The great majority of helical membrane proteins are inserted co-translationally into the ER membrane through a continuous ribosome-translocon channel. The efficiency of membrane insertion depends on transmembrane (TM) helix amino acid composition, the helix length and the position of the amino acids within the helix. In this work, we conducted a computational analysis of the composition and location of amino acids in transmembrane helices found in membrane proteins of known structure to obtain an extensive set of designed polypeptide segments with naturally occurring amino acid distributions. Then, using an in vitro translation system in the presence of biological membranes, we experimentally validated our predictions by analyzing its membrane integration capacity. Coupled with known strategies to control membrane protein topology, these findings may pave the way to de novo membrane protein design.
Manuel Bañó‐Polo, Carlos Baeza-Delgado, Silvia Tamborero, Anthony Hazel, Brayan Grau, Ing-Marie Nilsson, Paul Whitley, James C. Gumbart, Gunnar Von Heijne, Ismael Mingarro
Brayan Grau, Rian Kormos, Manuel Bañó‐Polo, Kehan Chen, Ma Jesús García-Murria, Fatlum Hajredini, Manuel M. Sánchez del Pino, Hyunil Jo, Luis Martínez‐Gil, Gunnar Von Heijne, William F. DeGrado, Ismael Mingarro
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