Semisynthesis of functional transmembrane proteins in GUVs

Cellular transmembrane (TM) proteins are essential sentries of the cell facilitating cell-cell communication, internal signaling, and solute transport. Reconstituting functional TM proteins into model membranes remains a challenge due to the difficulty of expressing hydrophobic TM domains and the required use of detergents. Herein, we use a intein-mediated ligation strategy to semisynthesize bitopic TM proteins in synthetic membranes. We have adapted the trans splicing capabilities of split inteins for a native peptide ligation between a synthetic TM peptide embedded in the membrane of giant unilamellar vesicles (GUVs) and an expressed soluble protein. We demonstrate that the extracellular domain of programmed cell death protein 1 (PD-1), a mammalian transmembrane immune checkpoint receptor, retains its function for binding its ligand PD-L1 at a reconstituted membrane interface after ligation to a synthetic TM peptide in GUV membranes. We envision that the construction of full-length TM proteins using orthogonal split intein-mediated semisynthetic protein ligations will expand applications of membrane protein reconstitution in pharmacology, biochemistry, biophysics, and artificial cell development.

Membrane Protein Modified Electrodes in Bioelectrocatalysis

Transmembrane proteins involved in metabolic redox reactions and photosynthesis catalyse a plethora of key energy-conversion processes and are thus of great interest for bioelectrocatalysis-based applications. The development of membrane protein modified electrodes has made it possible to efficiently exchange electrons between proteins and electrodes, allowing mechanistic studies and potentially applications in biofuels generation and energy conversion. Here, we summarise the most common electrode modification and their characterisation techniques for membrane proteins involved in biofuels conversion and semi-artificial photosynthesis. We discuss the challenges of applications of membrane protein modified electrodes for bioelectrocatalysis and comment on emerging methods and future directions, including recent advances in membrane protein reconstitution strategies and the development of microbial electrosynthesis and whole-cell semi-artificial photosynthesis.

New approach for membrane protein reconstitution into peptidiscs and basis for their adaptability to different proteins

Previously we introduced peptidiscs as an alternative to detergents to stabilize membrane proteins in solution (Carlson et al., 2018). Here, we present ‘on-gradient’ reconstitution, a new gentle approach for the reconstitution of labile membrane-protein complexes, and used it to reconstitute Rhodobacter sphaeroides reaction center complexes, demonstrating that peptidiscs can adapt to transmembrane domains of very different sizes and shapes. Using the conventional ‘on-bead’ approach, we reconstituted Escherichia coli proteins MsbA and MscS and find that peptidiscs stabilize them in their native conformation and allow for high-resolution structure determination by cryo-electron microscopy. The structures reveal that peptidisc peptides can arrange around transmembrane proteins differently, thus revealing the structural basis for why peptidiscs can stabilize such a large variety of membrane proteins. Together, our results establish the gentle and easy-to-use peptidiscs as a potentially universal alternative to detergents as a means to stabilize membrane proteins in solution for structural and functional studies.