Christine Blaineau

Genetic nomenclature for Trypanosoma and Leishmania

Christine Clayton *, Mark Adams , Renata Almeida , Theo Baltz , Mike Barrett , Patrick Bastien , Sabina Belli , Stephen Beverley , Nicolas Biteau , Jenefer Blackwell , Christine Blaineau , Michael Boshart , Frederic Bringaud , George Cross , Angela Cruz , Wim Degrave , John Donelson , Najib El-Sayed , Gioliang Fu , Klaus Ersfeld , Wendy Gibson , Keith Gull , Alasdair Ivens , John Kelly , Daniel Lawson , John Lebowitz , Phelix Majiwa , Keith Matthews , Sara Melville , Gilles Merlin , Paul Michels , Peter Myler , Alan Norrish , Fred Opperdoes , Barbara Papadopoulou , Marilyn Parsons , Thomas Seebeck , Deborah Smith , Kenneth Stuart , Michael Turner , Elisabetta Ullu , Luc Vanhamme aa

Conserved linkage groups associated with large-scale chromosomal rearrangements between Old World and New World Leishmania genomes

The genus Leishmania can be taxonomically separated into three main groups: the Old World subgenus L. (Leishmania), the New World subgenus L. (Leishmania) and the New World subgenus L. (Viannia). The haploid genome of Old World Leishmania species has been shown to contain 36 chromosomes defined as physical linkage groups; the latter were found entirely conserved across species. In the present study, we tried to verify whether this conservation of the genome structure extends to the New World species of Leishmania. 300 loci were explored by hybridization on optimized pulsed field gel electrophoresis separations of the chromosomes of polymorphic strains of the six main pathogenic Leishmania species of the New World. When comparing these New World karyotypes with their Old World counterparts, 32 out of 36 linkage groups were found conserved among all species. Four chromosomal rearrangements were found. All species belonging to the L. (Viannia) subgenus were characterized by the presence (i) of a short sequence exchange between chromosomes 26 and 35, and (ii) more importantly, of a fused version of chromosomes 20 and 34 which are separated in all Old World species. 69 additional markers were isolated from a plasmid library specifically constructed from the rearranged chromosomes 20+34 in an attempt to detect mechanisms other than a fusion or breakage: only two markers out of 40 did not belong to the linkage groups 20 and 34. On the other hand, all strains belonging to the New World subgenus L. (Leishmania) were characterized by two different chromosomal rearrangements of the same type (fusion/breakage) as above as compared with Old World species: chromosomes 8+29 and 20+36. Consequently, these two groups of species have 35 and 34 heterologous chromosomes, respectively. Overall, these results show that large-scale chromosomal rearrangements occurred during the evolution of the genus Leishmania, and that the three main groups of pathogenic species are characterized by different chromosome numbers. Nevertheless, translocations seem particularly rare, and the conservation of the major linkage groups should be an essential feature for the compared genetics between species of this parasite.

Structural organisation of microsatellite families in the Leishmania genome and polymorphisms at two (CA)n loci

In the present study, we have analysed the frequency and distribution of several microsatellite DNAs [(CA)n, (GGT)n and (GCA)n] in the genome of Leishmania. Hybridisation analysis on the molecular karyotypes of different Leishmania strains showed the presence of these three microsatellites on all chromosomes of the parasite. The number of microsatellite clusters appeared grossly similar among strains from different Old World complexes. However, these three microsatellite families showed an uneven distribution among heterologous chromosomes of the same strain. Moreover, restriction analysis of chromosome I in various strains of Leishmania infantum showed a strong clustering of these microsatellites in the same chromosomal region. A partial genomic library was screened with a (CA)n probe, and 21 positive clones were isolated. The sequencing of these clones confirmed the association of various microsatellites such as (CA)n, (CT)n, and (GCA)n. Finally, specific polymerase chain reaction amplification of two cloned (CA)n loci demonstrated allelic size polymorphisms among strains within L. infantum and Leishmania donovani. Most of the 34 strains analysed were found to be monoallelic, while two alleles were found in a small number of strains. The interest of these sequences for studies on ploidy and population genetics of the parasite is discussed.

Molecular Karyotype Analysis in Leishmania

The advent of pulsed field electrophoresis has allowed a direct approach to the karyotype of Leishmania. The molecular karyotype thus obtained is a stable characteristic of a given strain, although minor modifications may occur during in vitro maintenance. Between 20 and 28 chromosomal bands can be resolved depending on the strain, ranging in size from approximately 250 to 2600 kb. The technique has revealed a striking degree of polymorphism in the size and number of the chromosomal bands between different strains, and this seems independent of the category (species, zymodeme, population) to which the strains belong. It appears that only certain strains originating from the same geographic area may share extensive similarities. This polymorphism can largely be accounted for by chromosome size variations, which can involve up to 25% of the chromosome length. As a result, homologous chromosomes can exist in versions of markedly different size within the same strain. When this occurs with several different chromosomes, the interpretation of PFE patterns appears difficult without prior identification of the size-variable chromosomes and of the chromosome homologies. DNA deletions and amplifications have been shown to account for some of these size modifications, but other mechanisms are probably involved; nevertheless, interchromosomal exchange does not seem to play a major role in these polymorphisms. These chromosomal rearrangements, yet in an early stage of characterization, exhibit two relevant features: they seem (1) to affect essentially the subtelomeric regions and (2) to occur in a recurrent nonrandom manner. Chromosomal rearrangements sharing the same characteristics have been identified in yeast and other protozoa such as Trypanosoma and Plasmodium. The significance of this hypervariability for the biology of the parasite remains unknown, but it can be expected that such mechanisms have been maintained for some purpose; genes specifically located near chromosome ends might benefit from rapid sequence change, alternating activation, or polymorphism of expression. The chromosomal plasticity could represent a general mode of mutation in these parasites, in parallel with genetic exchange which may be uncommon in nature. The molecular characterization of these rearrangements, the identification of each chromosome with the help of physical restriction maps and linkage maps, and the collation of such data on a number of strains and species should allow a significant progress in the understanding of the genetics of Leishmania, in particular as regards ploidy, generation of phenotypic diversity, and genome evolution. Finally, like other models, this is susceptible to improve our knowledge of DNA-DNA interactions and of the chromosome functional structure and dynamics.

Multiple forms of chromosome I, II and V in a restricted population of Leishmania infantum contrasting with monomorphism in individual strains suggest haploidy or automixy

We have resolved the molecular karyotypes of 22 Leishmania infantum strains isolated between 1980 and 1988 in a restricted geographic area and belonging to zymodemes MON-11, -29 and -33. Three strains were isolated from sandflies and all the others from human cutaneous lesions. A high degree of karyotypic homology is observed among these strains, contrasting with the highly polymorphic MON-1 strains isolated in the same area. We have analysed the time-dependent evolution of size variants of chromosomes I to V, each identified by chromosome-specific DNA probes. More evidence is given for the role of subtelomeric regions in chromosomal size variation in Leishmania for both chromosomes I and II. At the population level, the chromosomes I, II and V are present in respectively 8, 4 and 3 distinct sizes. Furthermore, and despite the small size of the sample, various combinations were observed among these different chromosomal forms. These results could be explained by the occurrence of a high rate of recurrent mutations or of genetic exchange. In contrast, only one chromosomal form was observed in individual karyotypes for the chromosomes I-V. These results could tally with the hypothesis of a haploid organisation for these chromosomes and strains, or, in the frame of a diploid organisation, with the hypothesis of a predominantly automictic sexuality giving rise to 2 identical forms of the homologues in the same strain.

Convervation among Old World Leishmania species of six physical linkage groups defined in Leishmania infantum small chromosomes

We have characterised 49 DNA probes specific for each of the six smallest chromosomes in Leishmania infantum and have examined the allocation of these probes in the molecular karyotypes of the other Old World Leishmania species Leishmania donovani, Leishmania major, Leishmania tropica and Leishmania aethiopica. These 49 probes define 6 physical linkage groups in the molecular karyotypes of various strains of L. infantum. 40 of these probes hybridise in the other Old World Leishmania species and show a remarkably conserved linkage pattern. No interchromosomal exchange nor fusion could be detected. Thus, in spite of the chromosomal size polymorphisms, the general structure of the genome seems to be conserved in the six smallest chromosomes among Old World Leishmania species. This structural genomic homogeneity should be helpful for mapping studies of any Old World Leishmania genomes.

A polymorphic minisatellite sequence in the subtelomeric regions of chromosomes I and V in Leishmania infantum

A minisatellite DNA sequence is described for the first time in Leishmania infantum. It is borne by four chromosomes and consists of an 81-bp repeat unit organised in several clusters. On chromosomes I and V of L. infantum, the clusters are tightly located in the size-variable subtelomeric regions. The organisation of this sequence may be related to that of the subtelomeric interspersed repeat sequences identified in the human genome. The sequencing of seven repeat units, some subcloned from the same cluster, allowed the definition of a consensus sequence of 81 bp, particularly G/C rich (73%). Two subfamilies were clearly defined: one exhibits a 91-95% homology with the consensus sequence; the second one comprises two monomers sharing a 91% homology but only 77% homology with the consensus sequence. The two types of monomers can be found in the same cluster. These data suggest interactions between monomers and a possible role of this sequence in the instability of these regions. Finally, restriction fragment length polymorphisms were revealed by this sequence among various strains of L. infantum. Besides allowing the detection of recombination events in the unstable regions of the chromosomes, this new marker may become a useful tool in the study of the parasite population dynamics in leishmaniasis foci.

A direct method for the chromosomal assignment of DNA markers in Leishmania

A simple method for the chromosomal assignment of any DNA marker would be an important tool for the ongoing project to map the genome of the protozoan parasite Leishmania. The Leishmania chromosomes enter pulsed field gel electrophoresis (PFGE) gels under current electrophoretic conditions, but their direct identification in a given strain is hampered by their stacking in a few chromosomal bands, and by the very frequent size variations of the same chromosome among parasite strains. To overcome these problems. we determined the complete karyotypes of 12 Old World Leishmania cloned strains. This enabled us to select three of these strains that display great chromosome size polymorphisms, such that every chromosome can be individualized by a specific pattern after hybridization onto these three karyotypes. The complete resolution of the genomes of these three strains can be carried out with only three electrophoretic conditions. This makes a series of three blots sufficient for the assignment of any new marker on a particular Leishmania chromosome.

Chromosome fragmentation in leishmania.

Chromosome fragmentation (CF) constitutes one means of manipulating eukaryotic genomes and provides a powerful tool for examining both the structure and function of chromosomes. During the past 15 yr, CF, which is based on the use of transfection, has been widely used in yeast and mammals to elucidate the functional elements required for normal chromosome maintenance. However, in view of the relatively late development of parasite genome projects, this strategy has only been used recently in parasites. Here, we describe basic methods for CF (except telomere-mediated fragmentation) experiments and analysis in Leishmania. Current limitations of this methodology are precisely the lack of knowledge of the nature of centromeres and autonomously replicating sequences in this and other protozoa, the poor understanding of precise recombination mechanisms, as well as the fact that the deletion of unknown genes essential to parasite survival may interfere with recombination events and chromosomal rearrangements. Still, this powerful method has enriched our basic knowledge of chromosomal structure and maintenance.