ZDHHC13 is a likely pseudoenzyme protein S-acyltransferase that functions via a non-canonical mechanism

S-acylation is the addition of fatty acids to cysteine residues to regulate protein function and localization. S-acylation is catalyzed by the ZDHHC (Asp-His-His-Cys) family of protein S-acyltransferases (PATs), which S-acylate protein substrates by first auto-S-acylating the catalytic cysteine of the DHHC active site followed by transfer to the substrate. ZDHHC13 and ZDHHC17 are related ankyrin repeat domain (ANK) PATs that S-acylate multiple neuronal proteins, including huntingtin (HTT), the protein mutated in Huntington disease. However, unlike ZDHHC17 and other human PATs, ZDHHC13 possesses a non-canonical DQHC active site. As the first histidine is essential for auto-S-acylation, it is unclear if ZDHHC13 is catalytically active. Our phylogenetic analysis of eukaryotic ANK-containing PATs shows that ZDHHC13 orthologues are more divergent compared to ZDHHC17. While the ZDHHC17 DHHC is highly conserved, the motif varies among ZDHHC13 orthologues, with some vertebrate lineages containing a serine in place of the catalytic cysteine. Interestingly, we found that the ZDHHC13 S-acylation is lower than that of ZDHHC17, but the ZDHHC13 catalytic cysteine is indeed S-acylated. While expression of wild type (WT) ZDHHC13 in ZDHHC13 deficient HEK293T cells increased S-acylation of a HTT1-588 fragment, surprisingly, expression of catalytically dead DQHS ZDHHC13 was still able to facilitate HTT1-588 S-acylation equally. This suggests the ZDHHC13 catalytic cysteine is not required for S-acylation of target proteins, suggesting ZDHHC13 may coordinate another PAT. Indeed, we identified ZDHHC13 in high-molecular weight complexes. Our results indicate that ZDHHC13 is a likely pseudoenzyme that may function via a non-conventional mechanism reliant on other PATs. This work broadens our understanding of the function of this non-canonical PAT.