Whole-Genome Comparison of Mycobacterium tuberculosis Clinical and Laboratory Strains

Virulence and immunity are poorly understood in Mycobacteriumtuberculosis. We sequenced the complete genome of the M. tuberculosisclinical strain CDC1551 and performed a whole-genome comparisonwith the laboratory strain H37Rv in order to identify polymorphicsequences with potential relevance to disease pathogenesis,immunity, and evolution. We found large-sequence and single-nucleotidepolymorphisms in numerous genes. Polymorphic loci included aphospholipase C, a membrane lipoprotein, members of an adenylatecyclase gene family, and members of the PE/PPE gene family,some of which have been implicated in virulence or the hostimmune response. Several gene families, including the PE/PPEgene family, also had significantly higher synonymous and nonsynonymoussubstitution frequencies compared to the genome as a whole.We tested a large sample of M. tuberculosis clinical isolatesfor a subset of the large-sequence and single-nucleotide polymorphismsand found widespread genetic variability at many of these loci.We performed phylogenetic and epidemiological analysis to investigatethe evolutionary relationships among isolates and the originsof specific polymorphic loci. A number of these polymorphismsappear to have occurred multiple times as independent events,suggesting that these changes may be under selective pressure.Together, these results demonstrate that polymorphisms amongM. tuberculosis strains are more extensive than initially anticipated,and genetic variation may have an important role in diseasepathogenesis and immunity.

INTRODUCTION

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Introduction

Current evidence suggests that as a species Mycobacterium tuberculosisexhibits very little genomic sequence diversity (24, 34). Mostgenetic variability that has been detected is associated withtransposable elements and drug resistance phenotypes (5, 17,28, 38). It follows that M. tuberculosis should exhibit verylittle phenotypic variation in immunologic and virulence factors.However, evidence of phenotypic diversity among clinical isolatesconflicts with this hypothesis (22, 37). The presence of significantsequence diversity in M. tuberculosis would provide a basisfor understanding pathogenesis, immune mechanisms, and bacterialevolution. Polymorphic genes are good candidates for virulenceand immune determinants, because proteins that interact directlywith the host are known to have elevated divergence. Polymorphicsequences also serve as markers for phylogenetic and evolutionarystudies. Such studies are currently limited by a paucity ofknown genetic markers.

Recently, the genome of the M. tuberculosis laboratory strainH37Rv was completely sequenced (GenBank accession no. NC_000962)(10). This sequence provided important insights into the biologyof this species but did little to address issues of sequencediversity. Furthermore, significant differences can be documentedamong the genomes of laboratory strains with long historiesof passage and among recent clinical isolates (25). H37Rv hadbeen passaged for many decades outside of the human host. Thus,the relevance of the H37Rv genome sequence to clinical M. tuberculosisstrains has been questioned. We sequenced the genome of a clinicalM. tuberculosis strain, CDC1551 (GenBank accession no. AE000516),and performed a comprehensive sequence comparison. In contrastto H37Rv, CDC1551 is a strain involved in a recent cluster oftuberculosis cases and is known to be transmissible and virulentin humans (38). The CDC1551 strain appears to be highly infectiousin humans, is comparable in virulence to strain H37Rv in animalmodels (8), and has greater immunoreactivity than H37Rv andother clinical strains due to increased induction of tumor necrosisfactor alpha, interleukin-6 (IL-6), IL-10, and IL-12 (22).

Investigators have utilized a variety of low- and high-resolutioncomparative genome techniques to identify differences in thegenomes of Mycobacterium bovis, M. bovis BCG vaccine strains,and M. tuberculosis laboratory and clinical strains. Low-resolutionanalyses have included subtractive hybridizations and investigationsof sequence variations associated with restriction length polymorphisms.These methods have identified a number of sequence differencesbetween the different mycobacterial species and strains (15,16, 21, 26). However, low resolution analysis has inherent limitations.Consequently, the polymorphisms identified have been eithervery large or restricted to localized areas of the M. tuberculosisgenome. Comparative genomic techniques with higher resolutionhave also been performed recently. However, these studies havebeen limited by the use of H37Rv as the single reference strain(6, 7, 18). The only whole-genome comparison undertaken thusfar has been an incomplete and inaccurate comparison of theH37Rv and CDC1551 strains. This study apparently used an incompleteversion of the CDC1551 strain sequence and resulted, for example,in the misidentification of several comparative deletions instrain CDC1551 (7). Here we present the first comparison ofthe complete genomes from strains H37Rv and CDC1551, includingdifferences resulting from large-sequence polymorphisms (LSPs)(greater than 10 bp) and single-nucleotide polymorphisms (SNPs).We discovered an unexpectedly high degree of sequence variationbetween the two genomes and determined that much of the variationwas also present in a large panel of clinical M. tuberculosisisolates.

MATERIALS AND METHODS

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Materials and Methods

Genome sequencing. The methodologies for library construction, template preparation,sequencing, and closure of the M. tuberculosis genome were primarilythose developed during the whole-genome shotgun sequencing ofthe 1.83-Mbp genome of Haemophilus influenzae (13). In brief,high-molecular-weight genomic DNA from strain CDC1551 was obtainedfrom a seed lot culture maintained by William Bishai, JohnsHopkins University School of Medicine. The genomic DNA was randomlysheared by nebulization and size selected for 2.0-kb fragments.The DNA fragments were cloned into a SmaI-digested pUC18 vector.The recombinant molecules were freshly transformed by electroporationinto DH10B electrocompetent cells (catalog no. 8290SA; GIBCOBRL) and transferred directly to a nutrient-rich SOB plate (13).Approximately 50,000 templates were prepared and sequenced withM13 forward and reverse primers. Sequencing reactions were analyzedon AB377 DNA sequencers. The random shotgun fragments were assembledwith the TIGR assembler (35). Sequence gaps were filled by selectinga template whose forward and reverse sequence reads were inadjacent contigs. Physical gaps were ordered by combinatorialPCR based on oligonucleotide primers designed from the endsof each group of assemblies. The sequences of the physical gapswere determined by primer walking across each of the PCR products.Contigs were edited with the TIGR editor.

Annotation. Open reading frames (ORFs) were identified with GLIMMER (30).The ORFs were searched against an in-house nonredundant aminoacid database with blast_extend_repraze, which uses a BLASTPalgorithm to generate pairwise amino acid alignments (4, 42).In addition to the pairwise alignments used to generate geneassignments, the ORFs were evaluated by comparison to a databaseof hidden Markov models generated from multiple sequence alignmentsfor protein families and superfamilies (33). A team of annotationexperts evaluated the results generated by these various toolsand assigned to each ORF with a significant match an accessionidentification and a biological-role identification.

Suffix tree analysis. We have developed a heuristic approach to aligning large segments(millions of base pairs in length) of closely related DNA sequence(11). The system uses a combination of three ideas: suffix trees,the longest common subsequence, and Smith-Waterman alignment.The complete nucleotide sequences of H37Rv and CDC1551 are providedas input. The alignment process then follows these steps. (i)A maximal unique match decomposition of the two genomes is performedto identify all maximal unique shared subsequences in both genomes.(ii) The matches are sorted based on a longest ascending subsequencealgorithm, providing an easy and natural scan of the alignmentfrom left to right. (iii) Gaps in the alignment are closed byperforming local identification of large inserts, repeats, smallmutated regions, tandem repeats, and SNPs. (iv) The alignmentis outputted, including all the matches in the maximal uniquematch alignment and the detailed alignments of regions thatdo not match exactly.

Polymorphism detection. One hundred sixty-nine clinical isolates taken at random froma collection of M. tuberculosis isolates cultured at MontefioreMedical Center and 64 clinical isolates cultured at The JohnsHopkins University School of Medicine were analyzed for LSPs.Genomic DNAs from the clinical isolates and strains CDC1551and H37Rv were bound onto Biotrans plus nylon membranes (ICNPharmaceuticals, Costa Mesa, Calif.) in longitudinal stripsusing a multislot hybridization apparatus (immunoblotter; Immunetics,Cambridge, Mass.). The membrane was then turned 90° in thesame slot blot apparatus and simultaneously hybridized with ${gamma}$ -³²P-labeled probes complementary to different LSPs. Forty-fourdifferent genomic DNA samples could be slotted in an array consistingof 44 lines extending across the membrane. Hybridizing of probesfor each LSP at 90° to this array permitted every probeto come into contact with every genomic DNA sample. All isolateswere subjected to DNA fingerprinting using IS6110-based restrictionpolymorphism analysis; low-band-number isolates were also testedwith a secondary fingerprinting technique (1).

SNPs. Some apparent SNPs might represent sequencing errors ratherthan true SNPs. Verification of the sequence differences wasaccomplished by two independent methods. One hundred SNPs werechosen at random, and the base calls were independently verifiedby inspection of the original electropherograms at The Institutefor Genomic Research (CDC1551) and The Sanger Center (H37Rv).In collaboration with Qiagen Genomics, Inc., these 100 SNPswere verified for both strains by using Masscode technologyfor SNP identification (19). The visual inspection of the electropherogramsand the Masscode results were in good agreement and indicatedthat 91% (80 of 88 successful assays) of the nucleotide differenceswere genuine. The number of synonymous and nonsynonymous substitutionsbetween the two strains was determined by alignment of homologousORFs with ClustalW (36). Poor alignments were removed basedon visual inspection, resulting in a comparison of 3,535 ORFs.The number of synonymous differences (S_d) and nonsynonymousdifferences (S_n) between homologous ORFs was calculated withthe program SNAP (20).

RESULTS

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Results

Whole-genome alignment. The complete genome sequence of M. tuberculosis strain CDC1551was determined utilizing the whole-genome shotgun strategy (13).The complete annotation of the CDC1551 genome is located atThe Institute for Genomic Research website at www.tigr.org/CMRand under GenBank accession no. AE000516. A whole-genome alignmentwas performed utilizing MUMmer software developed at The Institutefor Genomic Research (11). The circular representation of theM. tuberculosis chromosome illustrated in Fig. 1 depicts thelocation of each predicted protein coding region as well asselected features differing between the CDC1551 and H37Rv strains,including LSPs and SNPs.

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FIG.1. Circular representation of the M. tuberculosis chromosome illustrating the location of each predicted protein-coding region as well as selected features differing between the CDC1551 and H37Rv strains. The outer concentric circle shows predicted protein-coding regions on both strands, color coded according to role category. The second concentric circle shows the location of nonsynonymous substitutions (black). The third concentric circle shows the location of synonymous substitutions (blue). The fourth concentric circle shows the location of substitutions in noncoding regions (red). The fifth concentric circle shows the location of insertions in strain CDC1551, including coding (black) and noncoding (blue) regions, and the location of phage phiRv1 (red). The sixth concentric circle shows the location of insertions in strain H37Rv, including coding (black) and noncoding (blue) regions, and the location of phage phiRv1 (red). The seventh concentric circle shows the location of IS6110 insertion elements in strains CDC1551 (blue) and H37Rv (red). The eighth (innermost) concentric circle shows the location of tRNAs (blue) and rRNA (red).

The two genomes contained notable differences. The H37Rv straincontained 37 insertions (greater than 10 bp) relative to strainCDC1551. Twenty-six insertions affected ORFs (Fig. 1; Table1), and 11 were intergenic. The insertions in strain H37Rv includedtandem repeats, additions to the 5' or 3' ends of ORFs, andthe addition of complete ORFs. Complete ORFs included threeencoding hypothetical proteins (Rv0793, Rv3427c, Rv3428c), twoencoding PPE proteins (Rv3425, Rv3426), one encoding a PE_PGRSprotein (Rv3519), and two encoding proteins with putative functions(Rv0794c, a dihydrolipoamide dehydrogenase, and Rv0792c, a putativetranscriptional regulator). Forty-nine insertions were identifiedin strain CDC1551 relative to strain H37Rv. Thirty-five insertionsaffected ORFs (Fig. 1; Table 2), and 14 were intergenic. Inaddition to tandem repeats and additions to the 5' and 3' endsof ORFs, insertions introduced 17 complete ORFs. Eight ORFsencoded conserved hypothetical or hypothetical proteins (MT1813,MT2080, MT2080.1, MT2081, MT2420, MT2421, MT3427.1, and MT3429).The nine additional CDC1551 ORFs with functional assignmentsincluded genes encoding an adenylate cyclase (MT1360), a glycosyl-transferase(MT1800), an oxidoreductase (MT1801), a 12 transmembrane protein(MT1802), a membrane lipoprotein (MT2619), a PPE family protein(MT3248), paralogs of moaB (MT3426) and moaA (MT3427), and agene encoding a putative transcription regulatory protein (MT3428).The changes in the 5' end of a phospholipase C gene (MT1799)and the addition of a 12 transmembrane transport protein (MT1802)are particularly notable because of their potential role inbacterial virulence (32). It is worth noting that almost halfof the insertions and deletions in both strains involved genesencoding PPE or PE_PGRS family proteins. We found only one majorrearrangement of genome structure between the two strains. Aprophage, initially identified in the RD3 region of M. bovis(21) and later characterized as prophage phiRv1 in strain H37Rv(10), is associated with the REP13E12 family of repeats (14).In strain H37Rv, prophage phiRv1 is integrated between coordinates1,779,312 and 1,788,503. In strain CDC1551, phiRv1 is integratedinto a second member of the REP13E12 family at CDC1551 coordinates3,870,803 and 3,879,990.

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TABLE 1. Regions of insertions in ORFs in strain H37Rv relative to strain CDC1551

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TABLE 2. Regions of insertions in ORFs in strain CDC1551 relative to strain H37Rv

The IS3-type insertion sequence IS6110 is the principal epidemiologicalmarker for M. tuberculosis. A number of the insertions and deletionswere associated with this insertion sequence, suggesting a rolefor this element in genome plasticity (23, 41). Studies haveshown that homologous recombination between nearby copies ofIS6110 may result in genomic deletions and can be a mechanismfor generating genomic diversity (12). We identified 4 copiesof IS6110 in CDC1551 compared to 16 copies in H37Rv. Four ofthe 16 IS6110 elements present in H37Rv lacked the characteristic3- to 4-bp direct repeat and were directly adjacent to regionsthat were deleted relative to strain CDC1551. Two of these deletionsincluded the 6,807-bp region containing ORFs MT1799, MT1800,MT1801, and MT1802 and the 4,083-bp region deleted in strainH37Rv containing the molybdopterin cofactor biosynthesis genecluster (MT3426 and MT3427) (Table 2). While strain H37Rv containedseveral deletions associated with a possible mechanism of homologousrecombination between nearby IS6110 elements, none of the deletionsin strain CDC1551 appeared to be the result of such a mechanism.The association of the IS6110 element with the deletion of importantgenes calls into question its utility as a neutral marker forphylogenetic analysis.

Regions differing in the copy number of several genes betweenstrains H37Rv and CDC1551 were identified. Phylogenetic analysisof these regions revealed surprisingly contradictory evolutionaryrelationships among CDC1551, H37Rv, and M. bovis. Among thegenes encoding membrane lipoproteins in strain H37Rv were twogenes in tandem (Rv2543 and Rv2544). The homologous genome regionin strain CDC1551 contained the orthologs MT2618 and MT2620,respectively. However; a third ORF, MT2619, was interspersedbetween the two genes (Fig. 2a). Examination of the homologousregion in the M. bovis genome (www.sanger.ac.uk) revealed orthologsof the three membrane lipoprotein genes observed in the CDC1551genome in an indistinguishable organization and nucleotide sequence.There was essentially no nucleotide diversity between orthologs.The nucleotide diversity among the paralogs was similar forall three genes, indicating equivalent evolutionary distances.Phylogenetic analysis suggested that the three paralogs arosein a common ancestor of the M. tuberculosis complex by geneduplications and that subsequent loss of MT2619 occurred inthe H37Rv lineage.

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FIG. 2. (a) Schematic diagram of homologous genome region in strains H37Rv and CDC1551 encoding several membrane lipoproteins. The region in strain H37Rv contains two genes in tandem (Rv2543 and Rv2544) that are 87% identical to each other at the protein level. The homologous region in strain CDC1551 contains three genes (MT2618, MT2619, and MT2620), with the middle gene, MT2619, being unique to strain CDC1551 and 88 and 84% identical to MT2619 and MT2620, respectively. Homology between strain CDC1551 and M. bovis and equivalent evolutionary distances between paralogs suggest that the three paralogs arose in a common ancestor of the M. tuberculosis complex and subsequent loss of MT2619 occurred in the H37Rv lineage. (b) Schematic diagram of the tandem adenylate cyclase region. Two paralogous cyclases flank the region (MT1359/Rv1318c and MT1362/Rv1320c). Analysis revealed two cyclases (MT1360 and MT1361) between the two flanking genes in strain CDC1551 and only one cyclase (Rv1319c) in strain H37Rv. Rv1319c appears to be a chimera of the 5' half of MT1361 and the 3' half of MT1360. The 3' halves of all orthologs share >80% nucleotide identity, while the 5' halves appear diverse. Phylogenetic analysis indicates that the duplication events share a similar evolutionary distance. Inspection of the M. bovis sequence data reveals that this region is organized in an identical way to the H37Rv genome.

A second polymorphic region contained an unusual organizationof three (Rv1318c, Rv1319c, and Rv1320c) and four (MT1359, MT1360,MT1361, and MT1362) putative adenylate cyclase genes in tandemin strains H37Rv and CDC1551, respectively (Fig. 2b). Each ORFhad a strong match to the catalytic domain of guanylate or adenylatecyclase. The comparative sequence data between the two strainsshowed that in H37Rv, the middle gene of the cluster (Rv1319c)is actually an in-frame chimera corresponding to the 3' and5' ends of genes MT1360 and MT1361, respectively, from CDC1551(Fig. 2b). M. bovis has a structure similar to that of H37Rv.Phylogenetic analysis of this polymorphic region indicated thatthe in-frame chimera was generated by a deletion-fusion event.Thus, the ancestral structure was likely four tandem genes.The shared fusion in H37Rv and M. bovis could be due to a singleevent, indicating that these strains share a common ancestorrelative to CDC1551. Notably, this hypothesis conflicts withthe evolutionary scenario proposed for the membrane lipoproteingene duplication. Together, these findings indicate that geneticvariability in M. tuberculosis arises through a complex evolutionaryprocess that involves recombination or multiple insertion-deletionevents occurring independently at the same locus.

Heterogeneity of LSPs. The comparative sequence data between CDC1551 and H37Rv providedus with a starting point for characterizing the degree and frequencyof certain deletion/insertion events among clinical M. tuberculosisisolates. We tested 169 clinical M. tuberculosis isolates forthe presence of a subset of seventeen CDC1551-H37Rv LSPs representingknown and hypothetical genes. The seventeen probes for theseLSPs, the genes involved, and their respective coordinates arelisted in Table 3. The isolates included 19 restriction fragmentlength polymorphism (RFLP)-defined clusters and 88 unique isolates.We defined "clustered" isolates as those isolates which throughDNA fingerprinting of an insertion sequence element (IS6110)shared identical banding patterns. "Unique" isolates containedunique banding patterns. Clustered isolates are thought to havea common ancestor and to be possibly linked together by recenttransmission events, while unique isolates are likely to begenetically distinct strains (40). We discovered a surprisinglylarge degree of sequence heterogeneity among the clinical isolates.All of the 169 tested isolates lacked at least one LSP. An averageof 3.7 sequences were missing for each isolate, with a rangeof one to seven deletions. We reproducibly demonstrated thepresence or absence of specific LSPs in duplicate experiments,and we performed polymorphism specific PCR assays to reconfirma subset of these results (data not shown).

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TABLE 3. Probes for LSP in strains CDC1551 and H37Rv^e

We used a second set of epidemiologically well-characterizedisolates to determine whether variability of LSPs also occurredamong isolates that were closely linked through epidemiologicalinvestigations (referred to herein as "epi-linked" isolates).Clusters of epi-linked isolates presumably share a recent commonancestor as part of an outbreak of disease. Thus, they representvery closely related isolates. We studied 42 isolates that included16 RFLP-defined clusters and 15 unique isolates. Seven clusterscontained a total of 17 epi-linked isolates. The pattern ofLSPs was identical in all epi-linked isolates within a cluster.In contrast, four isolates within three clusters without epi-linkscontained deletions of at least one sequence (Fig. 3). As eachcluster is likely to have arisen from a common ancestor, theadditional deletions likely occurred subsequent to the commonancestor. We also found the same deletions in other clusteredand unique isolates. These findings suggest that the loss ofthese LSPs occurred multiple times as independent events, andthat new polymorphisms rarely develop within the short timeframe of a clinical outbreak of disease. Alternately, the disparateclustered and unique strains containing identical deletionscould have arisen from a common strain in which a unique ancestraldeletion occurred. However, this second hypothesis is not supportedby evidence for recurrent deletions within the phospholipaseC region (16) or by the contradictory deletion-based phylogenyof the adenylate cyclase region (see above).

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FIG. 3. The distribution of CDC1551/H37Rv LSPs in clinical M. tuberculosis strains using a slot blot cross hybridization method. Strains include unique isolates and clustered strains with and without epidemiological links. Clusters are grouped by letter (and number if subtyped by a secondary fingerprinting method). Strains with epidemiological links are designated by links. Probes to LSPs are described in Table 3.

Heterogeneity of SNPs. The comparison of the H37Rv and CDC1551 genomes identified 1,075SNPs between the two genomes (Table 4). Approximately 85% ofthe substitutions occurred in coding regions (93% of the genome).We found transitions (purine to purine and pyrimidine to pyrimidine)to be more numerous than transversions (purine to pyrimidineand pyrimidine to purine), which represented 61 and 39% of thesubstitutions, respectively. We calculated synonymous and nonsynonymoussubstitutions for 3,535 pairs of homologous ORFs. There wasat least one synonymous or one nonsynonymous substitution in298 (8.4%) or 457 (12.9%) of the ORFs, respectively. In total,there were 342 and 579 synonymous (S_d) and nonsynonymous (S_n)substitutions, respectively. The proportion of synonymous differencesper synonymous site corrected for the possibility that a sitechanged multiple times (D_s) was 3.6 x 10^-4, or a 1/D_s of 1 synonymoussubstitution per 2,752 synonymous sites. This value for D_s wasmore than threefold greater than that previously described forM. tuberculosis (34), emphasizing the unexpected sequence diversity.

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TABLE 4. Nucleotide substitutions between M. tuberculosis strains CDC1551 and H37Rv^a

Surprisingly, the ratio of M. tuberculosis D_s to nonsynonymoussubstitution (D_s/D_n) was approximately 1.6, in contrast to studiesof housekeeping genes in Escherichia coli and Salmonella entericaand invasion genes in S. enterica which show a D_s/D_n ratio ofranging from 4 to 17 (9, 39). The observation in E. coli andS. enterica is consistent with the generally accepted view thatthe many nonsynonymous substitutions are lost through purifyingselection. The ratio observed in M. tuberculosis indicates thatadditional selective pressure is present on synonymous substitutionsor there is decreased selective pressure against nonsynonymousmutations.

Patterns of synonymous and nonsynonymous substitutions can revealinformation about mutations and selective pressures on genes,as well as information about population structure and recombination.We analyzed the frequency of substitution for 877 gene familiesto see if any contained significantly more SNPs than the genomeas a whole. We calculated a P (the probability that the frequencyof substitution was due to random fluctuation) for synonymousand nonsynonymous substitutions for each gene family. We useda P of <0.0001 as a cutoff to identify gene families in whichthe higher frequency of substitution was not likely to be dueto random fluctuation (Table 5). We identified three paralogousfamilies with significantly more synonymous substitutions andnonsynonymous substitutions (gmt ["Genome Mycobacterium tuberculosis"database] domain_PF00924, gmt domain_75, and gmt domain_337[http://www.tigr.org/tigr-scripts/CMR2/ParalogousList.spl?db=gmt]).Thegmt domain 69 also had significantly higher synonymous substitutionrates, but the P for nonsynonymous substitutions was slightlyabove the cutoff. Interestingly, the PE and PPE paralogous family(gmt domain_PF00924) was among the three families with significantlyhigher synonymous and nonsynonymous substitutions. The PE andPPE genes encode a family of acidic, glycine-rich proteins thatare postulated to be expressed on the extracellular surfaceand are considered potential antigens for host immunity (27,31).

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TABLE 5. Paralogous families with significantly higher (P < 0.0001) frequencies of substitution

The fact that the H37Rv strain has been in culture for nearlya century raised the possibility that many of the nucleotidedifferences observed between the two strains could be a resultof in vitro passage. We examined a subset of 28 of the clinicalisolates for 11 nonsynonymous SNPs (4 of which resulted in conservativeamino acid substitutions) initially detected through the H37Rv-CDC1551comparison (Table 6). Seven of the eleven SNPs were polymorphicin at least 1 of the 28 isolates tested. Two of the SNPs, SNP-2904in the gene encoding the carbon starvation A protein and SNP-4090in a gene encoding a putative transcriptional regulator, werehighly polymorphic (each allele present in $>=$ 20% of the isolates).Thus, the SNPs discovered by the two-genome comparison appearto be broadly represented in clinical strains. The distributionsof SNP-2904 and SNP-4090 are comparable to those of two SNPspreviously described as highly polymorphic (gyrA-95 at codon95 of the gyrA gene and katG-463 at codon 463 of the katG gene)(34), suggesting that they might be useful for phylogeneticanalysis (Table 6).

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TABLE 6. SNPs in 28 clinical M. tuberculosis isolates^c

Phylogenetic analysis using LSPs and SNPs. We performed a phylogenetic analysis of 21 clinical isolates,H37Rv, CDC1551, and M. bovis using a combination of data fromLSPs, SNPs, and selected phenotypic traits (Fig. 4). The treeis supported by statistical analysis for most of the branchingpatterns. The phylogenetic analysis allows the assessment ofthe consistency of different markers with the consensus tree(Fig. 5). Several of the markers have a high consistency indexas well as a reasonable level of variability. These markersprovide information for constructing models of the phylogeneticrelationships between strains. As described above, analysisof the adenylate cyclase region contradicted the model in whichH37Rv, CDC1551, and M. bovis shared a common ancestor. The lowconsistency index of this region (marker 2) confirms on a populationlevel that the cyclase region would be expected to be a poorphylogenetic marker, explaining this apparent contradiction.Markers with low consistency indices represent regions of thegenome which may have evolved by mechanisms of convergence,recombination, and mutational frequencies outside the averagefor the species. Such sites can be useful in discriminatingamong strains linked by other markers, such as insertion sequencemarkers.

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FIG. 4. M. tuberculosis strain phylogeny based on a combination of LSPs, SNPs, and selected phenotypic traits. The tree shown is a consensus of the most parsimonious trees found using the heuristic search algorithm. Character state boxes are shown at the top (for LSPs, a blue box indicates presence and a yellow box indicates absence; for SNPs and other characters, colors correspond to different character states). Characters 1 to 12 are SNPs, characters 13 to 28 are LSPs, character 29 belongs to the Musser group, character 30 is Smear positive or negative, and character 31 is Site (pulmonary or extrapulmonary). Unresolved branching patterns are collapsed.

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FIG. 5. Consistency index for characters in the phylogenetic tree based on the LSPs and SNPs. Each column corresponds to the consistency index for a particular character (SNPs and LSPs). Each bar shows the minimum (black), average (striped), and maximum (grey) value of the consistency index over a large number of different trees (including multiple equally parsimonious trees and multiple distance trees). The percent variability indicates the variability of each marker in the 28 isolates tested. Calculations of the consistency indices were made using the MacClade program.

DISCUSSION

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Discussion

Several studies have compared closely related strains of bacteria,including Helicobacter pylori, several Chlamydia species, andpathogenic and nonpathogenic E. coli (2, 3, 25, 29). In general,these studies were limited to the sequencing of a comparativestrain or species and identification of polymorphisms betweenthe two but failed to extend the findings beyond the two strainsbeing compared.

Several studies of the Mycobacterium genus describe LSPs amongthe M. bovis BCG vaccine strains and virulent M. bovis as wellas among other tubercle bacilli (6, 15, 21, 18). While thesestudies describe several regions of LSP, the methodologies ofsubtractive hybridization and RFLP analysis limit the resolutionand therefore the utility of the markers described. Betts etal. (7) in their analysis of the M. tuberculosis proteome attempta comparative analysis of the genome contents of the H37Rv andCDC1551 strains. Several conclusions drawn from this analysisappear to be incorrect based on our present analysis. In particular,they describe eight ORFs completely unique to H37Rv, includingRv0278c, Rv0279c, Rv0746c, Rv0747, and Rv1087, all of the PE_PGRSfamily. The identification of a 5,742-bp deletion associatedwith ORFs Rv0278c and Rv0279c and a deletion of 4,910 bp associatedwith ORFs Rv0746c, Rv0747, and Rv0748 is incorrect and may bethe result of analyzing an incomplete version of the sequenceof strain CDC1551. Two other regions of strain H37Rv, bp 2,714,308to 2,714,808 and bp 3,933,523 to 3,936,659, are incorrectlyidentified as being deleted in strain CDC1551. Their analysisof insertions in the strain CDC1551 genome relative to strainH37Rv also appears to contain several errors. They failed toidentify approximately 15 regions of insertion in strain CDC1551relative to H37Rv. Among these regions was a 4,425-bp regioncontaining ORFs MT3426 and MT3427 and moaB and moaA paralogs,respectively. Most of the coordinates reported by Betts et al.(7) are incorrect with respect to strain CDC1551. This is againlikely due to the analysis of an incomplete genome sequence.

We initially undertook the sequencing and annotation of a secondM. tuberculosis strain, CDC1551, in an attempt to correlategenotypic changes with strain phenotype. Prior to our studyit was generally accepted that little sequence variation existed.Our study demonstrates that a much higher level of polymorphismis present among the M. tuberculosis species. This discoverycomplicates attempts to associate specific genotypic changeswith phenotypic differences. However, it also provides severalimportant opportunities.

First, it is likely that a subset of the polymorphic sequencescode for genes involved in host-pathogen interactions. A statisticalanalysis of the single-base substitution frequency in 877 genefamilies identified several families in which the frequencyof substitution was significantly greater than that observedfor the genome as a whole. This included the PE/PPE gene family,which encodes acidic, glycine-rich proteins that are postulatedto be expressed on the extracellular surface and are consideredpotential antigens for host immunity (27, 31). The higher substitutionfrequency in this family might be the result of antigenic variationor may be due to other interactions with the host. Three othergene families representing conserved hypothetical proteins alsohad a higher substitution frequency. These genes warrant furtherinvestigation as potential candidates for virulence or immunogenicity.The LSPs that we discovered may also encode proteins involvedin disease pathogenesis as demonstrated by the polymorphismsin one of the phospholipase C genes and members of the PE/PPEgene family.

Second, the level of LSPs and SNPs that we discovered amongthe M. tuberculosis isolates suggested that we could also developa set of markers that would be valuable in studying the phylogeneticsof the M. tuberculosis species and other tubercle bacilli. Analysisof two LSPs, an ORF encoding a membrane lipoprotein and an ORFencoding a putative adenylate cyclase, suggested conflictingscenarios of the evolutionary relationship of CDC1551, H37Rv,and M. bovis. However, phylogenetic analysis of 21 clinicalisolates along with strains CDC1551, H37Rv, and M. bovis demonstratedthat the adenylate cyclase region had a low consistency indexand would be a poor phylogenetic marker, explaining its apparentcontradiction with the membrane lipoprotein region. Other polymorphismswith high consistency indexes were discovered that are likelyto be excellent markers for investigating the evolution andphylogenetics of this species.

We demonstrated that the D_s is more than threefold greater thanestimated previously (24, 34). Interestingly, the D_s-to-D_n ratiowas close to 1, unlike the much higher level expected if selectionwas against nonsynonymous but not synonymous substitutions.This could be due to decreased selective pressure against nonsynonymousmutations. For example, the prolonged passage of strain H37Rvin culture may have permitted the accumulation of nonsynonymousmutations in many genes that would otherwise be under strictselection in vivo. Alternatively, selective pressure may existfor certain synonymous substitutions. This may be due to codonbias aimed at maintaining a high G+C content (65.6%) and thuslimiting the number of synonymous substitutions. Other explanationsconsistent with M. tuberculosis biology include a low recombinationfrequency, a small population size, or a recent bottleneck inM. tuberculosis evolution.

The sequencing of approximately 8.8 Mbp of M. tuberculosis (thecombined complete sequences of strains CDC1551 and H37Rv) providedapproximately 74 LSPs and more than 1,000 SNPs as potentiallyinformative markers. Based on the consistency indices of the17 LSPs and 10 SNPs evaluated, 5 and 2, respectively, wouldbe good phylogenetic markers. This compares favorably with theeffort by Sreevatsan et al. (34) in sequencing 2 Mbp of 26 selectedgenes and the identification of 32 SNPs, of which 2 were presentat high frequency. The comprehensive comparison based on a genome-widescan between just two isolates suggests that polymorphisms betweenM. tuberculosis strains may be more extensive than initiallyanticipated and that such polymorphisms may have great valuein providing comparative information for the basis of humancolonization, infectivity, and virulence and informative locifor the analysis of evolutionary and phylogenetic relationshipswithin the Mycobacterium genus and among clinical isolates.

ACKNOWLEDGMENTS

We thank J. Parkhill, The Sanger Center, for review of the H37Rvelectropherograms; A. Duesterhoeft and K. Dix, Qiagen Genomic,Inc., for Masscode verification of SNPS; and The Sanger Centerfor the availability of the M. bovis sequence data.

This work was supported by the National Institute of Allergyand Infectious Diseases, National Institutes of Health, grantsRO1-AI40125 and AI46669.

FOOTNOTES

* Corresponding author. Mailing address: The Institute for Genomic Research, 9712 Medical Center Dr., Rockville, MD 20850. Phone: (301) 838-3508. Fax: (301) 838-0208. E-mail: rdfleisc{at}tigr.org.

REFERENCES

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