The research performed for the SF-Leishyb project demonstrated that reactive oxygen species (ROS) in Lutzomyia longipalpis sand fly guts affect Leishmania tropica's ability to establish infection. In addition, we identified the Leishmania gene Gex1 as essential for the hybridization process: by performing experimental hybridization assays, we showed that Gex1 is essential for hybridization and is needed in only one of the two parental cells. This is an important result, as no other gene has been described as completely essential for Leishmania hybridization in the literature so far. Sexual reproduction mechanisms in Leishmania and other trypanosomatid parasites remain poorly understood, despite hybridization being a key driver of genomic plasticity. This plasticity influences important parasite traits like tissue tropism, virulence, and drug resistance. The study's findings contribute significantly to this emerging field. Our ongoing research is focused on understanding Gex1's mode of action and exploring how ROS levels in the gut affect its expression.
More over, I could evidence the high capability of the strain Leishmania donovani Ld1S to engage in sexual reproduction. This result – and the characterization of the resulting hybrids - is an important milestone in the experimental study of Leishmania reproduction, that has been historically limited by the rarity of hybridization events. Finally, the collaboration we set up with our colleagues of Bari University led us to produce a very unusual hybrid as well as key findings regarding its genomic composition, genic expression and phenotype of Leishmania hybrids.
Together, our results provide significant new insights into the mechanisms of sexual reproduction in Leishmania parasites, a process that has long been elusive, despise its relevance in the phenotypic manifestations of these pathogens.