Motifs in nucleic acids: Molecular mechanics restraints for base pairing and base stacking
Identifieur interne : 000257 ( France/Analysis ); précédent : 000256; suivant : 000258Motifs in nucleic acids: Molecular mechanics restraints for base pairing and base stacking
Auteurs : Stephen C. Harvey [États-Unis] ; Chunlin Wang [États-Unis] ; Stephane Teletchea [France] ; Richard Lavery [France]Source :
- Journal of Computational Chemistry [ 0192-8651 ] ; 2003-01-15.
English descriptors
- Teeft :
- Angular term, Anticodon, Anticodon loop, Base normals, Base pair, Base pairing, Base pairing restraints, Base pairs, Base plane, Biomol struct dyns, Chain rule, Computational chemistry, Computational chemistry figure, Control atoms, Coplanarity, Coplanarity restraint, Crystal structures, Cubic function, Current implementation, Curves analysis, Default value, Distance restraints, Double helices, Double helix, Duplex, Electrostatic interactions, Energy penalty, Helicoidal parameters, Helix, Helix axis, Hoogsteen, Horizontal components, Initial duplex, Initial structure, Interatomic distance, Jumna, Jumna minimization, Jumna optimization, Light lines, Loop geometry, Major groove, Minor groove, Modeling, Molecular mechanics restraints, Negative gradient, Nucleic, Nucleic acid structures, Nucleic acids, Nucleotide, Pairing, Pairing restraints, Perpendicular, Present work, Probability distributions, Purine, Pyrimidine, Reference atoms, Restraint, Restraint terms, Standard force, Translational cycle, Trna anticodon, Various vectors, Vertical axis, Wiley periodicals.
Abstract
In building and refining nucleic acid structures, it is often desirable to enforce particular base pairing and/or base stacking interactions. Energy‐based modeling programs with classical molecular mechanics force fields do not lend themselves to the easy imposition of penalty terms corresponding to such restraints, because the requirement that two bases lie in or near the same plane (pairing) or that they lie in parallel planes (stacking) cannot be easily expressed in terms of traditional interactions involving two atoms (bonds), three atoms (angles), or four atoms (torsions). Here we derive expressions that define a collection of pseudobonds and pseudoangles through which molecular mechanics restraints for base pairing and stacking can be imposed. We have implemented these restraints into the JUMNA package for modeling DNA and RNA structures. JUMNA scripts can specify base pairing with a variety of standard geometries (Watson–Crick, Hoogsteen, wobble, etc.), or with user‐defined geometries; they can also specify stacking arrangements. We have also implemented “soft‐core” functions to modify van der Waals and electrostatic interactions to avoid steric conflicts in particularly difficult refinements where two backbones need to pass through one another. Test cases are presented to show the utility of the method. The restraints could be adapted for implementation in other molecular mechanics packages. © 2002 Wiley Periodicals, Inc. J Comput Chem 24: 1–9, 2003
Url:
DOI: 10.1002/jcc.10173
Affiliations:
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Kollman</title><title level="j" type="alt">JOURNAL OF COMPUTATIONAL CHEMISTRY</title><idno type="ISSN">0192-8651</idno><idno type="eISSN">1096-987X</idno><imprint><biblScope unit="vol">24</biblScope><biblScope unit="issue">1</biblScope><biblScope unit="page" from="1">1</biblScope><biblScope unit="page" to="9">9</biblScope><biblScope unit="page-count">9</biblScope><publisher>Wiley Subscription Services, Inc., A Wiley Company</publisher><pubPlace>New York</pubPlace><date type="published" when="2003-01-15">2003-01-15</date></imprint><idno type="ISSN">0192-8651</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0192-8651</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="Teeft" xml:lang="en"><term>Angular term</term><term>Anticodon</term><term>Anticodon loop</term><term>Base normals</term><term>Base pair</term><term>Base pairing</term><term>Base pairing restraints</term><term>Base pairs</term><term>Base plane</term><term>Biomol struct dyns</term><term>Chain rule</term><term>Computational chemistry</term><term>Computational chemistry figure</term><term>Control atoms</term><term>Coplanarity</term><term>Coplanarity restraint</term><term>Crystal structures</term><term>Cubic function</term><term>Current implementation</term><term>Curves analysis</term><term>Default value</term><term>Distance restraints</term><term>Double helices</term><term>Double helix</term><term>Duplex</term><term>Electrostatic interactions</term><term>Energy penalty</term><term>Helicoidal parameters</term><term>Helix</term><term>Helix axis</term><term>Hoogsteen</term><term>Horizontal components</term><term>Initial duplex</term><term>Initial structure</term><term>Interatomic distance</term><term>Jumna</term><term>Jumna minimization</term><term>Jumna optimization</term><term>Light lines</term><term>Loop geometry</term><term>Major groove</term><term>Minor groove</term><term>Modeling</term><term>Molecular mechanics restraints</term><term>Negative gradient</term><term>Nucleic</term><term>Nucleic acid structures</term><term>Nucleic acids</term><term>Nucleotide</term><term>Pairing</term><term>Pairing restraints</term><term>Perpendicular</term><term>Present work</term><term>Probability distributions</term><term>Purine</term><term>Pyrimidine</term><term>Reference atoms</term><term>Restraint</term><term>Restraint terms</term><term>Standard force</term><term>Translational cycle</term><term>Trna anticodon</term><term>Various vectors</term><term>Vertical axis</term><term>Wiley periodicals</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="de">In building and refining nucleic acid structures, it is often desirable to enforce particular base pairing and/or base stacking interactions. Energy‐based modeling programs with classical molecular mechanics force fields do not lend themselves to the easy imposition of penalty terms corresponding to such restraints, because the requirement that two bases lie in or near the same plane (pairing) or that they lie in parallel planes (stacking) cannot be easily expressed in terms of traditional interactions involving two atoms (bonds), three atoms (angles), or four atoms (torsions). Here we derive expressions that define a collection of pseudobonds and pseudoangles through which molecular mechanics restraints for base pairing and stacking can be imposed. We have implemented these restraints into the JUMNA package for modeling DNA and RNA structures. JUMNA scripts can specify base pairing with a variety of standard geometries (Watson–Crick, Hoogsteen, wobble, etc.), or with user‐defined geometries; they can also specify stacking arrangements. We have also implemented “soft‐core” functions to modify van der Waals and electrostatic interactions to avoid steric conflicts in particularly difficult refinements where two backbones need to pass through one another. Test cases are presented to show the utility of the method. The restraints could be adapted for implementation in other molecular mechanics packages. © 2002 Wiley Periodicals, Inc. J Comput Chem 24: 1–9, 2003</div></front></TEI><affiliations><list><country><li>France</li><li>États-Unis</li></country><region><li>Alabama</li><li>Île-de-France</li></region><settlement><li>Paris</li></settlement></list><tree><country name="États-Unis"><region name="Alabama"><name sortKey="Harvey, Stephen C" sort="Harvey, Stephen C" uniqKey="Harvey S" first="Stephen C." last="Harvey">Stephen C. Harvey</name></region><name sortKey="Harvey, Stephen C" sort="Harvey, Stephen C" uniqKey="Harvey S" first="Stephen C." last="Harvey">Stephen C. Harvey</name><name sortKey="Harvey, Stephen C" sort="Harvey, Stephen C" uniqKey="Harvey S" first="Stephen C." last="Harvey">Stephen C. Harvey</name><name sortKey="Wang, Chunlin" sort="Wang, Chunlin" uniqKey="Wang C" first="Chunlin" last="Wang">Chunlin Wang</name></country><country name="France"><region name="Île-de-France"><name sortKey="Teletchea, Stephane" sort="Teletchea, Stephane" uniqKey="Teletchea S" first="Stephane" last="Teletchea">Stephane Teletchea</name></region><name sortKey="Lavery, Richard" sort="Lavery, Richard" uniqKey="Lavery R" first="Richard" last="Lavery">Richard Lavery</name><name sortKey="Teletchea, Stephane" sort="Teletchea, Stephane" uniqKey="Teletchea S" first="Stephane" last="Teletchea">Stephane Teletchea</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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