Antimicrobial Agents and Chemotherapy, November 2004, p . 4447-4449, Vol . 48, No . 11

Novel Mutations within the embB Gene in Ethambutol-Susceptible Clinical Isolates of Mycobacterium tuberculosis

Ann S . G . Lee,^1* Siti Noor Khadijah Othman,¹ Yu Min Ho,¹ and Sin Yew Wong²

Division of Medical Sciences, National Cancer Centre,¹ Department of Infectious Diseases, Tan Tock Seng Hospital, Singapore, Singapore²

Received 30 March 2004/ Returned for modification 10 May 2004/ Accepted 15 July 2004

Alterations at codon 306 of embB have been identified as being the most common alteration in EMB-resistant M . tuberculosis clinical isolates (8, 12, 17-20, 23, 29) . Initial work on 51 EMB-resistant isolates had shown that 89% of these isolates had alterations at residue 306 of embB, but these alterations were not detected in 30 EMB-susceptible isolates (23) . A subsequent study confirmed this high frequency of embB306 alterations, with 67% of 75 EMB-resistant isolates having mutations not found in EMB-susceptible strains (19) . This led to several groups developing targeted strategies for the detection of embB306 alterations (7, 16, 21, 30) . Amino acids within the EMB resistance-determining region of EmbB proteins are well conserved among mycobacterial species, including those from M . tuberculosis, M . leprae, and M . smegmatis (2), and mutations within this region have been detected in EMB-resistant isolates of M . tuberculosis .

The aim of this present work was to screen all regions of the embB gene with previously reported mutations in order to assess the contribution of mutations within this gene to EMB resistance in M . tuberculosis clinical isolates from Singapore .

Drug susceptibility testing was done using the BACTEC 460 radiometric method (Becton Dickinson, Towson, Md.) (2.5 µg/ml) . Twenty-five consecutive M . tuberculosis isolates resistant to EMB and 20 EMB-susceptible isolates from Singapore were collected as previously described (5, 10) .

DNA extracted from the isolates was analyzed by amplifying four fragments, using the PCR primers shown in Table 1 . The PCR products were purified (QIAquick PCR purification kit or QIAquick gel extraction kit; QIAGEN) and directly sequenced using the BigDye Terminator sequencing kit and the ABI PRISM 377 automated sequencer (PE Biosystems, Branchburg, N.J.) . Confirmation of mutations was done by reamplification and resequencing .

 
IS6110 profiling was done according to standard procedures to determine if the isolates were epidemiologically independent (28) . All isolates with the same nucleotide substitutions in this study were deemed to be epidemiologically unassociated as they had distinct IS6110 fingerprints .

Overall, mutations in the embB gene were detected in 17 (68%) of the 25 EMB-resistant isolates (Table 2) . Mutations at embB306 were detected in 12 of these 25 (48%) EMB-resistant isolates . Notably, all of the 12 EMB-resistant isolates with embB306 mutations were also resistant to isoniazid . All five EMB-resistant isolates with mutations at codon 497 were resistant to at least three antituberculosis drugs . Three isolates monoresistant to EMB had no detectable mutations in embB .

 
This is the first report of a double substitution (ATGATM, where M represents the nucleotides A and C), resulting in a MetIle alteration at the frequently altered codon 306 of embB in an EMB-susceptible isolate (Table 2) . This isolate was resistant to both isoniazid and rifampin .

In addition, three other alterations were also detected in EMB-susceptible isolates, G406D and two novel mutations, M423I and A659T . The isolate with the G406N substitution was also resistant to isoniazid and rifampin, while the isolate with the M423I alteration was monoresistant to isoniazid and the isolate with the A659T alteration was monoresistant to streptomycin . In total, alterations in the embB gene were detected in 4 (20%) of the 20 EMB-susceptible isolates (Table 2) .

There is a possibility that these mutations may have occurred in susceptible isolates due to cross-contamination of the PCR product, heteroresistance involving mixed cultures, or errors in the susceptibility testing, though every effort was undertaken to avoid this .

Alterations in embB in EMB-susceptible isolates at codons other than codon 306 have been documented in only two isolates with the G406D alteration (20) and one isolate with the S347T alteration (8) . This paucity of information is due in part to some studies targeting only embB306 (17, 29), several reporting no mutations (1, 12, 19, 23), and others not including EMB-susceptible isolates (22, 31) .

Interestingly, all three EMB monoresistant isolates in this present study did not have any detectable alterations in embB . In contrast, all 58 EMB-susceptible isolates in this and other studies with embB alterations were resistant to other antituberculosis drugs as well (8, 17, 20, 29) . These observations support the hypothesis that a target other than EmbB may exist for EMB which may be activated during combination treatment with other first-line antituberculosis drugs, resulting in susceptibility to EMB (17) .

Importantly, if all alterations of embB306 are considered polymorphisms, then only a minority of EMB-resistant isolates would be mutated . A similar scenario was observed in studies defining the role of the katG gene in isoniazid resistance in M . tuberculosis . Members of our group and others have shown that the predominant alteration in katG is R463L, which is detected in both isoniazid-resistant and -susceptible isolates and hence is considered a polymorphism and an unreliable indicator of isoniazid resistance (11, 13, 27) . Thus, it is imperative for all studies elucidating the molecular mechanisms of drug resistance in M . tuberculosis to include drug-susceptible isolates as controls .

Another interesting finding of this study was the presence of resistance to other antituberculosis drugs when alterations of embB were present . Further investigations are necessary in order to understand the involvement of these drugs in the molecular mechanism of EMB resistance .

In conclusion, alterations at embB306 may not confer resistance to EMB but may be common polymorphisms in clinical isolates of M . tuberculosis . The clinical significance of this alteration is dubious, and further evaluation of EMB-susceptible isolates from other geographic regions is warranted .

This work was supported by the National Medical Research Council of Singapore .

1. Abbadi, S., H . G . Rashed, G . P . Morlock, C . L . Woodley, O . El Shanawy, and R . C . Cooksey. 2001 . Characterization of IS6110 restriction fragment length polymorphism patterns and mechanisms of antimicrobial resistance for multidrug-resistant isolates of Mycobacterium tuberculosis from a major reference hospital in Assiut, Egypt . J . Clin . Microbiol . 39:2330-2334.
2. Alcaide, F., G . E . Pfyffer, and A . Telenti. 1997 . Role of embB in natural and acquired resistance to ethambutol in mycobacteria . Antimicrob . Agents Chemother . 41:2270-2273.
3. Belanger, A . E., G . S . Besra, M . E . Ford, K . Mikusova, J . T . Belisle, P . J . Brennan, and J . M . Inamine. 1996 . The embAB genes of Mycobacterium avium encode an arabinosyl transferase involved in cell wall arabinan biosynthesis that is the target for the antimycobacterial drug ethambutol . Proc . Natl . Acad . Sci . USA 93:11919-11924.
4. Besra, G . S., K . H . Khoo, M . R . McNeil, A . Dell, H . R . Morris, and P . J . Brennan. 1995 . A new interpretation of the structure of the mycolyl-arabinogalactan complex of Mycobacterium tuberculosis as revealed through characterization of oligoglycosylalditol fragments by fast-atom bombardment mass spectrometry and 1H nuclear magnetic resonance spectroscopy . Biochemistry 34:4257-4266.
5. Boudville, I . C., S . Y . Wong, and I . Snodgrass. 1997 . Drug-resistant tuberculosis in Singapore, 1995 to 1996 . Ann . Acad . Med . Singapore 26:549-556.
6. Brennan, P . J., and H . Nikaido. 1995 . The envelope of mycobacteria . Annu . Rev . Biochem . 64:29-63.
7. Cooksey, R . C., G . P . Morlock, B . P . Holloway, J . Limor, and M . Hepburn. 2002 . Temperature-mediated heteroduplex analysis performed by using denaturing high-performance liquid chromatography to identify sequence polymorphisms in Mycobacterium tuberculosis complex organisms . J . Clin . Microbiol . 40:1610-1616.
8. Escalante, P., S . Ramaswamy, H . Sanabria, H . Soini, X . Pan, O . Valiente-Castillo, and J . M . Musser. 1998 . Genotypic characterization of drug-resistant Mycobacterium tuberculosis isolates from Peru . Tuber . Lung Dis . 79:111-118.
9. Khoo, K . H., E . Douglas, P . Azadi, J . M . Inamine, G . S . Besra, K . Mikusova, P . J . Brennan, and D . Chatterjee. 1996 . Truncated structural variants of lipoarabinomannan in ethambutol drug-resistant strains of Mycobacterium smegmatis . Inhibition of arabinan biosynthesis by ethambutol . J . Biol . Chem . 271:28682-28690.
10. Lee, A . S., I . H . Lim, L . L . Tang, A . Telenti, and S . Y . Wong. 1999 . Contribution of kasA analysis to detection of isoniazid-resistant Mycobacterium tuberculosis in Singapore . Antimicrob . Agents Chemother . 43:2087-2089.
11. Lee, A . S., L . L . Tang, I . H . Lim, M . L . Ling, L . Tay, and S . Y . Wong. 1997 . Lack of clinical significance for the common arginine-to-leucine substitution at codon 463 of the katG gene in isoniazid-resistant Mycobacterium tuberculosis in Singapore . J Infect . Dis . 176:1125-1127.
12. Lee, H . Y., H . J . Myoung, H . E . Bang, G . H . Bai, S . J . Kim, J . D . Kim, and S . N . Cho. 2002 . Mutations in the embB locus among Korean clinical isolates of Mycobacterium tuberculosis resistant to ethambutol . Yonsei Med . J . 43:59-64.
13. Leung, E . T., K . M . Kam, A . Chiu, P . L . Ho, W . H . Seto, K . Y . Yuen, and W . C . Yam. 2003 . Detection of katG Ser315Thr substitution in respiratory specimens from patients with isoniazid-resistant Mycobacterium tuberculosis using PCR-RFLP . J . Med . Microbiol . 52:999-1003.
14. Maddry, J . A., W . J . Suling, and R . C . Reynolds. 1996 . Glycosyltransferases as targets for inhibition of cell wall synthesis in M . tuberculosis and M . avium . Res . Microbiol . 147:106-112.
15. Mikusova, K., R . A . Slayden, G . S . Besra, and P . J . Brennan. 1995 . Biogenesis of the mycobacterial cell wall and the site of action of ethambutol . Antimicrob . Agents Chemother . 39:2484-2489.
16. Mokrousov, I., O . Narvskaya, E . Limeschenko, T . Otten, and B . Vyshnevskiy. 2002 . Detection of ethambutol-resistant Mycobacterium tuberculosis strains by multiplex allele-specific PCR assay targeting embB306 mutations . J . Clin . Microbiol . 40:1617-1620.
17. Mokrousov, I., T . Otten, B . Vyshnevskiy, and O . Narvskaya. 2002 . Detection of embB306 mutations in ethambutol-susceptible clinical isolates of Mycobacterium tuberculosis from Northwestern Russia: implications for genotypic resistance testing . J . Clin . Microbiol . 40:3810-3813.
18. Ramaswamy, S., and J . M . Musser. 1998 . Molecular genetic basis of antimicrobial agent resistance in Mycobacterium tuberculosis: 1998 update . Tuber . Lung Dis . 79:3-29.
19. Ramaswamy, S . V., A . G . Amin, S . Goksel, C . E . Stager, S . J . Dou, H . El Sahly, S . L . Moghazeh, B . N . Kreiswirth, and J . M . Musser. 2000 . Molecular genetic analysis of nucleotide polymorphisms associated with ethambutol resistance in human isolates of Mycobacterium tuberculosis . Antimicrob . Agents Chemother . 44:326-336.
20. Ramaswamy, S . V., S . J . Dou, A . Rendon, Z . Yang, M . D . Cave, and E . A . Graviss. 2004 . Genotypic analysis of multidrug-resistant Mycobacterium tuberculosis isolates from Monterrey, Mexico . J . Med . Microbiol . 53:107-113.
21. Rinder, H., K . T . Mieskes, E . Tortoli, E . Richter, M . Casal, M . Vaquero, E . Cambau, K . Feldmann, and T . Loscher. 2001 . Detection of embB codon 306 mutations in ethambutol resistant Mycobacterium tuberculosis directly from sputum samples: a low-cost, rapid approach . Mol . Cell Probes 15:37-42.
22. Sharaf-Eldin, G . S., N . S . Saeed, M . E . Hamid, A . M . Jordaan, G . D . Van der Spuy, R . M . Warren, P . D . Van Helden, and T . C . Victor. 2002 . Molecular analysis of clinical isolates of Mycobacterium tuberculosis collected from patients with persistent disease in the Khartoum region of Sudan . J . Infect . 44:244-251.
23. Sreevatsan, S., K . E . Stockbauer, X . Pan, B . N . Kreiswirth, S . L . Moghazeh, W . R . Jacobs, Jr., A . Telenti, and J . M . Musser. 1997 . Ethambutol resistance in Mycobacterium tuberculosis: critical role of embB mutations . Antimicrob . Agents Chemother . 41:1677-1681.
24. Takayama, K., E . L . Armstrong, K . A . Kunugi, and J . O . Kilburn. 1979 . Inhibition by ethambutol of mycolic acid transfer into the cell wall of Mycobacterium smegmatis . Antimicrob . Agents Chemother . 16:240-242.
25. Takayama, K., and J . O . Kilburn. 1989 . Inhibition of synthesis of arabinogalactan by ethambutol in Mycobacterium smegmatis . Antimicrob . Agents Chemother . 33:1493-1499.
26. Telenti, A., W . J . Philipp, S . Sreevatsan, C . Bernasconi, K . E . Stockbauer, B . Wieles, J . M . Musser, and W . R . Jacobs, Jr. 1997 . The emb operon, a gene cluster of Mycobacterium tuberculosis involved in resistance to ethambutol . Nat . Med . 3:567-570.
27. van Doorn, H . R., E . J . Kuijper, A . van der Ende, A . G . Welten, D . van Soolingen, P . E . de Haas, and J . Dankert. 2001 . The susceptibility of Mycobacterium tuberculosis to isoniazid and the ArgLeu mutation at codon 463 of katG are not associated . J . Clin . Microbiol . 39:1591-1594.
28. van Embden, J . D . A., M . D . Cave, J . T . Crawford, J . W . Dale, K . D . Eisenach, B . Gicquel, P . Hermans, C . Martin, R . McAdam, T . M . Shinnick, and P . M . Small. 1993 . Strain identification of Mycobacterium tuberculosis by DNA fingerprinting: recommendations for a standardized methodology . J . Clin . Microbiol . 31:406-409.
29. Van Rie, A., R . Warren, I . Mshanga, A . M . Jordaan, G . D . van der Spuy, M . Richardson, J . Simpson, R . P . Gie, D . A . Enarson, N . Beyers, P . D . van Helden, and T . C . Victor. 2001 . Analysis for a limited number of gene codons can predict drug resistance of Mycobacterium tuberculosis in a high-incidence community . J . Clin . Microbiol . 39:636-641.
30. Victor, T . C., A . M . Jordaan, A . van Rie, G . D . van der Spuy, M . Richardson, P . D . van Helden, and R . Warren. 1999 . Detection of mutations in drug resistance genes of Mycobacterium tuberculosis by a dot-blot hybridization strategy . Tuber . Lung Dis . 79:343-348.
31. Wang, W., H . Li, X . Wu, A . Wang, Z . Wang, J . Liu, H . Chen, M . Lin, J . Wang, Y . Ye, and S . Li. 2002 . Clinical application and evaluation of the detection of five drug resistance genes in Mycobacterium tuberculosis . Zhonghua Jie He He Hu Xi Za Zhi . 25:670-673 . (In Chinese.)
32. Wolucka, B . A., M . R . McNeil, E . de Hoffmann, T . Chojnacki, and P . J . Brennan. 1994 . Recognition of the lipid intermediate for arabinogalactan/arabinomannan biosynthesis and its relation to the mode of action of ethambutol on mycobacteria . J . Biol . Chem . 269:23328-23335.

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