Grau, B.; Kormos, R.; Bano-Polo, M.; Chen, K.; Garcia-Murria, M. J.; Hajredini, F.; Sanchez del Pino, M.; Jo, H.; Martinez-Gil, L.; Von Heijne, G.; DeGrado, W.; Mingarro, I.

Biological membranes consist of a lipid bilayer studded with integral and peripheral membrane proteins. Most -helical membrane proteins require protein-conducting insertases known as translocons to assist in their membrane insertion and folding. While the sequence-dependent propensities for a helix to either translocate through the translocon or insert into the membrane have been codified into numerical hydrophobicity scales, the corresponding propensity to partition into the membrane interface remains unraveled. By engineering diagnostic glycosylation sites around test peptide sequences inserted into a host protein, we devised a system that can differentiate between water-soluble, surface-bound, and transmembrane (TM) states of the sequence based on its glycosylation pattern. Using this system, we determined the sequence-dependent propensities for transfer from the translocon to a TM, interfacial or extramembrane space. UMAP analysis of a large collection of TM and water-soluble helices provide useful embeddings for analysis of these propensities and aid in understanding the physical properties and functions of antimicrobial, lytic, and fusogenic peptides.