Application of PCR-RFLP for the exploration of the molecular diversity of Leishmania infantum in Algeria

In recent years, new methods have been developed for the molecular typing of Leishmania that need to be extensively validated by studies of clinical isolates in a well defined epidemiological context. The present study is a contribution to this effort. Using PCR-RFLP of gp63 and cpb genes, we analysed 59 isolates of L. (L.) infantum obtained from different regions of Algeria and originating from different clinical forms, hosts and zymodemes. PCR-RFLP identified 15 different genotypes among the four zymodemes analysed, thereby demonstrating a higher discriminatory power than multilocus enzyme electrophoresis. We did not see any significant relationships between PCR-RFLP patterns and host origin. However, cpb polymorphism showed two interesting trends: a possible relationship with the cutaneous origin of the isolates and an association with a West-East cline. We verified the proof of evidence of the direct applicability of gp63 and cpb PCR-RFLP in blood samples from dogs. Further work is needed to compare the sensitivity of pattern detection with cpb and gp63 PCR-RFLP but our results pave the way to future multilocus PCR-RFLP studies of L. (L.) infantum populations

Antigen genes for molecular epidemiology of leishmaniasis: polymorphism of cysteine proteinase B and surface metalloprotease glycoprotein 63 in the Leishmania donovani complex

BACKGROUND: Efficient monitoring of endemic and resurgent visceral leishmaniasis (VL) requires discriminatory molecular tools that allow direct characterization of etiological agents (i.e., the Leishmania donovani complex) in host tissues. This characterization is possible through restriction fragment-length polymorphism (RFLP) analysis of polymerase chain reaction (PCR)-amplified sequences (PCR-RFLP). METHODS: We present 2 new PCR-RFLP assays that target the gene locus of cysteine proteinase B (cpb), an important Leishmania antigen. The assays were applied to the characterization of 15 reference strains of the L. donovani complex, and their discriminatory power was compared with that of PCR-RFLP analysis of the gp63 gene, another Leishmania antigen, and with that of multilocus enzyme electrophoresis (MLEE), which is the reference standard for parasite typing. RESULTS: Restriction patterns of the cpb locus were polymorphic, but less so than gp63 patterns. When data for both loci were combined, differences between PCR-RFLP and MLEE results were encountered. Antigen gene analysis was more discriminatory and supported a different classification of parasites, one that fitted with their geographic origin. PCR-RFLP analysis of cpb also allowed direct genotyping of parasites in bone marrow aspirate and venous blood samples obtained from patients with VL. CONCLUSION: Antigen genes constitute valid targets for PCR-based Leishmania typing without the need for isolation of parasites

Comparison of molecular markers for strain typing of Leishmania infantum

The epidemiology of Leishmania infantum, the etiological agent of visceral leishmaniasis, is changing rapidly; hence powerful typing tools are required in order to monitor the parasite populations spreading and to adapt adequate control measures. We compared here the resolving power of four molecular methods at the zymodeme level: PCR-RFLP analysis of kDNA minicircles (kDNAPCR-RFLP) and antigen genes (cysteine proteinase b and major surface protease, cpb- and gp63PCR-RFLP), multilocus microsatellite typing (MLMT) and random amplification of polymorphic DNA (RAPD) were applied to samples of 25 L. infantum MON-1 strains obtained from different hosts (HIV+ patients, HIV- patients and dogs) coming from three Spanish foci: Madrid, Mallorca and Ibiza. While RAPD was not sufficiently resolving, the other three methods allowed genotyping within the zymodeme. KDNAPCR-RFLP and MLMT were the most discriminatory and appeared the most adequate for strain fingerprinting. In an eco-geographical context, cpbPCR-RFLP, MLMT and kDNAPCR-RFLP were all informative: they showed here a similar picture, with the existence of cluster(s) of isolates from the islands and other one(s) of mixed composition (Madrid and the islands). None of the markers revealed an association with the host type or the clinical form. In general, there was a significant correlation between each pair of distances calculated from the cpb, microsatellite and kDNA data, respectively, but visual inspection of the trees revealed a better congruence between cpb and microsatellite trees. The methods used here are complementary and each adapted to answer specific epidemiological questions. Their choice should be the result of a compromise between the required resolving power, the genetic features of the respective markers and the technical aspects

Genetic Heterogeneity in Clinical Isolates of Leishmania donovani from India▿

Genetic diversity within 45 Indian Leishmania donovani isolates was analyzed using seven genetic markers. While kinetoplast DNA (kDNA) analysis revealed 15 genotypes, 8 genotypes were obtained by analysis of other markers. In contrast to earlier reports, our data suggest that significant genetic polymorphisms exist in L. donovani strains in Bihar, India. Our results confirm the presence of 2 zymodemes in India

Fluorogenic assay for molecular typing of the Leishmania donovani complex: taxonomic and clinical applications

We describe a new fluorogenic assay for the identification of species and intraspecies groups within the Leishmania donovani complex. The assay combined (1) 2 polymerase chain reactions targeting the 2 cysteine proteinase b isogenes and (2) a fluorescence-resonance energy transfer/melting curve analysis of the polymorphisms within a 31-nt region. All strains within the L. donovani complex were distinguished from L. tropica, L. major, and L. aethiopica, and 5 distinct groups were identified within the L. donovani complex. Discrepancies were observed with the present taxonomy on the basis of isoenzyme analysis and concerned East African strains, which suggests the need for a systematic reevaluation of the taxonomy. The capacity to type parasites directly from clinical samples was demonstrated with blood and bone marrow samples. This rapid and high-throughput alternative for molecular diagnosis and epidemiological studies of visceral leishmaniasis could be adapted for use with other Leishmania species

DNA damage in normally and prematurely aged mice

Steady-state levels of spontaneous DNA damage, the by-product of normal metabolism and environmental exposure, are controlled by DNA repair pathways. Incomplete repair or an age-related increase in damage production and/or decline in repair could lead to an accumulation of DNA damage, increasing mutation rate, affecting transcription and/or activating programmed cell death or senescence. These consequences of DNA damage metabolism are highly conserved and the accumulation of lesions in the DNA of the genome could, therefore, provide a universal cause of aging. An important corollary of this hypothesis is that defects in DNA repair cause both premature aging and accelerated DNA damage accumulation. While the former has been well-documented, the reliable quantification of the various lesions thought to accumulate in DNA during aging has been a challenge. Here, we quantified inhibition of long distance PCR as a measure of DNA damage in liver and brain of both normal and prematurely aging, DNA repair defective mice. The results indicate a marginal, but statistically significant, increase of spontaneous DNA damage with age in normal mouse liver but not in brain. Increased levels of DNA damage were not observed in the DNA repair defective mice. We also show that oxidative lesions do not increase with age. These results indicate that neither normal nor premature aging is accompanied by a dramatic increase in DNA damage. This suggests that factors other than DNA damage per se, e.g., cellular responses to DNA damage, are responsible for the aging phenotype in mice

American tegumentary leishmaniasis: antigen-gene polymorphism, taxonomy and clinical pleomorphism

Multi-locus enzyme electrophoresis is the current gold standard for the genetic characterisation of Leishmania. However, this method is time-consuming and, more importantly, cannot be directly applied to parasites present in host tissue. PCR-based methods represent an ideal alternative but, to date, a multi-locus analysis has not been applied to the same sample. This has now been achieved with a sample of 55 neotropical isolates (Leishmania (Viannia) braziliensis, L. (V.) peruviana, L. (V.) guyanensis, L. (V.) lainsoni and L. (L.) amazonensis), using five different genes as targets, four of which encoded major Leishmania antigens (gp63, Hsp70, H2B and Cpb). Our multi-locus approach strongly supports the current taxonomy and demonstrates a highly robust method of distinguishing different strains. Within L. (V.) braziliensis, we did not encounter so far specific genetic differences between parasites isolated from cutaneous and mucosal lesions. Interestingly, results provided by each of the different antigen-genes in the species considered, were different, suggesting different selective pressures. Our work emphasises the need for a multi-disciplinary approach to study the clinical pleomorphism of leishmaniasis

Identification of Old World Leishmania spp. by specific polymerase chain reaction amplification of cysteine proteinase B genes and rapid dipstick detection

We used the cysteine proteinase B (cpb) gene family of the trypanosomatid genus Leishmania as a target to develop rapid, specific, and easy-to-use polymerase chain reaction (PCR) tests to discriminate Leishmania infantum, Leishmania donovani, Leishmania tropica, Leishmania aethiopica, and Leishmania major. Identification of all 5 Old World species and validation of intraspecies variability are features lacking in other species-specific PCRs. Amplicon analysis was done on agarose gels and was further simplified by using an oligochromatography dipstick to detect L. infantum and L. donovani products. Because the analytical sensitivity is lower than that of certain other species- and genus-specific PCRs, our assays are especially valuable for use on cultured isolates or directly on cryostabilates. As such, they can be implemented by research and health centers having access to culturing, DNA isolation, and PCR