Assessment of Autophagy in Leishmania Parasites.

Leishmaniasis is a neglected tropical disease caused by numerous species of Leishmania parasites, including Leishmania major. The parasite is transmitted by several species of sandfly vectors and infects myeloid cells leading to a myriad of inflammatory responses, immune dysregulations, and disease manifestations. Every cell undergoes autophagy, a self-regulated degradative process that permits the cells to recycle damaged or worn-out organelles in order to maintain cellular health and homeostasis.

Antigen recognition reinforces regulatory T cell mediated Leishmania major persistence.

Cutaneous Leishmania major infection elicits a rapid T cell response that is insufficient to clear residually infected cells, possibly due to the accumulation of regulatory T cells in healed skin. Here, we used Leishmania-specific TCR transgenic mice as a sensitive tool to characterize parasite-specific effector and immunosuppressive responses in vivo using two-photon microscopy. We show that Leishmania-specific Tregs displayed higher suppressive activity compared to polyclonal Tregs, that was mediated through IL-10 and not through disrupting cell-cell contacts or antigen presentation.

leaf extract enhances host resistance to infection in mice by regulating host immune response and disrupting the activity of parasite superoxide dismutase enzyme.

African trypanosomiasis, a neglected tropical disease, is caused by diverse species of the protozoan parasite belonging to the genus . Although anti-trypanosomal medications exist, the increase in drug resistance and persistent antigenic variation has necessitated the development of newer and more efficacious therapeutic agents which are selectively toxic to the parasite. In this study, we assessed the trypanocidal efficacy of leaf extract (-extract) .

Prohibitin plays a role in the functional plasticity of macrophages.

Immunometabolism plays a crucial role in the activation and functional plasticity of immune cells, which in large determines a variety of health and disease states. Factors that integrate immunometabolism in immune cell signaling and functions are beginning to be identified. Previously, we have reported that two transgenic mouse models, Mito-Ob and mutant Mito-Ob (m-Mito-Ob), overexpressing a pleiotropic protein, prohibitin (PHB) or a mutant form of PHB (Tyr114Phe-PHB or m-PHB), respectively, developed distinct immunometabolic phenotypes.