Venkatraman J, Aggarwal K, Balaram P
Molecular Biophysics Unit, Indian Institute of Science, Banglore, India.
Chem Biol. 2001 Jul;8(7):611-25. doi: 10.1016/s1074-5521(01)00036-9.
Non-enzymatic glycation of proteins has been implicated in various diabetic complications and age-related disorders. Proteins undergo glycation at the N-terminus or at the epsilon-amino group of lysine residues. The observation that only a fraction of all lysine residues undergo glycation indicates the role of the immediate chemical environment in the glycation reaction. Here we have constructed helical peptide models, which juxtapose lysine with potentially catalytic residues in order to probe their roles in the individual steps of the glycation reaction.
The peptides investigated in this study are constrained to adopt helical conformations allowing residues in the i and i+4 positions to come into spatial proximity, while residues i and i+2 are far apart. The placing of aspartic acid and histidine residues at interacting positions with lysine modulates the steps involved in early peptide glycation (reversible Schiff base formation and its subsequent irreversible conversion to a ketoamine product, the Amadori rearrangement). Proximal positioning of aspartic acid or histidine with respect to the reactive lysine residue retards initial Schiff base formation. On the contrary, aspartic acid promotes catalysis of the Amadori rearrangement. Presence of the strongly basic residue arginine proximate to lysine favorably affects the pK(a) of both the lysine epsilon-amino group and the singly glycated lysine, aiding in the formation of doubly glycated species. The Amadori product also formed carboxymethyl lysine, an advanced glycation endproduct (AGE), in a time-dependent manner.
Stereochemically defined peptide scaffolds are convenient tools for studying near neighbor effects on the reactivity of functional amino acid sidechains. The present study utilizes stereochemically defined peptide helices to effectively demonstrate that aspartic acid is an efficient catalytic residue in the Amadori arrangement. The results emphasize the structural determinants of Schiff base and Amadori product formation in the final accumulation of glycated peptides.
蛋白质的非酶糖基化与多种糖尿病并发症和年龄相关疾病有关。蛋白质在N端或赖氨酸残基的ε-氨基处发生糖基化。所有赖氨酸残基中只有一部分发生糖基化这一现象表明了紧邻的化学环境在糖基化反应中的作用。在此,我们构建了螺旋肽模型,将赖氨酸与潜在的催化残基并列放置,以探究它们在糖基化反应各个步骤中的作用。
本研究中所研究的肽被限制为采用螺旋构象,使得i位和i + 4位的残基在空间上接近,而i位和i + 2位的残基相距较远。将天冬氨酸和组氨酸残基放置在与赖氨酸相互作用的位置,可调节早期肽糖基化所涉及的步骤(可逆的席夫碱形成及其随后不可逆地转化为酮胺产物,即阿马多里重排)。天冬氨酸或组氨酸相对于反应性赖氨酸残基的近端定位会延迟初始席夫碱的形成。相反,天冬氨酸促进阿马多里重排的催化作用。紧邻赖氨酸存在强碱性残基精氨酸会有利地影响赖氨酸ε-氨基和单糖基化赖氨酸的pK(a),有助于形成双糖基化物种。阿马多里产物还以时间依赖性方式形成了羧甲基赖氨酸,一种晚期糖基化终产物(AGE)。
立体化学定义的肽支架是研究近邻效应如何影响功能性氨基酸侧链反应性的便捷工具。本研究利用立体化学定义的肽螺旋有效地证明了天冬氨酸是阿马多里重排中的有效催化残基。结果强调了糖基化肽最终积累过程中席夫碱和阿马多里产物形成的结构决定因素。
