Conformational flexibility in T4 endonuclease VII revealed by crystallography: implications for substrate binding and cleavage

The structure of the N62D mutant of the junction-resolving endonuclease VII (EndoVII) from phage T4 has been refined at 1.3 A, and a second wild-type crystal form solved and refined at 2.8 A resolution. Comparison of the mutant with the wild-type protein structure in two different crystal environmen...

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Veröffentlicht in:	Journal of molecular biology 2001-04, Vol.308 (2), p.311-323
Hauptverfasser:	Raaijmakers, H, Törö, I, Birkenbihl, R, Kemper, B, Suck, D
Format:	Artikel
Sprache:	eng
Schlagworte:	Amino Acid Substitution - genetics Bacteriophage T4 - enzymology Bacteriophage T4 - genetics Binding Sites Calcium - metabolism Catalysis Crystallography, X-Ray Dimerization DNA - chemistry DNA - metabolism Endodeoxyribonucleases - chemistry Endodeoxyribonucleases - genetics Endodeoxyribonucleases - metabolism endonuclease VII Ions - metabolism Magnesium - metabolism Models, Molecular Mutation - genetics Phage T4 Pliability Protein Conformation Recombinases Substrate Specificity Sulfates - metabolism Transposases - chemistry
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container_title	Journal of molecular biology
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creator	Raaijmakers, H Törö, I Birkenbihl, R Kemper, B Suck, D
description	The structure of the N62D mutant of the junction-resolving endonuclease VII (EndoVII) from phage T4 has been refined at 1.3 A, and a second wild-type crystal form solved and refined at 2.8 A resolution. Comparison of the mutant with the wild-type protein structure in two different crystal environments reveals considerable conformational flexibility at the dimer level affecting the substrate-binding cleft, the dimerization interface and the orientation of the C-terminal domains. The opening of the DNA-binding cleft, the orientation of the C-terminal domains relative to the central dimerization domain as well as the relative positioning of helices in the dimerization interface appear to be sensitive to the crystal packing environment. The highly unexpected rearrangement within the extended hydrophobic interface does change the contact surface area but keeps the number of hydrophobic contacts about the same and will therefore not require significant energy input. The conformational flexibility most likely is of functional significance for the broad substrate specificity of EndoVII. Binding of sulphate ions in the mutant structure and their positions relative to the active-site metal ions and residues known to be essential for catalysis allows us to propose a possible catalytic mechanism. A comparison with the active-site geometries of other magnesium-dependent nucleases, among them the homing endonuclease I-PpoI and Serratia endonuclease, shows common features, suggesting related catalytic mechanisms.
doi_str_mv	10.1006/jmbi.2001.4592
format	Article
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Comparison of the mutant with the wild-type protein structure in two different crystal environments reveals considerable conformational flexibility at the dimer level affecting the substrate-binding cleft, the dimerization interface and the orientation of the C-terminal domains. The opening of the DNA-binding cleft, the orientation of the C-terminal domains relative to the central dimerization domain as well as the relative positioning of helices in the dimerization interface appear to be sensitive to the crystal packing environment. The highly unexpected rearrangement within the extended hydrophobic interface does change the contact surface area but keeps the number of hydrophobic contacts about the same and will therefore not require significant energy input. The conformational flexibility most likely is of functional significance for the broad substrate specificity of EndoVII. Binding of sulphate ions in the mutant structure and their positions relative to the active-site metal ions and residues known to be essential for catalysis allows us to propose a possible catalytic mechanism. 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Comparison of the mutant with the wild-type protein structure in two different crystal environments reveals considerable conformational flexibility at the dimer level affecting the substrate-binding cleft, the dimerization interface and the orientation of the C-terminal domains. The opening of the DNA-binding cleft, the orientation of the C-terminal domains relative to the central dimerization domain as well as the relative positioning of helices in the dimerization interface appear to be sensitive to the crystal packing environment. The highly unexpected rearrangement within the extended hydrophobic interface does change the contact surface area but keeps the number of hydrophobic contacts about the same and will therefore not require significant energy input. The conformational flexibility most likely is of functional significance for the broad substrate specificity of EndoVII. Binding of sulphate ions in the mutant structure and their positions relative to the active-site metal ions and residues known to be essential for catalysis allows us to propose a possible catalytic mechanism. 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Comparison of the mutant with the wild-type protein structure in two different crystal environments reveals considerable conformational flexibility at the dimer level affecting the substrate-binding cleft, the dimerization interface and the orientation of the C-terminal domains. The opening of the DNA-binding cleft, the orientation of the C-terminal domains relative to the central dimerization domain as well as the relative positioning of helices in the dimerization interface appear to be sensitive to the crystal packing environment. The highly unexpected rearrangement within the extended hydrophobic interface does change the contact surface area but keeps the number of hydrophobic contacts about the same and will therefore not require significant energy input. The conformational flexibility most likely is of functional significance for the broad substrate specificity of EndoVII. Binding of sulphate ions in the mutant structure and their positions relative to the active-site metal ions and residues known to be essential for catalysis allows us to propose a possible catalytic mechanism. A comparison with the active-site geometries of other magnesium-dependent nucleases, among them the homing endonuclease I-PpoI and Serratia endonuclease, shows common features, suggesting related catalytic mechanisms.</abstract><cop>England</cop><pmid>11327769</pmid><doi>10.1006/jmbi.2001.4592</doi><tpages>13</tpages></addata></record>
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source	MEDLINE; Elsevier ScienceDirect Journals
subjects	Amino Acid Substitution - genetics Bacteriophage T4 - enzymology Bacteriophage T4 - genetics Binding Sites Calcium - metabolism Catalysis Crystallography, X-Ray Dimerization DNA - chemistry DNA - metabolism Endodeoxyribonucleases - chemistry Endodeoxyribonucleases - genetics Endodeoxyribonucleases - metabolism endonuclease VII Ions - metabolism Magnesium - metabolism Models, Molecular Mutation - genetics Phage T4 Pliability Protein Conformation Recombinases Substrate Specificity Sulfates - metabolism Transposases - chemistry
title	Conformational flexibility in T4 endonuclease VII revealed by crystallography: implications for substrate binding and cleavage
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