On abnormal Phlebotomus perniciosus (Diptera: Psychodidae: Phlebotominae) from the center of Tunisia.

Phlebotomus perniciosus is the most important vector of Leishmania infantum in the Western part of the Mediterranean basin. Atypical specimens of Ph. perniciosus called (pna) with a parameral sheath simply curved, not bifurcated, have been reported in many locations. In this study, we describe abnormal Ph. perniciosus male specimens. Sand flies were collected in center Tunisia and identified morphologically. Cytochrome b PCR-sequencing was carried out for abnormal Ph. perniciosus male specimens in order to confirm the morphological identification and assess the intraspecific genetic polymorphism. Abnormal Ph. perniciosus specimens were characterized by a multifurcated parameral sheath. A parsimonious haplotype network based on cyt b locus analysis showed that typical and abnormal Ph. perniciosus described in our investigation were grouped together in the same branch. Thus, genetic outcomes confirmed that the new phenotype is only an original morphotype of Ph. perniciosus.

Blood meal analysis and molecular detection of mammalian Leishmania DNA in wild-caught Sergentomyia spp. from Tunisia and Saudi Arabia.

Phlebotomine sand flies (Diptera: Phlebotominae) belonging to the genus Phlebotomus are vectors of pathogens such as arboviruses, bacteria, and parasites (Leishmania). Species of the genus Sergentomyia (Se.) transmit Sauroleishmania (Reptile Leishmania) and feed on cold-blooded vertebrates; recently, they have been incriminated in mammalian Leishmania transmission. In addition, they have been reported to feed on warm-blooded vertebrates. This study aimed to (i) screen wild-caught Sergentomyia species for the detection of mammalian Leishmania and (ii) identify the blood meal origin of engorged females. The sand flies were collected using centers for disease control and prevention (CDC) traps, mounted and identified morphologically. Only females of the genus Sergentomyia were screened for Leishmania infection using PCR targeting the 18S ribosomal DNA locus. For positive specimens, Leishmania parasites were typed using nested PCR targeting ribosomal internal transcribed spacer 1 followed by digestion with HaeIII. The PCR-RFLP results were confirmed through sequencing. Blood meal identification was performed through PCR amplification of the vertebrate cytochrome b gene using degenerate primers followed by sequencing. In total, 6026 sand fly specimens were collected between 2009 and 2018. Among these, 511 belonged to five species of Sergentomyia genus: Se. minuta (58.51%), Se. fallax (18.01%), Se. clydei (14.68%), Se. dreyfussi (6.26%), and Se. antennata (2.54%). A total of 256 female Sergentomyia sp. specimens were screened for Leishmania infection. Seventeen (17) were positive (6.64%). Two Leishmania species were identified. Leishmania major DNA was detected in five specimens; this included three Se. fallax, one Se. minuta, and one Se. dreyfussi collected from Tunisia. Leishmania infantum/L. donovani complex was detected in four Se. minuta and three Se. dreyfussi specimens collected from Tunisia. In addition, we identified the blood meal origin of five engorged Se. minuta specimens collected from Tunisia. Sequencing results revealed two blood sources: humans (n = 4) and reptiles (n = 1) indicating possible role of Sergentomyia species in the transmission of human Leishmania. In addition, these species could be involved in the life cycle of L. infantum/L. donovani complex and L. major. The results of the blood meal origin showed that Sergentomyia fed on both cold- and warm-blooded vertebrates. These findings enable a better understanding of the behavior of this sand fly genus. Further studies should focus on the role of Sergentomyia in human Leishmania transmission and possible control of this disease.

Epidemiology of Pityriasis versicolor in Tunisia: Clinical features and characterization of Malassezia species.

Malassezia (M.) genus includes commensal yeasts of increasing medical importance, as they result in many diseases, ranging from pityriasis versicolor (PV) to systemic infections. Previous studies reported geographical variations in distribution of Malassezia species in PV lesions. The aims of the current study were to define the clinico-demographic features of PV in Tunisia, to characterize Malassezia isolates using phenotypic and molecular techniques and to find out any association between species and clinico-demographic parameters. In total, 120 PV patients were enrolled in this study. Skin scrapings were collected and inoculated on Sabouraud agar and modified Dixon medium. Malassezia species were identified using conventional phenotypic methods and 26 s rDNA PCR-RFLP. The highest prevalence of PV was observed among young adults' group. The most affected body areas were the back and neck. In overall, 50.8% and 35% of PV cases had pruritus and history of recurrence respectively. The overall concordance between phenotypic and molecular methods was high (80.95%). The discordant results are rather due to the presence of multiple species in a single culture than true misidentification. Using PCR-RFLP, M. furfur was the most isolated species (38.7%) followed by M. globosa (37.7%), M. restricta and M. sympodialis. No statistically significant association was noted between Malassezia spp. and clinico-demographic characteristics. Unlike many reports from temperate climate countries, M. furfur and M. globosa along together were the most frequently isolated species in Tunisian PV patients. Although phenotypic methods remain simple and cost-effective, molecular techniques are considered as fast and accurate methods for diagnosis purposes.

Molecular detection and identification of Leishmania DNA and blood meal analysis in Phlebotomus (Larroussius) species.

BACKGROUND: Phlebotomus (Larroussius) perniciosus and Canis familiaris are respectively the only confirmed vector and reservoir for the transmission of Leishmania (L.) infantum MON-1 in Tunisia. However, the vector and reservoir hosts of the two other zymodemes, MON-24 and MON-80, are still unknown. The aim of this study was to analyze the L. infantum life cycle in a Tunisian leishmaniasis focus. For this purpose, we have focused on: i) the detection, quantification and identification of Leishmania among this sand fly population, and ii) the analysis of the blood meal preferences of Larroussius (Lar.) subgenus sand flies to identify the potential reservoirs. METHODOLOGY AND FINDINGS: A total of 3,831 sand flies were collected in seven locations from the center of Tunisia affected by human visceral leishmaniasis. The collected sand flies belonged to two genus Phlebotomus (Ph.) (five species) and Sergentomyia (four species). From the collected 1,029 Lar. subgenus female sand flies, 8.26% was positive to Leishmania by ITS1 nested PCR. Three Leishmania spp. were identified: L. infantum 28% (24/85), L. killicki 13% (11/85), and L. major 22% (19/85). To identify the blood meal sources in Ph. Lar. subgenus sand flies, engorged females were analyzed by PCR-sequencing targeting the vertebrate cytochrome b gene. Among the 177 analyzed blood-fed females, 169 samples were positive. Sequencing results showed seven blood sources: cattle, human, sheep, chicken, goat, donkey, and turkey. In addition, mixed blood meals were detected in twelve cases. Leishmania DNA was found in 21 engorged females, with a wide range of blood meal sources: cattle, chicken, goat, chicken/cattle, chicken/sheep, chicken/turkey and human/cattle. The parasite load was quantified in fed and unfed infected sand flies using a real time PCR targeting kinetoplast DNA. The average parasite load was 1,174 parasites/reaction and 90 parasites/reaction in unfed and fed flies, respectively. CONCLUSION: Our results support the role of Ph. longicuspis, Ph. perfiliewi, and Ph. perniciosus in L. infantum transmission. Furthermore, these species could be involved in L. major and L. killicki life cycles. The combination of the parasite detection and the blood meal analysis in this study highlights the incrimination of the identified vertebrate in Leishmania transmission. In addition, we quantify for the first time the parasite load in naturally infected sand flies caught in Tunisia. These findings are relevant for a better understanding of L. infantum transmission cycle in the country. Further investigations and control measures are needed to manage L. infantum transmission and its spreading.

Transmission cycle analysis in a Leishmania infantum focus: Infection rates and blood meal origins in sand flies (Diptera: Psychodidae).

An entomological study was conducted in a Leishmania infantum focus, including the identification of the sand fly species, the detection and the characterization of Leishmania DNA in female sand flies, and blood meal origins in engorged sand flies. A total of 643 sand flies (31% female, 69% male) was identified based on their morphological features or molecular markers. Ten different species were identified, with Phlebotomus perniciosus, the confirmed vector of L. infantum, being the most abundant (56%), P. papatasi in 25% of sand flies, the unique vector species of L. major, and P. longicuspis in 7% of cases, the suspected second vector of L. infantum. Moreover, the infection rate was 3.4% in P. perniciousus, P. papatasi, P. longicuspis, and Sergentomya minuta. Also, L. infantum was identified in five unfed P. perniciosus and two P. longicuspis. Our results suggest the vector role of P. perniciosus and P. longicuspis in the transmission cycle of L. infantum. The DNA of four mammalian species (human, rabbit, horse, and cow) was identified in the blood meals of sand flies, suggesting that these species are potential reservoirs of leishmaniasis, though it is not yet fully elucidated (especially for MON-24 and MON-80). We suggest the existence of different transmission cycles of L. infantum involving different species of sand flies and hosts.

The vector competence of Phlebotomus perniciosus for Leishmania infantum zymodemes of Tunisia.

Experimental infections of Phlebotomus (L.) perniciosus from a colony established in Madrid (Spain) carried out with the Leishmania (L.) infantum zymodemes MON-1, MON-24, and MON-80 isolated in Tunisia are reported here. Laboratory-reared female sand flies were experimentally fed via membrane feeding device on a suspension of L. infantum promastigotes in defibrinated rabbit blood (107/ml). Engorged females were dissected at progressive time points postfeeding to observe the intravectorial cycle of different L. infantum zymodemes. Development in the sand fly midgut of L. infantum parasites to the infective metacyclic promastigotes and monitoring the forward progression of parasites to finally reach the stomodeal valve (SV) of the sand fly were assessed. All tested L. infantum zymodemes developed properly in P. perniciosus. Experimental feeding with suspensions of promastigotes of all zymodemes led to very heavy late-stage infections. MON-24 and MON-80 zymodemes colonized the (SV) of P. perniciosus earlier than zymodeme MON-1, 2 and 4 days, respectively. Metacyclic promastigotes were observed in all experimental infections. The study shows for the first time that colonized P. perniciosus is able to acquire, retain, and develop in its midgut the zymodemes MON-24 and MON-80 isolated in Tunisia and highlights the putative role of this sand fly species in the transmission of such zymodemes to mammalian hosts in this country. The ability of experimentally infected sand fly species to transmit by bite such zymodemes needs to be assessed.

Clinical Presentation of Cutaneous Leishmaniasis caused by Leishmania major.

BACKGROUND/AIMS: The diagnosis of cutaneous leishmaniasis (CL) is based on the microscopic detection of amastigote, isolation of the parasite, or the detection of Leishmania DNA. Nevertheless, since these techniques are time consuming and not usually available in many endemic countries, the diagnosis remains clinical. Consequently, such disease may be overlooked because of its similarity to other skin diseases. The aim of this study is to describe the clinical polymorphism of CL caused by Leishmaniamajor. METHODS: A cross-sectional survey was carried out on 166 patients. Diagnoses were made by both microscopic examination of stained tissue-scraping smears and PCR. The Leishmania species was identified by restriction enzyme analysis of the ribosomal internal transcribed spacer 1 region. The clinical polymorphism was analyzed only for patients with a positive diagnosis for CL and L. major as the identified species. RESULTS AND CONCLUSION: Of the 166 patients, 75 patients fit the inclusion criteria. Twelve different types of CL caused by L. major were defined. The most common type was the ulcero-crusted form followed by the papulonodular form and the impetigenous form. The ulcerated, mucocutaneous, lupoid, and sporotricoid forms were less common. The eczematiform, erysipeloid, verrucous, psoriasiform, and pseudotumoral types were represented by a single case. Zoonotic CL caused by L. major can simulate many other skin diseases, which may lead to a significant spread of this disease and increases in morbidity and drug resistance. This large polymorphism may be the result of a complex association between the genetics of the parasite and the immune response of the host.

Unexpected co-detection of promastigote and amastigote Leishmania forms in a human cutaneous lesion: implications for leishmaniasis physiopathology and treatment.

Cutaneous leishmaniasis pathogenicity depends on the survival and replication of the parasitic protozoa in the form of non-motile amastigotes inside macrophages. Here, we report the unprecedented observation of both Leishmania major amastigote and promastigote forms (the latter is normally detected only in the mid gut of the insect vector or in vitro culture) in a cutaneous lesion of a 6-year-old boy. This finding suggests that modifications of the skin lesion environment, such as maceration and changes in pH or temperature, could promote the in situ transformation of Leishmania amastigotes into promastigotes. This observation raises questions about the physiopathology of cutaneous leishmaniasis and the influence of micro-environmental changes on the efficiency of topical treatments.

Transmission of visceral leishmaniasis in a previously non-endemic region of Tunisia: detection of Leishmania DNA in Phlebotomus perniciosus.

Visceral leishmaniasis (VL) has been endemic in northern Tunisia and has occurred sporadically in the center of Tunisia. Recently, there have been several cases from areas known to be free of VL. We report in this work all human and canine cases of VL recorded between 2003 and 2011 and an entomological study of phlebotomine fauna in a previously non-endemic region. Sixty-three cases of VL were diagnosed and identified as L. infantum using several different methods. Eight species of 179 sand flies were caught and identified by both morphological and molecular methods. Two genera were present, Phlebotomus and Sergentomya, with an abundance of the subgenus Phlebotomus (Larrousius) spp., a classic vector of VL in Tunisia. Moreover, Leishmania DNA was detected in seven unfed Phlebotomus pernicousus and L. infantum was identified in three of them. This result confirms the establishment of a transmission cycle of VL in the studied region by the coexistence of infected vectors with infected hosts.

Twenty-four new human cases of cutaneous leishmaniasis due to Leishmania killicki in Metlaoui, southwestern Tunisia: probable role of Phlebotomus sergenti in the transmission.

Metlaoui district in the South-west of Tunisia is a classical focus of cutaneous leishmaniasis (CL) due to Leishmania major. Since 2005, a single case of CL due to L. killicki has been reported. We report twenty four human cases due to this parasite, affecting men and women from 2 to 70 years old. Leishmania killicki have been typed using molecular techniques: polymerase chain reaction (PCR) followed by restriction fragment length polymorphism (RFLP) and gene sequencing. Four strains from patients have been successfully cultured on NNN medium and isoenzymatically typed as L. killicki MON-8. Our results strongly suggests that Metlaoui is a new L. killicki focus with a stable transmission cycle. Sand flies fauna in the same focus was also studied. 1400 Phlebotomine sand flies (785 males/615 females) have been caught during an entomological survey. Leishmania major DNA has been found in one P. papatasi female, the most abundant species, whereas L. killicki DNA has been found in one Phlebotomus sergenti female emphasizing the probable role of this species as vector of this zoonotic parasite.

First detection of Leishmania killicki (Kinetoplastida, Trypanosomatidae) in Ctenodactylus gundi (Rodentia, Ctenodactylidae), a possible reservoir of human cutaneous leishmaniasis in Tunisia.

BACKGROUND: Leishmania killicki was originally described in 1980 in southeast Tunisia. It was also recently reported in Lybia and Algeria. Nevertheless, neither vector nor reservoirs of this parasite are known. The identification of the vector and the animal reservoir host of L. killicki is critical for the establishment of an efficient control strategy. FINDINGS: blood, popliteal lymph node, spleen, bone marrow, liver and skin were collected from 50 rodents in 2009 in south western Tunisia. Samples were smeared onto glass slides, cultured on NNN medium and tested by polymerase chain reaction for Leishmania detection. Parasites were detected by PCR from 10 Psammomys obesus and from two Ctenodactylus gundi. Parasite identification was performed simultaneously by internal transcribed spacer 1 PCR-RFLP and by PCR sequencing. Both Leishmania major and Leishmania killicki were identified from infected Psammomys and Ctenodactylus gundi respectively. CONCLUSION: This is the first report of Leishmania killicki identified from Ctenodactylus gundi in Tunisia. This result supports the assumption that C. gundi is a potential reservoir for Leishmania killicki.

Development of a polymerase chain reaction-restriction fragment length polymorphism assay for Leishmania major/Leishmania killicki/Leishmania infantum discrimination from clinical samples, application in a Tunisian focus.

Topoisomerase II gene of Leishmania genus was used to develop a molecular tool for detection and species differentiation of Leishmania from clinical samples. Identification was achieved by a polymerase chain reaction followed by digestion with 2 restriction endonucleases BstU1 and Taq1. Despite the relatively low sensitivity, it is able to differentiate between 3 complexes responsible for cutaneous leishmaniasis.

Population structure of Tunisian Leishmania infantum and evidence for the existence of hybrids and gene flow between genetically different populations.

Twenty-seven strains of Leishmania infantum from north and central Tunisia belonging to the three main MON zymodemes (the MON-typing system is based on multilocus enzyme electrophoresis (MLEE) of 15 enzymes) found in this country (MON-1, MON-24 and MON-80) and representing different pathologies (visceral, cutaneous and canine leishmaniasis) have been studied to understand the genetic polymorphism within this species. Intraspecific variation could be detected in L. infantum by the use of 14 hypervariable microsatellite markers. In addition to microsatellite repeat length variation, a high degree of allelic heterozygosity has been observed among the strains investigated, suggestive of sexual recombination within L. infantum groups. The two major clusters found by using Bayesian statistics as well as distance analysis are consistent with the classification based on isoenzymes, dividing Tunisian L. infantum into MON-1 and MON-24/MON-80. Moreover, the existence of hybrid strains between the MON-1 and the non-MON-1 populations has been shown and verified by analysis of clones of one of these strains. Substructure analysis discriminated four groups of L. infantum. The major MON-1 cluster split into two groups, one comprising only Tunisian strains and the second both Tunisian and European strains. The major MON-24 cluster was subdivided into two groups with geographical and clinical feature correlations: a dermotropic group of strains mainly from the north, and a viscerotropic group of strains from the centre of Tunisia. The four viscerotropic hybrid strains all originated from central Tunisia and were typed by MLEE as MON-24 or MON-80. To our knowledge, this is the first report describing relationships between clinical picture and population substructure of L. infantum MON-24 based on genotype data, as well as the existence of hybrids between zymodemes MON-1 and MON-24/MON-80, and proving one of these hybrid strains by molecular analysis of the parent strain and its clones.