An efficient screening method for purifying and crystallizing membrane proteins using modified clear-native PAGE.

Membrane proteins, such as G-protein coupled receptors, control communication between cells and their environments and are indispensable for many cellular functions. Nevertheless, structural studies on membrane proteins lag behind those on water-soluble proteins, due to their low structural stability, making it difficult to obtain crystals for X-ray crystallography. Optimizing conditions to improve the stability of membrane proteins is essential for successful crystallization. However, the optimization usually requires large amounts of purified samples, and it is a time-consuming and trial-and-error process. Here, we report a rapid method for precrystallization screening of membrane proteins using Clear Native polyacrylamide gel electrophoresis (CN-PAGE) with the modified Coomassie Brilliant Blue G-250 (mCBB) stain that was reduced in sodium formate. A2A adenosine receptor (A2AAR) was selected as a target membrane protein, for which we previously obtained the crystal structure using an antibody, and was expressed as a red fluorescent protein fusion for in-gel fluorescence detection. The mCBB CN-PAGE method enabled the optimization of the solubilization, purification, and crystallization conditions of A2AAR using the solubilized membrane fraction expressing the protein without purification procedures. These data suggest the applicability of mCBB CN-PAGE technique to a wide variety of integral membrane proteins.

Identification of thermostabilizing mutations for a membrane protein whose three-dimensional structure is unknown.

We recently developed a physics-based method for identifying thermostabilizing mutations of a membrane protein. The method uses a free-energy function F where the importance of translational entropy of hydrocarbon groups within the lipid bilayer is emphasized. All of the possible mutations can rapidly be examined. The method was illustrated for the adenosine A2a receptor (A2a R) whose three-dimensional (3D) structure experimentally determined was utilized as the wild-type structure. Nine single mutations and a double mutation predicted to be stabilizing or destabilizing were checked by referring to the experimental results: The success rate was remarkably high. In this work, we postulate that the 3D structure of A2a R is unknown. We construct candidate models for the 3D structure using the homology modeling and select the model giving the lowest value to the change in F on protein folding. The performance achieved is only slightly lower than that in the recent work. © 2016 Wiley Periodicals, Inc.

Binding interactions of the peripheral stalk subunit isoforms from human V-ATPase.

The mammalian peripheral stalk subunits of the vacuolar-type H(+)-ATPases (V-ATPases) possess several isoforms (C1, C2, E1, E2, G1, G2, G3, a1, a2, a3, and a4), which may play significant role in regulating ATPase assembly and disassembly in different tissues. To better understand the structure and function of V-ATPase, we expressed and purified several isoforms of the human V-ATPase peripheral stalk: E1G1, E1G2, E1G3, E2G1, E2G2, E2G3, C1, C2, H, a1NT, and a2NT. Here, we investigated and characterized the isoforms of the peripheral stalk region of human V-ATPase with respect to their affinity and kinetics in different combination. We found that different isoforms interacted in a similar manner with the isoforms of other subunits. The differences in binding affinities among isoforms were minor from our in vitro studies. However, such minor differences from the binding interaction among isoforms might provide valuable information for the future structural-functional studies of this holoenzyme.

Identification of Thermostabilizing Mutations for Membrane Proteins: Rapid Method Based on Statistical Thermodynamics.

Membrane proteins are responsible for the communication between cells and their environments. They are indispensable to the expression of life phenomena and also implicated in a number of diseases. Nevertheless, the studies on membrane proteins are far behind those on water-soluble proteins, primarily due to their low structural stability. Introduction of mutations can enhance their thermostability and stability in detergents, but the stabilizing mutations are currently identified by experiments. The recently reported computational methods suffer such drawbacks as the exploration of only limited mutational space and the empiricism whose results are difficult to physically interpret. Here we develop a rapid method that allows us to treat all of the possible mutations. It employs a free-energy function (FEF) that takes into account the translational entropy of hydrocarbon groups within the lipid bilayer as well as the protein intramolecular hydrogen bonding. The method is illustrated for the adenosine A2a receptor whose wild-type structure is known and utilized. We propose a reliable strategy of finding key residues to be mutated and selecting their mutations, which will lead to considerably higher stability. Representative single mutants predicted to be stabilizing or destabilizing were experimentally examined and the success rate was found to be remarkably high. The melting temperature Tm for two of them was substantially higher than that of the wild type. A double mutant with even higher Tm was also obtained. Our FEF captures the essential physics of the stability changes upon mutations.