Simple and Rapid Synthesis of Branched Peptides through Microwave-Assisted On-Bead Ligation

Review on the o-Aminoaniline Moiety in Peptide and Protein Chemistry

Peptides and proteins are important functional biomolecules both inside and outside of living organisms. The ability to prepare various types of functionalized peptides and proteins is essential for understanding fundamental biological processes, such as protein folding and post-translational modifications (PTMs), and for developing new therapeutics for many diseases, such as cancers and neurodegenerative diseases. The o-aminoaniline moiety was first proposed for activation to a thioester precursor and used for native chemical ligation to prepare large peptides and proteins. In the past decade, the function of o-aminoaniline has been greatly expanded to facilitate the preparation of homogeneously modified peptide and protein samples, where the modifications can include cyclization, C-terminus diversification, etc. Many o-aminoaniline derivatives have also been developed to overcome the inherent limitations of previous versions. In this review, we attempt to summarize the recent developments of different o-aminoaniline derivatives, focusing on their application to the preparation of functional peptide and protein molecules.

Hierarchical Self-Assembly of Short Peptides: Nanostructure Formation, Function Tailoring, and Applications

This article explores the hierarchical self-assembly of short peptides, which refers to the structured spatial arrangements of these molecules over long distances. This phenomenon is commonly found in nature and has important implications for biological structure and function. Short peptides are preferred for self-assembly because they have the ability to spontaneously create various nanostructures. This process, known as bottom-up assembly, allows for the addition of functional groups at the carboxyl or amine ends of the peptides. These functional groups enable specific functions that are extremely valuable in the fields of biotechnology and biomedicine. This text discusses the basic processes involved in the self-assembly of short peptides, such as the characteristics of amino acid side chains, the categorization of short peptides according to their chemical structure, the influence of intermolecular forces, and the dynamic nature of the self-assembly process. In addition, the paper discusses the various uses of short peptides in the disciplines of biomedicine and optoelectronics, including stimulus-responsive hydrogels, tissue engineering, and drug delivery. The article also suggests rational design principles for controlling the hierarchical self-assembly of short peptides, creating new commercial applications, particularly with functional hydrogels, and offers insights into the future of the discipline.

Evolution of branched peptides as novel biomaterials

Branched peptide-based materials draw inspiration from dendritic structures to emulate the complex architecture of native tissues, aiming to enhance the performance of biomaterials in medical applications. These innovative materials benefit from several key features: they exhibit slower degradation rates, greater stiffness, and the ability to self-assemble. These properties are crucial for maintaining the structural integrity and functionality of the materials over time. By integrating bioactive peptides and natural polymers within their branched frameworks, these materials offer modularity and tunability and can accommodate a range of mechanical properties, degradation rates, and biological functions making them suitable for biomedical applications, including drug delivery systems, wound healing scaffolds, and tissue engineering constructs. In drug delivery, these materials can be engineered to release therapeutic agents in a controlled manner, enhancing the efficacy and safety of treatments. In wound healing, they provide a supportive environment which promotes rapid and efficient tissue repair. The combination of biomimetic design and functional adaptability makes branched peptide-based materials a promising candidate for the development of next-generation biomaterials, paving the way for significant advancements in healthcare.

One-Step Synthesis of 3-(Fmoc-amino acid)-3,4-diaminobenzoic Acids

A one-step method for synthesizing 3-(Fmoc-amino acid)-3,4-diaminobenzoic acids was used to prepare preloaded diaminobenzoate resin. The coupling of free diaminobenzoic acid and Fmoc-amino acids gave pure products in 40-94% yield without any purification step in addition to precipitation except for histidine. For the proline residue, crude products were collected and used for solid-phase peptide synthesis to give a moderate yield of a pentapeptide. In addition, this method was used to prepare unusual amino acid derivatives, namely, (2-naphthyl) alanine and 6-aminohexanoic acid derivatives, in 50 and 65% yield, respectively.

Branched Multimeric Peptides as Affinity Reagents for the Detection of α-Klotho Protein

α-Klotho, an aging-related protein found in the kidney, parathyroid gland, and choroid plexus, acts as an essential co-receptor with the fibroblast growth factor 23 receptor complex to regulate serum phosphate and vitamin D levels. Decreased levels of α-Klotho are a hallmark of age-associated diseases. Detecting or labeling α-Klotho in biological milieu has long been a challenge, however, hampering the understanding of its role. Here, we developed branched peptides by single-shot parallel automated fast-flow synthesis that recognize α-Klotho with improved affinity relative to their monomeric versions. These peptides were further shown to selectively label Klotho for live imaging in kidney cells. Our results demonstrate that automated flow technology enables rapid synthesis of complex peptide architectures, showing promise for future detection of α-Klotho in physiological settings.

Facile Solid-Phase Synthesis of Well-Defined Defect Lysine Dendrimers

An efficient solid-phase method has been reported to prepare well-defined lysine defect dendrimers. Using orthogonally protected lysine residues, pure G2 to G4 lysine defect dendrimers were prepared with 48-95% yields within 13 h. Remarkably, high-purity products were collected via precipitation without further purification steps. This method was applied to prepare a pair of 4-carboxyphenylboronic acid-decorated defect dendrimers (16 and 17), which possessed the same number of boronic acids. The binding affinity of 16, in which the ε-amines of G1 lysine are fractured, for glucose and sorbitol was 4 times that of 17. This investigation indicated the role of allocation and distribution of peripheries for the dendrimer's properties and activity.