Genetically encoded crosslinkers to address protein-protein interactions.

Noncanonical amino acids (ncAAs) for photo- and chemical crosslinking are powerful biochemical tools for studying and manipulating interactions between proteins both in vitro and in intact cells. Since the first crosslinking ncAAs were genetically encoded about 20 years ago, the technology has now ripened beyond the proof-of-principle demonstrations and is contributing to the study of relevant biological questions in the frame of modern integrative approaches. Here, we provide an overview of available photo-activatable ncAAs for photo-crosslinking and electrophilic ncAAs for genetically encoded chemical crosslinking (GECX), with a major focus on the most recent entries such as ncAAs for SuFEx click chemistry and photo-activatable ncAAs for chemical crosslinking. We present recent examples of the application of genetically encoded crosslinkers to capture protein-protein interactions and identify interaction partners in live cells, to investigate molecular mechanisms of protein function, to stabilize protein complexes for structural studies, to derive structural information about protein complexes from the physiological cell environment, up to perspective applications of GECX-ncAAs for the development of covalent drugs.

Structural details of a Class B GPCR-arrestin complex revealed by genetically encoded crosslinkers in living cells.

Understanding the molecular basis of arrestin-mediated regulation of GPCRs is critical for deciphering signaling mechanisms and designing functional selectivity. However, structural studies of GPCR-arrestin complexes are hampered by their highly dynamic nature. Here, we dissect the interaction of arrestin-2 (arr2) with the secretin-like parathyroid hormone 1 receptor PTH1R using genetically encoded crosslinking amino acids in live cells. We identify 136 intermolecular proximity points that guide the construction of energy-optimized molecular models for the PTH1R-arr2 complex. Our data reveal flexible receptor elements missing in existing structures, including intracellular loop 3 and the proximal C-tail, and suggest a functional role of a hitherto overlooked positively charged region at the arrestin N-edge. Unbiased MD simulations highlight the stability and dynamic nature of the complex. Our integrative approach yields structural insights into protein-protein complexes in a biologically relevant live-cell environment and provides information inaccessible to classical structural methods, while also revealing the dynamics of the system.

Biochemical insights into structure and function of arrestins.

Arrestins (arr) are multifunctional cytosolic adaptors that bind to active and phosphorylated G protein-coupled receptors (GPCRs) via a highly versatile interface. Arrestins stop G protein signaling and trigger other signaling pathways. Recently, 3D structures of arr-GPCR complexes have been solved, which provide a bulk of structural information for understanding the mechanism of arr recruitment and activation. However, many questions about the functional consequences of structural details and the dynamics of the arr-GPCR interaction remain open. A wealth of information about key determinants for the arr-GPCR interaction and their functional relevance, and dynamic insights into the process of arr binding and the functional outcomes of different binding modes have been provided by a series of biochemical methods which we review here. Importantly, most of these methods provide information from the live cell, which is a necessary validation and complement for structural data. With the main focus on the most recent research, we will highlight major findings about arr structure, function, and dynamics derived from mutagenesis studies, cross-linking studies, conformational probes, and sensors, and we summarize available systems to detect arr recruitment. Furthermore, we discuss recent findings and directions of in silico investigations in arr-GPCR complexes.