Leishmania donovani P23 protects parasites against HSP90 inhibitor-mediated growth arrest.

In Leishmania donovani, the HSP90 chaperone complex plays an essential role in the control of the parasite's life cycle, general viability and infectivity. Several of the associated co-chaperones were also shown to be essential for viability and/or infectivity to mammalian cells. Here, we identify and describe the co-chaperone P23 and distinguish its function from that of the structurally related small heat shock protein HSP23.

A small heat shock protein is essential for thermotolerance and intracellular survival of Leishmania donovani.

Leishmania parasites must survive and proliferate in two vastly different environments - the guts of poikilothermic sandflies and the antigen-presenting cells of homeothermic mammals. The change of temperature during the transmission from sandflies to mammals is both a key trigger for the progression of their life cycle and for elevated synthesis of heat shock proteins, which have been implicated in their survival at higher temperatures. Although the functions of the main heat shock protein families in the Leishmania life cycle have been studied, nothing is known about the roles played by small heat shock proteins.

The Hsp90-Sti1 interaction is critical for Leishmania donovani proliferation in both life cycle stages.

The heat shock protein 90 plays a pivotal role in the life cycle control of Leishmania donovani promoting the fast-growing insect stage of this parasite. Equally important for insect stage growth is the co-chaperone Sti1. We show that replacement of Sti1 is only feasible in the presence of additional Sti1 transgenes indicating an essential role.

Phosphoproteome dynamics reveal heat-shock protein complexes specific to the Leishmania donovani infectious stage.

Leishmania is exposed to a sudden increase in environmental temperature during the infectious cycle that triggers stage differentiation and adapts the parasite phenotype to intracellular survival in the mammalian host. The absence of classical promoter-dependent mechanisms of gene regulation and constitutive expression of most of the heat-shock proteins (HSPs) in these human pathogens raise important unresolved questions as to regulation of the heat-shock response and stage-specific functions of Leishmania HSPs. Here we used a gel-based quantitative approach to assess the Leishmania donovani phosphoproteome and revealed that 38% of the proteins showed significant stage-specific differences, with a strong focus of amastigote-specific phosphoproteins on chaperone function.

The co-chaperone SGT of Leishmania donovani is essential for the parasite's viability.

Molecular chaperone proteins play a pivotal role in the protozoan parasite Leishmania donovani, controlling cell fate and ensuring intracellular survival. In higher eukaryotes, the so-called co-chaperone proteins are required for client protein recognition and proper function of chaperones, among them the small glutamine-rich tetratricopeptide repeat proteins (SGT) which interact with both HSP70 and HSP90 chaperones. An atypical SGT homolog is found in the L.

One-step generation of double-allele gene replacement mutants in Leishmania donovani.

Due to the apparent lack of sexual recombination in Leishmania spp., gene replacement strategies in this diploid organism necessitate the subsequent targeting of two gene alleles by using two constructs, bearing different antibiotic resistance markers. This approach is time consuming and often gives rise to spontaneous amplification of the targeted gene, nullifying efforts to create functional null mutants.