Major groove width variations in RNA structures determined by NMR and impact of 13C residual chemical shift anisotropy and 1H–13C residual dipolar coupling on refinement

被引:0
作者
Blanton S. Tolbert
Yasuyuki Miyazaki
Shawn Barton
Benyam Kinde
Patrice Starck
Rashmi Singh
Ad Bax
David A. Case
Michael F. Summers
机构
[1] University of Maryland Baltimore County,Howard Hughes Medical Institute and Department of Chemistry and Biochemistry
[2] Miami University of Ohio,Department of Chemistry and Biochemistry
[3] NIDDK,Laboratory of Chemical Physics
[4] National Institutes of Health,Department of Chemistry & Chemical Biology and BioMaPS Institute
[5] Rutgers University,undefined
来源
Journal of Biomolecular NMR | 2010年 / 47卷
关键词
NMR; RNA structure determination; Isotope labeling; Residual dipolar coupling; Residual chemical shift anisotropy;
D O I
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中图分类号
学科分类号
摘要
Ribonucleic acid structure determination by NMR spectroscopy relies primarily on local structural restraints provided by 1H–1H NOEs and J-couplings. When employed loosely, these restraints are broadly compatible with A- and B-like helical geometries and give rise to calculated structures that are highly sensitive to the force fields employed during refinement. A survey of recently reported NMR structures reveals significant variations in helical parameters, particularly the major groove width. Although helical parameters observed in high-resolution X-ray crystal structures of isolated A-form RNA helices are sensitive to crystal packing effects, variations among the published X-ray structures are significantly smaller than those observed in NMR structures. Here we show that restraints derived from aromatic 1H–13C residual dipolar couplings (RDCs) and residual chemical shift anisotropies (RCSAs) can overcome NMR restraint and force field deficiencies and afford structures with helical properties similar to those observed in high-resolution X-ray structures.
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页码:205 / 219
页数:14
相关论文
共 254 条
  • [1] Al-Hashimi HM(2007)Beyond static structures of RNA by NMR: folding, refolding, and dynamics at atomic resolution Biopolymers 86 345-347
  • [2] Al-Hashimi HM(2002)Residual dipolar couplings: synergy between NMR and structural genomics J Biomol NMR 22 1-8
  • [3] Patel DJ(2008)RNA dynamics: it is about time Curr Opin Struct Biol 18 321-329
  • [4] Al-Hashimi HM(2001)Alignment of the HTLV-I Rex peptide bound to its target RNA aptamer from magnetic field-induced residual dipolar couplings and intermolecular hydrogen bonds J Am Chem Soc 123 3179-3180
  • [5] Walter NG(2001)Field- and phage-induced dipolar couplings in a homodimeric DNA quadruplex: relative orientation of G. (C-A) triad and G-tetrad motifs and direct determination of C2 symmetry axis orientation J Am Chem Soc 123 633-640
  • [6] Al-Hashimi HM(2001)Determining stoichiometry in homomultimeric nucleic acid complexes using magnetic field induced residual dipolar couplings J Am Chem Soc 123 5806-5807
  • [7] Gorin A(2002)Concerted motions in HIV-1 TAR RNA may allow access to bound state conformations: RNA dynamics from NMR residual dipolar couplings J Mol Biol 315 95-102
  • [8] Majumdar A(2003)Mg2+-induced variations in the conformation and dynamics of HIV-1 TAR RNA probed using NMR residual dipolar couplings J Mol Biol 329 867-873
  • [9] Patel DJ(1997)How accurately and precisely can RNA structure be determined by NMR? J Mol Biol 267 338-351
  • [10] Al-Hashimi HM(1998)An alpha/beta-HSQC-alpha/beta experiment for spin-state selective editing of IS cross peaks J Magn Reson 133 364-367
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