A unifying mechanism for the biogenesis of prokaryotic membrane proteins co-operatively integrated by the Sec and Tat pathways

Abstract

AbstractThe vast majority of polytopic membrane proteins are inserted into the cytoplasmic membrane of prokaryotes by the general secretory (Sec) pathway. However, a subset of monotopic proteins that contain non-covalently-bound redox cofactors depend on the twin-arginine translocase (Tat) machinery for membrane integration. Recently actinobacterial Rieske iron-sulfur cluster-containing proteins were identified as an unusual class of membrane proteins that require both the Sec and Tat pathways for the insertion of their three transmembrane domains (TMDs). The Sec pathway inserts the first two TMDs of these proteins co-translationally, but releases the polypeptide prior to the integration of TMD3 to allow folding of the cofactor-containing domain and its translocation by Tat. Here we have investigated features of the Streptomyces coelicolor Rieske polypeptide that modulate its interaction with the Sec and Tat machineries. Mutagenesis of a highly conserved loop region between Sec-dependent TMD2 and Tat-dependent TMD3 shows that it plays no significant role in coordinating the activities of the two translocases, but that a minimum loop length of approximately eight amino acids is required for the Tat machinery to recognise TMD3. Instead we show that a combination of relatively low hydrophobicity of TMD3, coupled with the presence of C-terminal positively-charged amino acids, results in abortive insertion of TMD3 by the Sec pathway and its release at the cytoplasmic side of the membrane. Bioinformatic analysis identified two further families of polytopic membrane proteins that share features of dual Sec-Tat-targeted membrane proteins. A predicted heme-molybdenum cofactor-containing protein with five TMDs, and a polyferredoxin also with five predicted TMDs, are encoded across bacterial and archaeal genomes. We demonstrate that membrane insertion of representatives of each of these newly-identified protein families is dependent on more than one protein translocase, with the Tat machinery recognising TMD5. Importantly, the combination of low hydrophobicity of the final TMD and the presence of multiple C-terminal positive charges that serve as critical Sec-release features for the actinobacterial Rieske protein also dictate Sec release in these further protein families. Therefore we conclude that a simple unifying mechanism governs the assembly of dual targeted membrane proteins.