RESUMO
The signal peptidase complex (SPC) mediates processing of signal peptides of secretory precursors. But, recent studies show that the eukaryotic SPC also cleaves internal transmembrane segments of some membrane proteins, and its non-catalytic subunit, Spc1/SPCS1 plays a critical role in this process. To assess the impact of Spc1 on membrane proteostasis, we carried out quantitative proteomics of yeast cells with and without Spc1. Our data show that the abundance of the membrane proteome in yeast cells lacking Spc1 is in general reduced compared to that in wild-type cells, implicating its role in controlling the cellular levels of membrane proteins.
RESUMO
Signal peptidase (SPase) cleaves the signal sequences (SSs) of secretory precursors. It contains an evolutionarily conserved membrane protein subunit, Spc1, that is dispensable for the catalytic activity of SPase and whose role remains unknown. In this study, we investigated the function of yeast Spc1. First, we set up an in vivo SPase cleavage assay using variants of the secretory protein carboxypeptidase Y (CPY) with SSs modified in the N-terminal and hydrophobic core regions. When comparing the SS cleavage efficiencies of these variants in cells with or without Spc1, we found that signal-anchored sequences became more susceptible to cleavage by SPase without Spc1. Furthermore, SPase-mediated processing of model membrane proteins was enhanced in the absence of Spc1 and was reduced upon overexpression of Spc1. Spc1 co-immunoprecipitated with proteins carrying uncleaved signal-anchored or transmembrane (TM) segments. Taken together, these results suggest that Spc1 protects TM segments from SPase action, thereby sharpening SPase substrate selection and acting as a negative regulator of the SPase-mediated processing of membrane proteins.
