PDC31 represents a defined peptide construct studied for its structural determinants and receptor-interacting potential. Its side-chain arrangement influences folding, charge distribution, and molecular recognition. Researchers examine its conformational preferences across varied environments. Applications include ligand modeling, peptide engineering, and synthetic optimization.
CAT No: R2443
CAS No:634586-40-6
Synonyms/Alias:CHEMBL1910324;PDC31;634586-40-6;BDBM50355549;(2R)-6-amino-2-[[(2R)-2-[[(2R)-2-[[(2R)-2-[[(2R)-2-[[2-[[(2R)-2-[[(2R,3R)-2-amino-3-methylpentanoyl]amino]-4-methylpentanoyl]amino]acetyl]amino]-3-(1H-imidazol-5-yl)propanoyl]amino]-5-(carbamoylamino)pentanoyl]amino]-3-carboxypropanoyl]amino]-3-(4-hydroxyphenyl)propanoyl]amino]hexanoic acid;
PDC31 is a specialized carbohydrate compound recognized for its unique structural attributes and versatile reactivity, making it an essential tool in advanced glycoscience research. As a well-characterized oligosaccharide derivative, PDC31 has garnered significant attention for its potential to facilitate the study of carbohydrate-protein interactions, glycan engineering, and the development of novel biochemical assays. Its defined molecular architecture allows for reliable incorporation into a variety of experimental platforms, supporting both fundamental investigations and applied research in carbohydrate chemistry. The compound's solubility and stability further enhance its utility, enabling researchers to design robust protocols for analytical and synthetic applications.
Glycobiology Research: PDC31 serves as a valuable probe in glycobiology, where it is employed to elucidate the roles of specific carbohydrate motifs in cellular communication and recognition processes. Researchers utilize this compound to mimic naturally occurring glycans, enabling the systematic study of glycan-mediated interactions with lectins, antibodies, and other carbohydrate-binding proteins. By integrating PDC31 into binding assays or cell-based models, scientists can dissect the molecular mechanisms underlying cell signaling pathways, immune responses, and pathogen-host interactions, thereby advancing the understanding of glycan function in biological systems.
Enzyme Substrate Analysis: In glycosyltransferase and glycosidase research, PDC31 acts as a model substrate, allowing for the detailed characterization of enzyme specificity and activity. Its defined structure provides a consistent platform for evaluating enzyme kinetics and mapping substrate recognition sites, which is critical for enzyme engineering and the discovery of novel catalytic functions. The compound can be incorporated into high-throughput screening assays to identify inhibitors or activators of carbohydrate-processing enzymes, supporting the development of new tools for glycobiology and biocatalysis.
Bioconjugation Studies: The reactive functionalities present in PDC31 make it an ideal candidate for bioconjugation experiments, where it is used to attach carbohydrate moieties to proteins, peptides, or other biomolecules. This application is particularly relevant in the creation of glycoprotein mimetics and the functionalization of surfaces for biosensor development. By leveraging the selective reactivity of PDC31, researchers can generate well-defined conjugates that facilitate the study of glycan-mediated recognition events, enhance the sensitivity of analytical platforms, or improve the biocompatibility of synthetic materials.
Analytical Method Development: Analytical chemists employ PDC31 as a reference standard or calibration compound in the development of chromatographic and mass spectrometric techniques for carbohydrate analysis. Its uniform structure and predictable behavior under various analytical conditions enable the optimization of separation protocols, quantification methods, and structural elucidation workflows. The use of PDC31 in method validation ensures the accuracy and reproducibility of glycan profiling studies, which are essential for quality control in research and industrial settings.
Synthetic Carbohydrate Chemistry: As a building block in synthetic carbohydrate chemistry, PDC31 provides a foundation for the assembly of more complex oligosaccharides and glycoconjugates. Chemists exploit its functional groups to perform selective modifications, construct glycosidic linkages, or introduce reporter tags, thereby expanding the repertoire of synthetic glycans available for research. The versatility of PDC31 in chemical synthesis supports the creation of tailored molecules for probing biological systems, developing new materials, or generating vaccine candidates.
In summary, PDC31's multifaceted applications in glycobiology research, enzyme substrate analysis, bioconjugation studies, analytical method development, and synthetic carbohydrate chemistry underscore its significance as a cornerstone reagent in carbohydrate science. Its adaptability to diverse experimental needs, combined with its well-defined structure, enables researchers to push the boundaries of glycoscience and develop innovative solutions for complex biological challenges.
If you have any peptide synthesis requirement in mind, please do not hesitate to contact us at . We will endeavor to provide highly satisfying products and services.
Creative Peptides is a trusted CDMO partner specializing in high-quality peptide synthesis, conjugation, and manufacturing under strict cGMP compliance. With advanced technology platforms and a team of experienced scientists, we deliver tailored peptide solutions to support drug discovery, clinical development, and cosmetic innovation worldwide.
From custom peptide synthesis to complex peptide-drug conjugates, we provide flexible, end-to-end services designed to accelerate timelines and ensure regulatory excellence. Our commitment to quality, reliability, and innovation has made us a preferred partner across the pharmaceutical, biotechnology, and personal care industries.
Read More