AcetyLeish: acetylation-driven control of stage differentiation and virulence in Leishmania mexicana

Protein acetylation regulates essential processes across eukaryotes. In trypanosomatids, stage-specific acetylation suggests roles in parasite differentiation. Here, we functionally characterized zinc-dependent lysine deacetylases (DAC1, DAC3, DAC4, and DAC5) in Leishmania mexicana . CRISPR-Cas9-mediated disruption revealed that DAC1 and DAC3 are essential for procyclics, while DAC4 and DAC5 are dispensable. DAC1 and DAC5 are localized in the cytoplasm, and DAC3 and DAC4 in the nucleus. Functional analysis implicates DAC1, DAC3, and DAC5 in procyclic proliferation, whereas DAC1 and DAC5 drive promastigote-to-metacyclic differentiation. DAC5 was required for metacyclogenesis in the sand flies, the promastigote–amastigote transition, and amastigote intracellular replication. Notably, DAC5-null parasites failed to induce lesions in mice, displaying an attenuated phenotype. Proteomic profiling uncovered altered acetylation patterns in DAC mutants, linking DAC5 to cytoskeleton regulation and cell cycle control. These findings identify acetylation as a central regulator of Leishmania stage differentiation and highlight DAC5 as a key factor in parasite virulence.