Solid-Phase Synthesis of Lipidated Ras Peptides Employing the Ellman Sulfonamide Linker

Therapeutic peptides: chemical strategies fortify peptides for enhanced disease treatment efficacy

Therapeutic peptides, as a unique form of medication composed of orderly arranged sequences of amino acids, are valued for their high affinity, specificity, low immunogenicity, and economical production costs. Currently, more than 100 peptides have already secured market approval. Over 150 are actively undergoing clinical trials, while an additional 400-600 are in the preclinical research stage. Despite this, their clinical application is limited by factors such as salt sensitivity, brief residence in the bloodstream, inadequate cellular uptake, and high structural flexibility. By employing suitable chemical methods to modify peptides, it is possible to regulate important physicochemical factors such as charge, hydrophobicity, conformation, amphiphilicity, and sequence that affect the physicochemical properties and biological activity of peptides. This can overcome the inherent deficiencies of peptides, enhance their pharmacokinetic properties and biological activity, and promote continuous progress in the field of research. A diverse array of modified peptides is currently being developed and investigated across numerous therapeutic fields. Drawing on the latest research, this review encapsulates the essential physicochemical factors and significant chemical modification strategies that influence the properties and biological activity of peptides as pharmaceuticals. It also assesses how physicochemical factors affect the application of peptide drugs in disease treatment and the effectiveness of chemical strategies in disease therapy. Concurrently, this review discusses the prospective advancements in therapeutic peptide development, with the goal of offering guidance for designing and optimizing therapeutic peptides and to delve deeper into the therapeutic potential of peptides for disease intervention.

General, Mild, and Metal-Free Synthesis of Phenyl Selenoesters from Anhydrides and Their Use in Peptide Synthesis

A mild, practical, and simple procedure for phenyl selenoesters synthesis from several anhydrides and diphenyl diselenide was developed. This transition-metal-free method provides a straightforward entry to storable Fmoc-amino acid selenoesters which are effective chemoselective acylating reagents. An application to oligopeptide synthesis was illustrated.

Synthesis of lipidated peptides

One of the main reasons of the high diversity and complexity of the human proteome compared to the human genome is the extensive work performed by the posttranslational machinery to incorporate numerous different functionalities on proteins. The covalent attachment of chemical moieties in proteins after translation is known as posttranslational modification (PTM) and has a crucial role in controlling protein localization and activity. Relevant modifications include phosphorylation, carboxymethylation, glycosylation, acetylation, or lipidation. Despite their essential role on protein function, the synthesis of fully posttranslationally modified proteins has been challenging. However, important advances on chemical biology have enabled the synthesis of fully posttranslationally modified peptides and proteins. As a result of this, peptides bearing, i.e., phosphorylated amino acids, C-terminal methylations, lipid modifications, or nonnatural tags have become accessible. These peptides, as well as the corresponding proteins obtained using ligation techniques, have been invaluable tools in biochemical and biophysical studies. As an example of these advances, this chapter describes the methods developed for the synthesis of lipidated peptides from the Ras and Rab families.

Solid-phase peptide synthesis: an overview focused on the preparation of biologically relevant peptides

Tailor-made design preparation of complex peptide sequence including posttranslational modifications, fluorescent labels, unnatural amino acids are of exceptional value for biological studies of several important diseases. The possibility to obtain these molecules in sufficient amounts in relative short time is thanks to the solid-phase approach.

Click reactions in protein chemistry: from the preparation of semisynthetic enzymes to new click enzymes

Click-chemistry is an approach based on cycloaddition reactions which has been successfully used as a chemical approach for complex organic molecules and which has recently starred in a boom in the world of protein chemistry. The advantage of the use of this technique in protein chemistry is based on a very high and efficient chemoselectivity, which usually requires simple or no purification and is extremely rate-accelerated in aqueous media. The perspective discusses some of the most recent advances in the application of this reaction in selective enzyme surface modification for the creation of new semisynthetic enzymes (fluorescence labeled enzymes, peptide-enzyme conjugates, glycosylated enzymes), and interestingly, the recent design and creation of "click" enzymes.