Antileishmanial effect of silver nanoparticles and their enhanced antiparasitic activity under ultraviolet light.

Leishmaniasis is a protozoan vector-borne disease and is one of the biggest health problems of the world. Antileishmanial drugs have disadvantages such as toxicity and the recent development of resistance. One of the best-known mechanisms of the antibacterial effects of silver nanoparticles (Ag-NPs) is the production of reactive oxygen species to which Leishmania parasites are very sensitive. So far no information about the effects of Ag-NPs on Leishmania tropica parasites, the causative agent of leishmaniasis, exists in the literature. The aim of this study was to investigate the effects of Ag-NPs on biological parameters of L. tropica such as morphology, metabolic activity, proliferation, infectivity, and survival in host cells, in vitro. Consequently, parasite morphology and infectivity were impaired in comparison with the control. Also, enhanced effects of Ag-NPs were demonstrated on the morphology and infectivity of parasites under ultraviolet (UV) light. Ag-NPs demonstrated significant antileishmanial effects by inhibiting the proliferation and metabolic activity of promastigotes by 1.5- to threefold, respectively, in the dark, and 2- to 6.5-fold, respectively, under UV light. Of note, Ag-NPs inhibited the survival of amastigotes in host cells, and this effect was more significant in the presence of UV light. Thus, for the first time the antileishmanial effects of Ag-NPs on L. tropica parasites were demonstrated along with the enhanced antimicrobial activity of Ag-NPs under UV light. Determination of the antileishmanial effects of Ag-NPs is very important for the further development of new compounds containing nanoparticles in leishmaniasis treatment.

Leishmania tropica: the effect of darkness and light on biological activities in vitro.

Leishmania parasites can be exposed to effects of light in their vectors and hosts, at various periods. However, there is no information about the effects of light on Leishmania parasites. The aim of this study is to investigate the effects of light on various cell parameters of Leishmania tropica, in vitro. All experiments were conducted on L. tropica promastigotes and amastigote-macrophage cultures, using flow cytometric analysis, MTT and phenol-sulfuric acid assay, DAPI and Giemsa. The results showed that the morphology of parasites has changed; the cell cycle has been affected and this caused parasites to remain at G0/G1 phase. Furthermore the proliferation, infectivity, glucose consumption and mitochondrial dehydrogenase activities of parasites were decreased. Thus, for the first time, in this study, the effects of light on biological activities of Leishmania parasites were shown. These new information about parasites' biology, would be very important to investigate the effects of light on the parasites in infected vectors and hosts.

Vaccine development against cutaneous leishmaniasis. Subcutaneous administration of radioattenuated parasites protects CBA mice against virulent Leishmania major challenge.

Experiments described in this paper were aimed at determining whether subcutaneous inoculation of live, avirulent Leishmania major would protect mice against infection by the virulent parasite. To this effect, promastigotes or amastigotes of a highly virulent strain of L. major (MRHO/IR/76), used in human trials of leishmanization, and which induces non-healing skin lesions in both CBA and BALB/c mice, were rendered non-pathogenic by gamma irradiation. A dose of 150 krad was required to abrogate the virulence of the parasite as tested on BALB/c mice. Strikingly, however, not all leishmanias were completely inactivated by this procedure since live parasites were detected in the footpads and/or the inguinal lymph nodes as long as 28 days (CBA) or 18 weeks (BALB/c) after injection. Furthermore, 150 krad-irradiated promastigotes retained the capacity to transform into amastigotes intracellularly in vitro. Subcutaneous inoculation of this irradiated 'vaccine' conferred onto CBA mice a high degree of protection against challenge by both the homologous and a heterologous (MRHO/SU/59/P) strains of L. major. Lymph node cells from protected animals acquired the capacity to activate infected macrophages in vitro to kill intracellular L. major. To allow for maximum development of immunoprotection, the irradiated promastigotes had to remain viable, perhaps reflecting a requirement for transformation into amastigotes in the vaccinated host.

Suppression of pathogenesis in cutaneous leishmaniasis by UV irradiation.

The effects of suberythematous levels of UV-B radiation on the development of of cutaneous leishmaniasis were studied in B10.129(10M) mice. Doses of 15 mJ cm-2 UV-B applied locally to the injection site suppressed the development of skin lesions after the inoculation of Leishmania major promastigotes. The primary targets of UV-B radiation appeared to be host cells and not leishmanial parasites, because UV-B irradiation of parasites cultured in vitro did not affect their viability, but did kill host cells. Furthermore, the same numbers of parasites were recovered from skin at the injection site in both irradiated and control mice. UV-B irradiation abrogated the induction of contact hypersensitivity to dinitrofluorobenzene and also abrogated the induction of delayed-type hypersensitivity responses to leishmanial antigens. These results suggest that local perturbations in the functions of the skin-associated lymphoid tissue during the initial phases of leishmanial infection can profoundly influence immunological response and the subsequent development of clinical disease.