Local Bilayer Hydrophobicity Modulates Membrane Protein Stability

Mapping Intimacies ◽

10.1101/2020.09.01.277897 ◽

2020 ◽

Author(s):

Dagan C. Marx ◽

Karen G. Fleming

Keyword(s):

Protein Folding ◽

Membrane Protein ◽

Hydrophobic Effect ◽

Water Concentration ◽

Side Chain ◽

Interfacial Region ◽

Side Chains ◽

Free Energies ◽

Membrane Protein Folding ◽

And Function

ABSTRACTThrough the insertion of nonpolar side chains into the bilayer, the hydrophobic effect has long been accepted as a driving force for membrane protein folding. However, how the changing chemical composition of the bilayer affects the magnitude side chain transfer free energies has historically not been well understood. A particularly challenging region for experimental interrogation is the bilayer interfacial region that is characterized by a steep polarity gradient. In this study we have determined the for nonpolar side chains as a function of bilayer position using a combination of experiment and simulation. We discovered an empirical correlation between the surface area of nonpolar side chain, the transfer free energies, and the local water concentration in the membrane that allows for to be accurately estimated at any location in the bilayer. Using these water-to-bilayer values, we calculated the interface-to-bilayer transfer free energy . We find that the are similar to the “biological”, translocon-based transfer free energies, indicating that the translocon energetically mimics the bilayer interface. Together these findings can be applied to increase the accuracy of computational workflows used to identify and design membrane proteins, as well as bring greater insight into our understanding of how disease-causing mutations affect membrane protein folding and function.

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Packing of apolar side chains enables accurate design of highly stable membrane proteins

Science ◽

10.1126/science.aav7541 ◽

2019 ◽

Vol 363 (6434) ◽

pp. 1418-1423 ◽

Cited By ~ 27

Author(s):

Marco Mravic ◽

Jessica L. Thomaston ◽

Maxwell Tucker ◽

Paige E. Solomon ◽

Lijun Liu ◽

...

Keyword(s):

Membrane Proteins ◽

Hydrophobic Effect ◽

Side Chain ◽

Side Chains ◽

Chain Packing ◽

Membrane Protein Folding ◽

Natural Protein ◽

Accurate Design ◽

Polar Interactions ◽

Packing Code

The features that stabilize the structures of membrane proteins remain poorly understood. Polar interactions contribute modestly, and the hydrophobic effect contributes little to the energetics of apolar side-chain packing in membranes. Disruption of steric packing can destabilize the native folds of membrane proteins, but is packing alone sufficient to drive folding in lipids? If so, then membrane proteins stabilized by this feature should be readily designed and structurally characterized—yet this has not been achieved. Through simulation of the natural protein phospholamban and redesign of variants, we define a steric packing code underlying its assembly. Synthetic membrane proteins designed using this code and stabilized entirely by apolar side chains conform to the intended fold. Although highly stable, the steric complementarity required for their folding is surprisingly stringent. Structural informatics shows that the designed packing motif recurs across the proteome, emphasizing a prominent role for precise apolar packing in membrane protein folding, stabilization, and evolution.

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Design of self-assembling transmembrane helical bundles to elucidate principles required for membrane protein folding and ion transport

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2016.0214 ◽

2017 ◽

Vol 372 (1726) ◽

pp. 20160214 ◽

Cited By ~ 12

Author(s):

Nathan H. Joh ◽

Gevorg Grigoryan ◽

Yibing Wu ◽

William F. DeGrado

Keyword(s):

Protein Folding ◽

Membrane Protein ◽

Protein Design ◽

De Novo ◽

Cell Signalling ◽

Membrane Protein Folding ◽

Cellular Processes ◽

Membrane Pores ◽

Self Assembling ◽

And Function

Ion transporters and channels are able to identify and act on specific substrates among myriads of ions and molecules critical to cellular processes, such as homeostasis, cell signalling, nutrient influx and drug efflux. Recently, we designed Rocker, a minimalist model for Zn 2+ /H + co-transport. The success of this effort suggests that de novo membrane protein design has now come of age so as to serve a key approach towards probing the determinants of membrane protein folding, assembly and function. Here, we review general principles that can be used to design membrane proteins, with particular reference to helical assemblies with transport function. We also provide new functional and NMR data that probe the dynamic mechanism of conduction through Rocker. This article is part of the themed issue ‘Membrane pores: from structure and assembly, to medicine and technology’.

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