Department of Physics, University of Warwick, Coventry CV4 7AL, United Kingdom.
J Am Chem Soc. 2011 Dec 14;133(49):19777-95. doi: 10.1021/ja206516u. Epub 2011 Nov 17.
By means of the (1)H chemical shifts and the proton-proton proximities as identified in (1)H double-quantum (DQ) combined rotation and multiple-pulse spectroscopy (CRAMPS) solid-state NMR correlation spectra, ribbon-like and quartet-like self-assembly can be identified for guanosine derivatives without isotopic labeling for which it was not possible to obtain single crystals suitable for diffraction. Specifically, characteristic spectral fingerprints are observed for dG(C10)(2) and dG(C3)(2) derivatives, for which quartet-like and ribbon-like self-assembly has been unambiguously identified by (15)N refocused INADEQUATE spectra in a previous study of (15)N-labeled derivatives (Pham, T. N.; et al. J. Am. Chem. Soc.2005, 127, 16018). The NH (1)H chemical shift is observed to be higher (13-15 ppm) for ribbon-like self-assembly as compared to 10-11 ppm for a quartet-like arrangement, corresponding to a change from NH···N to NH···O intermolecular hydrogen bonding. The order of the two NH(2)(1)H chemical shifts is also inverted, with the NH(2) proton closest in space to the NH proton having a higher or lower (1)H chemical shift than that of the other NH(2) proton for ribbon-like as opposed to quartet-like self-assembly. For the dG(C3)(2) derivative for which a single-crystal diffraction structure is available, the distinct resonances and DQ peaks are assigned by means of gauge-including projector-augmented wave (GIPAW) chemical shift calculations. In addition, (14)N-(1)H correlation spectra obtained at 850 MHz under fast (60 kHz) magic-angle spinning (MAS) confirm the assignment of the NH and NH(2) chemical shifts for the dG(C3)(2) derivative and allow longer range through-space N···H proximities to be identified, notably to the N7 nitrogens on the opposite hydrogen-bonding face.
通过 1H 化学位移和质子-质子间距的识别,如在 1H 双量子(DQ)联合旋转和多脉冲光谱(CRAMPS)固态 NMR 相关光谱中所确定的,可以识别鸟苷衍生物的带状和四重态自组装,而无需对其进行同位素标记,因为对于这些衍生物,无法获得适合衍射的单晶。具体而言,对于 dG(C10)(2)和 dG(C3)(2)衍生物,观察到特征谱指纹,通过之前对 15N 标记衍生物的(15)N 重聚焦 INADEQUATE 光谱研究,已明确鉴定出四重态和带状自组装(Pham,T.N.;等。J. Am. Chem. Soc.2005,127,16018)。与四重态排列的 10-11 ppm 相比,带状自组装的 NH(1)H 化学位移观察到更高(13-15 ppm),这对应于从 NH···N 到 NH···O 分子间氢键的变化。两个 NH(2)(1)H 化学位移的顺序也颠倒了,对于带状自组装,空间上最接近 NH 质子的 NH(2)质子的(1)H 化学位移比另一个 NH(2)质子高或低;而对于四重态自组装则相反。对于具有单晶衍射结构的 dG(C3)(2)衍生物,通过使用包括量规的投影增强波(GIPAW)化学位移计算,对明显的共振和 DQ 峰进行了分配。此外,在 850 MHz 下以快速(60 kHz)魔角旋转(MAS)获得的 14N-(1)H 相关光谱证实了 dG(C3)(2)衍生物的 NH 和 NH(2)化学位移的分配,并允许识别更长的空间内 N···H 间距,特别是在相反的氢键面上的 N7 氮。
