Resources

Proteomics Databases



Metabolomics Databases

• • Mechanism of Protein Identification

  Proteins are vital molecules executing numerous functions within living organisms, and understanding their structure and function is essential for biological research. Protein identification is a process used to determine the type, structure, and function of proteins, with extensive applications in biology, medicine, and drug development. This article details the mechanisms of protein identification, encompassing steps from sample preparation to final identification.

• • Principle of Protein Identification

  Proteins are essential molecules in living organisms, performing various functions, including structural support, catalysis, signal transduction, and immune response. Identifying proteins is critical in biological research as it provides insight into the functions and mechanisms of organisms.

• • Mechanism of Protein Analysis

  Protein analysis is integral to modern biochemical and biopharmaceutical research. Understanding the mechanisms of protein analysis is crucial for elucidating protein structure, function, and interactions. These insights are essential for advancing our knowledge of cellular processes, disease mechanisms, and therapeutic development. This article explores the mechanisms underlying protein analysis, emphasizing the methodologies, applications, and challenges involved.

• • Application of Protein Analysis

  Protein analysis is a crucial element in the field of biochemistry and biopharmaceutical research. By providing in-depth insights into the structure, function, and interactions of proteins, protein analysis aids in understanding biological processes, disease mechanisms, and therapeutic targets.

• • Workflow of Protein Analysis

  Protein analysis is a critical component of biochemical and biopharmaceutical research, providing valuable insights into the structure, function, and interactions of proteins. These macromolecules play essential roles in virtually all cellular processes. Understanding their characteristics and behaviors is vital for deciphering biological mechanisms, disease pathways, and therapeutic targets.

• • Principle of Protein Analysis

  Protein analysis is a fundamental aspect of biochemical and biopharmaceutical research, providing insights into the structure, function, and interactions of proteins. Proteins are crucial macromolecules involved in virtually all cellular processes, and their analysis can reveal information essential for understanding biological mechanisms, disease progression, and therapeutic development.

• • Mechanism of 2D Blue Native/SDS-PAGE Protein Complex Analysis

  2D Blue Native/SDS-PAGE complex analysis is a sophisticated technique employed to elucidate the structure and function of protein complexes. This method synergizes Blue Native PAGE with Sodium Dodecyl Sulfate Polyacrylamide Gel Electrophoresis (SDS-PAGE), facilitating the separation and analysis of protein complexes from complex biological samples through a sequential two-step process. This article explicates the fundamental principles and mechanisms underlying 2D Blue Native/SDS-PAGE.

• • Application of 2D Blue Native/SDS-PAGE Protein Complex Analysis

  Protein complexes play crucial roles in physiological and pathological processes within cells. Understanding their composition and structure is essential for investigating biological processes and developing therapies. Two-Dimensional Blue Native/SDS-PAGE (2D BN/SDS-PAGE) is a powerful technique for analyzing protein complexes.

• • Workflow of 2D Blue Native/SDS-PAGE Protein Complex Analysis

  2D Blue Native/SDS-PAGE complex analysis is a robust technique for separating and analyzing protein complexes. It combines Blue Native Polyacrylamide Gel Electrophoresis (BN-PAGE) with subsequent SDS-PAGE, providing detailed information about the native state and components of protein complexes in the same gel. This method is invaluable for elucidating protein interactions, complex structures, and functions.

• • N-Glycan Profiling and Its Analysis Workflow

  N-glycan analysis is a method used to analyze glycan structures, especially when studying glycosylation on proteins or other biomolecules. Glycosylation (or glycation) is a common mode of biomolecular modification in cells, playing a key role in protein stability, activity, cell signaling, cell-cell interaction, and more.   N-glycan refers to the glycan chain attached to the asparagine nitrogen, which is a type of N-linked glycoprotein.