Seed-type vacuolar processing enzymes recognize the 619th asparagine residue to posttranslationally cleave the HMW-GS 1Dy10-m619SN allele

High molecular weight glutenin subunits (HMW-GSs) are critical grain storage proteins in wheat, which govern its unique processing quality. A HMW-GS 1Dy10 allele variant (1Dy10-m619SN), carrying a serine-to-asparagine substitution at the 619th residue, undergoes partial posttranslational cleavage. This modification leads to improved cookie-making quality. However, the Enzymes mediating this cleavage remain unknown. In this study, we identified vacuolar processing Enzymes (VPEs) as candidates for 1Dy10-m619SN processing using TurboID-based proximity labeling and RNA-seq analysis. In vitro cleavage assays confirmed that VPEs catalyzed 1Dy10-m619SN cleavage. Phylogenic analysis revealed that there are two seed-type VPEs in wheat, TaVPEI and TaVPEII, with TaVPEI being further subdivided into TaVPEI-1, TaVPEI-2, and TaVPEI-3. Despite sharing conserved catalytic domains, these isoforms display distinct temporal expression patterns, with TaVPEI-1 expression showing the strongest correlation with the posttranslational cleavage of 1Dy10-m619SN. TaVPEI-1 protein is localized to the vacuole, the well-known deposition site for HMW-GSs. Overexpression of TaVPEI-1 in wheat enhances the 1Dy10-m619SN cleavage. Collectively, these findings demonstrate that the seed-type VPEs in wheat are responsible for the posttranslational cleavage of 1Dy10-m619SN, which provides new insights into the molecular basis of wheat's unique processing quality.

asparagine; high molecular weight glutenin subunits; posttranslational cleavage; vacuolar processing enzymes; wheat.