Accelerated active case detection of visceral leishmaniasis patients in endemic villages of Bangladesh.

BACKGROUND: The visceral leishmaniasis (VL) elimination program in Bangladesh is in its attack phase. The primary goal of this phase is to decrease the burden of VL as much as possible. Active case detection (ACD) by the fever camp method and an approach using past VL cases in the last 6-12 months have been found useful for detection of VL patients in the community. We aimed to explore the yield of Accelerated Active Case Detection (AACD) of non-self reporting VL as well as the factors that are associated with non-self reporting to hospitals in endemic communities of Bangladesh. METHODS: Our study was conducted in the Trishal sub-district of Mymensingh, a highly VL endemic region of Bangladesh. We used a two-stage sampling strategy from 12 VL endemic unions of Trishal. Two villages from each union were selected at random. We looked for VL patients who had self-reported to the hospital and were under treatment from these villages. Then we conducted AACD for VL cases in those villages using house-to-house visit. Suspected VL cases were referred to the Trishal hospital where diagnosis and treatment of VL was done following National Guidelines for VL case management. We collected socio-demographic information from patients or a patient guardian using a structured questionnaire. RESULTS: The total number of VL cases was 51. Nineteen of 51 (37.3%) were identified by AACD. Poverty, female gender and poor knowledge about VL were independent factors associated with non self-reporting to the hospital. CONCLUSION: Our primary finding is that AACD is a useful method for early detection of VL cases that would otherwise go unreported to the hospital in later stage due to poverty, poor knowledge about VL and gender inequity. We recommend that the National VL Program should consider AACD to strengthen its early VL case detection strategy.

Genetic diversity and structure in Leishmania infantum populations from southeastern Europe revealed by microsatellite analysis.

BACKGROUND: The dynamic re-emergence of visceral leishmaniasis (VL) in south Europe and the northward shift to Leishmania-free European countries are well-documented. However, the epidemiology of VL due to Leishmania infantum in southeastern (SE) Europe and the Balkans is inadequately examined. Herein, we aim to re-evaluate and compare the population structure of L. infantum in SE and southwestern (SW) Europe. METHODS: Leishmania strains collected from humans and canines in Turkey, Cyprus, Bulgaria, Greece, Albania and Croatia, were characterized by the K26-PCR assay and multilocus enzyme electrophoresis (MLEE). Genetic diversity was assessed by multilocus microsatellite typing (MLMT) and MLM Types were analyzed by model- and distance- based algorithms to infer the population structure of 128 L. infantum strains. RESULTS: L. infantum MON-1 was found predominant in SE Europe, whilst 16.8% of strains were MON-98. Distinct genetic populations revealed clear differentiation between SE and SW European strains. Interestingly, Cypriot canine isolates were genetically isolated and formed a monophyletic group, suggesting the constitution of a clonal MON-1 population circulating among dogs. In contrast, two highly heterogeneous populations enclosed all MON-1 and MON-98 strains from the other SE European countries. Structure sub-clustering, phylogenetic and Splitstree analysis also revealed two distinct Croatian subpopulations. A mosaic of evolutionary effects resulted in consecutive sub-structuring, which indicated substantial differentiation and gene flow among strains of both zymodemes. CONCLUSIONS: This is the first population genetic study of L. infantum in SE Europe and the Balkans. Our findings demonstrate the differentiation between SE and SW European strains; revealing the partition of Croatian strains between these populations and the genetic isolation of Cypriot strains. This mirrors the geographic position of Croatia located in central Europe and the natural isolation of the island of Cyprus. We have analysed the largest number of MON-98 strains so far. Our results indicate extensive gene flow, recombination and no differentiation between MON-1 and MON-98 zymodemes. No correlation either to host specificity or place and year of strain isolation was identified. Our findings may be associated with intensive host migration and common eco-epidemiological characteristics in these countries and give valuable insight into the dynamics of VL.

Molecular markers for Phlebotomus papatasi (Diptera: Psychodidae) and their usefulness for population genetic analysis.

Three molecular typing tools: multilocus microsatellite typing, cytochrome b sequence analysis and internal transcribed spacer 2 (ITS2) sequence analysis, were evaluated for their usefulness in inferring the population structure of Phlebotomus papatasi sand flies. ITS2 sequence analysis did not prove suitable for inferring phylogenetic and population genetic relationships across P. papatasi sand flies. Microsatellite markers showed high resolution in differentiating globally distributed P. papatasi populations, whereas cytochrome b sequence analysis provided insight into the relationships between closely related populations from the Mediterranean. Population structure, differentiation and demographic history among P. papatasi are important for understanding patterns of dispersal in this species and for planning appropriate control measures.

Molecular detection of Microsporum persicolor in soil suggesting widespread dispersal in central India.

A survey was conducted from 1999 to 2003 as part of a microbial biodiversity study on geophilic and keratinophilic fungi in central India. Among the keratinophilic fungi recovered were 82 isolates belonging to the dermatophyte genus Microsporum. Species were provisionally identified by morphology and confirmed by PCR-RFLP and sequencing of the ITS regions of rDNA. Microsporum persicolor appeared to be preponderant in central Indian soils, outnumbering the common geophilic species of Microsporum filvum and Microsporum gypseum. Three dinucleotide microsatellite markers were developed and their use revealed immense intraspecific variation among Indian populations of M. persicolor which would indicate that this species was not recently introduced into India. No correlation was established between the genotypes and the geographical location or the habitat of the isolates.

A virulent genotype of Microsporum canis is responsible for the majority of human infections.

The zoophilic dermatophyte species Microsporum canis belongs to the Arthroderma otae complex and is known to mate with tester strains of that teleomorph species, at least in the laboratory. Human infections are likely to be acquired from the fur of cats, dogs and horses. Epidemiological studies to reveal sources and routes of infection have been hampered by a lack of polymorphic molecular markers. Human cases mainly concern moderately inflammatory tinea corporis and tinea capitis, but, as cases of highly inflammatory ringworm are also observed, the question arises as to whether all lineages of M. canis are equally virulent to humans. In this study, two microsatellite markers were developed and used to analyse a global set of 101 M. canis strains to reveal patterns of genetic variation and dispersal. Using a Bayesian and a distance approach for structuring the M. canis samples, three populations could be distinguished, with evidence of recombination in one of them (III). This population contained 44 % of the animal isolates and only 9 % of the human strains. Population I, with strictly clonal reproduction (comprising a single multilocus genotype), contained 74 % of the global collection of strains from humans, but only 23 % of the animal strains. From these findings, it was concluded that population differentiation in M. canis is not allopatric, but rather is due to the emergence of a (virulent) genotype that has a high potential to infect the human host. Adaptation of genotypes resulting in a particular clinical manifestation was not evident. Furthermore, isolates from horses did not show a monophyletic clustering.

Microsatellite markers reveal geographic population differentiation in Trichophyton rubrum.

A worldwide selection of more than 200 isolates of the anthropophilic dermatophyte Trichophyton rubrum were analysed using seven microsatellite markers. Fifty-five multilocus genotypes were recognized, allowing a subdivision of the species into two populations. Both populations reproduced strictly clonally, showed a different predilection on the human host (scalp vs foot) and displayed geographic differentiation. Genotypes of one population originated predominantly from Africa, whilst the second population showed a worldwide distribution excluding the African continent. Genotypic diversity was highest in the African population, despite the lower number of strains analysed, suggesting that T. rubrum is likely to have evolved in Africa. No diagnostic correlation was observed between multilocus genotypes and any of the phenotypical characteristics of the strains. The involvement of multiple strains in a single patient detected by workers using other typing methods was not supported by these microsatellite markers. Four of the developed microsatellite markers may be applied for diagnostic purposes.

Multilocus microsatellite typing (MLMT) reveals genetically isolated populations between and within the main endemic regions of visceral leishmaniasis.

Multilocus enzyme electrophoresis (MLEE) is the gold standard for taxonomy and strain typing of Leishmania, but has some limitations. An alternative reliable and fast genotyping method for addressing population genetic and key epidemiological questions, is multilocus microsatellite typing (MLMT). MLMT using 15 markers was applied to 91 strains of L. donovani, L. archibaldi, L. infantum and L. chagasi from major endemic regions of visceral leishmaniasis. Population structures were inferred by combination of Bayesian model-based and distance-based approaches. Six main genetically distinct populations were identified: (1) L. infantum/L. chagasi MON-1 and (2) L. infantum/L. chagasi non-MON-1, both Mediterranean region/South America; (3) L. donovani (MON-18), L. archibaldi (MON-82), L. infantum (MON-30, 81) and (4) L. donovani (MON-31, 274), L. archibaldi (MON-82, 257, 258), L. infantum (MON-267), both Sudan/Ethiopia; (5) L. donovani MON-2, India; (6) L. donovani (MON-36, 37, 38), Kenya and India. Substructures according to place and time of strain isolation were detected. The VL populations seem to be predominantly clonal with a high level of inbreeding. Allelic diversity was highest in the Mediterranean region, intermediate in Africa and lowest in India. MLMT provides a powerful tool for global taxonomic, population genetic and epidemiological studies of the L.donovani complex.

Multilocus microsatellite typing as a new tool for discrimination of Leishmania infantum MON-1 strains.

The Leishmania donovani complex, which consists of L. donovani, L. infantum-L. chagasi, and L. archibaldi, is responsible for visceral manifestations of leishmaniasis. Multilocus enzyme electrophoresis is the standard method for the characterization and identification of strains of Leishmania. For L. infantum, the predominance of zymodeme MON-1 significantly reduces the discriminative power of this approach. In the present study, we developed 17 independent polymorphic microsatellite markers for the typing of strains of L. infantum, with the main emphasis on zymodeme MON-1. The discriminative powers of 11 markers selected from among these markers were tested by using a panel of 63 isolates of the L. donovani complex. Unique multilocus genotypes were observed for the strains analyzed, with only three exceptions. Model-based and distance-based analyses of the data set showed comparable results. It was possible to discriminate between L. donovani sensu stricto, a non-MON-1 group of L. infantum isolates, and a MON-1 group of L. infantum isolates. Within MON-1, three clusters with geographical correlations became apparent. The frequency of heterozygosity in the alleles analyzed varied extremely between the different groups of isolates. The main clusters described are not consistent with species definitions based on isoenzyme analysis but confirm the results of former PCR-based investigations.

Analysis of ribosomal DNA internal transcribed spacer sequences of the Leishmania donovani complex.

To understand phylogenetic relationships of species and strains within the Leishmania donovani complex, we have analyzed the ribosomal DNA internal transcribed spacer (ITS) sequences of 27 Leishmania infantum, 2 Leishmania chagasi, 18 L. donovani and 5 Leishmania archibaldi strains of different zymodemes and geographical origin. Eight ITS sequence types were found. All detected sequence variation within ITS1 and ITS2 was based on 12 polymorphic microsatellites. The L. infantum strains from the Mediterranean region, China and L. chagasi from the New World formed a phylogenetic group well separated from the second main group including all strains from East Africa and India. Within the latter group three distinct phylogenetic subgroups could be differentiated: (1) L. donovani (Sudan/Ethiopia, China) + L. archibaldi (Sudan), (2) L. donovani (Sudan/Ethiopia) + L. infantum (Sudan) + L. archibaldi (Sudan/Ethiopia), and (3) L. donovani (Kenya, India). These groups are not consistent with previous species definitions based on isoenzyme analyses, e.g. L. infantum is polyphyletic and L. archibaldi is not supported as a distinct species. Two groups of Indian strains could be differentiated, one of which has an identical sequence type to the strains from Kenya. Three main lineages of strains can thus be differentiated in East Africa: two quite distantly related groups of strains from Sudan/Ethiopia, and a third group including all strains from Kenya, which is more closely related to part of the Indian strains than to any of the Sudanese/Ethiopian groups. The ITS sequence analysis presented here supports the need for revision of the taxonomy of the L. donovani complex.

Genetic and biological diversity among populations of Leishmania major from Central Asia, the Middle East and Africa.

Evidence is provided for genetic and biological variation among Leishmania major strains that correlates with their geographical origin. The host-parasite relationship also appears to be specific. Great gerbils, Rhombomys opimus, and fat sand rats, Psammomys obesus, are the main reservoir hosts in Central Asia and the Middle East, respectively. However, the Central Asian parasite failed to infect the Middle Eastern rodent host in the laboratory, and vice versa. A permissively primed intergenic polymorphic (PPIP)-PCR and a single-stranded conformation polymorphism (SSCP)-PCR exposed genetic polymorphism among 30 strains of L. major from different geographical regions. This was verified by subsequent sequencing of DNA from the same strains using four genomic targets: (a) the NADH-dehydrogenase (NADH-DH) gene, (b) the 6-phosphogluconate dehydrogenase (6PGD) gene, (c) the ribosomal internal transcribed spacers, and (d) an anonymous DNA sequence originally amplified with random primers. All the genetic markers indicated that the nine Central Asian strains were a separate homogenous genetic group. The Middle Eastern strains formed another geographical group that displayed heterogeneity corresponding with their different Middle Eastern locations. Molecular markers and host-parasite relationships confirmed that Central Asian and Middle Eastern strains are genetically and biologically distinct sub-populations of L. major. Three African strains of L. major were genetically closer to the Middle Eastern strains, and a representative one did infect fat sand rats, but they had distinct permissively primed inter-genic polymorphic PCR patterns and internal transcribed spacer 2 types.

PCR diagnosis and characterization of Leishmania in local and imported clinical samples.

Leishmaniasis diagnosis in regions where multiple species exist should identify each species directly in the clinical sample without parasite culturing. The sensitivity of two PCR approaches which amplify part of the ssu rRNA gene and the ribosomal internal transcribed spacer (ITS), respectively, was determined using human and dog blood seeded with Leishmania promastigotes. ssu-rDNA-PCR was more sensitive than ITS1-PCR, however species identification was not possible by the former approach. When a nested ITS1-PCR was used its sensitivity equaled the ssu-rDNA-PCR. Digestion of ITS1 amplicon with the restriction enzyme HaeIII distinguished all medically relevant Leishmania species. ITS1-PCR was used to diagnose 162 local and imported suspected cases of leishmaniasis in Israel, the Palestinian Authority and Germany. 113 cases (69.7%) were positive by PCR and species identification was possible in 110 samples. Leishmania DNA was also amplified and identified at the species level from archived non-stained and Giemsa stained microscope slides.

Strain typing in Leishmania donovani by using sequence-confirmed amplified region analysis.

To differentiate strains of Leishmania donovani, allelic markers at the DNA level were developed by sequence-confirmed amplified region analysis (SCAR). Homologous fragments from different strains of L. donovani were amplified by PCR using random primers and subsequently screened for single-strand conformation polymorphisms. Direct sequencing revealed 55 sequence polymorphisms in eight co-dominant DNA markers; 38 of them were single point mutations. Heterozygosity was evident for 69% and fixed heterozygosity for 25% of all polymorphisms. At most polymorphic sites one of the segregation genotypes was missing. Nineteen unique multilocus genotypes were identified among 29 strains of L. donovani. One genotype was represented by eight Sudanese strains; also two strains from Sudan as well as two strains from Kenya, respectively, shared identical genotypes. All other strains had individual multilocus genotypes. Calculation of genetic distances showed a correlation between multilocus genotypes and the geographical origin of these strains. African strains were found in one well-supported cluster with Kenyan and Sudanese strains clearly separated. SCAR markers seem to represent a random sample of neutral genetic variation present in natural populations. They are co-dominant because they can detect all possible allele combinations in a diploid organism and may, therefore, be very useful for population genetic analysis in Leishmania.