Engineering an unnatural Nalpha-anchored disulfide into BPTI by total chemical synthesis: structural and functional consequences

Non-Canonical Amino Acids in Analyses of Protease Structure and Function

All known organisms encode 20 canonical amino acids by base triplets in the genetic code. The cellular translational machinery produces proteins consisting mainly of these amino acids. Several hundred natural amino acids serve important functions in metabolism, as scaffold molecules, and in signal transduction. New side chains are generated mainly by post-translational modifications, while others have altered backbones, such as the β- or γ-amino acids, or they undergo stereochemical inversion, e.g., in the case of D-amino acids. In addition, the number of non-canonical amino acids has further increased by chemical syntheses. Since many of these non-canonical amino acids confer resistance to proteolytic degradation, they are potential protease inhibitors and tools for specificity profiling studies in substrate optimization and enzyme inhibition. Other applications include in vitro and in vivo studies of enzyme kinetics, molecular interactions and bioimaging, to name a few. Amino acids with bio-orthogonal labels are particularly attractive, enabling various cross-link and click reactions for structure-functional studies. Here, we cover the latest developments in protease research with non-canonical amino acids, which opens up a great potential, e.g., for novel prodrugs activated by proteases or for other pharmaceutical compounds, some of which have already reached the clinical trial stage.

Novel protein science enabled by total chemical synthesis

Chemical synthesis is a well-established method for the preparation in the research laboratory of multiple-tens-of-milligram amounts of correctly folded, high purity protein molecules. Chemically synthesized proteins enable a broad spectrum of novel protein science. Racemic mixtures consisting of d-protein and l-protein enantiomers facilitate crystallization and determination of protein structures by X-ray diffraction. d-Proteins enable the systematic development of unnatural mirror image protein molecules that bind with high affinity to natural protein targets. The d-protein form of a therapeutic target can also be used to screen natural product libraries to identify novel small molecule leads for drug development. Proteins with novel polypeptide chain topologies including branched, circular, linear-loop, and interpenetrating polypeptide chains can be constructed by chemical synthesis. Medicinal chemistry can be applied to optimize the properties of therapeutic protein molecules. Chemical synthesis has been used to redesign glycoproteins and for the a priori design and construction of covalently constrained novel protein scaffolds not found in nature. Versatile and precise labeling of protein molecules by chemical synthesis facilitates effective application of advanced physical methods including multidimensional nuclear magnetic resonance and time-resolved FTIR for the elucidation of protein structure-activity relationships. The chemistries used for total synthesis of proteins have been adapted to making artificial molecular devices and protein-inspired nanomolecular constructs. Research to develop mirror image life in the laboratory is in its very earliest stages, based on the total chemical synthesis of d-protein forms of polymerase enzymes.

Semisynthesis of proteins by expressed protein ligation

Expressed protein ligation (EPL) is a protein engineering approach that allows recombinant and synthetic polypeptides to be chemoselectively and regioselectively joined together. The approach makes the primary structure of most proteins accessible to the tools of synthetic organic chemistry, enabling the covalent structure of proteins to be modified in an unprecedented fashion. The ability to incorporate noncoded amino acids, biophysical probes, and stable isotopes into specific locations within proteins provides research tools to peer into the inner workings of these molecules. In this review I discuss the development of this technology, its broad application to biological systems, and its possible role in the area of proteomics.

Recent advances in the application of expressed protein ligation to protein engineering

Expressed protein ligation is a technique for joining recombinantly expressed proteins to polypeptides containing biophysical probes, post-translational modifications or unnatural amino acids. Recent advances have expanded the scope of expressed protein ligation and have allowed the approach to be applied to the study of basic biological questions.

Challenges for protein chemical synthesis in the 21st century: bridging genomics and proteomics

The Human Genome Project and other major sequencing projects have rapidly provided a vast array of new protein sequences. In the postgenomic era, the physical form of many of these gene-encoded sequences will be vital for biomedical research and drug development. In this epoch, the advantages of protein chemical synthesis will complement recombinant-DNA methods, and will be used to provide rapid access to small proteins or functional receptor domains. In this review the key methodological advances that have made the synthesis of long peptides and small proteins more effective will be presented. Focus is given to the issues and goals of contemporary chemical protein synthesis, including (1) the rapid chain assembly of tailored peptide segments for use in ligation strategies, and (2) development of highly efficient and universal chemoselective ligation strategies. Biopolymers (Pept Sci) 55: 217-226, 2000

Synthesis of native proteins by chemical ligation

In just a few short years, the chemical ligation of unprotected peptide segments in aqueous solution has established itself as the most practical method for the total synthesis of native proteins. A wide range of proteins has been prepared. These synthetic molecules have led to the elucidation of gene function, to the discovery of novel biology, and to the determination of new three-dimensional protein structures by both NMR and X-ray crystallography. The facile access to novel analogs provided by chemical protein synthesis has led to original insights into the molecular basis of protein function in a number of systems. Chemical protein synthesis has also enabled the systematic development of proteins with enhanced potency and specificity as candidate therapeutic agents.