2017
DOI: 10.1038/nchembio.2371
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Computational design of ligand-binding membrane receptors with high selectivity

Abstract: Accurate modeling and design of protein-ligand interactions have broad applications in cell, synthetic biology and drug discovery but remain challenging without experimental protein structures. Here we developed an integrated protein homology modeling-ligand docking-protein design approach that reconstructs protein-ligand binding sites from homolog protein structures in the presence of protein-bound ligand poses to capture conformational selection and induced fit modes of ligand binding. In structure modeling … Show more

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Cited by 36 publications
(27 citation statements)
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“…A remaining challenge is to create tools for membrane proteins (3): a class of molecules that constitute over 30% of all proteins (4) and are targets for 60% of pharmaceuticals (5). There have been several achievements in membrane protein design including a zinc-transporting tetramer Rocker (6), an ion-conducting protein based on the Escherichia Coli Wza transporter (7), β-barrel pores with increased selectivity (8), receptors with new ligand-binding properties (9,10), and designed de novo α-helical bundles that insert into the membrane (11). For these advances, design of lipid-facing positions often used a native sequence or restricted the chemistry and/or size of amino acids.…”
mentioning
confidence: 99%
“…A remaining challenge is to create tools for membrane proteins (3): a class of molecules that constitute over 30% of all proteins (4) and are targets for 60% of pharmaceuticals (5). There have been several achievements in membrane protein design including a zinc-transporting tetramer Rocker (6), an ion-conducting protein based on the Escherichia Coli Wza transporter (7), β-barrel pores with increased selectivity (8), receptors with new ligand-binding properties (9,10), and designed de novo α-helical bundles that insert into the membrane (11). For these advances, design of lipid-facing positions often used a native sequence or restricted the chemistry and/or size of amino acids.…”
mentioning
confidence: 99%
“…Thankfully, methods for multistate design are being developed [91][92][93][94]. For instance, Grigoryan et al use such an approach to design leucine zippers that selectively bind a single partner from 20 members of the bZIP family by modelling potential offtarget interactions as part of the design process [95]; Löffler et al engineer a (ba) 8 -barrel into a retro-aldolase with measurable, albeit low, catalytic efficiency [94]; and Feng et al use conformation ensembles to engineer ligand-binding G-protein-coupled receptors [96 ].…”
Section: Challenges Aheadmentioning
confidence: 99%
“…engineering) of a GPCR protein, which shows how a protein design algorithm may guide the alteration of transmembrane proteins affinity toward a certain ligand [89]. However, due to the complexity of transmembrane proteins as mentioned before, the design procedure was limited to rely mostly on homology modeling and ligand docking [90]. …”
Section: The Scope Of Automated Protein Designmentioning
confidence: 99%