Long-range restriction maps of size-variable homologous chromosomes in Leishmania infantum

Constitutive mosaic aneuploidy is a unique genetic feature widespread in the Leishmania genus

Using fluorescence in situ hybridization, we determined the ploidy of four species of Leishmania: Leishmania infantum, Leishmania donovani, Leishmania tropica and Leishmania amazonensis. We found that each cell in a strain possesses a combination of mono-, di- and trisomies for all chromosomes; ploidy patterns were different among all strains/species. These results extend those we previously described in Leishmania major, demonstrating that mosaic aneuploidy is a genetic feature widespread to the Leishmania genus. In addition to the genetic consequences induced by this mosaicism, the apparent absence of alternation between haploid/diploid stages questions the modality of genetic exchange in Leishmania sp.

Adaptive mechanisms in pathogens: universal aneuploidy in Leishmania

Genomic stability and maintenance of the correct chromosome number are assumed to be essential for normal development in eukaryotes. Aneuploidy is usually associated with severe abnormalities and decrease of cell fitness, but some organisms appear to rely on aneuploidy for rapid adaptation to changing environments. This phenomenon is mostly described in pathogenic fungi and cancer cells. However, recent genome studies highlight the importance of Leishmania as a new model for studies on aneuploidy. Several reports revealed extensive variation in chromosome copy number, indicating that aneuploidy is a constitutive feature of this protozoan parasite genus. Aneuploidy appears to be beneficial in organisms that are primarily asexual, unicellular, and that undergo sporadic epidemic expansions, including common pathogens as well as cancer.

Evolutionary genomics of Entamoeba

Entamoeba histolytica is a human pathogen that causes amoebic dysentery and leads to significant morbidity and mortality worldwide. Understanding the genome and evolution of the parasite will help explain how, when and why it causes disease. Here we review current knowledge about the evolutionary genomics of Entamoeba: how differences between the genomes of different species may help explain different phenotypes, and how variation among E. histolytica parasites reveals patterns of population structure. The imminent expansion of the amount genome data will greatly improve our knowledge of the genus and of pathogenic species within it.

Modulation of gene expression in drug resistant Leishmania is associated with gene amplification, gene deletion and chromosome aneuploidy

Gene expression and DNA copy number analyses using full genome oligonucleotide microarrays of Leishmania reveal molecular mechanisms of methotrexate resistance.

Background

Drug resistance can be complex, and several mutations responsible for it can co-exist in a resistant cell. Transcriptional profiling is ideally suited for studying complex resistance genotypes and has the potential to lead to novel discoveries. We generated full genome 70-mer oligonucleotide microarrays for all protein coding genes of the human protozoan parasites Leishmania major and Leishmania infantum. These arrays were used to monitor gene expression in methotrexate resistant parasites.

Results

Leishmania is a eukaryotic organism with minimal control at the level of transcription initiation and few genes were differentially expressed without concomitant changes in DNA copy number. One exception was found in Leishmania major, where the expression of whole chromosomes was down-regulated. The microarrays highlighted several mechanisms by which the copy number of genes involved in resistance was altered; these include gene deletion, formation of extrachromosomal circular or linear amplicons, and the presence of supernumerary chromosomes. In the case of gene deletion or gene amplification, the rearrangements have occurred at the sites of repeated (direct or inverted) sequences. These repeats appear highly conserved in both species to facilitate the amplification of key genes during environmental changes. When direct or inverted repeats are absent in the vicinity of a gene conferring a selective advantage, Leishmania will resort to supernumerary chromosomes to increase the levels of a gene product.

Conclusion

Aneuploidy has been suggested as an important cause of drug resistance in several organisms and additional studies should reveal the potential importance of this phenomenon in drug resistance in Leishmania.

Genetic analysis of the human infective trypanosome Trypanosoma brucei gambiense: chromosomal segregation, crossing over, and the construction of a genetic map

A high-resolution genetic linkage map of the STIB 386 strain of Trypanosoma brucei gambiense is presented.

Background

Trypanosoma brucei is the causative agent of human sleeping sickness and animal trypanosomiasis in sub-Saharan Africa, and it has been subdivided into three subspecies: Trypanosoma brucei gambiense and Trypanosoma brucei rhodesiense, which cause sleeping sickness in humans, and the nonhuman infective Trypanosoma brucei brucei. T. b. gambiense is the most clinically relevant subspecies, being responsible for more than 90% of all trypanosomal disease in humans. The genome sequence is now available, and a Mendelian genetic system has been demonstrated in T. brucei, facilitating genetic analysis in this diploid protozoan parasite. As an essential step toward identifying loci that determine important traits in the human-infective subspecies, we report the construction of a high-resolution genetic map of the STIB 386 strain of T. b. gambiense.

Results

The genetic map was determined using 119 microsatellite markers assigned to the 11 megabase chromosomes. The total genetic map length of the linkage groups was 733.1 cM, covering a physical distance of 17.9 megabases with an average map unit size of 24 kilobases/cM. Forty-seven markers in this map were also used in a genetic map of the nonhuman infective T. b. brucei subspecies, permitting comparison of the two maps and showing that synteny is conserved between the two subspecies.

Conclusion

The genetic linkage map presented here is the first available for the human-infective trypanosome T. b. gambiense. In combination with the genome sequence, this opens up the possibility of using genetic analysis to identify the loci responsible for T. b. gambiense specific traits such as human infectivity as well as comparative studies of parasite field populations.

First complete chromosomal organization of a protozoan plant parasite (Phytomonas spp.)

Phytomonas spp. are members of the family Trypanosomatidae that parasitize plants and may cause lethal diseases in crops such as Coffee Phloem necrosis, Hartrot in coconut, and Marchitez sorpresiva in oil palm. In this study, the molecular karyotype of 6 isolates from latex plants has been entirely elucidated by pulsed-field gel electrophoresis and DNA hybridization. Twenty-one chromosomal linkage groups constituting heterologous chromosomes and sizing between 0.3 and 3 Mb could be physically defined by the use of 75 DNA markers (sequence-tagged sites and genes). From these data, the genome size can be estimated at 25.5 (+/-2) Mb. The physical linkage groups were consistently conserved in all strains examined. Moreover, the finding of several pairs of different-sized homologous chromosomes strongly suggest diploidy for this organism. The definition of the complete molecular karyotype of Phytomonas represents an essential primary step toward sequencing the genome of this parasite of economical importance.

Leishmania and the leishmaniases: a parasite genetic update and advances in taxonomy, epidemiology and pathogenicity in humans

Leishmaniases remain a major public health problem today despite the vast amount of research conducted on Leishmania pathogens. The biological model is genetically and ecologically complex. This paper explores the advances in Leishmania genetics and reviews population structure, taxonomy, epidemiology and pathogenicity. Current knowledge of Leishmania genetics is placed in the context of natural populations. Various studies have described a clonal structure for Leishmania but recombination, pseudo-recombination and other genetic processes have also been reported. The impact of these different models on epidemiology and the medical aspects of leishmaniases is considered from an evolutionary point of view. The role of these parasites in the expression of pathogenicity in humans is also explored. It is important to ascertain whether genetic variability of the parasites is related to the different clinical expressions of leishmaniasis. The review aims to put current knowledge of Leishmania and the leishmaniases in perspective and to underline priority questions which 'leishmaniacs' must answer in various domains: epidemiology, population genetics, taxonomy and pathogenicity. It concludes by presenting a number of feasible ways of responding to these questions.

Genetic diversity of Leishmania amazonensis strains isolated in northeastern Brazil as revealed by DNA sequencing, PCR-based analyses and molecular karyotyping

Background

Leishmania (Leishmania) amazonensis infection in man results in a clinical spectrum of disease manifestations ranging from cutaneous to mucosal or visceral involvement. In the present study, we have investigated the genetic variability of 18 L. amazonensis strains isolated in northeastern Brazil from patients with different clinical manifestations of leishmaniasis. Parasite DNA was analyzed by sequencing of the ITS flanking the 5.8 S subunit of the ribosomal RNA genes, by RAPD and SSR-PCR and by PFGE followed by hybridization with gene-specific probes.

Results

ITS sequencing and PCR-based methods revealed genetic heterogeneity among the L. amazonensis isolates examined and molecular karyotyping also showed variation in the chromosome size of different isolates. Unrooted genetic trees separated strains into different groups.

Conclusion

These results indicate that L. amazonensis strains isolated from leishmaniasis patients from northeastern Brazil are genetically diverse, however, no correlation between genetic polymorphism and phenotype were found.

Leishmania: sex, lies and karyotype

The exploration of the genome of the tryponosomotid protozoan Leishmania has been difficult until recently owing to a number of obstacles, not least our ignorance of the ploidy and of the number of chromosomes (as in many other protozoa, the latter do not condense during mitosis), the uncertainty of the species concept in these allegedly asexual protozoa and the absence of classical genetic studies. Here, Patrick Bastien, Christine Bloineou and Michel Pages discuss the advances in this field brought about by the advent of molecular biology and its techniques, with on emphasis on ploidy and genetic exchange. In particular, they discuss the data from pulsed field gel electrophoresis (PFGE). When coupled with DNA restriction analysis, PFGE constitutes a powerful tool for the direct examination o f chromosomes of protozoa.

Shotgun optical mapping of the entire Leishmania major Friedlin genome

Leishmania is a group of protozoan parasites which causes a broad spectrum of diseases resulting in widespread human suffering and death, as well as economic loss from the infection of some domestic animals and wildlife. To further understand the fundamental genomic architecture of this parasite, and to accelerate the on-going sequencing project, a whole-genome XbaI restriction map was constructed using the optical mapping system. This map supplemented traditional physical maps that were generated by fingerprinting and hybridization of cosmid and P1 clone libraries. Thirty-six optical map contigs were constructed for the corresponding known 36 chromosomes of the Leishmania major Friedlin genome. The chromosome sizes ranged from 326.9 to 2821.3 kb, with a total genome size of 34.7 Mb; the average XbaI restriction fragment was 25.3 kb, and ranged from 15.7 to 77.8 kb on a per chromosomes basis. Comparison between the optical maps and the in silico maps of sequence drawn from completed, nearly finished, or large sequence contigs showed that optical maps served several useful functions within the path to create finished sequence by: guiding aspects of the sequence assembly, identifying misassemblies, detection of cosmid or PAC clones misplacements to chromosomes, and validation of sequence stemming from varying degrees of finishing. Our results also showed the potential use of optical maps as a means to detect and characterize map segmental duplication within genomes.

Effect of large targeted deletions on the mitotic stability of an extra chromosome mediating drug resistance in Leishmania

A mitotically stable linear extra chromosome obtained in a Leishmania donovani strain rendered mycophenolic acid-resistant has been physically mapped. This 290-kb chromosome has an inverted duplicated structure around a central inversion region, and is derived from a conservative amplification event of a approximately 140-kb subtelomeric end of chromosome 19. Large-sized targeted deletions of the central region were performed through homologous recombination using three specific transfection vectors. The size of the extra chromosome was thus successfully reduced from 290 to 260, 200 and 120 kb respectively. The mitotic stability of these chromosomes was then analysed in drug-free cultures over >140 days. Results differed according to the deletion created. By contrast with the smallest deletion the two largest deletions altered mitotic stability, leading to progressive loss of the size-reduced chromosomes with similar kinetics in both mutants. The 30-kb region common to both deletions may therefore be considered as involved in mitotic stability. A 44-kb contig covering this region could be assembled and sequenced. The analysis of this sequence did not reveal any sequence elements typical of centromeric DNA. By contrast, its enrichment in homopolymer tracts suggests that this region might contain an origin of replication.

Chromosome structure and sequence organization between pathogenic and non-pathogenic Leishmania spp

We have used a chromosome fragmentation strategy based on systematic genomic insertions of the rare cutting yeast I-SceI endonuclease to assess structure and sequence organization of homologous chromosomes between evolutionary divergent pathogenic and non-pathogenic Leishmania species. This method was combined to physical mapping and hybridization studies using a number of specific chromosomal markers as probes. Our studies have concentrated on two different chromosomes of Leishmania major (L. major), L. donovani and L. infantum and of the non-pathogenic species L. tarentolae. Specific chromosome fragmentation events at the level of multiple I-SccI genomic integrations indicated that very similar distances separated internal genomic sequences between homologous chromosomes and that distances from chromosome ends were more variable. The order and orientation of genes along the homologous chromosomes were also conserved between species. With only few exceptions, genome organization between pathogenic and non-pathogenic Leishmania species was found to be highly conserved. Genomic comparison of pathogenic and non-pathogenic species may be useful for depicting regions involved in species-specific related pathologies.

The immunologically protective P-4 antigen of Leishmania amastigotes. A developmentally regulated single strand-specific nuclease associated with the endoplasmic reticulum

The purified membrane-associated Leishmania pifanoi amastigote protein P-4 has been shown to induce protective immunity against infection and to elicit preferentially a T helper 1-like response in peripheral blood mononuclear cells of patients with American cutaneous leishmaniasis. As this molecule is potentially important for future vaccine studies, the L. pifanoi gene encoding the P-4 membrane protein was cloned and sequenced. Southern blot analyses indicate the presence of six tandemly arrayed copies of the P-4 gene in L. pifanoi; homologues of the P-4 gene are found in all other species of the genus Leishmania examined. DNA-derived protein sequence data indicated an identity to the P1 zinc-dependent nuclease of Penicillium citrinum (20.8%) and the C-terminal domain of the 3' nucleotidase of Leishmania donovani (33.7%). Consistent with these sequence analyses, purified L. pifanoi P-4 protein possesses single strand nuclease (DNA and RNA) and phosphomonoesterase activity, with a preference for UMP > TMP > AMP >> CMP. Double-labeling immunofluorescence microscopic analyses employing anti-binding protein antibodies revealed that the P-4 protein is localized in the endoplasmic reticulum of the amastigote. Northern blot analyses indicated that the gene is selectively expressed in the intracellular amastigote stage (mammalian host) but not in the promastigote stage (insect) of the parasite. Based upon its subcellular localization and single-stranded specific nuclease activity, possible roles of the P-4 nuclease in the amastigote in RNA stability (gene expression) or DNA repair are discussed.

The size difference between leishmania major friedlin chromosome one homologues is localized to sub-telomeric repeats at one chromosomal end

Leishmania species are members of the evolutionarily ancient protozoan order Kinetoplastidae and are important human pathogens. The Leishmania genome is relatively small (approximately 34 Mbp) and is distributed among 36 chromosome pairs, ranging in size from 0.3 to 2.5 Mbp. The smallest chromosome of Leishmania major Friedlin, chrl, consists of three homologues which differ in size by approximately 29 kb. Previous sequence and Southern analyses of all three homologues reveal a conserved chromosomal core, consisting of coding and adjacent 'non-informational' sequence. Here we show the size difference between homologues is largely restricted to variation in both the number and content of several sub-telomeric repetitive elements localized on one chromosomal end. These repetitive elements also occur on other chromosomes, but some are more dispersed in the Leishmania genome than others.

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.

Genes and chromosomes of Leishmania infantum

During recent years, several Leishmania infantum genes have been cloned and characterized. Here, we have summarized the available information on the gene organization and expression in this protozoan parasite. From a comparative analysis, the following outstanding features were found to be common to most of the genes characterized: tandemly organized genes with conserved coding regions and divergent untranslated regions, polycistronic transcription and post-transcriptional regulation of gene expression. The analysis of chromosomes of L. infantum by pulsed-field electrophoresis showed the existence of both size and number polymorphisms such that each strain has a distinctive molecular karyotype. Despite this variability, highly conserved physical linkage groups exists among different strains of L. infantum and even among Old World Leishmania species. Gene mapping on the L. infantum molecular karyotype evidenced a bias in chromosomal distribution of, at least, the evolutionary conserved genes.

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.

Parasite genome analysis. A global map of the Leishmania major genome: prelude to genomic sequencing

In 1994, the World Health Organization (TDR) launched a new strategic initiative in parasite genome analysis, establishing international genome networks for filariae, Schistosoma, Leishmania, Trypanosoma brucei and T. cruzi. For Leishmania, a number of different but complementary approaches have been adopted by members of the Leishmania Genome Network. Our laboratory has been using cosmid clone fingerprinting to produce a physical map of the genome. Progress towards the completion of an integrated physical and biological map of L. major, and the preparations for genomic sequencing, are described.

Unravelling the Leishmania genome

The past few years have been significant advances in our understanding of eukaryotic genomes. In the field of parasitology, this is best exemplified by the application of genome mapping techniques to the study of genome structure and function in the protozoan parasite, Leishmania. Although much is known about the organism and the diseases it causes, molecular genetics has only recently begun to play a major part in elucidating some of the unusual characteristics of this interesting parasite. Mapping of the small (35 Mb) genome and determination of the functional role of genes by the application of in vitro homologous gene targeting techniques are revealing novel avenues for the development of prophylactic measures.

Conservation of low-copy gene loci in Old World leishmanias identifies mechanisms of parasite evolution and diagnostic markers

Genome plasticity has been hypothesized to be a driving force behind parasite speciation. We have evaluated divergence in single and low-copy genes in terms of locus organization, chromosomal localization and gene expression in Leishmania infantum, L. major, L. tropica and three widely divergent geographic isolates of L. donovani. Seventeen genes of low to moderate copy number (1-4 copies/haploid genome) were analyzed to identify restriction fragment length polymorphisms (RFLPs) providing heritable markers distinguishing Old World (OW) leishmanias. These RFLP markers were conserved in parasite isolates from primary infections demonstrating their utility as diagnostic tools. The species designations established by RFLP analysis of field isolates was confirmed by use of monoclonal antibodies. All 17 genes were present in each OW leishmania analyzed except LSIP (A45), which was absent from L. infantum. The 17 genes were found to be distributed among 9 distinct chromosomes. However, in spite of variations in chromosome karyotypes among the various OW leishmanias, individual gene probes localized to a similar sized chromosome from each isolate. These observations coupled with a molecular tree derived from RFLP data suggest that the OW leishmanias comprise a monophyletic lineage, with species associated with cutaneous disease exhibiting the greatest level of divergence. Data from this study supports previous observations that species causing cutaneous and visceral disease have diverged primarily by nucleotide substitutions. Such nucleotide divergence may not only lead to changes in protein function and antigenicity, but may also alter gene regulation programs as exemplified by the finding that the LdI-9-5 and LdE-6-1 genes were expressed only in visceralizing leishmanias.

The Leishmania genome comprises 36 chromosomes conserved across widely divergent human pathogenic species

All the physical linkage groups constituting the genome of Leishmania infantum have been identified for the first time by hybridization of specific DNA probes to pulsed field gradient-separated chromosomes. The numerous co-migrating chromosomes were individualised using the distinctive size polymorphisms which occur among strains of the L. infantum/L. donovani complex as a tool. A total of 244 probes, consisting of 41 known genes, 66 expressed sequence tags (ESTs) and 137 anonymous DNA sequences, were assigned to a specific linkage group. We show that this genome comprises 36 chromosomes ranging in size from 0.35 to -3 Mb. This information enabled us to compare the genome structure of L. infantum with those of the three other main Leishmania species that infect man in the Old World, L. major, L. tropica and L. aethiopica. The linkage groups were consistently conserved in all species examined. This result is in striking contrast to the large genetic distances that separate these species and suggests that conservation of the chromosome structure may be critical for this human pathogen. Finally, the high density of markers obtained during the present study (with a mean of 1 marker/130 kb) will speed up the construction of a detailed physical map that would facilitate the genetic analysis of this parasite, for which no classical genetics is available.

Genomic variation in Trypanosoma cruzi clonal cultures

Spontaneous changes in restriction DNA profiles and pulsed-field gel electrophoresis (PFGE) patterns, along with a concomitant loss of infectivity, were observed in infective clones of Trypanosoma cruzi strain Y either following a number of passages during the exponential growth phase of after subcloning in liver infusion tryptone (LIT) medium using as the probe a genomic fragment of the parasite (pMYP16), indicating naturally occurring rearrangements of DNA sequences. No variation could be detected when the genomic DNA was probed with conserved T. cruzi tubulin and actin genes. There was no correlation between such rearrangements and the life-cycle forms of the parasites, since trypomastigote forms showed the same karyotype and hybridization patterns as did epimastigote forms. The variations observed could be reverted and infectivity, recovered after inoculation of the parasites in newborn mice.

Families of adenylate cyclase genes in Trypanosoma brucei

Four genes for adenylate cyclase have been characterized in Trypanosoma brucei. One of them, esag 4 (for expression site associated gene 4) is present in different VSG (variant surface glycoprotein) gene expression sites and, thus, is only expressed in the bloodstream form of the parasite. The others, termed gresag 4.1, 4.2 and 4.3 (for genes related to esag 4) are expressed in both bloodstream and procyclic forms. In addition, we cloned a esag 4-related gene from T. congolense. Here we characterize the genomic organization of gresag 4.1 and 4.3. While gresag 4.3 is unique, gresag 4.1 exists as a multigenic family of at least nine members located on a 3-Mb chromosome. Six of them are clustered in a region of 300 kb, three copies being tandemly linked. The determination of the nucleotide sequence of a conserved 1.6 kb PstI fragment demonstrated the presence of two separate subgroups in this family. This gene arrangement is present in different isolates of T.b. brucei/rhodesiense/gambiense. Several gresag 4.1 copies are transcribed in both bloodstream and procyclic forms.

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.

Co-existence of circular and multiple linear amplicons in methotrexate-resistant Leishmania

Circular and linear amplicons were analyzed in detail in Leishmania tropica cells resistant to methotrexate (MTX). Both types of elements presented sequences related to the H locus and coexisted in resistant cells. The linear amplicons appeared first during the selection process (at 10 microM MTX) and varied with regard to size and structure in cells exposed to increasing concentrations of drug. The circular element was evident at higher concentrations (50 microMs) but was the major amplified DNA in cells resistant to 1000 microM MTX while the level of amplification of the linear elements remained low. The extrachromosomal DNAs were unstable in the absence of drug and their disappearance coincided with an increase in sensitivity to MTX. Mapping of the minichromosomes and the circular element showed that they were all constituted by inverted duplications. The circular amplicon contained an inverted repeat derived from the H locus that encompassed the pteridine reductase gene (PTR1) responsible for MTX resistance. The amplified segment in the linear amplicons was longer and included the pgpB and pgpC genes that encode P-glycoproteins of unknown function previously characterized in different Leishmania species.

Extensive polymorphism at the Gp63 locus in field isolates of Leishmania peruviana

Genetic diversity within and between tandemly arrayed copies of the Gp63 gene occurs in laboratory isolates of Leishmania spp., but the extent to which this represents natural genetic diversity has not been assessed. Here, the Gp63 locus is examined in 58 fresh isolates of L. peruviana, and clones derived from them, collected throughout the Peruvian Andes. Extensive polymorphism is observed, both in size of Gp63 containing chromosomes, and for restriction-fragment-length polymorphisms (RFLPs) at the Gp63 locus. All clones within an isolate are identical, including those with two distinct Gp63-hybridising chromosomal-sized pulsed-field gel electrophoresis (PFGE) bands, consistent with diploidy but with size differences in homologous chromosomes. For RFLP analysis, three enzymes were selected to cut within the coding region (PstI), in the intergenic region (SalI) and outside (EcoRI) the Gp63 gene cluster. PstI gave identical banding patterns across all isolates/clones. For EcoRI and SalI, all clones within an isolate were identical, but isolates were polymorphic for fragments at 13 (2-30 kb) and 8 (2.6-8.8 kb) different molecular mass locations generating 19 and 16 distinct RFLP patterns or genotypes for each enzyme, respectively. EcoRI restriction patterns, analysed by PFGE, were consistent with the presence of two clusters of Gp63 genes on each homologous chromosome, one contained within EcoRI fragments large enough to carry from 3 to 10 copies of the Gp63 gene, the second on fragments which could carry 1 or 2 copies of the gene. SalI patterns indicated variable restriction sites within clusters, but not within every intergenic region. A hierarchical analysis of variance of allele frequencies, expressed in terms of Wright's F-statistic, indicated significant barriers to gene flow at all levels, valleys within regions (north/south), villages within valleys, and individuals within villages. This extreme polymorphism at the Gp63 locus of L. peruviana demonstrates the great potential for generation of genetic diversity in parasite populations.

Parasitism and chromosome dynamics in protozoan parasites: is there a connection?

Genomic plasticity is a hallmark of many protozoan parasites, including Plasmodium spp, Trypanosoma spp, Leishmania ssp and Giardia lamblia. Strikingly, there is a common theme regarding the structural basis of this karyotype variability. Chromosomes are compartmentalized into conserved central domains and polymorphic chromosome ends. Since antigen-encoding genes frequently reside in telomere-proximal domains, it is tempting to speculate that the genetic flexibility of chromosome ends has been recruited as a tool in immune evasion strategies by some parasitic protozoa.

Karyotype plasticity in neotropical Leishmania: an index for measuring genomic distance among L. (V.) peruviana and L. (V.) braziliensis populations

A method for phenetic analysis of karyotype data has been developed for Leishmania populations. Measurement of size difference between chromosomes recognized by a given DNA probe in different isolates led to the formulation of a Chromosome Size Difference Index (CSDI). The method was applied to phenetic analysis of 4 sets of chromosomes--each set being recognized by a different probe--in 37 L. (Viannia) peruviana isolates sampled along a North-South transect through the Peruvian Andes and, in 11 L. (V.) braziliensis isolates from the Amazonian forest (Peru, Bolivia and Brazil). Karyotype variability was better accounted for by CSDI than by a method based on disjunctive encoding of karyotype data. CSDI evidenced the nature of relationships between L. braziliensis and L. peruviana and it provided a coherent picture of geographical and genomic differentiation among parasite populations. The latter did cluster according to their geographical origin. L. braziliensis was found karyotypically more homogeneous than L. peruviana. Within L. peruviana, Northern populations were closer to L. braziliensis than to Southern L. peruviana populations. The validity of karyotypic populations, or karyodemes, was sustained.

Conservation 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.

Inverted repeat structure and homologous sequences in the LD1 amplicons of Leishmania spp

In the parasitic trypanosomatids of the genus Leishmania, novel circular (CD) and linear (LD) multicopy genetic elements arise de novo either spontaneously or as a result of drug selection. We report that the LD1 minichromosomes of L. donovani, L. major and L. mexicana (ranging in size from 180 to 230 kb) have an inverted repeat structure and contain homologous sequences located at similar distances from the telomere; one half of the chromosome being the mirror image of the other. They must therefore have originated from a unique conserved source chromosome; the size polymorphism being generated by the point at which inversion occurs. The circular CD1 elements appear to be circularised segments of the LD1 elements. These observations lead to a unified concept of how minichromosomes LD1 and circular CD1 genetic elements emerge within the Leishmania and contribute to evolution of karyotype.

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.

Cloning and sequencing of the Leishmania major actin-encoding gene

We report the cloning and characterization of the genomic sequence of the actin (Act)-encoding gene (act) from Leishmania major. Restriction maps of two genomic clones, as well as genomic Southern analysis strongly suggest that the act of L. major is a single-copy gene. A single 1.6-kb transcript is detected in Northern blots. The deduced amino-acid sequence shows 68-89% identity with Act sequences from other eukaryotes.

Molecular karyotype variation in Leishmania (Viannia) peruviana: indication of geographical populations in Peru distributed along a north-south cline

Forty-one Leishmania peruviana isolates were selected along a north-south transect which crossed areas endemic for uta in three different biogeographical regions in the Peruvian Andes. The isolates were analysed by molecular karyotyping and hybridization with three chromosome-derived DNA probes. All the isolates could be distinguished from L. braziliensis by their pLb-134 hybridization patterns. However, the patterns with the other probes (pLb-168 and -22) could be used to cluster the Peruvian isolates in discrete groups (karyodemes) which varied in their level of similarity with L. braziliensis. The geographical distribution of these karyodemes supports the hypothesis that eco-graphical isolation has contributed to the heterogeneity of L. peruviana.

Stable amplification of a linear extrachromosomal DNA in mycophenolic acid-resistant Leishmania donovani

Pulsed field gel electrophoretic analysis of chromosomes of MPA100 cells, a strain of Leishmania donovani that possesses an approx. 15-fold amplified IMP dehydrogenase (IMPDH) gene copy number, revealed a new 280-kb extrachromosomal DNA, IMPDH-280, that was not present in wild type parental cells. Southern blots of these pulsed field gels revealed that the vast majority of the amplified impdh genes were localized on IMPDH-280. In addition to the 700-kb wild type chromosome, the impdh probe also recognized a 740-kb chromosome in the MPA100 genome. The pulse time-dependent relative mobility of IMPDH-280 in pulsed field gels, the failure of limited gamma-irradiation to generate a new discrete DNA fragment, and the susceptibility of IMPDH-280 to lambda-exonuclease digestion, demonstrated that IMPDH-280 was a linear molecule. IMPDH-280 was also recognized by a telomere probe but not by fragments derived from amplified DNAs found in other drug-resistant Leishmania. IMPDH-280 and the drug resistance phenotype remained stable when MPA100 cells were propagated in the absence of drug for 2 years. The appearance of IMPDH-280 in MPA100 cells represents one of the first examples of an amplification of a linear extrachromosomal DNA element mediating drug resistance in Leishmania and the first instance of a linear DNA amplification that is stable in the absence of selective pressure.

Dynamics and size polymorphisms of minichromosomes in Leishmania major LV-561 cloned lines

Various lines and cloned lines of Leishmania major of varying degrees of virulence in BALB/c mice possessed size polymorphic multicopy minichromosomes related to previously described LD1/CD1 and 715-class DNAs of Leishmania. The minichromosomes were not necessary for virulence. Two of these DNAs (M180 and M210), coexisting in a single cloned line, showed remarkable dynamics in terms of loss or gain when followed through multiple transfers during in vitro culture and in vivo passage in BALB/c mice. Although there was significant sequence heterogeneity among minichromosomes, M180 sequences were present within large (megabase) and in intermediate (550-760 kb) chromosomes in the L. major lines analysed. M180 related small DNAs were also detected in Leishmania mexicana and Leishmania donovani isolates, suggesting that the generation of these molecules involves a common, probably functional basic mechanism widespread in Leishmania.

The chromosomes of Leishmania

Chromosome size polymorphisms occur in Leishmania such that each strain of a given species has a distinctive molecular karyotype. Despite this variability, the chromosomal similarities among closely related strains of Leishmania are sufficiently characteristic to permit classification of unidentified clinical isolates. Mechanisms generating chromosome size polymorphisms are related to chromosomal evolution. In this review, Geoffrey Lighthall and Suzanne Giannini explain that the chromosomal profiles of members of different species may be diverging from a conserved 'consensus' karyotype at different rates, and present a current understanding of the genomic organization of Leishmania with emphasis on chromosomal elements.

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.

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.

Loss of the GP46/M-2 surface membrane glycoprotein gene family in the Leishmania braziliensis complex

Immunization with the GP46/M-2 membrane glycoprotein of Leishmania amazonensis has been shown to induce a protective immune response against infection. We have surveyed a variety of trypanosomatid species and genera for the presence and expression of this gene family, information that will be relevant to future vaccine studies against leishmaniasis. Molecular karyotype analysis revealed the presence of GP46/M-2 genes in all members of the Leishmania mexicana complex, Leishmania major, Leishmania donovani, Leishmania tarentolae, and Crithidia fasciculata. In contrast, DNAs from species of the Leishmania braziliensis complex (L. braziliensis, Leishmania guyanensis, and Leishmania panamensis) failed to hybridize to GP46/M-2 probes. Western blot analyses with several polyclonal antisera against the GP46/M-2 protein revealed protein expression in L. major and L. donovani, but not L. panamensis or L. braziliensis. Phylogenetic analysis suggests that a loss of the GP46A gene family occurred following separation of the L. braziliensis complex, prior to speciation events within this complex. These data indicate that GP46/M-2 membrane glycoprotein may not be critical to parasite survival, but may play an ancillary role during the developmental cycle.