水合蛋白质中的¹⁴N¹H和²H¹H交叉弛豫

14N1H and 2H1H cross-relaxation in hydrated proteins.

作者信息

Winter F, Kimmich R

出版信息

Biophys J. 1985 Aug;48(2):331-5. doi: 10.1016/S0006-3495(85)83787-5.

DOI:10.1016/S0006-3495(85)83787-5

PMID:4052566

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1329325/

Abstract

The frequency dependence of the proton spin-lattice relaxation time T1 of solid hydrated bovine serum albumin and alpha-chymotrypsin has been measured over 4.5 decades in the range 10(4) to 3 X 10(8) Hz mainly by the aid of the field-cycling technique. The comparison between H2O- and D2O-hydrated samples permitted the distinction of exchangeable and unexchangeable protons. In all cases the 14N1H cross-relaxation dips due mainly to the amide groups have been observed. In addition, in the case of the deuterium exchanged proteins a 2H1H quadrupole dip appears. The amide groups act as relaxation sinks due to the coupling of the amide proton to 14N and adjacent protons. Outside of the dip regions the proton-proton coupling dominates. The fluctuations of the 14N1H and 1H1H interactions are of a different type. The unexchangeable protons show a T1 dispersion outside of the quadrupole dip regions given by the exceptional power law T1 approximately v0.75 +/- 0.05. It is shown that apart from structural information of the 14N spectra, 14N1H cross-relaxation spectroscopy permits the determination of correlation times in the range 10(-7) s less than tau less than 10(-4)S.

摘要

主要借助场循环技术，在10⁴至3×10⁸Hz范围内跨越4.5个数量级，测量了固体水合牛血清白蛋白和α-胰凝乳蛋白酶的质子自旋-晶格弛豫时间T1的频率依赖性。通过比较H₂O水合样品和D₂O水合样品，可以区分可交换质子和不可交换质子。在所有情况下，均观察到主要归因于酰胺基团的¹⁴N¹H交叉弛豫凹陷。此外，在氘交换蛋白的情况下，出现了²H¹H四极凹陷。由于酰胺质子与¹⁴N及相邻质子的耦合，酰胺基团充当弛豫阱。在凹陷区域之外，质子-质子耦合起主导作用。¹⁴N¹H和¹H¹H相互作用的波动属于不同类型。不可交换质子在四极凹陷区域之外呈现出T1色散，由特殊的幂律T1≈v⁰.⁷⁵±⁰.⁰⁵给出。结果表明，除了¹⁴N光谱的结构信息外，¹⁴N¹H交叉弛豫光谱还可以测定10⁻⁷s＜τ＜10⁻⁴s范围内的相关时间。

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