Site-specific in vitro and in vivo incorporation of molecular probes to study G-protein-coupled receptors.

Chemical modification of proteins has a rich history in biochemistry and chemical biology. However, studies of membrane protein function, especially in cases where functional expression is low and purification and reconstitution are not feasible, present unique challenges. Heptahelical G-protein-coupled receptors (GPCRs) are a particularly important class of cell-surface receptors that represent targets of more than a quarter of all therapeutic drugs. Understanding with chemical precision how GPCRs function in biological membranes remains a central problem in biology. Recently a number of creative strategies have been developed that allow site-specific attachment of chemical probes or tags directly on expressed receptors or on biologically active peptide ligands or substrates. One particularly important advance is the genetic encoding of unnatural amino acids (UAAs) with unique small bioorthogonal tags using amber codon suppression in mammalian cells. This method should allow site-specific labeling of GPCRs with various molecular probes to facilitate cell-based studies of protein-protein or protein-ligand interactions and the visualization of conformational changes using fluorescence spectroscopy or single-molecule imaging.

A general method for scanning unnatural amino acid mutagenesis.

Current approaches to protein site-directed mutagenesis require an independent user operation for each mutation. This can impede large-scale scanning mutagenesis projects such as the mapping of protein interaction surfaces, active sites, or epitopes. It also prevents the creation of protein libraries of defined complexity for directed evolution purposes. Here we present a simple, fast, and effective way to perform scanning codon mutagenesis throughout a protein sequence. The process allows the researcher to define the new codon change, and therefore any amino acid mutation can be achieved. We demonstrate this approach by creating a library of proteins that contain single unnatural amino acid mutations encoded by the amber stop codon, TAG. The mutant proteins generated by this method can be expressed and assayed individually or used together as a mixed population of "rationally diversified" protein sequences.

Peptide mass fingerprinting using isotopically encoded photo-crosslinking amino acids.

When isotopically labelled photo-crosslinking amino acids are site-specifically incorporated into proteins, in combination with the corresponding non-labeled analogue, cross-linked tryptic peptides are easily identified in mass spectra via characteristic "doublet" patterns.