BIOMAT Database Logo BIOMAT Database Logo

Covalent binding of [35S]cysteine to the labile binding site of the third component of complement: a physiological approach. 1985

C J Rutherford, and D R Jenkins

The alternative pathway of complement was activated physiologically by agarose beads to which [35S]cysteine had been bound by a disulfide link. The activated form of the third component of complement, C3b, which had bound to the radioactive cysteine was then released from the agarose bead with dithiothreitol. The [35S]cysteine was shown to be covalently bound to the alpha' chain of C3b, and to its known major breakdown product, the 66,000-Da polypeptide. This is highly suggestive that complement activation has led to formation of a peptide bond between the radioactive cysteine and the labile binding site on the alpha' chain of C3b. This radioactive marker will enable the amino acid sequence of the labile binding site to be determined, with the knowledge that the labeling of the amino acid(s) has occurred during physiological activation.

UI MeSH Term Description Entries
D008968 Molecular Conformation The characteristic three-dimensional shape of a molecule. Molecular Configuration,3D Molecular Structure,Configuration, Molecular,Molecular Structure, Three Dimensional,Three Dimensional Molecular Structure,3D Molecular Structures,Configurations, Molecular,Conformation, Molecular,Conformations, Molecular,Molecular Configurations,Molecular Conformations,Molecular Structure, 3D,Molecular Structures, 3D,Structure, 3D Molecular,Structures, 3D Molecular
D003167 Complement Activation The sequential activation of serum COMPLEMENT PROTEINS to create the COMPLEMENT MEMBRANE ATTACK COMPLEX. Factors initiating complement activation include ANTIGEN-ANTIBODY COMPLEXES, microbial ANTIGENS, or cell surface POLYSACCHARIDES. Activation, Complement,Activations, Complement,Complement Activations
D003171 Complement Pathway, Classical Complement activation initiated by the binding of COMPLEMENT C1 to ANTIGEN-ANTIBODY COMPLEXES at the COMPLEMENT C1Q subunit. This leads to the sequential activation of COMPLEMENT C1R and COMPLEMENT C1S subunits. Activated C1s cleaves COMPLEMENT C4 and COMPLEMENT C2 forming the membrane-bound classical C3 CONVERTASE (C4B2A) and the subsequent C5 CONVERTASE (C4B2A3B) leading to cleavage of COMPLEMENT C5 and the assembly of COMPLEMENT MEMBRANE ATTACK COMPLEX. Classical Complement Pathway,Classical Complement Activation Pathway,Complement Activation Pathway, Classical
D003179 Complement C3b The larger fragment generated from the cleavage of COMPLEMENT C3 by C3 CONVERTASE. It is a constituent of the ALTERNATIVE PATHWAY C3 CONVERTASE (C3bBb), and COMPLEMENT C5 CONVERTASES in both the classical (C4b2a3b) and the alternative (C3bBb3b) pathway. C3b participates in IMMUNE ADHERENCE REACTION and enhances PHAGOCYTOSIS. It can be inactivated (iC3b) or cleaved by various proteases to yield fragments such as COMPLEMENT C3C; COMPLEMENT C3D; C3e; C3f; and C3g. C3b Complement,C3bi,Complement 3b,Complement Component 3b,Inactivated C3b,iC3b,C3b, Complement,C3b, Inactivated,Complement, C3b,Component 3b, Complement
D003545 Cysteine A thiol-containing non-essential amino acid that is oxidized to form CYSTINE. Cysteine Hydrochloride,Half-Cystine,L-Cysteine,Zinc Cysteinate,Half Cystine,L Cysteine
D004591 Electrophoresis, Polyacrylamide Gel Electrophoresis in which a polyacrylamide gel is used as the diffusion medium. Polyacrylamide Gel Electrophoresis,SDS-PAGE,Sodium Dodecyl Sulfate-PAGE,Gel Electrophoresis, Polyacrylamide,SDS PAGE,Sodium Dodecyl Sulfate PAGE,Sodium Dodecyl Sulfate-PAGEs
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D012685 Sepharose Agarose,Sepharose 4B,Sepharose C1 4B,4B, Sepharose C1,C1 4B, Sepharose
D013462 Sulfur Radioisotopes Unstable isotopes of sulfur that decay or disintegrate spontaneously emitting radiation. S 29-31, 35, 37, and 38 are radioactive sulfur isotopes. Radioisotopes, Sulfur

Related Publications

C J Rutherford, and D R Jenkins
Attachment of [35S]cysteine to the labile site of the third component of complement via the alternative pathway.
January 1983, Clinical immunology and immunopathology,
C J Rutherford, and D R Jenkins
The third component of complement: covalent attachment of a radioactive sugar to the labile binding site of C3 via the alternative pathway.
June 1981, Journal of immunology (Baltimore, Md. : 1950),
C J Rutherford, and D R Jenkins
The third (C3) and the fourth (C4) components of complement: labile binding site and covalent bond formation.
January 1983, Annals of the New York Academy of Sciences,
C J Rutherford, and D R Jenkins
Mapping of the properdin-binding site in the third component of complement.
January 1984, The Biochemical journal,
C J Rutherford, and D R Jenkins
Localization of the conglutinin binding site on the third component of human complement.
February 1985, Journal of immunology (Baltimore, Md. : 1950),
C J Rutherford, and D R Jenkins
The covalent binding reaction of complement component C3.
July 1998, Journal of immunology (Baltimore, Md. : 1950),
C J Rutherford, and D R Jenkins
The covalent-binding reaction of complement component C3.
January 1981, The Biochemical journal,
C J Rutherford, and D R Jenkins
The physiological breakdown of the third component of human complement.
January 1980, Molecular immunology,
C J Rutherford, and D R Jenkins
A discontinuous factor H binding site in the third component of complement as delineated by synthetic peptides.
August 1988, The Journal of biological chemistry,
C J Rutherford, and D R Jenkins
Mapping of the C3d receptor (CR2)-binding site and a neoantigenic site in the C3d domain of the third component of complement.
June 1985, Proceedings of the National Academy of Sciences of the United States of America,
Copied contents to your clipboard!