Snapshot of Moving and Expanding Clones of Mycobacterium tuberculosis and Their Global Distribution Assessed by Spoligotyping in an International Study

The present update on the global distribution of Mycobacteriumtuberculosis complex spoligotypes provides both the octal andbinary descriptions of the spoligotypes for M. tuberculosiscomplex, including Mycobacterium bovis, from >90 countries(13,008 patterns grouped into 813 shared types containing 11,708isolates and 1,300 orphan patterns). A number of potential indiceswere developed to summarize the information on the biogeographicalspecificity of a given shared type, as well as its geographicalspreading (matching code and spreading index, respectively).To facilitate the analysis of hundreds of spoligotypes eachmade up of a binary succession of 43 bits of information, anumber of major and minor visual rules were also defined. Atotal of six major rules (A to F) with the precise descriptionof the extra missing spacers (minor rules) were used to define36 major clades (or families) of M. tuberculosis. Some majorclades identified were the East African-Indian (EAI) clade,the Beijing clade, the Haarlem clade, the Latin American andMediterranean (LAM) clade, the Central Asian (CAS) clade, aEuropean clade of IS6110 low banders (X; highly prevalent inthe United States and United Kingdom), and a widespread yetpoorly defined clade (T). When the visual rules defined abovewere used for an automated labeling of the 813 shared typesto define nine superfamilies of strains (Mycobacterium africanum,Beijing, M. bovis, EAI, CAS, T, Haarlem, X, and LAM), 96.9%of the shared types received a label, showing the potentialfor automated labeling of M. tuberculosis families in well-definedphylogeographical families. Intercontinental matches of sharedtypes among eight continents and subcontinents (Africa, NorthAmerica, Central America, South America, Europe, the MiddleEast and Central Asia, and the Far East) are analyzed and discussed.

INTRODUCTION

Top

Introduction

Tuberculosis (TB) remains a major killer, with >8 millionnew cases and >2 million deaths each year. TB control essentiallyrelies on improvement of expanded and reliable local microbiologicaldiagnostic capacities, the availability of drugs on a worldwidebasis, and compliance through adequate treatment strategy. Otherrelated problems include the AIDS epidemic, less access to healthservices in countries needing it badly, and increasing multidrugresistance. Due to increased human migration from high-prevalenceareas, there may also be a danger of the spread of multidrug-resistantTB and consequently a need for earlier detection of new outbreaks(8). A better knowledge of moving and expanding clones, suchas Beijing (2, 3), that may harbor various degrees of virulence(25) is also urgently needed. In this context, the genotypingof tubercle bacilli and the study of the virulences of variousclones from different settings may help to better define TBcontrol measures.

Complementary to traditional epidemiology, molecular epidemiologybased on PCR fingerprinting methods, such as spacer oligonucleotidetyping (spoligotyping) (13), has emerged as a fast, reliable,and cost-effective alternative to traditional IS6110 restrictionfragment length polymorphism (RFLP) fingerprinting. Based onthe variability of the direct-repeat (DR) locus (9, 10, 13,14, 27, 29), spoligotyping is useful both for tracking epidemics(2, 7, 12, 13, 15, 32) and to detect new outbreaks and betterdefine high-risk populations in order to focus prevention strategieson the subpopulations that need them most (28). In this context,the construction of polymorphism databases constitutes a powerfultool for studying the epidemiology and evolutionary geneticsof tubercle bacilli (23) and, ultimately, the mechanisms ofgenetic variability by using data-mining methods (19). However,previous databases were only poorly representative of the worldwidediversity of Mycobacterium tuberculosis genomes (20, 21, 22),e.g., the previously published 259 shared types (identical spoligotypesshared by two or more patient isolates; available online athttp://www.cdc.gov/ncidod/EID/vol7no3/sola_data.htm) containedmore than two-thirds of the isolates from Europe and the UnitedStates. Nonetheless, these initial studies supported the factthat a significant number of M. tuberculosis isolates are confinedto specific geographic locations (20, 21, 22).

In this article, we describe an update on the global distributionof M. tuberculosis complex spoligotypes (SpolDB3.0). With atotal of 13,008 patterns from >90 countries, the SpolDB3.0database contains both the octal (4) and binary (13) descriptionsof the spoligotypes for all the current M. tuberculosis complexmembers (M. tuberculosis, Mycobacterium africanum, Mycobacteriumbovis, Mycobacterium microti, Mycobacterium canetti, and Mycobacteriumcaprae). It also better describes the diversity of TB genotypes,since the 24 most prevalent alleles now represent only 53% ofthe total instead of 65%, as in a previous study (22). Similarly,the computation of the genetic diversity index (H [24]) givesan H of 97.4% with the current version of the database comparedto 93% with the previous version of the database.

MATERIALS AND METHODS

Top

Materials and Methods

Database. Spoligotyping was performed using a methodology reported earlier(13). It is assumed that most of the new shared types representtrue polymorphism and highlight both past and present populationgenetics of the M. tuberculosis complex. A total of 558 newalleles, observed at least twice, were added to the previouslypublished data (22). The database (SpolDB3.0), containing sharedtypes ST1 to 817, is available upon request or at http://www.pasteur-guadeloupe.fr/tb/spoldb3.htm(note that ST 633, 714, 729, and 770 were removed from the databasedue to artifacts and will be attributed at a later stage). SpolDB3.0contains a total of 11,708 entries in an Excel spreadsheet,representative of various continents as follows: Africa, 1,303(Burundi, n = 12; Burkina Faso, n = 1; Central African Republic,n = 122; Cameroon, n = 380; East Africa [undefined], n = 15;Egypt, n = 25; Ethiopia, n = 2; Guinea-Bissau, n = 189; IvoryCoast, n = 25; Kenya, n = 8; Mozambique, n = 4; Mauritania,n = 2; Namibia, n = 76; Rwanda, n = 2; Senegal, n = 64; Somalia,n = 3; Tunisia, n = 3; Tanzania, n = 1; Uganda, n = 5; SouthAfrica, n = 123; Zimbabwe, n = 241); Asia, 1,048 (Middle Eastand Central Asia, n = 291; Far East Asia, n = 757); Middle Eastand Central Asia (Comoro Islands, n = 1; India, n = 44; Iran,n = 108; Sri Lanka, n = 3; Mauritius, n = 2; Madagascar, n =62; Pakistan, n = 53; Reunion Island, n = 12; Saudi Arabia,n = 6); Far East Asia (China, n = 50; Indonesia, n = 29; Japan,n = 6; South Korea, n = 1; Malaysia, n = 27; Mongolia, n = 18;Philippines, n = 45; Thailand, n = 11; Vietnam, n = 570); Europe,3,927 (Austria, n = 455; Belgium, n = 71; Switzerland, n = 1;Czech Republic, n = 8; Germany, n = 51; Denmark, n = 214; Spain,n = 103; France, n = 727; United Kingdom, n = 828; Ireland,n = 96; Italy, n = 203; Netherlands, n = 929; Portugal, n =2; Romania, n = 10; Russia, n = 160; Sweden, n = 69); Americas,5,157 (North America, n = 3,860; Central America, n = 530; SouthAmerica, n = 767); and Oceania, 273 (Australia, n = 194; NewZealand, n = 32; French Polynesia, n = 1; United States-Hawaii,n = 46). The patterns from the Americas could be further split:North America (United States, n = 3,850; Canada, n = 10); CentralAmerica (Barbados, n = 6; Cuba, n = 219; Guadeloupe, n = 171;Haiti, n = 86; Honduras, n = 1; Martinique, n = 44; Mexico,n = 3); and South America (Argentina, n = 192; Bolivia, n =4; Brazil, n = 248; Curaçao, n = 1; Chile, n = 2; Ecuador,n = 2; French Guiana, n = 191; Peru, n = 3; Surinam, n = 6;Venezuela, n = 118). It should be emphasized that the exactcountry designation was not available for some isolates fromEast Africa and that Madagascar (MDG) was included in subcontinent6 (Middle East and Central Asia) for historical and anthropologicalreasons. Finally, in SpolDB3.0, the M. tuberculosis type strain,H37Rv (ST 451); the vaccinal strain M. bovis BCG (ST 482); andthe rare species M. canettii (ST 592), M. microti (ST 639, 640,641, and 642), and M. caprae (ST 644, 645, 646, 647, and 648)have been mentioned under the column geographic specificity.M. africanum and M. bovis isolates have not been marked specificallybut are easily recognizable on the basis of their specific spoligotypesignatures, i.e., the absence of spacers sp8, -9, and -39 inM. africanum (30) and sp39 to -43 in M. bovis (13).

Description of SpolDB3.0 and definition of indices. In SpolDB3.0, the first column (type) attributes a number toeach spoligotype in our database, the second column (full spoligotypedescription) shows the patterns obtained, the third column (octalnomenclature) shows the representation of the binary patternsaccording to the octal nomenclature described previously (4),the fourth column (geographic specificity) shows the sourceof the data (provider country) recorded as a three-digit ISO3166code (available at http://www.din.de/gremien/nas/nabd/iso3166ma),the fifth column (total) shows the total number of isolatesfor each of the shared types described, the sixth column showsthe percentage of a given spoligotype in the database, and theseventh column (area) shows the number of provider countriesreporting the particular shared type. The eighth column showsthe matching code (MC), which summarizes the information recordedon the geographical specificity of a given shared type (1, Africa;2, North America; 3, Central America; 4, South America; 5, Europe;6, Middle East and Central Asia; 7, Far East Asia; and 8, Oceania).A one-digit number (value, 1 to 8) means that the shared typeis observed in a single continent, whereas a two (or more)-digitnumber suggests an intercontinental match for a given sharedtype. The number of digits increases with the geographical spreadingof a given shared type. Although the MC describes both old (inextinction) and new (epidemic) alleles at this stage, its significancewill increase when the relative phylogenetic position of eachspoligotype allele is known. Indeed, the exact dynamics behindthe relative contribution of each of the given spoligotypesmay not be easy to assess, e.g., rare and localized clones maybe either undergoing extinction or emerging. The ninth columnin SpolDB3.0 shows the spreading index (SI), which is obtainedby dividing the total number of isolates for a given sharedtype by the number of areas where it has been observed. As opposedto the MC index, which gives an idea of the geographical specificity(the number of continents where similar shared types are found),the SI provides a quantitative indicator. Thus, for a givenspoligotype, the correlation among the MC, SI, and areas (Ar)of distribution, according to ISO3166 codes, and the spoligotypingstructure may help us to infer if a clone is undergoing extinctionor emerging. The 10th and 11th columns, respectively, show thequalifiers C1 and C2 that tentatively define a shared type asendemic, localized, or ubiquitous (C1) and as rare, recurrent,common, or epidemic (C2). The qualifiers C1 and C2 and sometypical examples extracted from SpolDB3.0 are described in thealgorithm illustrated in Fig. 1. Indeed, the epidemic historyof the disease in a given setting may provide important cluesabout the spreading of a given spoligotype, e.g., in low-prevalencecountries, identical spoligotypes are more likely than in high-prevalencecountries to represent past transmission events. It should bementioned, however, that these qualifiers are not definitive,and they may be revised when the database grows further.

View larger version (27K):
[in this window]
[in a new window]
FIG. 1. Definition of qualifiers C1 and C2 according to geographic and quantitative distributions of spoligotypes in SpolDB3.0 with examples.

Another Excel spreadsheet (not shown in the link to SpolDB3.0provided above) contains the precise source of all informationprocessed, such as the countries and names of all investigatorsand key identification numbers for strain identification. Inthe following analysis, matching of shared types was done betweengeographic areas of isolation and not between nationalities.

Visual rules for defining major spoligotyping families. Simultaneous analysis of a visual pattern made up of a binarysuccession of information of 43 bits is not an easy task forthe human brain. Octal numbering (4) is an improvement for databasestorage but has not yet proven useful for taxonomic and phylogeneticanalysis. Moreover, previous work using mathematical modelinghas shown that not all spacer positions in a spoligotype carrythe same amount of information (19). Consequently, in orderto better recognize patterns visually, we found it convenientto define six major visual rules as follows: rule A, absenceof sp29 to -32, presence of sp33, and absence of sp34; ruleB, absence of sp21 to -24 and sp33 to -36; rule C, absence ofsp18 and sp33 to -36; rule D, absence of sp39 to -43; rule E,absence of sp31 and sp33 to -36; rule F, absence of sp33 to-36. These six major rules were used together with the precisedescription of the extra missing spacers (minor rules) to definea total of 36 major clades of circulating M. tuberculosis isolates(5; http://www.cdc.gov/ncidod/EID/vol8no11/02-0125-Table.htm).Some major clades identified are the Beijing clade; the EastAfrican-Indian (EAI) clade; the Haarlem clade; the Latin Americanand Mediterranean (LAM) clade; the Central Asian (CAS) clade;a European clade of IS6110 low banders, i.e., isolates containing $<=$ 4 copies of the IS6110 element (X; highly prevalent in the UnitedStates and United Kingdom); and a widespread yet poorly definedclade (T) characterized by the absence of sp33 to -36.

RESULTS

Top

Results

Global distribution of the shared types. The 13,008 spoligotype patterns were grouped into 813 sharedtypes containing 11,708 (90%) of the isolates and 1,300 (10%)orphan patterns (clinical isolates showing unique spoligotypes).Since the publication of the previous database (22), the numberof clustered isolates (shared types) has increased from 84 (2,779of 3,319) to 90% (11,708 of 13,008). An identical clusteringrate was found in the largest spoligotyping study publishedso far, which was performed in Texas and totaled 1,283 patients(20).

The distribution of the shared types, their respective sizes,and their relative distributions in different locations aresummarized in Fig. 2. The 20 most frequent types among the 813shared types totaled 5,865 clinical isolates, i.e., 50% of allthe clustered isolates. Three of these profiles correspond toM. bovis: types 683 and 481 for M. bovis and type 482 for M.bovis BCG. The addition of the next 30 most frequent spoligotypesslightly increased the total number of shared types assessed(65% instead of the initial 50%). SpolDB3.0 better describesthe diversity of TB genotypes, since the 24 most prevalent allelesnow represent only 53% of the total instead of 65% as in theprevious study (22). The computation of the genetic diversityindex (24) is done using the formula H = 2n(1 - ${Sigma}$ x_i²)/2n - 1,where H is the genetic diversity index, x is the frequency ofthe allele i, and n is the population size, giving an H valueof 97.4% with the current version of the database. An identicalcalculation with the previous version gave an H value of 93%(22).

View larger version (29K):
[in this window]
[in a new window]
FIG. 2. Histograms derived from the database summarizing the distribution of shared types (A), their sizes (B), and their relative distributions in different locations (C).

In Fig. 2A, which depicts the 20 most frequent spoligotypes,the Beijing type (ST 1) is the most frequent (1,282 isolates,or 11% of all clustered isolates), followed by the Haarlem type(ST 47 and ST 50, representing $~$ 6% of all clustered isolates).The newly designated X1 and X2 spoligotypes (ST 119 and ST 137),which tend to be highly prevalent in the United Kingdom andthe United States, represent 6.4% of the clustered isolates.Figure 2B shows that one-third of all the shared types consistof two isolates only. This result suggests an important localdiversity of spoligotyping. Nonetheless, a match of two identicalbut rare spoligotypes found in a single setting is differentfrom a match found by database comparison of two widely separatedisolates. The first case may be an early indicator of clonalexpansion and ongoing transmission, whereas the second case,depending on the spoligotype, is likely to be due to homoplasy(independent acquisition of two similar structures without commonancestors). Alternatively, such matches, whether near extinctionor not, may also reflect past epidemiological events. Figure2C shows that one-third of the shared types are repeatedly foundwithin a single geographic area. This result corroborates theobservations from Fig. 2B and suggests that spoligotyping performedas a single genotyping method in a new setting may be a goodindicator of strain identity and helps to produce a precisepicture of epidemiologically important clones.

Matching analysis of shared types found in one or two geographic locations. Table 1 shows the results of matching analysis of shared typeswhich have been reported in one or two continental regions asdefined in Materials and Methods (n = 625). This analysis demonstratesthat the diversity of clustered spoligotypes is high withinEurope (n = 163), the United States (n = 119), and Africa (n= 53). When the sample size is normalized, the diversity, limitedto a specific continent (the number of shared types limitedto a given continent divided by the total number of isolateswithin the continent), appears to be highest within Europe (n= 163 of 3,927, or 0.041), followed by Africa (n = 53 of 1,303,or 0.039) and the United States (n = 119 of 5,157, or 0.023).On the other hand, the lowest diversity is found in the FarEast (n = 9 of 757, or 0.011). The greatest number of intercontinentalmatches is found between North America and Europe (n = 88).This class is made up of clones that are likely to represent,at least partly, historical TB transmission events between Europeand the United States, a phenomenon that may be explained eitherby the relatively old demographic links between these two continentsor by recent transmission from identical high-prevalence countries.A significant number of these intercontinental matches are alsofound between Africa and Europe (n = 22), South America andEurope (n = 17), Central America and Europe (n = 13), the MiddleEast and Europe (n = 13), and, to a lesser extent, between FarEast Asia and North America (n = 12). These data should be interpretedin the light of old, as well as recent, migratory flux and deservefurther study. Among the matches between Europe and the MiddleEast and Central Asia, a majority concerned IS6110 low bandersfrom the United Kingdom that are known to be linked to the EAIclade of M. tuberculosis (14, 23). However, the recent findingof a spoligotype harboring a typical EAI signature (sp29 to-32 with sp34 missing) in a sample from 15th-century M. tuberculosisDNA found in the Wharram Percy medieval village in the UnitedKingdom is controversial as far as the precise origin of theEAI clade (16).

View this table:
[in this window]
[in a new window]
TABLE 1. Total numbers of intercontinental matches of shared types among eight continents and subcontinents^a

Snapshot of moving and expanding clones of M. tuberculosis and their global distribution. In a previous report on 259 shared types observed for 3,319isolates from 47 countries, at least six major clades of tuberclebacilli were described (22). The present study permitted usto define a total of 36 potential superfamilies of spoligotypesusing visual major rules A to F, defined in Materials and Methods,and a number of minor rules available online at http://www.cdc.gov/ncidod/EID/vol8no11/02-0125-Table.htm.Automated Excel labeling of the whole database (n = 813 sharedtypes) following the visual rules defined above, and on a totalof nine superfamilies of strains (M. africanum, Beijing, M.bovis, EAI, CAS, T group of families, Haarlem, X family, andLAM family), resulted in the labeling of 788 of 813 (96.9%)shared types. These results should be further assessed and generalizedusing data-mining methods (19).

The distribution of the most frequently observed spoligotypes,schematized in Fig. 3, underlined some major differences amongthe continental regions studied, e.g., the number of orphantypes (or singletons) ranged from a low of 8% (North America)to a high of 21% (Middle East and Central Asia). Similarly,minor shared types ranged from 12% in the Far East to >50%in Europe and the Middle East and Central Asia. Among majorclades, the heterogeneity of the distribution of the Beijingtype (type 1 in the database) was noteworthy: it ranged from<2% in South America to 3 to 5% in Central America, Europe,Africa, and the Middle East and Central Asia, 13% in Oceania,16% in North America, and as high as 45% in the Far East. Consideringthe multidrug resistance of the Beijing strains (2, 3, 29),the high prevalence of this clade in certain regions of theworld is an important issue for effective TB control. Anotherinteresting feature from Africa is the significantly high proportionof M. africanum strains (type 181), which represent 6% of allspoligotypes.

View larger version (45K):
[in this window]
[in a new window]
FIG. 3. Global distribution of M. tuberculosis complex spoligotypes assessed on 11,708 clustered isolates split into 813 shared types by continental regions, as defined in SpolDB3.0 (http://www.pasteur-guadeloupe.fr/tb/spoldb3).

DISCUSSION

Top

Discussion

Some recent papers have dealt with the construction of spoligotypingdatabases (20, 21, 22). Soini et al. (20) described a studyof 1,429 M. tuberculosis isolates from 1,283 patients as partof an ongoing population-based TB epidemiology study in Houston,Tex. This paper was soon followed by a report of the biogeographicaldistribution of 3,319 spoligotype patterns and 259 shared typesfrom 47 countries worldwide (22). The first study essentiallyfocused on isolates from patients residing in a single statein the United States, whereas in the second study, >73% ofthe isolates described were from Europe and the United States.Despite these limitations, the studies underlined the fact thata significant number of M. tuberculosis isolates in circulationwere essentially confined to specific geographic locations (20,22). By including new spoligotyping data from all over the world,SpolDB3.0 has increased the overall representation; nonetheless,a more representative description of the worldwide diversityof tubercle bacilli should be possible through the acquisitionof information from Asian and African countries.

The construction of global polymorphism databases constitutesa powerful tool, as it permits a quantitative estimation ofthe measure of DNA variations at the chromosomal level by thenumber of genetic structures observed so far. Similarly to whatis done in Drosophila melanogaster population genetics, whereinversions have been classified as "common ubiquitous, rareendemic, recurrent endemic and unique endemic" (24), we attemptedto categorize most of the geographic variations in the DR lociobserved so far by spoligotyping, so as to have a better knowledgeof moving and expanding clones of M. tuberculosis. For thispurpose, we introduced new indices (MC and SI) and qualifiers(C1 and C2) in order to better describe the spatiotemporal statusof natural populations of the M. tuberculosis complex. For thespatial distribution, the populations studied were defined asendemic, localized, or ubiquitous. For the quantitative distribution,the populations were defined as epidemic, common, recurrent,or rare. These definitions synthetically define a spatiotemporalstatus for each shared type and, together with its genetic structure,may provide a global idea of its evolutionary history.

The results obtained also underline the well-known fact thatcasual contacts and sporadic cases, although difficult to detect,are responsible for most of the microepidemics and constitutean important means of TB transmission (6). Our next objectiveis to better describe the genetic diversity of the M. tuberculosiscomplex worldwide, which may be achieved by recruitment of adequateclinical isolates or DNA samples or inclusion of representativespoligotyping data in the database. Construction of new mathematicalmodels that permit an interpretation based on the combinationof DNA fingerprinting, epidemiological, and demographical datashould further improve our knowledge of evolutionary processesthat intervene in the development and spread of infectious diseases.

Regarding the genetic variability of the DR locus, it was recentlyshown to be a part of a larger family of sequence repeats amongprokaryotes (11). Much remains to be done to precisely definethe potential phylogenetic links within various alleles of thislocus, as well as to investigate potential links that are foundacross individual studies targeting local epidemiological issues,particularly since TB does not respect man-made frontiers. Littleis also known about the microevolutionary events associatedwith the DR locus and how they may influence the interpretationof both spoligotyping and IS6110 RFLP data (31). Indeed, differentisolates from the same strain family and isolates from differentstrain families may rarely converge to give the same spoligotypepattern (31). Though of limited importance, this bias may beinvestigated in detail in future by using second-generationspoligotyping based on a set of new spacer oligonucleotides(26) or by assessment of other genetic markers (18) in selectedstrains. The management of such projects will be facilitatedby automation of data entry and data mining to further updateSpolDB3.0 (1, 19). The data acquisition, similarity search,and matching process; labeling; and translation from binaryto octal format and vice versa are already automated, and futuredata exchange and internet working of SpolDB3.0 with other databases(such as IS6110 RFLP or mycobacterial interspersed repetitiveunits) should soon allow new queries to be screened againstan updated version.

The facility by which detection of matches between potentiallylinked strains can be achieved may make SpolDB3.0 a new toolfor international studies of TB transmission. Indeed, the detectionof a match between two rare profiles in SpolDB3.0 may be a startto gathering complementary genotyping information, such as IS6110RFLP or polymorphic GC-rich-sequence RFLP in other internationaldatabases, to demonstrate clonality of the studied isolates(17) and to detect unsuspected epidemiological links. In conclusion,SpolDB3.0 constitutes a potential tool for global TB epidemiologyand population genetics and M. tuberculosis complex taxonomyand phylogeny. It underlines major differences in the populationstructures of tubercle bacilli within the eight subcontinentsstudied, and by using new indices and qualifiers, it has ledto better interpretation methods and the possibility of futurecomparison with other methods, such as mycobacterial interspersedrepetitive units (18). Nevertheless, further work is still neededto get a more exhaustive global picture of worldwide tuberclebacillus genetic variability. Another major issue will be theability to link this genetic diversity to virulence and/or fitnessfactors and ultimately to the genetic predisposition factorsof the human or animal hosts.

ACKNOWLEDGMENTS

We are highly grateful to G. Källenius and T. Koivula (Sweden),P. Palittapongarnpim (Thailand), H. Kasai (Japan), G. Haase(Germany), and R. Frothingham (United States) for their collaboration.We also thank all investigators who transmitted their spoligotypingdata to Institut Pasteur de Guadeloupe or the RIVM in Bilthoven,as well as other investigators who published studies with exhaustivedescriptions of their spoligotyping patterns and the originsof the isolates, allowing such databases to be constructed.

This work was supported through grants by the DélégationGénérale au Réseau International des InstitutsPasteur et Instituts Associés, Institut Pasteur, Paris,France, and the Fondation Française Raoul Follereau,Paris, France. It also benefited from the EU Project QLK2-CT-2000-630,entitled New Generation Genetic Markers and Techniques for theEpidemiology and Control of Tuberculosis.

FOOTNOTES

* Corresponding author. Mailing address: Unité de la Tuberculose et des Mycobactéries, Institut Pasteur de Guadeloupe, Morne Jolivière, BP 484, 97165 Pointe à Pitre-Cedex, Guadeloupe. Fax: 590 (590) 893 880. E-mail for Christophe Sola: csola{at}pasteur-guadeloupe.fr. E-mail for Nalin Rastogi: nrastogi{at}pasteur-guadeloupe.fr.

This work is dedicated to the memories of Anne Devallois, whoinitiated the spoligotyping project in Guadeloupe in 1996 butdied tragically at the age of 30 years, and Gerald Martin, coinvestigator,who also died tragically during the course of the present study.

REFERENCES

Top