Mycobacterium tuberculosis, the etiological agent of tuberculosis, has lost many coding and noncoding regions in its genome during the course of evolution. We performed region-of-difference (RD) analysis using PCRbased genotyping of 131 M. tuberculosis clinical isolates obtained from four different countries, namely, India, Peru, Libya, and Angola. Our studies revealed that RD patterns are often distinct for strains circulating in specific geographical regions and can be used to trace the descent and spread of an isolate from its original reservoir. We describe our findings, which show that no single isolate from the four countries (n ؍ 131) had all the 15 RDs either deleted or retained. Tuberculosis-specific deletion 1 (TbD1) was found to be conserved in 23% of the Indian isolates, indicating their possible ancient origin. RD9 was the most conserved region, RD11 was predominantly deleted, and RD6 was the most variable among the isolates in our collection irrespective of their geographic region. In contrast to earlier reports, our results demonstrate that the deletion of RD1 does not correlate with a decrease in the virulence potential of M. tuberculosis, as Indian isolates (n ؍ 30) examined by us were from diseased individuals and yet had lost the RD1 region. Our results further illustrated that the intactness of the RD5 region may be associated with increased virulence of the organism. This study highlights that the RDs in M. tuberculosis genomes are geographically distributed and specific and may possibly be associated with virulence spectrum. Tuberculosis (TB) remains an important cause of mortality worldwide; treatment of the disease has been further complicated by the increased number of human immunodeficiency virus-TB (HIV-TB)-coinfected patients. The future does not appear to be bright, as no breakthrough in the development of drugs and vaccines has been reported even after 8 years of availability of the complete genome sequence of Mycobacterium tuberculosis. Knowledge of genetic variability, mycobacterial population dynamics, and evolutionary genetics holds a lot of promise for understanding epidemic potentials of strains, their host tropism, differences in virulence, antibiotic susceptibility, etc., and will be possibly important for the treatment and control of the disease (26,30).Sequence analyses of the M. tuberculosis complex isolates have revealed that allelic polymorphism is rare, occurring at the rate of ϳ1 in 10,000 bp (28). As a result, the genomic fluidity in M. tuberculosis complex is largely due to nonrandom deletions apart from mobility of insertion sequences and transduction mediated by mycobacteriophages. Several PCR-based approaches have been developed to analyze the genomic diversity of the M. tuberculosis complex (1,2,12,15,16,19,22,25,27,29,31). The available strain-typing data revealed that regions of deletion are not randomly distributed throughout the genome but instead tend to aggregate, suggesting that a genomic region is vulnerable to changes which may prove deleterious to ...
