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1G80

NMR SOLUTION STRUCTURE OF D(GCGTACGC)2

Summary for 1G80
Entry DOI10.2210/pdb1g80/pdb
Related108D 1G7Z 203D 204D
Descriptor5'-D(*GP*CP*GP*TP*AP*CP*GP*C)-3' (1 entity in total)
Functional Keywordsdna, psoralen, hmt, c13 dynamics, conformational exchange, phosphate conformation, deoxyribose conformation, helical parameter, order parameter
Total number of polymer chains2
Total formula weight4855.21
Authors
Isaacs, R.J.,Spielmann, H.P. (deposition date: 2000-11-15, release date: 2001-03-28, Last modification date: 2024-05-22)
Primary citationIsaacs, R.J.,Spielmann, H.P.
Relationship of DNA structure to internal dynamics: correlation of helical parameters from NOE-based NMR solution structures of d(GCGTACGC)(2) and d(CGCTAGCG)(2) with (13)C order parameters implies conformational coupling in dinucleotide units.
J.Mol.Biol., 307:525-540, 2001
Cited by
PubMed Abstract: The coupling between the conformational properties of double-stranded DNA and its internal dynamics has been examined. The solution structures of the isomeric DNA oligomers d(GCGTACGC)(2) (UM) and d(CGCTAGCG)(2) (CTSYM) were determined with (1)H NMR spectroscopy by utilizing distance restraints from total relaxation matrix analysis of NOESY cross-peak intensities in restrained molecular dynamics calculations. The root-mean-square deviation of the coordinates for the ensemble of structures was 0.13 A for UM and 0.49 A for CTSYM, with crystallographic equivalent R(c)=0.41 and 0.39 and sixth-root residual R(x)=0.11 and 0.10 for UM and CTSYM, respectively. Both UM and CTSYM are B-form with straight helical axes and show sequence-dependent variations in conformation. The internal dynamics of UM and CTSYM were previously determined by analysis of (13)C relaxation parameters in the context of the Lipari & Szabo model-free formalism. Helical parameters for the two DNA oligomers were examined for linear correlations with the order parameters (S(2)) of groups of (13)C spins in base-pairs and dinucleotide units of UM and CTSYM. Correlations were found for six interstrand base-pair parameters tip, y-displacement, inclination, buckle and stretch with various combinations of S(2) for atoms in Watson-Crick base-pairs and for two inter-base-pair parameters, rise and roll with various combinations of S(2) for atoms in dinucleotides. The correlations for the interstrand base-pair helical parameters indicate that the conformations of the deoxyribose residues of each strand are dynamically coupled. Also, the inter-base-pair separation has a profound effect on the local internal motions available to the DNA, supporting the idea that rise is a principal degree of freedom for DNA conformational variability. The correlations indicate collective atomic motions of spins that may represent specific motional modes in DNA, and that base sequence has a predictable effect on the relative order of groups of spins both in the bases and in the deoxyribose ring of the DNA backbone. These observations suggest that an important functional outcome of DNA base sequence is the modulation of both the conformation and dynamic behavior of the DNA backbone.
PubMed: 11254380
DOI: 10.1006/jmbi.2001.4498
PDB entries with the same primary citation
Experimental method
SOLUTION NMR
Structure validation

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數據於2024-11-13公開中

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