We analyzed a global collection of Mycobacterium tuberculosis strains using 212 single nucleotide polymorphism (SNP) markers. SNP nucleotide diversity was high (average across all SNPs, 0.19), and 96% of the SNP locus pairs were in complete linkage disequilibrium. Cluster analyses identified six deeply branching, phylogenetically distinct SNP cluster groups (SCGs) and five subgroups. The SCGs were strongly associated with the geographical origin of the M. tuberculosis samples and the birthplace of the human hosts. The most ancestral cluster (SCG-1) predominated in patients from the Indian subcontinent, while SCG-1 and another ancestral cluster (SCG-2) predominated in patients from East Asia, suggesting that M. tuberculosis first arose in the Indian subcontinent and spread worldwide through East Asia. Restricted SCG diversity and the prevalence of less ancestral SCGs in indigenous populations in Uganda and Mexico suggested a more recent introduction of M. tuberculosis into these regions. The East African Indian and Beijing spoligotypes were concordant with SCG-1 and SCG-2, respectively; X and Central Asian spoligotypes were also associated with one SCG or subgroup combination. Other clades had less consistent associations with SCGs. Mycobacterial interspersed repetitive unit (MIRU) analysis provided less robust phylogenetic information, and only 6 of the 12 MIRU microsatellite loci were highly differentiated between SCGs as measured by G ST . Finally, an algorithm was devised to identify two minimal sets of either 45 or 6 SNPs that could be used in future investigations to enable global collaborations for studies on evolution, strain differentiation, and biological differences of M. tuberculosis.Compared to many bacterial species, Mycobacterium tuberculosis harbors relatively little genetic diversity (21, 34, 37); however, there is increasing evidence that the interstrain variation that exists is biologically significant. Clinical M. tuberculosis isolates have variable gene expression profiles (25) and have different numbers of genes deleted from their chromosome (32). In animal models, M. tuberculosis appears to engender a range of immune responses and variable degrees of virulence depending on the infecting strain (5,7,47,55). In human infections, molecular epidemiological studies have suggested that certain M. tuberculosis types, identified by DNA fingerprinting, can be especially prone to drug resistance acquisition (17, 59, 65) or to global dissemination (3, 9, 27, 40, 66,
