Pneumol . 2003 ; 29 : 89 - 97 .

[26] ²⁶
Ferreira KR , Cavalcante EG , De-La-Torre-Ugarte-Guanilo MC , Berti RA , Bertolozzi MR . Portadores de tuberculose multirresistente em um centro de referência: perfil sócio-demográfico e clínico-epidemiológico . Rev Esc Enferm USP . 2011 ; 45 N. Esp : 1685 - 9 .

[27] ²⁷
Vance J , Santos A , Sadofsky L , Morice A , Cervantes J . Effect of high glucose on human alveolar macrophage phenotype and phagocytosis of mycobacteria . Lung . 2019 ; 197 : 89 - 94 .

[28] ²⁸
Silva DR , Muñoz-Torrico M , Duarte R , Galvão T , Bonini EH , Arbex FF , et al . Risk factors for tuberculosis: diabetes, smoking, alcohol use, and the use of other drugs . J Bras Pneumol . 2018 ; 44 : 145 - 52 .

[29] ²⁹
Sharma P , Lalwani J , Pandey P , Thakur A . Factors associated with the development of secondary multidrug-resistant tuberculosis . Int J Prev Med . 2019 ; 10 : 67 .

[30] ³⁰
Chen J , Peng P , Du Y , Ren Y , Chen L , Rao Y , et al . Early detection of multidrug- and pre-extensively drug-resistant tuberculosis from smear-positive sputum by direct sequencing . BMC Infect Dis . 2017 ; 17 : 300 .

[31] ³¹
Avalos E , Catanzaro D , Catanzaro A , Ganiats T , Brodine S , Alcaraz J , et al . Frequency and geographic distribution of gyrA and gyrB mutations associated with fluoroquinolone resistance in clinical Mycobacterium tuberculosis isolates: a systematic review . PloS One . 2015 ; 10 : e0120470 .

[32] ³²
Lau RW , Ho PL , Kao RY , Yew WW , Lau TC , Cheng VC , et al . Molecular characterization of fluoroquinolone resistance in Mycobacterium tuberculosis: functional analysis of gyrA mutation at position 74 . Antimicrob Agents Chemother . 2011 ; 55 : 608 - 14 .

[33] ³³
Farhat MR , Jacobson KR , Franke MF , Kaur D , Sloutsky A , Mitnick CD , et al . Gyrase mutations are associated with variable levels of fluoroquinolone resistance in mycobacterium tuberculosis . J Clin Microbiol . 2016 ; 54 : 727 - 33 .

[34] ³⁴
Cloete R , Kapp E , Joubert J , Christoffels A , Malan SF . Molecular modelling and simulation studies of the Mycobacterium tuberculosis multidrug efflux pump protein Rv1258c . PloS One . 2018 ; 13 : e0207605 .

[35] ³⁵
Zignol M , Cabibbe AM , Dean AS , Glaziou P , Alikhanova N , Ama C , et al . Genetic sequencing for surveillance of drug resistance in tuberculosis in highly endemic countries: a multi-country population-based surveillance study . Lancet Infect Dis . 2018 ; 18 : 675 - 83 .

[36] ³⁶
Menezes AS , Medeiros CN , organizadores . Perfil socioeconômico de Fortaleza . 2ª ed. Fortaleza : Governo do Estado do Ceará ; 2012 . [ cited 2019 Jul 20 ]. Available from: https://www.ipece.ce.gov.br/wp-content/uploads/sites/45/2015/02/Perfil-Socioeconomico-Fortaleza-final-email.pdf
» https://www.ipece.ce.gov.br/wp-content/uploads/sites/45/2015/02/Perfil-Socioeconomico-Fortaleza-final-email.pdf

[37] ³⁷
Oliveira VH , Medeiros CN , Carvalho JR . Violence and local development in Fortaleza, Brazil: a spatial regression analysis . Appl Spat Anal Policy . 2019 ; 12 : 147 - 66 .

[38] ³⁸
Harling G , Lima Neto AS , Sousa GS , Machado MM , Castro MC . Determinants of tuberculosis transmission and treatment abandonment in Fortaleza, Brazil . BMC Public Health . 2017 ; 17 : 508 .

[39] ³⁹
Vieira RC , Prado TN , Siqueira MG , Dietze R , Maciel EL . Distribuição espacial dos casos novos de tuberculose em Vitória, Estado do Espírito Santo, no período entre 2000 e 2005 . Rev Soc Bras Med Trop . 2008 ; 41 : 82 - 6 .

[40] ⁴⁰
Hino P , Villa TC , Cunha TN , Santos CB . Distribuição espacial de doenças endêmicas no município de Ribeirão Preto (SP) . Cien Saude Coletiva . 2011 ; 16 Suppl 1 : 1289 - 94 .

Primers	Sequence (5´- 3´)	Tm (°C)	Molecular weight (bp)
katG315F	GCTTCAAGACGTTCGGGTTC	59.5	840
katG315R	GGCAATCTCGGCTTCGC	60.8
-15inhAF	CGGGAAGATCCGCGTCG	60.3	806
-15inhAR	CTGCCGGAGACCGAACCT	61.3
rpoBF	GCGYCGGYCGCTATAAGGTC	60.7	818
rpoBR	CGAGACGTCCATGTAGTCCA	58.9
gyrAF	CGCAACCCTGCGTTCGAATTG	62.8	809
gyrAR	CCTCAACAACRCCGCGCAT	61
rrsF	ATAGGCGTTCCCTTGTGGC	60.1	778
rrsR	CACAAGAACACGCCACCG	60

Variables	Total N = 110 (%)	Cases N = 41 (%)	Controls N = 69 (%)	p ^a	OR (95% CI)
Age (years)
Mean (SD)	40.5 (13.4)	41 (11.2)	40 (14.7)
< 39	48 (43.6)	17 (41.5)	31 (44.9)	1
40 - 49	40 (36.4)	15 (36.6)	25 (36.2)	0.84 ^c	0.91 (0.4-2.2)
> 50	22 (20)	9 (21.9)	13 (18.8)	0.66 ^d	0.79 (0.3-2.2)
Gender
Male	68 (61.8)	20 (48.8)	48 (69.6)	0.03	0.4 (0.2-0.9)
Female	42 (38.2)	21 (51.2)	21 (30.4)		1.0
Ocuppation
Unemployed	79 (71.8)	32 (78.1)	47 (68.1)	0.26	1.7 (0.7-4.1)
Employed	31 (28.2)	9 (21.9)	22 (31.9)		1.0
Diabetes
Yes	20 (18.2)	15 (36.6)	5 (7.2)	<0.01 ^b	7.4 (2.4-22.4)
No	90 (81.8)	26 (63.4)	64 (92.8)		1
Alcohol use
Yes	63 (57.3)	24 (58.5)	39 (56.5)	0.84	1.1 (0.5-2.4)
No	47 (42.7)	17 (41.5)	30 (43.5)		1
History of previous disease
Yes	54 (49.1)	31 (75.6)	23 (33.3)	<0.01 ^b	6.2 (2.6-14.8)
No	56 (50.9)	10 (24.4)	46 (66.7)		1
Number of intradomiciliar contacts
≤ 3	69 (62.7)	19 (46.3)	50 (72.5)	<0.01	1
≥ 4	41 (37.3)	22 (53.7)	19 (27.5)		3.1 (1.4-6.8)

Drug	N (%)

	Total of Resistant samples	Total of Susceptible samples	Total of mutated samples ^a	Resistant with mutation	Susceptible with mutation	MAS-PCR ^a
INH	37 (90.1)	4 (9.9)
mabA
-15 position (C/T)			8 (19.5%)	8 (21.6%)	0	6 (14.6)
katG
codon 315
S315T (aGc/aCc)			31 (75.6)	28 (75.7)	3 (75)	27 (65.8)

RMP	37 (90.6)	4 (9.7)
rpoB			35 (85.4)			18 (43.9)
codon 516			15 (42.8)	15 (100)	0	15 (83.3)
D516Y (Gac/Tac)			7 (46.6)	7 (100)	0
D516V (gAc/gTc)			8 (53.4)	8 (100)	0
codon 526			3 (8.3)	3 (100)	0	3 (16.7)
H526Y (Cac/Tac)			1 (33.3)	1 (100)	0
H526R (cAc/cGc)			2 (66.7)	2 (100)	0
codon 531			17 (48.9)	15 (88.2)	2 (11.8)	0
S531L (tCg/tTg)			17 (100)	15 (100)	2 (11.8)

AG	18 (43.9)	23 (56.1)
rrs
codon 1401			0	0	0	0

FQ	nt	nt
gyrA			41 (100) ^a			4 (9.8)
codon 89			1 (2.4)			0
D89A (gAc/gGg)			1 (2.4)
codon 90			10 (24.4)			0
A90E (gCg/gAg)			2 (4.9)
A90V (gCg/gTg)			8 (19.5)
codon 94			6 (14.6)			4 (100)
D94G (gAc/gGc)			5 (12.2)
D94N (Gac/Aac)			1 (2.4)
codon 95			29 (70.7)			0
S95T (aGc/aCc)			29 (70.7)

Detected mutation	BACTEC MGIT 960

	Total	R	S	p ^a	kappa	s (%)

	N (%)	N (%)	N (%)
RMP
MAS-PCR
Yes	30 (73.2)	28 (75.6)	2 (50.0)	0.03	0.14	75.68
No	11 (26.8)	9 (24.4)	2 (50.0)
Total	41 (100)	37 (100)	4 (100)
Sequencing
Yes	35 (85.4)	33 (94.3)	2 (33.3)	1	0.61	94.29
No	6 (14.6)	2 (5.7)	4 (66.7)
Total	41 (100)	35 (100)	6 (100)

INH
MAS-PCR
Yes	38 (92.7)	36 (97.3)	2 (50.0)	0.56	0.53	97.30
No	3 (7.2)	1 (2.7)	2 (50.0)
Total	41 (100)	37 (100)	4 (100)
Sequencing
Yes	35 (85.4)	32 (88.9)	3 (60)	0.71	0.27	88.89
No	6 (14.6)	4 (11.1)	2 (40)
Total	41 (100)	36 (100)	5 (100)

Brasil

Brasil

Molecular characterization of pre-extensive drug resistant Mycobacterium tuberculosis in Northeast Brazil

ABSTRACT

INTRODUCTION

MATERIALS AND METHODS

RESULTS

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History