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Sudan: the possible original focus of visceral leishmaniasis

Published online by Cambridge University Press:  12 July 2001

F. PRATLONG ,
J. DEREURE ,
B. BUCHETON ,
S. EL-SAFI ,
A. DESSEIN ,
G. LANOTTE  and
J. P. DEDET
F. PRATLONG
Affiliation:
Laboratoire de Parasitologie et Centre National de Référence des Leishmanioses, CHU de Montpellier, 163 Rue Auguste-Broussonet, 34090 Montpellier, France
J. DEREURE
Affiliation:
Laboratoire de Parasitologie et Centre National de Référence des Leishmanioses, CHU de Montpellier, 163 Rue Auguste-Broussonet, 34090 Montpellier, France
B. BUCHETON
Affiliation:
Immunologie et Génétique des Maladies parasitaires, INSERM U 399, Faculté de Médecine, 27 Boulevard Jean-Moulin, 13385 Marseille Cedex 05, France
S. EL-SAFI
Affiliation:
Institute for Tropical Medicine, P.O. Box 1304, Khartoum, Sudan
A. DESSEIN
Affiliation:
Immunologie et Génétique des Maladies parasitaires, INSERM U 399, Faculté de Médecine, 27 Boulevard Jean-Moulin, 13385 Marseille Cedex 05, France
G. LANOTTE
Affiliation:
Laboratoire de Parasitologie et Centre National de Référence des Leishmanioses, CHU de Montpellier, 163 Rue Auguste-Broussonet, 34090 Montpellier, France
J. P. DEDET
Affiliation:
Laboratoire de Parasitologie et Centre National de Référence des Leishmanioses, CHU de Montpellier, 163 Rue Auguste-Broussonet, 34090 Montpellier, France
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Abstract

Fifty-two Leishmania strains, obtained from human patients and dogs in a visceral leishmaniasis focus in Sudan, were characterized by isoenzyme electrophoresis (15 enzymes). The phylogenetic analysis showed that the 7 Leishmania zymodemes obtained hold ancestral positions on the phylogenetic tree, supporting the hypothesis of an East African origin of visceral leishmaniasis.

Keywords

LeishmaniasystematicsphylogenyLeishmania donovaniLeishmania archibaldiLeishmania infantumSudan
Type
Research Article
Information
Parasitology , Volume 122 , Issue 6 , June 2001 , pp. 599 - 605
Copyright
© 2001 Cambridge University Press

INTRODUCTION

Visceral leishmaniasis (VL) is a protozoal disease caused by Leishmania parasites present in 47 countries in 4 continents, with an estimated annual incidence of 500000 cases Desjeux, 1996). Two species belonging to the Leishmania subgenus are usually incriminated: Leishmania donovani (anthroponotic cycle) and L. infantum (zoonotic cycle). According to Garnham (1965), VL primitive foci are supposed to be located in Central Asia. This hypothesis should be challenged by a recent eco-epidemiological investigation carried out in Sudan, with identification of a large amount of VL strains.

VL was first reported from Sudan by Neave (1904). Since that date, VL has been found to be endemic in various parts of the country, with the occurrence of epidemic outbreaks, and represents an important public health problem. The parasite responsible from VL in Sudan was initially assigned to Leishmania donovani or L. archibaldi, while L. infantum was detected later. The taxonomic status of the Leishmania responsible for VL from Sudan has always been controversial.

An eco-epidemiological investigation carried out in 1997–98 in Gedaref state of Sudan, lead us to re-evaluate the taxonomic status of the 3 taxa by isoenzyme description of a large sample of human and canine strains. The phylogenetic analysis based on these strains supports the hypothesis of an East African origin of visceral leishmaniasis.

MATERIALS AND METHODS

Strains

Fifty-two Leishmania strains were studied, of which 49 were obtained from humans, and included 43 from VL cases, 5 from post-kala-azar dermal leishmanoids (PKDL) and 1 from a cutaneous leishmaniasis case (CL), and 3 were obtained from canine VL (CVL). (Table 1).

The sample collection was made from inguinal lymph nodes in the VL cases, popliteal lymph nodes in CVL cases, and from cutaneous biopsies for PKDL and CL cases. The strains were isolated on NNN medium with rabbit blood and 9‰ saline plus 250000 I.U./ml benzyl penicillin.

Biochemical description

Starch gel electrophoresis was performed according to the method described by Rioux et al. (1990), using the following 15 enzymatic systems. Malate dehydrogenase, MDH, EC 1.1.1.37; malic enzyme, ME, EC 1.1.1.40; isocitrate dehydrogenase, ICD, EC 1.1.1.42; 6-phosphogluconate dehydrogenase, PGD, EC 1.1.1.44; glucose-6-phosphate dehydrogenase, G6PD, EC 1.1.1.49; glutamate dehydrogenase, GLUD, EC 1.4.1.3; NADH diaphorase, DIA, EC 1.6.2.2; purine nucleoside phosphorylase 1, NP1, EC 2.4.2.1; purine nucleoside phosphorylase 2, NP2, EC 2.4.2.*; glutamate-oxaloacetate transaminases, GOT1 and GOT2, EC 2.6.1.1; phosphoglucomutase, PGM, EC 5.4.2.2; fumarate hydratase, FH, EC 4.2.1.2; mannose phosphate isomerase, MPI, EC 5.3.1.8; glucose phosphate isomerase, GPI, EC 5.3.1.9.

Isoelectrofocusing was used as a technique of greater resolving power for glutamate oxaloacetate transaminase (Piarroux et al. 1994). The isoenzymatic profiles of the reference strains used are presented in Table 2.

Table 2. Enzyme profiles of the 53 reference strains of Old World Leishmania used in this study (Zymodemes found in Sudan in grey panel)

Phenetic and cladistic analysis

For the taxonomic study, 53 operational taxonomic units (OTU), corresponding to the zymodemes, were used. Of these 49 were included in the phylogenetic complexes as defined by Rioux & Lanotte (1993), 30 for the L. infantum phylogenetic complex, 16 for the L. donovani phylogenetic complex (including the L. archibaldi taxon), 2 for the L. tropica phylogenetic complex and 1 for the L. killicki phylogenetic complex, (these last 2 complexes being used as sister groups), and the 4 new zymodemes detected during the present study.

The phenogram was built using the Jaccard distance index (Sj), with the aggregative strategy of complete links (Jaccard, 1908). The cladogram construction was based on Hennig's principles (Hennig, 1965) and used the MIX software of Felsenstein.

RESULTS

Seven different zymodemes included in the 3 taxa L. donovani, L. archibaldi and L. infantum were obtained within the 52 Leishmania strains studied (Table 1). The distribution of these zymodemes according to host is as follows. L. donovani MON-18 (n = 31) and MON-274 (n = 1), L. infantum MON-30 (n = 10) and MON-267 (n = 1), L. archibaldi MON-257 (n = 5), and MON-258 (n = 1) from humans, and L. infantum MON-267 (n = 1) and L. archibaldi MON-82 (n = 1) and MON-257 (n = 1) from dogs (Table 2). Zymodemes MON-257, MON-258, MON-267 and MON-274 are new zymodemes found during the present study, to which is added the L. infantum MON-81 zymodeme previously described from Sudan (Moreno, 1989) (Table 2).

The phenogram based on 53 OTU shows 3 branches clearly individualized (Sj = 0.27) (Fig. 1). The first branch (A), corresponding to L. infantum, includes a group of 31 zymodemes: MON-1, MON-11, MON-24, MON-27, MON-28, MON-29, MON-30, MON-33, MON-34, MON-72, MON-77, MON-78, MON-80, MON-81, MON-98, MON-105, MON-108, MON-111, MON-136, MON-183, MON-185, MON-187, MON-188, MON-189, MON-190, MON-198, MON-199, MON-201, MON-228, MON-253 and MON-267. The second one (B), corresponding to L. donovani, includes a group of 16 zymodemes: MON-2, MON-3, MON-18, MON-31, MON-32, MON-35, MON-36, MON-37, MON-38, MON-73, MON-83, MON-84, MON-138, MON-191, MON-268 and MON-274. The third (C), corresponding to L. archibaldi, includes 3 zymodemes: MON-82, MON-257 and MON-258.

Fig. 1. The phenogram built on the base of 53 OTU (Jaccard index; complete links) shows 3 groups: Leishmania infantum (A), L. donovani (B) and L. archibaldi (C).

The most parsimonious cladistic tree, based on 15 characters (genenzymes) and 59 states (allozymes), has 70 evolutionary steps (Fig. 2). It clearly shows 3 branches, corresponding to L. infantum, L. archibaldi and L. donovani, as defined by Rioux et al. (1990), and directly depending on the variation of the glutamate oxaloacetate transaminase (GOT1 and GOT2), and markedly distinct from L. tropica and L. killicki.

Fig. 2. The most parsimonious cladogram has 70 evolutive steps. It shows clearly 3 branches corresponding respectively to the phylogenetic complexes Leishmania infantum, L. donovani and L. archibaldi.

The 8 zymodemes found in Sudan are located at the base of these branches, in an ancestral position.

DISCUSSION

Shortly after the discovery of the parasite causing VL in India (Laveran & Mesnil, 1903), it was named L. donovani. The worldwide distribution of the disease led the authors to name various taxa according to geographical origin and clinical and epidemiological features. So, in addition to L. donovani (India) the following names were proposed: L. infantum for the Mediterranean basis (Nicolle, 1908), L. donovani var. archibaldi for East Africa (Castellani & Chalmers, 1919), and L. chagasi in South America (Cunha & Chagas, 1937). Linnaean classifications essentially based on extrinsic characters (Lumsden, 1974), of which the up-dated version is that of Lainson & Shaw (1987), include all these taxa within the ‘L. donovani complex’.

The names L. donovani archibaldi and L. archibaldi have been used indiscriminately by various subsequent authors for the parasite responsible for VL in Sudan. Brumpt (1936) included L. donovani var. archibaldi as a synonym of L. donovani. L. donovani has also been reported in Sudan in sporadic cutaneous leishmaniasis cases in humans and in a few wild animals (Adler, Foner & Montiglio, 1966).

The first identifications of the parasite responsible for leishmaniasis in Sudan, using serological criteria, were made by Adler et al. (1966). The identification of the parasite as L. donovani was later confirmed by other criteria, such as excreted factor, DNA buoyant density and isoenzyme characters (Chance et al. 1978; Schnur & Zuckerman, 1977; Schnur et al. 1981).

Description of more Sudanese strains by isoenzymes showed polymorphism. Various L. donovani zymodemes were described by Le Blancq & Peters (1986), El-Hassan et al. (1993) and Ibrahim et al. (1995), and 4 zymodemes were reported as belonging to the 2 taxa, L. donovani and L. infantum, by Moreno (1989).

Numerical methods were applied to the taxonomy of Leishmania by Lanotte et al. (1981) using isoenzyme characters; within the ‘L. donovani complex’, these authors recognized the ‘L. infantum complex’. The continuation of the work of this group lead Moreno et al. (1986) to confirm the division of L. donovani s.l. into 2 new systematic complexes: L. donovani nov. sens and L. infantum nov. comb. This division was based on the variation of the GOT enzyme (GOT1131 and GOT1132 for L. donovani and GOT1001 and GOT1002 for L. infantum) and was supported by epidemiological arguments (anthroponotic zymodemes in the case of L. donovani versus zoonotic ones for L. infantum).

The name L. archibaldi was reintroduced by Rioux et al. (1990) for a single zymodeme (MON-82), the taxonomic position of which is not clearly established on the phenogram: sometimes this zymodeme clusters with L. donovani, sometimes with L. infantum, while it appears in the phylogenetic tree as a distinct branch, between the L. donovani and L. infantum branches. The zymodemes at the base of these branches are those from Sudan (MON-18 from L. donovani and MON-30 for L. infantum). Rioux et al. (1990), proposed a phenetic classification in which L. archibaldi was included in the phenetic complex L. donovani.

In the phylogenetic complexes suggested by Rioux & Lanotte (1993), L. archibaldi is included within the L. donovani complex, distinct from the L. infantum complex.

The 3 zymodemes MON-18, MON-82 and MON-30 originating from Sudan and placed in an ancestral position on the cladogram of Rioux et al. (1990), were found again in 2 later studies of different foci carried out by Ashford et al. (1992) and Oskam et al. (1998). According to Rioux et al. (1990), MON-18 is the ancestral zymodeme of the L. donovani complex and MON-30 is the ancestral zymodeme of the L. infantum complex.

Recognition of these systematic complexes on the basis of GOT enzyme variation is contested by various authors who suggest grouping the zymodemes belonging to these two taxa in a single group L. donovani sensu lato (Ashford et al. 1992).

During an epidemiological survey carried out in the Gedaref province of Sudan, the parasites responsible for human VL and CVL were identified using the same techniques as the previous works. In addition to the 3 zymodemes previously discussed and to the L. infantum MON-81 previously described (Moreno, 1989), 4 new zymodemes were found (MON-257, MON-258, MON-267, MON-274) among a large sample of strains.

Phenetic analysis showed 3 branches clearly delineated and linked at a high level (S = 0.27). Two of these groups were later designated as the phenetic complexes L. infantum (group A) and L. donovani (group B) (Rioux et al. 1990). The third group separated at the same level as the previous ones, should be designated as L. archibaldi, as including the MON-82 zymodeme. These 3 groups are also individualized on the cladogram as 3 distinct branches according to the values of the GOT enzyme, of which GOT1101 and GOT1102 are diagnostic for L. archibaldi.

The authenticity of the L. donovani and L. infantum phenetic and phylogenetic complexes, based on isoenzyme analysis and supported by epidemiological criteria (anthroponotic versus zoonotic), should allow the separation L. archibaldi as a new complex. The recent evidence of L. archibaldi in humans and dogs (Dereure et al. 2000) is in favour of a zoonotic origin for this complex, an hypothesis yet to be confirmed by a larger epidemiological investigation. An alternative possibility should be to consider these 3 groups as different clusters of the same unit and corresponding to L. donovani sensu lato.

All the zymodemes found in Sudan, including the 4 new ones described during the present study, hold ancestral positions on the phylogenetic tree. This work, based on the analysis of a large number of isolates, gives experimental support to the idea previously expressed by Ashford et al. (1992), that Sudan should be considered as the possible original focus of VL, from which the disease has spread around the world.

The authors would like to thank: Professors D. A. Evans and R. W. Ashford for revision of the manuscript; Y. Balard, G. Serres and P. Lami for expert technical assistance; Mr L. Bertolus for preparation of the figures; and Mrs I. Bourdel for typing the manuscript. This work received financial support from the European Community (INCO-DC no. ERBIC 18CT980373) and the French Ministry of Education, Research and Technology (contract PRFMNIP98). The Centre National de Référence des Leishmanioses receives financial support from French Ministry of Health.

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Figure 0

Table 1. WHO code and isoenzyme identification of 49 human and 3 canine strains studied from the Gedaref state (Sudan)

Figure 1

Table 2. Enzyme profiles of the 53 reference strains of Old World Leishmania used in this study

Figure 2

Fig. 1. The phenogram built on the base of 53 OTU (Jaccard index; complete links) shows 3 groups: Leishmania infantum (A), L. donovani (B) and L. archibaldi (C).

Figure 3

Fig. 2. The most parsimonious cladogram has 70 evolutive steps. It shows clearly 3 branches corresponding respectively to the phylogenetic complexes Leishmania infantum, L. donovani and L. archibaldi.