Structure of an immunoglobulin Fab fragment specific for triple-stranded DNA

Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of intense research because of its potential use in the control of gene expression and in the development of sequence-specific reagents for cleaving...

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Published in	The Journal of biological chemistry Vol. 269; no. 5; pp. 3615 - 3622
Main Authors	Mol, C.D., Muir, A.K., Cygler, M., Lee, J.S., Anderson, W.F.
Format	Journal Article
Language	English
Published	Bethesda, MD American Society for Biochemistry and Molecular Biology 04.02.1994
Subjects	Amino Acid Sequence Animals Antibodies, immunoglobulins Antibodies, Monoclonal - chemistry Binding Sites, Antibody Biological and medical sciences Computer Graphics DNA - immunology Fundamental and applied biological sciences. Psychology Fundamental immunology Hydrogen Bonding Immunoglobulin Fab Fragments - chemistry Immunoglobulin Heavy Chains - chemistry Immunoglobulin Light Chains - chemistry Mice Models, Molecular Molecular immunology Monoclonal antibodies Polydeoxyribonucleotides - immunology Protein Conformation Protein Structure, Secondary Thermodynamics Vertebrata Mammalia Mouse DNA Rodentia Triple helical structure Monoclonal antibody Fab-Fragment X ray diffraction Modeling Spatial structure
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ISSN	0021-9258 1067-8816 1083-351X 1083-351X
DOI	10.1016/S0021-9258(17)41907-7

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Abstract	Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of intense research because of its potential use in the control of gene expression and in the development of sequence-specific reagents for cleaving DNA. In a triplex of this type, the second pyrimidine strand is in a parallel orientation to the purine strand and forms Hoogsteen base pairs with it via the major groove. We describe here the three-dimensional crystal structure determination of the antigen-binding fragment (Fab) from the murine monoclonal antibody Jel 318. Jel 318 is specific for triple-stranded DNA, with a preference for the sequence poly[d(T.m5C)].poly[d(G.A)].poly[(d(m5C+.T)]. The structure has been solved by the molecular replacement method and refined by molecular dynamics to an R value of 0.20 at a resolution of 2.8 A. The crystals have cell dimensions that are very similar to those of the previously determined structure of Fab Kol, but the Fab fragments pack within the unit cell in a completely different manner. The protein is in an extended conformation, with an elbow angle of 154 degrees. The shape and electrostatic surface potential of the antibody combining site suggest a possible model for the recognition of triplex DNA in which residues of CDR-H2 (where CDR represents complementarity-determining region) make specific contact with the DNA bases in the minor groove of the triplex.
AbstractList	Triple-stranded DNA of the form poly(Pyr)-poly-(Pur)-poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of intense research because of its potential use in the control of gene expression and in the development of sequence-specific reagents for cleaving DNA. In a triplex of this type, the second pyrimidine strand is in a parallel orientation to the purine strand and forms Hoogsteen base pairs with it via the major groove. We describe here the three-dimensional crystal structure determination of the antigen-binding fragment (Fab) from the murine monoclonal antibody Jel 318. Jel 318 is specific for triple-stranded DNA, with a preference for the sequence poly[d(T-m super(5)C)]-poly[d(G-A)]-poly[(d(m super(5)C super(+)T)]. The structure has been solved by the molecular replacement method and refined by molecular dynamics to an R value of 0.20 at a resolution of 2.8 angstrom. The crystals have cell dimensions that are very similar to those of the previously determined structure of Fab Kol, but the Fab fragments pack within the unit cell in a completely different manner. The protein is in an extended conformation, with an elbow angle of 154 degree . The shape and electrostatic surface potential of the antibody combining site suggest a possible model for the recognition of triplex DNA in which residues of CDR-H2 (where CDR represents complementarity-determining region) make specific contact with the DNA bases in the minor groove of the triplex. (DBO) Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of intense research because of its potential use in the control of gene expression and in the development of sequence-specific reagents for cleaving DNA. In a triplex of this type, the second pyrimidine strand is in a parallel orientation to the purine strand and forms Hoogsteen base pairs with it via the major groove. We describe here the three-dimensional crystal structure determination of the antigen-binding fragment (Fab) from the murine monoclonal antibody Jel 318. Jel 318 is specific for triple-stranded DNA, with a preference for the sequence poly[d(T.m5C)].poly[d(G.A)].poly[(d(m5C+.T)]. The structure has been solved by the molecular replacement method and refined by molecular dynamics to an R value of 0.20 at a resolution of 2.8 A. The crystals have cell dimensions that are very similar to those of the previously determined structure of Fab Kol, but the Fab fragments pack within the unit cell in a completely different manner. The protein is in an extended conformation, with an elbow angle of 154 degrees. The shape and electrostatic surface potential of the antibody combining site suggest a possible model for the recognition of triplex DNA in which residues of CDR-H2 (where CDR represents complementarity-determining region) make specific contact with the DNA bases in the minor groove of the triplex. Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of intense research because of its potential use in the control of gene expression and in the development of sequence-specific reagents for cleaving DNA. In a triplex of this type, the second pyrimidine strand is in a parallel orientation to the purine strand and forms Hoogsteen base pairs with it via the major groove. We describe here the three-dimensional crystal structure determination of the antigen-binding fragment (Fab) from the murine monoclonal antibody Jel 318. Jel 318 is specific for triple-stranded DNA, with a preference for the sequence poly[d(T.m5C)].poly[d(G.A)].poly[(d(m5C+.T)]. The structure has been solved by the molecular replacement method and refined by molecular dynamics to an R value of 0.20 at a resolution of 2.8 A. The crystals have cell dimensions that are very similar to those of the previously determined structure of Fab Kol, but the Fab fragments pack within the unit cell in a completely different manner. The protein is in an extended conformation, with an elbow angle of 154 degrees. The shape and electrostatic surface potential of the antibody combining site suggest a possible model for the recognition of triplex DNA in which residues of CDR-H2 (where CDR represents complementarity-determining region) make specific contact with the DNA bases in the minor groove of the triplex. Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of intense research because of its potential use in the control of gene expression and in the development of sequence-specific reagents for cleaving DNA. In a triplex of this type, the second pyrimidine strand is in a parallel orientation to the purine strand and forms Hoogsteen base pairs with it via the major groove. We describe here the three-dimensional crystal structure determination of the antigen-binding fragment (Fab) from the murine monoclonal antibody Jel 318. Jel 318 is specific for triple-stranded DNA, with a preference for the sequence poly[d(T.m5C)].poly[d(G.A)].poly[(d(m5C+.T)]. The structure has been solved by the molecular replacement method and refined by molecular dynamics to an R value of 0.20 at a resolution of 2.8 A. The crystals have cell dimensions that are very similar to those of the previously determined structure of Fab Kol, but the Fab fragments pack within the unit cell in a completely different manner. The protein is in an extended conformation, with an elbow angle of 154 degrees. The shape and electrostatic surface potential of the antibody combining site suggest a possible model for the recognition of triplex DNA in which residues of CDR-H2 (where CDR represents complementarity-determining region) make specific contact with the DNA bases in the minor groove of the triplex.Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of intense research because of its potential use in the control of gene expression and in the development of sequence-specific reagents for cleaving DNA. In a triplex of this type, the second pyrimidine strand is in a parallel orientation to the purine strand and forms Hoogsteen base pairs with it via the major groove. We describe here the three-dimensional crystal structure determination of the antigen-binding fragment (Fab) from the murine monoclonal antibody Jel 318. Jel 318 is specific for triple-stranded DNA, with a preference for the sequence poly[d(T.m5C)].poly[d(G.A)].poly[(d(m5C+.T)]. The structure has been solved by the molecular replacement method and refined by molecular dynamics to an R value of 0.20 at a resolution of 2.8 A. The crystals have cell dimensions that are very similar to those of the previously determined structure of Fab Kol, but the Fab fragments pack within the unit cell in a completely different manner. The protein is in an extended conformation, with an elbow angle of 154 degrees. The shape and electrostatic surface potential of the antibody combining site suggest a possible model for the recognition of triplex DNA in which residues of CDR-H2 (where CDR represents complementarity-determining region) make specific contact with the DNA bases in the minor groove of the triplex.
Author	J S Lee W F Anderson A K Muir C D Mol M Cygler
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Snippet	Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of... Triple-stranded DNA of the form poly(Pyr).poly-(Pur).poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of... Triple-stranded DNA of the form poly(Pyr)-poly-(Pur)-poly(Pyr) (where Pyr represents a pyrimidine, and Pur represents a purine) has become the subject of...
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StartPage	3615
SubjectTerms	Amino Acid Sequence Animals Antibodies, immunoglobulins Antibodies, Monoclonal - chemistry Binding Sites, Antibody Biological and medical sciences Computer Graphics DNA - immunology Fundamental and applied biological sciences. Psychology Fundamental immunology Hydrogen Bonding Immunoglobulin Fab Fragments - chemistry Immunoglobulin Heavy Chains - chemistry Immunoglobulin Light Chains - chemistry Mice Models, Molecular Molecular immunology Monoclonal antibodies Polydeoxyribonucleotides - immunology Protein Conformation Protein Structure, Secondary Thermodynamics
Title	Structure of an immunoglobulin Fab fragment specific for triple-stranded DNA
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