Refining structural models of membrane proteins with disordered domains in phospholipid nanodiscs

Abstract

AbstractSmall-angle scattering can be used to derive structural information about membrane proteins reconstituted in suitable carrier systems enabling solubilization of the membrane proteins in question. Since the studies are done in solution, there is no need for crystallization or deposition on sample grids, and it is in principle possible to obtain structural information about intrinsically disordered regions which cannot be resolved by crystallography or the quantitative link to which is hard to establish using e.g. electron microscopy methods. In this study, tetramers of the gated spinach aquaporin SoPIP2;1 were reconstituted into nanodiscs and small-angle x-ray scattering data were recorded. From these data, we refine structural models of the entire nanodisc-membrane protein complex including the flexible regions using newly developed models based on Fast Debye sums. We introduce software for these computations available via online repositories and discuss the implications and limitations of these methods.Author summaryWhen it comes to investigating the structure and function of the proteins, a particular class of proteins are known to be cumbersome and problematic: membrane proteins that reside in the cell membrane and regulate and facilitate a number of critical biological processes. Such proteins can often not be studied by conventional means as they unravel and denature structurally or even precipitate in solution. To add insult to injury, such membrane proteins also often contain parts that are intrinsically disordered rendering them irresolvable by e.g. traditional crystallographic techniques and hard to describe structurally. Here, we present a combined computational and experimental approach (as well as the necessary software) to analyze and determine the structure of such proteins in close-to-native conditions in so-called nanodiscs, a biological carrier systems, using small-angle scattering and molecular simulations.