Effects of salivary gland homogenate from wild-caught and laboratory-reared Lutzomyia longipalpis on the evolution and immunomodulation of Leishmania (Leishmania) amazonensis infection.

We investigated the effects of Lutzomyia longipalpis salivary glands homogenate of wild-caught and laboratory-reared vectors on the lesion evolution and immunomodulation of the infection caused by Leishmania (Leishmania) amazonensis. To compare the effect of both salivary glands homogenate (SGH), C57BL/6 mice were inoculated subcutaneously into the hind footpads or into the ear dermis with 10(6) promastigotes in the presence or not of SGH from wild-caught and laboratory-colonized sand flies. Comparing SGH groups, the lesion size was lower in mice co-inoculated with wild-caught SGH, as the parasitism and the infiltration of macrophages at the inoculation site. Wild-caught SGH also determined lower production of IL-4 and IL-10 but higher IL-12 levels compared with laboratory-reared SGH. Our findings address a probable bias by using SGH from laboratory-colonized sand flies instead of wild-caught vector SGH in studies concerning saliva effects. A possible mild influence of sand fly saliva in natural infections caused by Leishmania is also speculated, as infection is transmitted by wild and not by laboratory-reared vectors.

Detection and identification of Leishmania species in field-captured phlebotomine sandflies based on mini-exon gene PCR.

Leishmaniasis is one of the most diverse and complex of all vector-borne diseases. Because it involves several overlapping species and sandfly vectors, the disease has a complex ecology and epidemiology. Adequate therapy and follow-up depend on parasitological diagnosis, but classical methods present several constraints when identifying species. We describe a polymerase chain reaction (PCR) which uses primers designed from mini-exon repetitive sequences that are specific for subgenus LeishmaniaViannia (PV), as well as sequences with specificity for genus (PG) that can distinguish between Leishmania species from other insect flagellates with minor differences in PCR products. For standardization, these PCR were tested in experimentally infected sandflies, and Leishmania infection in these insects was successfully confirmed. This methodology identified a 3.9% infection rate in field-captured phlebotomine sandflies from an endemic region in Brazil. Natural infection by Leishmania species was identified in three samples of Lutzomyia longipalpis, of which two were Leishmania (L.) chagasi and one Leishmania (L.) amazonensis. Irrespective of specific epidemiological conclusions, the method used in this study was able to identify Leishmania infections both in experimentally infected and field-captured phlebotomine sandflies, and could be a useful tool in epidemiological studies and strategic planning for the control of human leishmaniasis.

Lutzomyia longipalpis peritrophic matrix: formation, structure, and chemical composition.

Sandflies are vectors of several pathogens, constituting serious health problems. Lutzomyia longipalpis (Lutz & Neiva, 1912) is the main vector of Leishmania chagasi, agent of visceral leishmaniasis. They synthesize a thick bag-like structure that surrounds the bloodmeal, named peritrophic matrix (PM). One of the major roles of PM in blood-fed insects includes protection against ingested pathogens by providing a defensive barrier to their development. We used traditional and modern morphological methods as well as biochemical and immunolabeling tools to define details of the PM structure of the Lu. longipalpis sandfly, including composition, synthesis, and degradation. The kinetics of PM formation and degradation was found to be related to the ingestion and time of digestion of the bloodmeal. The midgut changes its size and morphology after the blood ingestion and during the course of digestion. A striking morphological modification takes place in the midgut epithelium after the stretching caused by the bloodmeal, revealing a population of cells that was not observed in the unfed midgut. The transmission and scanning electron microscopies were used to reveal several morphological aspects of PM formation. The PM looks thicker and well formed 24 h after the bloodmeal. Presence of chitin in the PM was demonstrated by immunolabeling with an alpha-chitin monoclonal antibody. SDS-polyacrylamide gel electrophoresis showed at least five protein bands with molecular masses of 38.7-135 kDa, induced by the protein-free diet. Mouse polyclonal antiserum was produced against PMs induced by protein-free meal and used in Western blotting, which revealed at least three associated proteins.