Johnson B A, Shirokawa J M, Hancock W S, Spellman M W, Basa L J, Aswad D W
School of Biological Sciences, University of California, Irvine 92717.
J Biol Chem. 1989 Aug 25;264(24):14262-71.
In vitro aging at pH 7.4, 37 degrees C causes natural sequence recombinant human growth hormone (rhGH), methionyl rhGH, and human pituitary growth hormone to become substrates for bovine brain protein carboxyl methyltransferase, an enzyme that modifies the "side chain" alpha-carboxyl group present at atypical isoaspartyl linkages. The substrate capacity of rhGH increased at a rate of 1.8 methyl-accepting sites/day/100 molecules of hormone. Reversed-phase high performance liquid chromatography (HPLC) of trypsin digests of aged rhGH revealed two altered peptides not present in digests of control rhGH. These two fragments, which had the amino acid compositions of residues 128-134 (Leu-Glu-Asp-Gly-Ser-Pro-Arg) and 146-158 (Phe-Asp-Thr-Asn-Ser-His-Asn-Asp-Asp-Ala-Leu-Leu-Lys), contained the majority of the induced methylation sites, 22 and 58%, respectively. Isoaspartate can result from deamidation of asparagine or isomerization of aspartate. Isomerization of Asp-130, the only candidate site in 128-134, was corroborated by coelution of the altered fragment with the synthetic isoaspartyl peptide upon reversed-phase HPLC. Evidence is presented that the altered 146-158 fragment is a mixture of two peptides resulting from deamidation of Asn-149 to form 70-80% isoaspartate and 20-30% aspartate at this position. The position of isoaspartate in the altered 146-158 fragment was deduced from mass spectrometry, which indicated a single deamidated asparagine; from methylation stoichiometry, which indicated only one methylation site; and from automated Edman degradation, which showed an absence of asparagine and a low yield of aspartate at position 149. These results show that isoaspartate formation from both aspartate and asparagine is a significant, and possibly the major, source of spontaneous covalent alteration of rhGH and that enzymatic carboxyl methylation provides a powerful tool for assessing this type of modification.
在pH 7.4、37摄氏度的体外老化条件下,天然序列重组人生长激素(rhGH)、甲硫氨酰rhGH和人垂体生长激素会成为牛脑蛋白羧基甲基转移酶的底物,该酶可修饰存在于非典型异天冬氨酰连接中的“侧链”α - 羧基。rhGH的底物能力以每天每100个激素分子1.8个甲基接受位点的速率增加。对老化rhGH的胰蛋白酶消化产物进行反相高效液相色谱(HPLC)分析,发现对照rhGH消化产物中不存在的两个改变的肽段。这两个片段的氨基酸组成分别为残基128 - 134(Leu - Glu - Asp - Gly - Ser - Pro - Arg)和146 - 158(Phe - Asp - Thr - Asn - Ser - His - Asn - Asp - Asp - Ala - Leu - Leu - Lys),分别包含大部分诱导的甲基化位点,即22%和58%。异天冬氨酸可由天冬酰胺的脱酰胺作用或天冬氨酸的异构化作用产生。通过反相HPLC分析,改变的片段与合成的异天冬氨酰肽共洗脱,证实了128 - 134中唯一的候选位点Asp - 130发生了异构化。有证据表明,改变的146 - 158片段是两个肽段的混合物,这是由于Asn - 149脱酰胺形成了该位置70 - 80%的异天冬氨酸和20 - 30%的天冬氨酸。通过质谱法推断出改变的146 - 158片段中异天冬氨酸的位置,质谱显示存在一个单一的脱酰胺天冬酰胺;甲基化化学计量法表明只有一个甲基化位点;自动Edman降解显示在位置149处不存在天冬酰胺且天冬氨酸产量较低。这些结果表明,天冬氨酸和天冬酰胺形成异天冬氨酸是rhGH自发共价改变的一个重要且可能是主要的来源,并且酶促羧基甲基化提供了一个强大的工具来评估这种类型的修饰。
