铵水间质子交换的再研究: 不受扩散约束的化学交换

波谱学杂志

铵水间质子交换的再研究: 不受扩散约束的化学交换

张永洪, 毛希安*

中国科学院武汉物理与数学研究所波谱与原子分子物理国家重点实验室, 武汉 430071

收稿日期:2002-02-26 修回日期:2002-04-23 出版日期:2002-09-05 发布日期:2002-09-05
作者简介:张永洪(1970-)，男，湖北天门人，博士研究生。*通讯联系人
基金资助:
国家自然科学基金资助项目（29725307）.

REVISIT TO HYDROGEN EXCHANGE BETWEEN AMMONIUM AND WATER: Diffusion Independent Chemical Exchange

ZHANG Yong-hong，MAO Xi-an*

State Key Laboratory of Magnetic Resonance and Atomic Molecular Physics, Wuhan Institute of Physics and Mathematics, The Chinese Academy of Sciences P.O. Box, 71010, Wuhan 430071, China

Received:2002-02-26 Revised:2002-04-23 Online:2002-09-05 Published:2002-09-05
Supported by:
国家自然科学基金资助项目（29725307）.

摘要/Abstract

摘要：

对铵盐水溶液中铵离子与水分子间的质子交换进行了再研究. 以核磁共振(NMR) 波谱学方法测定了不同pH值, 不同温度和含不同共存盐浓度的氯化铵水溶液中质子交换速率, 组分自扩散系数及NMR自旋晶格弛豫时间. 结果显示铵水间的质子交换并不受交换主体分子或离子自扩散的约束. 交换机理包括化学键和氢键的交换. 在溶液中, 水分子以氢键为桥梁连接铵和其因水解而产生的碱性部分——氨. 在氢交换的过程中, 氨从水分子接受一个氢成为铵, 同时另外一端的铵提供一个氢给水分子而变成氨, 或者一个氢从水分子转移到氨而同时另外一个氢从铵转移到水. 在铵水质子交换的过程中没有净的电荷转移. 在低pH条件下, 由水解产生的氨的浓度降低, 亦即铵-水-氨复合物减少, 结果氢交换的可能性降低. 这解释了生物氢交换体系中的一种常见的在低pH值条件下氢交换变慢的现象.

关键词: 铵水溶液, 质子交换, 氢键, 化学键, 自扩散

Abstract:

Hydrogen exchange between ammonium and water is revisited. Exchange rate constants, diffusion coefficients and relaxation times for solutions with var ied pH, temperature and concentration of a coexisting salt are measured using NM Rspectroscopy. It is demonstrated that the hydrogen exchange in ammonium soluti ons is independent of apparent diffusion. The mechanism involves chemical-bond/ h ydrogen-bond exchange. In solutions, water molecules, with the help of hydrogen - bonding, serve as abridge to connect the ammonium with its base partner ammonia . During hydrogen exchange, the ammonia accepts a hydrogen from water while the a mmonium donates a hydrogen to water, or ahydrogen jumps from water to ammonium and at the same time another hydrogen jumps back from ammonium to water. There is nonet hydrogen transfer between ammonium and water. At lower pH, the concentr ation of ammonia becomes lower and less ammonium-water-ammonia complex is form ed . As aresult, the probability of the hydrogen exchange is reduced. This explain s why at lower pH hydrogen exchange is slow, a common phenomenon observed in bio logical hydrogen exchange systems.

Key words: ammonium aqueous solution, hydrogen exchange, hydrogen bond, chemical bond, self-diffusion

中图分类号:

O482.53

张永洪, 毛希安. 铵水间质子交换的再研究: 不受扩散约束的化学交换[J]. 波谱学杂志.

ZHANG Yong-hong，MAO Xi-an. REVISIT TO HYDROGEN EXCHANGE BETWEEN AMMONIUM AND WATER: Diffusion Independent Chemical Exchange[J]. Chinese Journal of Magnetic Resonance.

参考文献

［1］Wüethrich K. NMR of Proteins and Nucleic Acids[M].New York: Wiley Interscience, 1986.

［2］Woodward C, Barbar E, Carulla N, et al. Experimental App roaches to Protein Folding Based on the Concept of a Slow Hydrogen Exchange Core[J]. J Mol Graph Model, 2001, 19: 94-101.

［3］Bai Y W, Sosnick T, Mayne R L, et al. Protein Folding Intermediates: Native-State Hydrogen Exchange[J]. Science, 1995, 269: 192- 197.

［4］Englander S W. Protein Folding Intermediates and Pathways Studies by Hy drogen Exchange[J]. Ann Rev Biophys Biomol Struc, 2000, 29: 213-238.

［5］Mierlo C P M, van and Steensma E. Protein folding and stability investiga ted by fluorescence, circular dichroism (CD), and nuclear magnetic resonance (NMR) spectroscopy: the flavodoxin story[J]. J Biotechn, 2000,79: 281-298.

［6］Bain A D. Blurring the distinction between slow and intermediate chemic al exchange[J]. Biochem Cell Biol, 1998, 76: 171-176.

［7］Patel D J, Surl A K, Jiang F, et al. Structure, Recognition and Adaptive Binding in RNA Aptamer Complexes[J]. {J Mol} Biol, 1997, 272: 645-664.

［8］Emerson M T, Grunwald E, Kromhout R A. Proton-Transfer Studies by Nucle ar Magnetic Resonance. I. Diffusion Control in the Reaction of Ammonium Ion i n Aqueous Acid[J]. J Chem Phys, 1960, 33: 547-555.

［9］Grunwald E, Karabatsos P J, Kromhout R A, et al. Proton-Tran sfer Studies by Nuclear Magnetic Resonance. II. Rate Constants and Mechanism for the Reaction CH₃NH⁺₃+OH₂+NH₂CH₃ in Aqueous Acid[J]. J Chem Phys, 1960, 33: 556-563.

［10］Emerson M T, Grunwald E, Kaplan M L, et al. Proton-Transfe r Studies by Nuclear Magnetic Resonance. III. The Mean Life of the Amine-Water Hydrogen Bond in Aqueous Solution[J]. J Am Chem Soc, 1960, 82: 6307-6314.

［11］Eigen M, Proton Transfer, Acid-Base Catalysis, and Enzymatic Hydrolysis. P art I: Elementary Processes[J]. Angew Chem Intl Ed, 1964, 3: 1-19.

and the references therein.

［12］Englander S W, Downer N W, Teitelbaum H. Hydrogen Exchange[J]. Ann- Rev Biochem, 1972, 41: 903-924. and the references therein.

［13］Perrin C L. Proton Exchange in Amides: Surprises from Simple Systems[J]. Acc Chem Res, 1989, 22: 268-275.

［14］Perrin C L, Engler R E. Secondary H/D Kinetic Isotope Effect for Dissociation of Aqueous Ammonium Ion[J]. J Phys Chem, 1991, 95: 8431-8433.

［15］Nonin S, Gueron M, Leroy J L. Terminal Base pairs of Oligodeoxynucl eotides: Imino Proton Exchange and Fraying[J]. Biochemistry, 1995, 34: 10652- 10659.

［16］Kettani A, Gueron M, Leroy J L. Amino Proton Exchange Processes in Mononucleosides[J]. J Am Chem Soc, 1997, 119: 1108-1115.

［17］Jeener J, Meier B H, Bachman P, et al. Investigation of exchan ge processes by two-dimensional NMR spectroscopy[J]. J Chem Phys, 1979, 71: 4 546.

［18］Wu D, Chen A, Johnson Jr C S. An Improved Diffusion-Ordered Spec tros copy Experiment Incorporating Bipolar-Gradient Pulses[J]. J Magn Reson, 1995, 115A: 260.

［19］Mao X A, Kohlmann O. Diffusion-Broadened Velocity Spectra of Conv e ction in Variable-Temperature BP-LED Experiments[J]. J Mag Reson, 2001, 150: 35.

［20］Johnson Jr C S. Effects of Chemical Exchange in Diffusion-Ordered 2D NMR Spectra[J]. J Magn Reson, 1993, 102A: 214.

［21］Holz M, Mao X A, Seiferling D, et al. Experimental study of dyna mic isotope effects in molecular liquids: Detection of translation-rotation cou pling[J]. J Chem Phys, 1996, 104: 669.

［22］Bockris J O'M, Reddy A K N. in Modern Electrochemistry, Vol. 1. Ionics. 2nd ed[M]. New York: Plenum Press, 1998. Chap 4.

［23］Perrin C L, Gipe R K. Rotation, Solvation, and Hydrogen Bonding of Aqueo us Ammonium Ion[J]. J Am Chem Soc, 1986, 108: 1089.

［24］Perrin C L, Gipe R K. Rotation and Solvation of Ammonium Ion[J]. Sci ence, 1987, 238: 1393.

［25］Atkins P W. in Physical Chemistry (second edition)[M]. London: Oxford University Press, 1982. 368.

[1]	黄俊霖, 余亦华. 扩散序谱(DOSY)实验中扩散系数维数字分辨率的影响[J]. 波谱学杂志, 2018, 35(3): 287-293.
[2]	葛玉玮, 刘买利, 甘哲宏, 李从刚. 质子化学位移各向异性的测量[J]. 波谱学杂志, 2018, 35(2): 255-267.
[3]	何保江1，徐秀娟1，杨伟平1，张文娟1，吴瑞3，黄少华2，杨盈2，柏正武3. 基质辅助 NMR 中色谱技术的研究进展[J]. 波谱学杂志, 2015, 32(4): 699-706.
[4]	茹阁英, 罗精明, 徐阳粼, 冯继文. 分子量分布对线性PNIPA/D₂O溶液相变和扩散性质的影响[J]. 波谱学杂志, 2011, 28(3): 349-356.
[5]	王琳琳, 赵新, 孙万赋. 聚酰胺66溶液弛豫行为的NMR研究[J]. 波谱学杂志, 2010, 27(2): 150-156.
[6]	代博娜；彭敏；陈群. 壳聚糖和N-羟基苯并三氮唑相互作用的NMR研究[J]. 波谱学杂志, 2008, 25(4): 453-460.
[7]	欧阳捷1 ; 张巍1 ; 彭捷1 ; 邓志威1 ; 李丽娅2 ; 林文翰2 . 几种含氮化合物的核磁共振测试 [J]. 波谱学杂志, 2006, 23(4): 457-465.
[8]	邹琴, 赵新, 孙万赋. 丙烯腈γ辐射聚合的NMR研究[J]. 波谱学杂志, 2006, 23(2): 187-192.
[9]	高玉贺, 陈家富, 许新胜. 国内CIDEP研究进展[J]. 波谱学杂志, 2006, 23(1): 129-141.
[10]	彭敏, 孔旭新, 张惠平, 陈群. α-环糊精/水杨酸等包络物的NMR自扩散研究[J]. 波谱学杂志, 2005, 22(2): 141-147.
[11]	闫秀玲, 孙万赋, 唐军, 张建斌, 赵新. 紫外光辐照聚乙烯醇的¹H NMR研究[J]. 波谱学杂志, 2004, 21(4): 493-498.
[12]	周平, 欧阳植勋. 钴超分子络合物中的氢键相互作用——⁵⁹Co核磁共振研究及分子模拟[J]. 波谱学杂志, 2004, 21(1): 1-15.
[13]	崔艳芳1,2，文健3，刘买利1*. 应用脉冲梯度场NMR研究脂蛋白的自扩散系数分布[J]. 波谱学杂志, 2003, 20(1): 8-15.
[14]	邵伟艳，钟世舟，胡小鹏，蔡继文. ［Co(tren)(amino acidato-N, O)］X₂·nH₂O在溶液中的NMR研究[J]. 波谱学杂志, 2002, 19(2): 149-157.
[15]	郑绍宽，陈忠，陈志伟，廖新丽. 分子间多量子相干横向弛豫时间(和自扩散系数)测量的参数优化和数据处理方法[J]. 波谱学杂志, 2001, 18(3): 281-289.