Kim S G, Lin L J, Reid B R
Department of Chemistry, University of Washington, Seattle 98195.
Biochemistry. 1992 Apr 14;31(14):3564-74. doi: 10.1021/bi00129a003.
In DNA or RNA duplexes, the six-bond C3'-O3'-P-O5'-C5'-C4'-C3' backbone linkage connecting adjacent residues contains six torsion angles (epsilon, zeta, alpha, beta, gamma, delta) but only four protons. This seriously limits the ability to define the backbone conformation by NMR using purely 1H-1H distance geometry (DG) methods. The problem is further compounded by the inability to assign two of the four backbone protons, namely the poorly resolved H5' and H5'' protons, and invariably leads to DG structures with poorly defined backbone conformations. We have developed and tested a reliable method to constrain the beta, gamma, and epsilon (and indirectly alpha and zeta) backbone torsion angles by lower-bound NOE distances to unassigned H5'/H5'' resonances combined with either 1H line widths or the conservative use of sigma J measurements; the method relies only on 1H 2-D NMR data, does not involve any structural assumptions, and leads to much improved backbone convergence among DG structures. The C4'-C5' torsion angle gamma is constrained by lower-bound NOE distances from H2' and from H6/H8 to any H5'/H5'', as well as by sigma JH4, coupling measurements in the 3.9-4.4 ppm region; delta is constrained by H1'-H4' NOE distances and by H3'-H4' and H3'-H2'' J couplings in COSY data; epsilon is partially constrained by H3' line width and/or further constrained by subtracting the minimum possible sigma JH3'-H from the observed sigma JH3' (COSY) to arrive at the maximum possible JH3'-P, which is then converted to H3'-P distance bounds. The angle beta is partially constrained via H5'-P and H5''-P distance bounds consistent with the maximum H5'-P and H5''-P J couplings derived from the observed H5' and H5'' line widths, while alpha and zeta are indirectly constrained by lower distance bounds on the observed (n)H1' to (n + 1)H5'/H5'' NOEs combined with the prior partial constraints on beta, gamma, delta, and epsilon. The combined effects of these additional constraints in determining distance geometry structures have been demonstrated using a 12-base duplex, [d(GCCGTTAACGGC)]2. Coordinate RMSDs per atom between structures refined with these constraints from random-embedded DG structures, from ideal A-DNA, and from B-DNA starting structures were less than 0.4 A for the central 8 base pairs indicating good convergence. All backbone angles for the central 8 base pairs are very well constrained with less than 10 degrees variation in any of the 48 torsion angles.
在DNA或RNA双链体中,连接相邻残基的六键C3'-O3'-P-O5'-C5'-C4'-C3'主链连接包含六个扭转角(ε、ζ、α、β、γ、δ),但只有四个质子。这严重限制了使用纯1H-1H距离几何(DG)方法通过核磁共振(NMR)来定义主链构象的能力。由于无法确定四个主链质子中的两个,即分辨不清的H5'和H5''质子,问题进一步复杂化,并且总是导致主链构象定义不明确的DG结构。我们已经开发并测试了一种可靠的方法,通过与未分配的H5'/H5''共振的下限NOE距离,结合1H线宽或保守使用σJ测量,来约束β、γ和ε(以及间接的α和ζ)主链扭转角;该方法仅依赖于1H二维NMR数据,不涉及任何结构假设,并且导致DG结构之间的主链收敛性有很大改善。C4'-C5'扭转角γ通过从H2'以及从H6/H8到任何H5'/H5''的下限NOE距离,以及在3.9 - 4.4 ppm区域的σJH4耦合测量来约束;δ通过H1'-H4' NOE距离以及COSY数据中的H3'-H4'和H3'-H2'' J耦合来约束;ε部分地通过H3'线宽来约束,和/或通过从观察到的σJH3'(COSY)中减去最小可能的σJH3'-H以得到最大可能的JH3'-P,然后将其转换为H3'-P距离界限来进一步约束。角度β通过与从观察到的H5'和H5''线宽导出的最大H5'-P和H5''-P J耦合一致的H5'-P和H5''-P距离界限部分地受到约束,而α和ζ通过观察到的(n)H1'到(n + 1)H5'/H5'' NOE的下限距离界限,结合对β、γ、δ和ε的先前部分约束来间接受到约束。使用12碱基双链体[d(GCCGTTAACGGC)]2已经证明了这些额外约束在确定距离几何结构中的综合效果。从随机嵌入的DG结构、理想A-DNA和B-DNA起始结构用这些约束进行结构优化后,中心8个碱基对的每个原子的坐标均方根偏差(RMSD)小于0.4 Å,表明收敛良好。中心8个碱基对的所有主链角度都受到很好的约束,48个扭转角中的任何一个的变化都小于10度。
