Study of Leishmania mexicana electrokaryotype by clamped homogeneous electric field electrophoresis

Chromosome size polymorphisms in the genus acanthamoeba electrokaryotype by pulsed-field gel electrophoresis

Twenty-eight strains from 12 species from the genus Acanthamoeba, including five isolates from amoebic keratitis patients, were subjected to molecular karyotyping by pulsed-field gel electrophoresis. 9 to 21 chromosome-sized DNA bands ranging from 200 kb to 3 Mb in size were detected. Molecular karyotypes also showed a wide multifariousness, i.e. there existed inter- and intraspecific heterogeneity. The five isolates from amoebic keratitis patients did not exhibit characteristic molecular karyotypes distinguishable from environmental isolates. Although karyotypic heterogeneity was observed within group I amoeba, they are distinguishable from those of group II and III. Strains having identical restriction fragment length polymorphism profiles of mtDNA did not have an identical molecular karyotype, i.e. weak correlation was found between molecular karyotypes and mtDNA restriction fragment length polymorphism profiles.

A biochemical and genetic study of Leishmania donovani pyruvate kinase

Here we present a biochemical and molecular biology study of the enzyme pyruvate kinase (PYK) from the parasitic protozoa Leishmania donovani. The PYK gene was cloned, mutagenised and over expressed and its kinetic parameters determined. Like in other kinetoplastids, L. donovani PYK is allosterically stimulated by the effector fructose 2,6 biphosphate and not by fructose 1,6 biphosphate. When the putative effector binding site of L. donovani PYK was mutagenised, we obtained two mutants with extreme kinetic behavior: Lys453Leu, which retained a sigmoidal kinetics and was little affected by the effector; and His480Gln, which deployed a hyperbolic kinetics that was not changed by the addition of the effector. Molecular Dynamics (MD) studies revealed that the mutations not only altered the effector binding site of L. donovani PYK but also changed the folding of its domain C.

Expression of fluorescent genes in Trypanosoma cruzi and Trypanosoma rangeli (Kinetoplastida: Trypanosomatidae): its application to parasite-vector biology

Two Trypanosoma cruzi-derived cloning vectors, pTREX-n and pBs:CalB1/CUB01, were used to drive the expression of green fluorescent protein (GFP) and DsRed in Trypanosoma rangeli Tejera, 1920, and Trypanosoma cruzi Chagas, 1909, isolates, respectively. Regardless of the species, group, or strain, parasites harboring the transfected constructs as either episomes or stable chromosomal integrations showed high-level expression of fluorescent proteins. Tagged flagellates of both species were used to experimentally infect Rhodnius prolixus Stal, 1953. In infected bugs, single or mixed infections of T. cruzi and T. rangeli displayed the typical cycle of each species, with no apparent interspecies interactions. In addition, infection of kidney monkey cells (LLC-MK2) with GFP-T. cruzi showed that the parasite retained its fluorescent tag while carrying out its life cycle within cultured cells. The use of GFP-tagged parasites as a tool for biological studies in experimental hosts is discussed, as is the application of this method for copopulation studies of same-host parasites.

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 region containing repeated elements is associated with transcriptional termination of Leishmania infantum ribosomal RNA genes

A novel repetitive DNA element has been isolated from the Leishmania infantum genome. The 348 bp long element, designated LiR3, was found to be located downstream from the 3'-end of the ribosomal RNA (rRNA) genes. This LiR3 element has short sequences with potential to form stem-loop structures similar to those of the bacterial rho-independent transcriptional terminators. Given both the structural features and the genomic location of this element we searched for a possible functional implication of these structures in the termination of rRNA transcription. Nuclear run-on assays indicated that indeed there is a transcriptional blockage associated with the LiR3 element. Several chi-like elements, resembling the recombination-promoting sites of Escherichia coli, were identified within the sequences associated with the stem-loop structures. A possible implication of these chi-like elements in rRNA gene conversion events is discussed.

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.

From population to genome: ecogenetics of Leishmania (Viannia) braziliensis and L. (V.) peruviana

The size polymorphism of nine chromosomes, recognized by specific probes, was analysed in populations of Leishmania (Viannia) braziliensis and L. (V.) peruviana from various Peruvian biogeographical units. Interpretation of the polymorphism, by statistical and phenetic methods, led to the identification of five consensus (alpha- and beta-tubulin) and four variable chromosomes. The dynamics of the variable chromosomes were studied. The promoter role of the environment on their polymorphism was indicated by: (1) the discrimination of L. braziliensis (forest) and L. peruviana (Andes) by the size of the chromosome containing the gp63 genes; and (2) the fact that, within L. peruviana, the polymorphism of the variable chromosomes revealed a strong eco-geographical structuring of parasite populations, accompanied by increasing chromosomal dissimilarity along a cline from north to south. The adaptative significance of the polymorphism of the variable chromosomes was suggested by: (1) a correlation between chromosomal polymorphism and phenotype variability (lesion type in patients and virulence in vitro); and (2) the association between the decrease in size of the gp63-containing chromosome from L. braziliensis to L. peruviana, and a rearrangement of the gp63 genes, probably accompanied by a decrease in their copy number. As chromosomal variation was shown to be more dependant on eco-geographical differences than isoenzymatic variation, chromosome variation and enzyme variation probably differ in adaptative significance.

Karyotype analysis of the monogenetic trypanosomatid Leptomonas collosoma

In order to develop a genetic system for the monogenetic trypanosomatids, we have analyzed the molecular karyotype of Leptomonas collosoma based on chromosome separation by clamped homogeneous electric field (CHEF) gel electrophoresis. The chromosome location of 5 RNA coding genes (SL, U6, 5S, 7SL and rRNA) and 2 protein coding genes (for HSP83 and alpha-tubulin) was determined. All of the L. collosoma genes examined were found on at least 2 chromosomes, which differ in size in the range of 100-500 kb, suggesting that the organism is diploid. The weighted sum of L. collosoma chromosomes separated by CHEF analysis was approximately 62 +/- 3 Mb, whereas the genome size determined by FACS was estimated at approx. 80 Mb. This suggests that some of the homologous chromosomes differ in their size. The analysis presented here may facilitate studies on the function of individual genes, and on the genetic stability of this organism.

Expression of the Leishmania tarentolae ubiquitin-encoding and mini-exon genes

To develop models for transcription and trans-splicing in kinetoplastid protozoa, we have characterized ubiquitin (Ubi) gene organization and mRNA processing in Leishmania tarentolae (Lt). Three ubi loci were characterized: two discrete Ubi-extension protein 52 (EP52)-encoding genes (ubiA and ubiB) and a polymorphic polyubiquitin-encoding gene (ubiC). The three loci resided on chromosomes of 2.05 Mb, 630 kb and 2.9 Mb, respectively. On the basis of upstream flanking gene identity, ubiB appears to be the homologue of the tandemly repeated ubi-EP52/1 and 2 in Trypanosoma brucei (Tb). Similar to Trypanosoma cruzi, Lt did not contain a homologue of the ubi-EP76 that has been found in Saccharomyces cerevisiae and multicellular organisms. All three Lt ubi loci were transcribed. The primary transcripts from the ubi loci were processed at the 5'-end by trans-splicing with the mini-exon. A Lt mini-exon gene (min) that gave rise to a 95-nt primary transcript, which is the second template in the trans-splicing reaction, was also characterized.

Pyruvate kinase of Leishmania mexicana mexicana. Cloning and analysis of the gene, overexpression in Escherichia coli and characterization of the enzyme

Leishmania mexicana mexicana contains two tandemly arranged genes for pyruvate kinase (PYK). The 5' located gene codes for a polypeptide with a molecular mass of 54,370. The calculated net charge and isoelectric point of the polypeptide are -6 and 6.5, respectively. Its amino-acid sequence is 73.7% identical to that of the Trypanosoma brucei PYK and 46.4-49.8% to the enzyme of mammalian cells. The second gene appears not to be functional, because its 5' and 3' extremities have undergone recombinations. L. m. mexicana PYK has been overexpressed in Escherichia coli, using a T7 expression system. Approximately 30% of the protein was detected in the soluble cell fraction. It has been highly purified by chromatography over DEAE-Sephacel and Affigel Blue. From a 1-1 culture 6 mg enzyme was obtained with a specific activity of 224 units mg-1. The protein has a subunit molecular mass of 59,000, as determined by SDS/PAGE, and an isoelectric point of 5.9. Some kinetic properties of the enzyme have been measured and compared with those reported for the T. brucei enzyme. The kinetics of both enzymes are very similar, the most important aspect being their activation by fructose 2,6-bisphosphate. Nevertheless, some differences were observed; the T. brucei enzyme is activated by the effector in a cooperative manner, whereas the activation of the L. m. mexicana enzyme is not cooperative.

Identification and detection of Trypanosoma cruzi by using a DNA amplification fingerprint obtained from the ribosomal intergenic spacer

We designed a PCR assay targeted on repeated elements of the ribosomal intergenic spacer which produces highly polymorphic DNA band patterns for different strains of Trypanosoma cruzi. By labeling the PCR products with digoxigenin and by chemiluminescence detection, we improved the assay sensitivity by three orders of magnitude to get T. cruzi strain fingerprints in feces of the trypanosome-infected triatomine bug vector. We also developed a capture assay for the digoxigenin-labeled PCR products that allowed us to detect T. cruzi in triatomine bug vector feces and in human serum samples with a solid support.

Identification of new world Leishmania using ribosomal gene spacer probes

DNA probes from the nontranscribed ribosomal spacer (NTS), of Leishmania garnhami and Leishmania braziliensis were constructed and tested for sensitivity and specificity against different Leishmania isolates. The L. garnhami probes were species-specific under hybridization conditions of high stringency, but displayed specificity for the mexicana complex under conditions of intermediate stringency. The L. braziliensis probes showed 'complex' specificity. RFLP for the nontranscribed spacer within the braziliensis complex revealed very homogeneous patterns even for organisms currently accepted as different species. A PCR assay for the detection of Leishmania from the braziliensis complex is presented.

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.

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.

Conservation of cation-transporting ATPase genes in Leishmania

DNA fragments isolated from Leishmania donovani ATPase genes were used to analyze the organization and expression of cation transporting ATPase genes in L. donovani, Leishmania tropica, Leishmania mexicana, Leishmania braziliensis, Trypanosoma brucei and Trypanosoma cruzi. The ATPase loci in all Leishmania species contained a tandem pair of ATPase genes arranged in head-to-tail orientation and separated by approximately 2 kb. No restriction site polymorphisms were detected in the internal portions of the Leishmania ATPase genes which contain domains conserved between the L. donovani and other eukaryotic plasma membrane ATPases. The ATPase locus of each of the four Leishmania species was mapped to a single small chromosome of approximately 750 kb. The ATPase locus of L. mexicana was differentially expressed. Promastigotes in exponential growth contained abundant transcripts from the upstream ATPase gene, while transcripts from the downstream gene were relatively scarce. Transcripts from the downstream ATPase gene increased in abundance in promastigotes allowed to reach the stationary phase of growth and were most abundant in amastigotes. The two trypanosome species were found to contain DNA fragments that hybridized strongly to the Leishmania ATPase gene.