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M K Liszewski
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Journal Articles
Journal:
Journal of Experimental Medicine
Journal of Experimental Medicine (1992) 175 (6): 1547–1551.
Published: 01 June 1992
Abstract
The cleavage of C3 is a critical step for complement (C) activation in the classical and alternative pathways. This reaction is controlled by the regulators of C activation protein family. Membrane cofactor protein (MCP) is a cofactor for the factor I-mediated inactivation of C3b and C4b. As a widely distributed membrane protein, MCP may protect host cells from inadvertent C activation. Human MCP has recently been shown to protect transfected rodent cells from human C-mediated lysis. In this report the relationship of MCP expression to C3b deposition and cytoprotection was examined using NIH/3T3 cells transfected with human MCP and exposed to human serum as a source of C and naturally occurring anti-mouse antibody. MCP inhibited C3b deposition in a dose-dependent fashion and inhibited lysis of the mouse cells expressing it. MCP did not inhibit lysis on bystander cells. These results demonstrate the protective role of MCP, at the cellular level, by an intrinsic mechanism.
Journal Articles
Journal:
Journal of Experimental Medicine
Journal of Experimental Medicine (1991) 174 (1): 93–102.
Published: 01 July 1991
Abstract
Membrane cofactor protein (MCP) is a complement regulatory protein that is expressed on human cells and cell lines as two relatively broad species with Mr of 58,000-68,000 and 48,000-56,000. The structure of a previously reported cDNA clone indicated that MCP was a type 1 membrane glycoprotein and a member of the regulators of complement activation gene/protein cluster. However, it did not provide an explanation for the unusual phenotypic pattern of MCP. Therefore, in parallel with an analysis of the gene, additional cDNAs were cloned and characterized. Six different MCP cDNA classes were identified. All encode the same 5' untranslated signal peptide, four SCRs, transmembrane domain, and basic amino acid anchor. However, they differ in the length and composition of an extracellular serine/threonine/proline (STP)-rich area, a site of heavy O-glycosylation, and cytoplasmic tail. Analysis of the MCP gene demonstrated that the variation in cDNA structure was a result of alternative splicing. Peripheral blood cells and cell lines predominantly expressed four of the six isoforms. These varied by the presence or absence of an STP-rich segment of 15 amino acids (STPB) and by the use of one of two cytoplasmic domains. Analysis by polymerase chain reaction, Northern blots, and transfection indicated that the predominance of MCP cDNA isoforms with STPB correlated with the high molecular weight protein phenotype, while the predominance of isoforms without STPB correlated with the lower molecular weight phenotype. The expression in a single cell of four distinct protein species with variable STP-rich regions and cytoplasmic tails represents an interesting example of the use of alternative splicing to provide variability in a mammalian protein.
Journal Articles
D M Lublin, M K Liszewski, T W Post, M A Arce, M M Le Beau, M B Rebentisch, L S Lemons, T Seya, J P Atkinson
Journal:
Journal of Experimental Medicine
Journal of Experimental Medicine (1988) 168 (1): 181–194.
Published: 01 July 1988
Abstract
Membrane cofactor protein (MCP), a regulatory molecular of the complement system with cofactor activity for the factor I-mediated inactivation of C3b and C4b, is widely distributed, being present on leukocytes, platelets, endothelial cells, epithelial cells, and fibroblasts. MCP was purified from a human T cell line (HSB2) and the NH2-terminal 24-amino acid sequence obtained by Edman degradation. An oligonucleotide probe based on this sequence was used to identify a clone from a human monocytic (U937) cDNA library. Nucleotide sequencing showed a 43-bp 5'-untranslated region, an open reading frame of 1,152 bp, and a 335-bp 3'-untranslated region followed by a 16-bp poly(A) track. The deduced full-length MCP protein consists of a 34-amino acid signal peptide and a 350-amino acid mature protein. The protein has, beginning at the NH2 terminus, four approximately 60-amino acid repeat units that match the consensus sequence found in a multigene family of complement regulatory proteins (C3b-receptor or CR1, C3d-receptor or CR2, decay-accelerating factor, C4-binding protein, and factor H), as well as several other complement and non-complement proteins. The remainder of the MCP protein consists of 25 amino acids that are rich in serine and threonine (probable site of heavy O-linked glycosylation of MCP), 17 amino acids of unknown significance, and a 23-amino acid transmembrane hydrophobic region followed by a 33-amino acid cytoplasmic tail. The MCP gene was localized to human chromosome 1, bands 1q31-41, by analysis of human x rodent somatic cell hybrid clones and by in situ hybridization. This same genetic region contains the multigene family of complement-regulatory proteins, which is thereby enlarged to include the functionally and structurally related MCP.