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Structure and flexibility of the multiple domain proteins that regulate complement activation

In this review we summarise more than 10 years of biophysical exploration into the structural biology of the regulators of complement activation (RCA). The five human proteins responsible for regulation of the early events of complement are homologous and are composed largely from building blocks ca...

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Published in:	Immunological reviews 2001-04, Vol.180 (1), p.146-161
Main Authors:	Kirkitadze, Marina D., Barlow, Paul N.
Format:	Article
Language:	English
Subjects:	Amino Acid Motifs Amino Acid Sequence Antigens, CD - chemistry Antigens, CD - physiology CD55 Antigens - chemistry CD55 Antigens - physiology Complement Activation complement control protein Complement Factor B - chemistry Complement Factor B - physiology Complement Factor H - chemistry Complement Factor H - physiology Consensus Sequence Humans Integrin alphaXbeta2 - chemistry Integrin alphaXbeta2 - physiology Magnetic Resonance Spectroscopy Membrane Cofactor Protein Membrane Glycoproteins - chemistry Membrane Glycoproteins - physiology Models, Molecular Molecular Sequence Data Protein Binding Protein Conformation Protein Structure, Tertiary Receptors, Complement 3b - chemistry Receptors, Complement 3b - physiology Receptors, Complement 3d - chemistry Receptors, Complement 3d - physiology Sequence Alignment Sequence Homology, Amino Acid Structure-Activity Relationship Viral Proteins - chemistry Viral Proteins - physiology
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description	In this review we summarise more than 10 years of biophysical exploration into the structural biology of the regulators of complement activation (RCA). The five human proteins responsible for regulation of the early events of complement are homologous and are composed largely from building blocks called “complement control protein (CCP) modules”. Unlike most multiple domain proteins they do not contain any of the other widely occurring module types. This apparent simplicity of RCA structure, however, is belied by their sophistication of function. In fact, the structures of the individual CCP modules exhibit wide variations on a common theme while the extent and nature of intermodular connections is diverse. Some neighbouring modules within a protein stabilise each other and some co‐operate to form specific binding surfaces. The degree of true “modularity” of CCPs is open to debate. The study of RCA proteins clearly illustrates the value of combining complementary structural biology techniques. The results could have implications for folding, evolution, flexibility and structure–function relationships of other molecules in the large, diverse and little understood category of multiple domain proteins. Work in the Barlow laboratory was supported by the Medical Research Council and the Biotechnology and Biological Sciences Research Council of the UK and by the Wellcome Trust. MDK was supported by the Human Frontiers Science Program.
doi_str_mv	10.1034/j.1600-065X.2001.1800113.x
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The results could have implications for folding, evolution, flexibility and structure–function relationships of other molecules in the large, diverse and little understood category of multiple domain proteins. Work in the Barlow laboratory was supported by the Medical Research Council and the Biotechnology and Biological Sciences Research Council of the UK and by the Wellcome Trust. 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The five human proteins responsible for regulation of the early events of complement are homologous and are composed largely from building blocks called “complement control protein (CCP) modules”. Unlike most multiple domain proteins they do not contain any of the other widely occurring module types. This apparent simplicity of RCA structure, however, is belied by their sophistication of function. In fact, the structures of the individual CCP modules exhibit wide variations on a common theme while the extent and nature of intermodular connections is diverse. Some neighbouring modules within a protein stabilise each other and some co‐operate to form specific binding surfaces. The degree of true “modularity” of CCPs is open to debate. The study of RCA proteins clearly illustrates the value of combining complementary structural biology techniques. The results could have implications for folding, evolution, flexibility and structure–function relationships of other molecules in the large, diverse and little understood category of multiple domain proteins. Work in the Barlow laboratory was supported by the Medical Research Council and the Biotechnology and Biological Sciences Research Council of the UK and by the Wellcome Trust. 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subjects	Amino Acid Motifs Amino Acid Sequence Antigens, CD - chemistry Antigens, CD - physiology CD55 Antigens - chemistry CD55 Antigens - physiology Complement Activation complement control protein Complement Factor B - chemistry Complement Factor B - physiology Complement Factor H - chemistry Complement Factor H - physiology Consensus Sequence Humans Integrin alphaXbeta2 - chemistry Integrin alphaXbeta2 - physiology Magnetic Resonance Spectroscopy Membrane Cofactor Protein Membrane Glycoproteins - chemistry Membrane Glycoproteins - physiology Models, Molecular Molecular Sequence Data Protein Binding Protein Conformation Protein Structure, Tertiary Receptors, Complement 3b - chemistry Receptors, Complement 3b - physiology Receptors, Complement 3d - chemistry Receptors, Complement 3d - physiology Sequence Alignment Sequence Homology, Amino Acid Structure-Activity Relationship Viral Proteins - chemistry Viral Proteins - physiology
title	Structure and flexibility of the multiple domain proteins that regulate complement activation
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