Transcription factor SOX-10 (332-340)

Transcription factor SOX-10 (332-340) is a synthetic peptide fragment corresponding to amino acids 332 through 340 of the SOX-10 protein, a member of the SOX (SRY-related HMG-box) family of transcription factors. SOX-10 plays a critical role in the regulation of gene expression during neural crest development, melanocyte differentiation, and glial cell lineage specification. The 332-340 peptide segment represents a defined epitope within the protein, making it valuable for a range of biochemical, immunological, and molecular biology investigations. Its sequence specificity and functional relevance enable researchers to probe the structural and regulatory properties of SOX-10, as well as to develop analytical tools for studying transcriptional control mechanisms in development and disease models.

Epitope mapping: The SOX-10 (332-340) peptide is frequently employed in epitope mapping studies to identify antibody binding sites within the SOX-10 protein. By using this defined peptide fragment in immunoassays, researchers can characterize the specificity of monoclonal and polyclonal antibodies, facilitating the development of highly selective immunodetection reagents. Such precise mapping is essential for generating reliable antibodies for Western blotting, immunohistochemistry, and ELISA applications, particularly when distinguishing SOX-10 from closely related SOX family members.

Antibody production: As an immunogen, the SOX-10 (332-340) peptide serves as a robust tool for generating custom antibodies against the SOX-10 protein. Conjugation of this peptide to carrier proteins enables the elicitation of targeted immune responses in host animals, resulting in antibodies that specifically recognize the 332-340 region. These antibodies are instrumental in both basic and applied research, supporting the study of SOX-10 expression patterns, functional roles, and regulatory dynamics in various biological systems.

Protein interaction studies: The defined sequence of the SOX-10 (332-340) peptide allows for detailed analysis of protein-protein interactions involving the SOX-10 transcription factor. Researchers can utilize this peptide in binding assays to investigate the molecular partners that associate with the C-terminal region of SOX-10. Such studies contribute to elucidating the mechanisms by which SOX-10 coordinates transcriptional complexes, modulates chromatin architecture, and integrates signaling pathways during cellular differentiation.

Peptide-based assay development: Incorporation of the SOX-10 (332-340) fragment into assay platforms supports the creation of sensitive and specific detection systems for SOX-10 activity. For example, the peptide can be used as a standard or competitive ligand in quantitative immunoassays, enabling the measurement of SOX-10 abundance or activity in cell lysates and tissue extracts. This approach is particularly valuable for monitoring SOX-10 dynamics in developmental biology, stem cell research, and studies of neural or pigment cell lineages.

Structural and functional analysis: The SOX-10 (332-340) peptide serves as a model system for investigating the structural features and post-translational modifications of the SOX-10 protein. Researchers can employ the peptide in mass spectrometry, NMR spectroscopy, or peptide array formats to analyze phosphorylation, methylation, or other modifications occurring within this region. Such studies provide insights into the regulatory mechanisms that influence SOX-10 function and its role in gene expression control during development and cellular differentiation.

1. Crystal Structure of BamB from Pseudomonas aeruginosa and Functional Evaluation of Its Conserved Structural Features

2. Constitutive and inflammation-dependent antimicrobial peptides produced by epithelium are differentially processed and inactivated by the commensal Finegoldia magna and the pathogen Streptococcus pyogenes

3. An Open-label, Single-center, Safety and Efficacy Study of Eyelash Polygrowth Factor Serum

4. Characterization of Novel P-Selectin Targeted Complement Inhibitors in Murine Models of Hindlimb Injury and Transplantation

5. Exosomes-mediated Transfer of miR-125a/b in Cell-to-cell Communication: A Novel Mechanism of Genetic Exchange in the Intestinal Microenvironment