Abstract

Chaco province is included in Argentinean ecoregions with human tegumentary leishmaniasis case records. During 2012-2014 in Pampa del Indio town an ecoepidemiological study was carried out including phlebotomine dynamics and its natural infection with Leishmania demonstrated by sand flies dissection, polymerase chain reaction and sequencing. The species recorded were: Migonemyia migonei (72.79%), Nyssomyia neivai (23.6%), Evandromyia cortelezzii (0.94%), Evandromyia sallesi (0.39%), Cortelezzii complex (1.61%), Evandromyia aldafalcaoae (0.05%), Psathyromyia bigeniculata (0.02%), Brumptomyia brumpti (0.6%) and Corumbaensis complex (0.01%). A total of 380 females sand flies (Cortelezzii complex, Mg. migonei and Ny. neivai) from peridomicile and extradomicile were individually dissected and no flagellates were observed in the intestinal tract. Later, these females were arranged in 38 pools for molecular analyses and Leishmania braziliensis DNA was amplified in 3 pools with a minimum infection rate of the total females of 0.8%, while specific rates were 0.5% for the Cortelezzii complex and 1.5% for Mg. migonei. In conclusion, our results would strengthen the hypothesis that, in the study area, these species are candidates to be incriminated as vectors, while further studies will be required to fulfill the criteria to characterize both species as proven vectors of Le. braziliensis.

Key words
Leishmaniasis; natural infection; phlebotomine sand flies; wild vector

INTRODUCTION

Phlebotomine sand flies in Argentina includes 38 species distributed in 14 provinces, with greater abundance and richness in the Northeast (ANE), Northwest (ANW) and Chaqueña regions (Quintana et al. 2012QUINTANA MG, FERNANDEZ MS & SALOMON OD. 2012. Distribution and abundance of Phlebotominae, vectors of leishmaniasis, in Argentina: Spatial and temporal analysis at different scales. J Trop Med Published online. doi: 10.1155/2012/652803 MCID: PMC3270461. PMID: 22315620., Szelag et al. 2017SZELAG EA, ROSA JR, QUINTANA MG & SALOMÓN OD. 2017. Temporal distribution of, and effect of anthropic modifications on, phlebotomine populations in the Chaco Bioregion, Argentina. The Royal Entomological Society. Medical and Veterinary Entomology 32: 206-2015.). In the latter, in the province of Chaco, 19 species distributed in the dry Chaco and wet Chaco bioregions were recorded (Szelag et al. 2017SZELAG EA, ROSA JR, QUINTANA MG & SALOMÓN OD. 2017. Temporal distribution of, and effect of anthropic modifications on, phlebotomine populations in the Chaco Bioregion, Argentina. The Royal Entomological Society. Medical and Veterinary Entomology 32: 206-2015.). Nyssomyia neivai and Migonemyia migonei were the most frequent and abundant species in wet Chaco and Mg. migonei and Cortelezzii complex in dry Chaco (Salomón et al. 2008a).

Nyssomyia neivai was the first species in Argentina involved as a probable vector of Leishmania (Viannia) braziliensis by amplification of the DNA of Leishmania sp. during the outbreak of tegumentary leishmaniasis (TL) in the province of Tucumán (ANW) (Córdoba Lanús et al. 2006CÓRDOBA LANÚS E, LIZARRALDE DE GROSSO M, PIÑERO JE, VALLADARES B & SALOMÓN OD. 2006. Natural infection of Lutzomyia neivai with Leishmania spp. in northwestern Argentina. Act Trop 98: 1-5.). In other studies Le. infantum DNA was detected in Ny. whitmani, Mg. migonei, Lutzomyia longipalpis and Micropigomyia quinquefer in the province of Misiones (ANE) (Acardi et al. 2010ACARDI S, LIOTTA DJ, SANTINI MS, ROMAGOSA CM & SALOMON OD. 2010. Detection of Leishmania infantum in naturally infected Lutzomyia longipalpis (Diptera: Psychodidae: Phlebotominae) and Canis familiaris in Misiones, Argentina: First report of PCR-RFLP and a sequencing confirmation assay. Mem Inst Oswaldo Cruz 105: 796-799., Moya et al. 2015MOYA SL, GIULIANI MG, MANTECA ACOSTA M, SALOMÓN OD & LIOTTA DJ. 2015. First description of Migonemyia migonei (França) and Nyssomyia whitmani (Antunes & Coutinho) (Psychodidae: Phlebotominae) natural infected by Leishmania infantum in Argentina. Acta Trop 184., 2017MOYA SL, GIULIANI MG, SANTINI MS, QUINTANA MG, SALOMÓN OD & LIOTTA DJ. 2017. Leishmania infantum DNA detected in phlebotomine species from Puerto Iguazú City, Misiones province, Argentina. Acta Trop 122-124.) and Le. braziliensis in Cortelezzii complex in Chaco (Rosa et al. 2012ROSA JR, PEREIRA DP, BRAZIL RP, ANDRADE FILHO JDA, SALOMÓN OD & SZELAG EA. 2012. Natural infection of Cortelezzii complex (Diptera: Psychodidae: Phlebotominae) with Leishmania braziliensis in Chaco, Argentina. Acta Trop 123: 128-131.). Lutzomyia longipalpis was incriminated as a vector of Leishmania infantum, the etiologic agent of visceral leishmaniasis (VL) in Misiones province (Acardi et al. 2010ACARDI S, LIOTTA DJ, SANTINI MS, ROMAGOSA CM & SALOMON OD. 2010. Detection of Leishmania infantum in naturally infected Lutzomyia longipalpis (Diptera: Psychodidae: Phlebotominae) and Canis familiaris in Misiones, Argentina: First report of PCR-RFLP and a sequencing confirmation assay. Mem Inst Oswaldo Cruz 105: 796-799.). However, vector capacity is a biological definition referred to as potential in sustaining the transmission over time. It requires compliance with certain criteria in addition to a distribution of cases consistent with epidemiological data or presence of genetic material of the pathogen (Ready 2013READY P. 2013. Biology of Phlebotomine Sand Flies as Vectors of Disease. Annu Rev Entomol 58: 227-250.).

Humans cases of TL increased in 22 of the 25 provincial departments of Chaco between 2010-2013, where the highest frequency was in Liberator General San Martin department from Pampa del Indio town, between 2012 and 2013. This led to the realization of ecoepidemiological studies in this locality through the active search of cases, studies of Phlebotominae dynamics and its natural infection or the detection of Leishmania DNA to define its role as a probable vector. In this context, it was proposed to determine the natural infection in sand flies captured in Pampa del Indio by observation of intestinal flagellates and the detection of Leishmania DNA by polymerase chain reaction (PCR) and sequencing.

MATERIALS AND METHODS

Study area

Province of Chaco, department General Liberator San Martín, Pampa del Indio (26°02’S 59°56’O) (Fig. 1). Pampa del Indio is located between the dry Chaco and wet Chaco bioregion divided by the 900mm isohyetal. The first is characterized by a semi-arid continental rainfall pattern between 500-800mm per year with the formation of xerophytic forests of quebracho/algarrobo (Schinopsis, Aspidosperma, and Prosopis) and quebracho/palo santo (Schinopsis and Bulnesia) and cacti. The wet Chaco bioregion has an Atlantic rainfall regime of 1,200mm per year, most frequently in summer and autumn, with the formation of parks and savannas (Cabrera 1971CABRERA AL. 1971. Fitogeografía de la República Argentina. Boletín de la Sociedad Argentina de Botánica 14: 1-25.).

Figure 1
Study area and its location in Pampa del Indio, in Chaco biogeographical eco-region of Chaco Province, Argentina.

Sample site

Campo Cacique site. It corresponds to a protected area where Quom ethnic communities reside near to Bermejo River with areas of secondary forest of quebracho and palo santo, and an herbaceous stratum composed of bromeliads and grasses forming part of the gallery forests to the Bermejo River.

Phlebotominae capture

January 2013 to December 2014. In Campo Cacique, CI-PI (S25°53’W 059°49’S) and C2-PI (S25°51’W 059°51’S) were selected because they were referred as a probable site of leishmaniasis infection. Captures were carried out with CDC light traps (Sudia & Chamberlain 1962SUDIA WD & CHAMBERLAIN RW. 1962. Battery-operated light trap, an improved model. Mosquito News 22: 126-129.) with monthly frequency for three consecutive nights installed in the stratum base at 1.5m above the ground and the height stratum at 10m height. The first one included the domicile and galleries, the peridomicile up to 50m from the domicile with chicken coops, sheep and cattle corral, and the extradomicile in a tree base with a height greater than 10m in the secondary vegetation until 100m from the peridomicile. The stratum height refers to the canopy of the same extradomicile tree at 10m height.

Phlebotominae identification and detection of Leishmania sp.:

Sand flies were separated from other insects and females without blood content in the digestive tract collected in summer, spring and autumn 2013 and summer 2014 were selected. They were individually dissected according to the methodology described by Rioux (1986)RIOUX JA, GUILVARD E, DEREURE J, LANOTTE G, DENIAL M, PRATLONG F, SERRES E & BELMONTE A. 1986. Infestation naturelle de Phlebotomus papatasi (Scopoli, 1786) par Leishmania major MON-25. A propôs de 28 souches isoléees dans um foyer du Sud marocain. Leishmania Taxonomie et phylogenèse. Aplication eco-épidémiologiques. Coll. Int. CNRS/INSERM, 1984. IMEEE, Montpellier, 471-480 p. with modifications oriented to the search for intestinal flagellates in phase contrast (40X). The identification of these females was made from the head mounted on an individual slide and the morphology of the spermathecae observed during dissection, while the rest of the sand flies were identified by the morphology of their entire bodies. The nomenclatures, abbreviations, and classification schemes were according to Galati et al. 2017GALATI EAB, GALVIS-OVALLOS F, LAWYER P, LÉGER N & DEPAQUIT J. 2017. An illustrated guide for characters and terminology used in descriptions of Phlebotominae (Diptera, Psychodidae). Parasite 24: 26. and Galati 2018GALATI EAB. 2018. Phlebotominae (Diptera, Psychodidae): Classification, Morphology and Terminology of Adults and Identification of American Taxa. In: Rangel E & Shaw J (Eds), Brazilian Sand Flies. Springer International Publishing AG, 494 p.. Cortelezzii complex refers to the females of Ev. cortelezzii and Ev. sallesi that are not differentiable based on morphological characters (Szelag et al. 2018SZELAG EA, ROSA JR, GALATI EAB, ANDRADE FILHO JD & SALOMÓN OD. 2018. Considerations on the species complex of the Cortelezzii series (Diptera: Psychodidae) and description of Evandromyia chacuensis sp. nov., a new Phlebotomine species of the Chaco Region, Argentina. J Med Entomol 55: 902-909.). On the other hand, males of Ev. cortlezzii and Ev. sallesi are treated in this work as different species for diversity index analysis. The species richness (S), Shannon-Wiener diversity index (Hʹ) and equitability of Pielou (J) were calculated to describe the communities where the sandflies with Leishmania DNA were captured. The selected females were grouped in lots of 10 females of the same species, site and date and kept at 4°C until molecular analysis at the National Institute of Tropical Medicine (INMeT-ANLIS), Puerto Iguazú, Misiones, Argentina. DNA extraction was performed by commercial DNA Puriprep-S Highway kit (Inbio, Argentina) from the unmacerated lots and with an incubation period of 1.45hs. For the detection of Leishmania DNA, the polymerase chain reaction (PCR) was performed with blank in the mini-exon gene belonging to the kinetoplast genome, using the Fme and Rme primers according to Marfurt et al. (2003)MARFURT J, NIEDERWIESER I, MAKIA D, BECK HP & FELGER I. 2003. Diagnostic genotyping of Old and New World Leishmania species by PCR- RFLP. -1483019381 Diagn Microbiol Infect Dis 46: 115-124., Gotaq green Master Mix (Promega, USA) and the reference strain MHOM/BR/75/M2903 as a positive control. The PCR products were separated by 1.5% agarose gel electrophoresis stained with Sybr Green (Invitrogen, USA) and visualized in 470nm blue light LED transilluminator. They were then purified and sent to sequence both ways (Macrogen Inc, Korea). Sequences were evaluated by chromatogram observation and edition in MEGA v.7, the identity was confirmed with the Basic Local Alignment Search Tool (BLAST). Minimum infection rates were calculated according to Paiva et al. 2010PAIVA BR, OLIVEIRA AG, DORVAL MEMC, GALATI EAB & MALAFRONTE RS. 2010. Species-specific identification of Leishmania in naturally infected sand flies captured in Mato Grosso do Sul State, Brazil. Acta Trop 115: 126-130. discriminating the values ​​according to the total analyzed (MIRt) and according to the total of each species (MIRs).

RESULTS

Phlebotominae capture

In total 35,727 phlebotomine: Mg. migonei (72.79%), Ny. neivai (23.6%), Evandromyia cortelezzii (0.94%), Ev. sallesi (0.39%), Cortelezzii complex (1.61%), Ev. aldafalcaoae (0.05%), Psathyromyia bigeniculata (0.02%), Brumptomyia brumpti (0.6%) and Corumbaensis complex (0.01%) were recorded. The greatest richness in C1-PI was in base (S=8) and in C2-PI, it was in peridomicile (S=9). In height, both sites had the same richness (S=6). The greatest diversity and equitability were observed at domicile (H´=0.8975; J= 0.4612) of C1-PI and, in base (H´=0.8929; J=0.4294) of C2-PI. Migonemyia migonei and Ny. neivai predominated in peridomicile in both sites and periods (p <0.0001); in extradomicile, only Mg. migonei with no records of Ny neivai in 2014 (p <0.0001). Cortelezzii complex predominated in the base stratum in 2013. The highest abundance was observed in C1-PI, in 2014 and the lowest in C2-PI in 2013.

Leishmania spp. Detection

A total of 380 phlebotomine were individually dissected for observation of flagellated forms then, they were identified and arranged in 38 pools: Cortelezzii complex (21 pools), Mg. migonei (13 pools) and Ny. neivai (4 pools). No flagellates were observed in the intestinal tract. Leishmania braziliensis DNA was amplified in 3 pools from samples of March, November and January 2013 (1 pool each) in different ecotopes, one pool of Cortelezzii complex and two pools ofMg. migonei (Table I). Taking into account the total number of females analyzed, the minimum infection rate resulted in MIRt = 0.8%, while according to the species, it resulted in 0.5% and 1.5% for Cortelezzii complex and Mg. migonei, respectively. The three sequences obtained were edited and resulted in 105 bp (same haplotype) that showed 100% identity with those available in GenBank for Le. braziliensis.

DISCUSSION

The evidence involving one species of Phlebotominae as a vector of Leishmania sp. includes seven biological criteria, five of them were proposed by Killick-Kendrick (1990)KILLICK-KENDRICK R. 1990. Phlebotomine vectors of the leishmaniases: a review. Med Vet Entomol 4: 1-24. Later, Bates (2007)BATES PA. 2007. Transmission of Leishmania metacyclic promastigotes by phlebotomine sand flies. Int J Parasitol 37: 1097-106. and Ready (2013)READY P. 2013. Biology of Phlebotomine Sand Flies as Vectors of Disease. Annu Rev Entomol 58: 227-250. incorporated mathematical criteria associated with epidemiological and ecological backgrounds. The Phlebotominae of the Old and the New World in which their role as vectors was demonstrated, meet the first four biological criteria (Ready 2013READY P. 2013. Biology of Phlebotomine Sand Flies as Vectors of Disease. Annu Rev Entomol 58: 227-250.).

Microscopic examination of dissected phlebotomine females from Pampa del Indio did not show mobile flagellates in their digestive tract. The molecular PCR methodology, on the other hand, amplified Leishmania DNA in 0.8% of the total females analyzed considering at least one infected individual in each. The BLAST analysis showed 100% similarity with Le. braziliensis sequences obtained from reference strains (accession numbers KF633196-97) (Van der Auwera et al. 2014VAN DER AUWERA G, RAVEL C, VERWEIJ JJ, BART A, SCHÖNIAN G & FELGER I. 2014. Evaluation of four single-locus markers for Leishmania species discrimination by sequencing. J Clin Microbiol 52: 1098-1104.). These results are consistent in considering that the dissection has low sensitivity due to the difficulty of observation inherent to the practice of the procedure, the small number of flagellates, the migration capacity, the stage and the size of the protozoan. However, this method is still necessary to determine the location of parasites in the digestive tract and, after fixation and coloration, the determination of stage (criterion 2: Observation of the infectious stage in the anterior midgut and the stomodeal valve) (Ready 2013READY P. 2013. Biology of Phlebotomine Sand Flies as Vectors of Disease. Annu Rev Entomol 58: 227-250.). Other conventional methods such as in vitro culture and inoculation in experimental animals generate uncertainty when interpreting the results. These observations were referred by Salomón (2002)SALOMÓN OD. 2002. Leishmaniosis: vectores y brotes epidémicos en Argentina. En: Actualizaciones en artropodología sanitaria Argentina. RAVE (Red Argentina de Estudio de Artrópodos Vectores de enfermedades Humanas) Serie: Enfermedades transmisibles. Publicación monográfica 2: 185-196. in Argentina, not observing flagellates in the dissection of more than 3,000 females of Lu. intermedia (s.l) Ny. neivai (s.s.) and Mg. migonei captured during TL outbreaks in provinces of ANE and ANW region in 2004 (Córdoba Lanús et al. 2006CÓRDOBA LANÚS E, LIZARRALDE DE GROSSO M, PIÑERO JE, VALLADARES B & SALOMÓN OD. 2006. Natural infection of Lutzomyia neivai with Leishmania spp. in northwestern Argentina. Act Trop 98: 1-5.). In this sense, the application of molecular biology techniques has greater sensitivity and specificity for the diagnosis and identification of species through amplification and sequencing of molecular markers (Saraiva et al. 2010SARAIVA L, ANDRADE FILHO JD, SILVA S DE O, DE ANDRADE A & MELO MN. 2010. The molecular detection of different Leishmania species within sand flies from a cutaneous and visceral leishmaniasis sympatric area in Southeastern Brazil. Mem Inst Oswaldo Cruz 105: 1033-1039., Van der Auwera 2014). However, the disadvantage is that it cannot determine the viability of the parasite or see its position in the digestive tract (criterion 2). These reasons make both methods complementary at the time of incriminating a species of phlebotomine as a probable vector (Bates 2007BATES PA. 2007. Transmission of Leishmania metacyclic promastigotes by phlebotomine sand flies. Int J Parasitol 37: 1097-106.).

The first antecedents in Argentina of detection of natural infection were in Salta and Tucumán provinces with Phlebotominae captured in endemic areas between 1999 and 2003. Nyssomyia neivai was framed as a vector when Le. (Viannia) DNA was detected with MIRs=0.9%, it being the prevalent species with 96.5% relative abundance (Córdoba Lanús et al. 2006CÓRDOBA LANÚS E, LIZARRALDE DE GROSSO M, PIÑERO JE, VALLADARES B & SALOMÓN OD. 2006. Natural infection of Lutzomyia neivai with Leishmania spp. in northwestern Argentina. Act Trop 98: 1-5.). Migonemyia migonei, widely distributed in South America, was framed as a Le. braziliensis vector in different regions of Brazil, Paraguay and Argentina (Salomón et al. 2008aSALOMÓN OD ET AL. 2008a. Phlebotominae (Diptera: Psycodidae) fauna in the Chaco region and Cutaneous Leishmaniasis transmission patterns in Argentina. Mem Inst Oswaldo Cruz 103: 578-584., bSALOMÓN OD, QUINTANA MG & ROSA JR. 2008b. Eco-epidemiologia de leishmaniasis cutánea en Argentina. Sociedad Iberoamericana de Información Científica (SIIC). Salud i Ciencia 16: 514-520.). Later studies suggested Mg. migonei as a putative or secondary vector in the transmission of Le. infantum due to its relative abundance in VL epidemic outbreaks in ANW provinces in the absence of the primary vector Lu. longipalpis (Salomón et al. 2010SALOMÓN OD, QUINTANA MG, BEZZI G, MORÁN M, BETBEDER E & VALDÉZ DV. 2010. Lutzomyia migonei as putative vector of visceral leishmaniasis in La Banda, Argentina. Acta Trop 113: 84-87.). Later, Le. infantum DNA was reported in females of this species (Moya et al. 2015MOYA SL, GIULIANI MG, MANTECA ACOSTA M, SALOMÓN OD & LIOTTA DJ. 2015. First description of Migonemyia migonei (França) and Nyssomyia whitmani (Antunes & Coutinho) (Psychodidae: Phlebotominae) natural infected by Leishmania infantum in Argentina. Acta Trop 184.) until Guimaraes et al. (2016)GUIMARÃES VCFV, PRUZINOVA K, SADLOVA J, VOLFOVA V, MYSKOVA J, PINTO BRANDÃO FILHO S & VOLF P. 2016. Lutzomyia migonei is a permissive vector competent for Leishmania infantum. Parasit Vectors 9: 159. proposed its role as a permissive vector by demonstrating its susceptibility in the development of Le. infantum.

Leishmania braziliensis DNA in Cortelezzii complex was detected in the dry Chaco bioregion in coincidence of space and time with the confirmation of human cases, with a minimum infection rate greater than that detected in this study, MIRs=4% (Rosa et al. 2012ROSA JR, PEREIRA DP, BRAZIL RP, ANDRADE FILHO JDA, SALOMÓN OD & SZELAG EA. 2012. Natural infection of Cortelezzii complex (Diptera: Psychodidae: Phlebotominae) with Leishmania braziliensis in Chaco, Argentina. Acta Trop 123: 128-131.). The molecular detection of Le. braziliensis DNA in Cortelezzii complex was reported in Belo Horizonte, Minas Gerais, Brazil, with a MIRs of 3.2%, without having observed flagellate in the intestine (Saraiva et al. 2010SARAIVA L, ANDRADE FILHO JD, SILVA S DE O, DE ANDRADE A & MELO MN. 2010. The molecular detection of different Leishmania species within sand flies from a cutaneous and visceral leishmaniasis sympatric area in Southeastern Brazil. Mem Inst Oswaldo Cruz 105: 1033-1039.). However, the highest MIRs for this species with Le. braziliensis was recorded by Lana et al. (2015)LANA RS, MICHALSKY EM, FORTES-DIAS CL, FRANÇA-SILVA JC, DE OLIVEIRA LARA-SILVA F, ROCHA LIMA ACV, MOREIRA DE AVELAR D, DIAS MARTINS JC & SANTOS DIAS E. 2015. Phlebotomine Sand Fly fauna and leishmania infection in the vicinity of the Serra do Cipó National Park, a natural brazilian heritage Site. Biomed Res Int, 1-9 p. in Jaboticatubas, Minas Gerais, Brazil with a value of 8.6% with relative abundance of Cortelezzii complex of 5.8%. These authors also reported Cortelezzii complex with Le. infantum infection (MIRs=1.9%). Also, in the same state of Brazil, Carvalho et al. (2008)CARVALHO GML, ANDRADE FILHO JD, FALCÃO AL, LIMA ACVMR & GONTIJO CMF. 2008. Naturally infected Lutzomyia sandflies in a Leishmania-endemic area of Brazil. Vector-Borne Zoonot Dis 8: 407-414., using molecular techniques, detected Le. infantum DNA in Ev. cortelezzii (MIRs= 7.1%) and Saraiva et al. (2009)SARAIVA L, CARVALHO GML, QUARESMA PF, LIMA ACVMR, FALCÃO AL & ANDRADE FILHO JD. 2009. Natural infection of Nyssomyia neivai (Pinto, 1926) and Evandromyia sallesi (Galvão & Coutinho, 1939) (Diptera: Psychodidae) by Leishmania infantum chagasi Cunha and Chagas, 1937 in Minas Gerais, Brazil. J Med Entomol 46: 1159-1163. through dissection found Le. infantum in Ev. sallesi (MIRs=16.7%). Both, in the studies cited and in ours, the relative abundance of the Cortelezzii complex was less than 13%, but due to the recent colonization observed in the center of the country (province of Córdoba) (Visintin et al. 2016VISINTIN AM, BERANEK MD, AMIEVA MJ, ROSA JR, ALMIRÓN WR & SALOMÓN OD. 2016. Spread of Phlebotominae in temperate climates: province of Córdoba, Argentina. Mem Inst Oswaldo Cruz 111: 75-78., Ontivero et al. 2018ONTIVERO M, BERANEK AB, ROSA JR, LUDUEÑA-ALMEIDA F & ALMIRÓN W. 2018. Seasonal distribution of Phlebotomine sandfly in a vulnerable area for tegumentary leishmaniasis transmission in Córdoba, Argentina. Acta Trop 178: 81-85.), its ability to adapt with broad thermo tolerance (Szelag et al. 2017SZELAG EA, ROSA JR, QUINTANA MG & SALOMÓN OD. 2017. Temporal distribution of, and effect of anthropic modifications on, phlebotomine populations in the Chaco Bioregion, Argentina. The Royal Entomological Society. Medical and Veterinary Entomology 32: 206-2015.), and the evidence discussed, we suggest that the species of the complex should be taken into account for future studies of vector competence.

In Pampa del Indio, Cortelezzii complex and Mg. migonei were recorded infected at domicile/peridomicile of C1-PI and in Base of C2-PI during the spring and summer months probably refer to their behavior in modified and little modified environments and to the food preference for synanthropic or wild animals. In the peridomicile of both sites, the presence of poultry (chickens and ducks), wool cattle (goats), equines and dogs, are probably attractive and a source of food for Phlebotominae females. In Argentina, there is a history of Le. (Viannnia) sp. DNA detection in Aotus azarai azarai monkeys in the province of Formosa (Acardi et al. 2013ACARDI SA, RAGO MV, LIOTTA DJ, FERNANDEZ-DUQUE E & SALOMÓN OD. 2013. Leishmania (Viannia) DNA detection by PCR-RFLP and sequencing in free-ranging owl monkeys (Aotus azarai azarai) from Formosa, Argentina. Vet Parasitol 193: 256-259.) and in sigmodontinal mammals (genus Akodon and Euryoryzomys russatus) infected with Le. braziliensis in Puerto Iguazú, Misiones, considered as potential wild reservoirs or incidental hosts (Fernández et al. 2017FERNÁNDEZ MS, FRASCHINA J, ACARDI S, LIOTTA DJ, LESTANI E, GIULIANI M, BUSCH M & SALOMÓN OD. 2017. Assessment of the role of small mammals in the transmission cycle of tegumentary leishmaniasis and first report of natural infection with Leishmania braziliensis in two sigmodontines in northeastern Argentina. Parasitology Research 117: 405-412.).

CONCLUSIONS

The eco-epidemiological map of the province of Chaco could include an intermediate or transition area between the bioregion of dry Chaco and wet Chaco with an overlap of common and autochthonous phlebotomine species of each subregion. In this geographical area and in the same period Le. braziliensis was amplified in human cases as in Cortelezzii complex and Mg. migonei applying criteria 1 and 4 (Strong strong ecological association and seasonality between phlebotomine, humans and reservoir animals). This would strengthen the hypothesis that, in the study area, these species are candidates to be incriminated as vectors, and further studies will be required to fulfill the criteria to characterize both species as proven vectors of Le. braziliensis.

ACKNOWLEDGMENTS

The authors acknowledge Dra. Paula Sartor, Hospital “Dr Dante Tardelli” Pampa del Indio’s laboratory boss and Celestina Segovia, Fortín Almirante Brown wasteland nursing assistant and sanitary agent for helping and for their support and logistics in field samplings, as well as the families who permitted the development of the project in the sample sites.

REFERENCES

Publication Dates

History