Proximity labeling methods for proteomic analysis of membrane proteins

Abstract

Membrane proteins constitute the filter that controls the cellular traffic of nutrients, ions and other essential molecules, as well as the transmission of signals across the membrane. These proteins interact with other proteins in the cytosol, cytoskeleton or the extracellular side of the membrane, giving rise to complex interactomes that are distributed throughout the various lipid microdomains of the membrane plane. In this manner, complex networks of protein-protein and protein-lipid interactions are formed which regulate the most diverse biological functions, and disturbance of these networks can lead to disease. Therefore, characterization of these interactomes is a priority for current biomedical sciences. Traditionally, such studies have largely depended on solubilization/dissociation of the essential components of multiprotein complexes with detergents of various strength. However, this technique may result in the loss of certain components of such complexes, especially those whose binding is weak or transient. Moreover, protein solubilization can lead to the formation of non-native spurious interactions. As an alternative, proximity labelling (PL) techniques have been developed in recent years that can identify interactors of the protein of interest in a native cellular environment, prior to solubilization. In this article, we review the recent advances in PL and explore the new possibilities they offer for the characterization of membrane interactomes. SignificanceMembranes establish a series of complex protein-protein and protein-lipid interactions that are essential for cell physiology. For decades, they have been one of the central objects of study in Cell and Molecular Biology. However, knowledge of the structure of membrane proteins and their respective interactomes lags far behind that of soluble proteins, mainly due to technical difficulties in their handling and characterization caused by their insolubility. Recent research has developed various techniques to study these proteins in their native cellular environment. In this review article we address the application to membrane proteins of the so-called ‘proximity labeling methods’, which allows neighborhood relationships to be established between proteins in intact cells. The scarcity of alternatives for study of the components of membrane complexes make these methods especially attractive for analyzing this type of membrane associated supramolecular structures.