Issue 48, 2021

Designed membrane protein heterodimers and control of their affinity by binding domain and membrane linker properties

Abstract

Many membrane proteins utilize dimerization to transmit signals across the cell membrane via regulation of the lateral binding affinity. The complexity of natural membrane proteins hampers the understanding of this regulation on a biophysical level. We designed simplified membrane proteins from well-defined soluble dimerization domains with tunable affinities, flexible linkers, and an inert membrane anchor. Live-cell single-molecule imaging demonstrates that their dimerization affinity indeed depends on the strength of their binding domains. We confirm that as predicted, the 2-dimensional affinity increases with the 3-dimensional binding affinity of the binding domains and decreases with linker lengths. Models of extended and coiled linkers delineate an expected range of 2-dimensional affinities, and our observations for proteins with medium binding strength agree well with the models. Our work helps in understanding the function of membrane proteins and has important implications for the design of synthetic receptors.

Graphical abstract: Designed membrane protein heterodimers and control of their affinity by binding domain and membrane linker properties

Supplementary files

Article information

Article type
Paper
Submitted
06 Oct 2021
Accepted
11 Nov 2021
First published
08 Dec 2021
This article is Open Access
Creative Commons BY license

Nanoscale, 2021,13, 20692-20702

Designed membrane protein heterodimers and control of their affinity by binding domain and membrane linker properties

C. Lan, A. Stulz, N. P. F. Barthes, S. Lauw, P. Salavei, M. Jung, H. Heerklotz and M. H. Ulbrich, Nanoscale, 2021, 13, 20692 DOI: 10.1039/D1NR06574B

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