通过质谱法追踪糖蛋白中糖基位点的氢/氘交换。
Tracking hydrogen/deuterium exchange at glycan sites in glycoproteins by mass spectrometry.
机构信息
Department of Medicinal Chemistry, University of Washington, Seattle, Washington 98195, USA.
出版信息
Anal Chem. 2011 Oct 1;83(19):7492-9. doi: 10.1021/ac201729v. Epub 2011 Sep 6.
Abstract
Hydrogen/deuterium exchange coupled to mass spectrometry (HDX-MS) has emerged as a technique for studying glycoproteins, which are often refractory to classical methods. Glycan chains are generally assumed to exchange protons very rapidly, making them invisible to this technique. Here, we show that under conditions commonly used for HDX-MS, acetamido groups within glycan chains retain a significant amount of deuterium. Using mono- and polysaccharide standards along with glycopeptides from a panel of glycoproteins, we demonstrate that N-acetyl hexosamines, along with modified Asn side chains, are responsible for this effect. Model compounds for sialic acid also displayed similar exchange kinetics, but terminal sialic acids in the context of an entire glycan chain did not contribute to deuterium retention. Furthermore, the presence of sialic acid appears to enhance the exchange rate of the nearby N-acetyl glucosamines. The ability to detect deuterium exchange at the glycan level opens the possibility of applying HDX-MS to monitor glycan interactions and dynamics.
摘要
氢/氘交换结合质谱(HDX-MS)已成为研究糖蛋白的一种技术,糖蛋白通常对经典方法具有抗性。糖链通常被认为会快速交换质子,从而使它们在该技术中不可见。在这里,我们表明,在通常用于 HDX-MS 的条件下,糖链中的乙酰氨基基团保留了大量氘。使用单糖和多糖标准品以及来自糖蛋白组的糖肽,我们证明 N-乙酰己糖胺以及修饰的 Asn 侧链是造成这种影响的原因。唾液酸的模型化合物也表现出类似的交换动力学,但整个糖链中末端唾液酸并没有导致氘保留。此外,唾液酸的存在似乎会提高附近 N-乙酰葡萄糖胺的交换速率。在聚糖水平上检测氘交换的能力为应用 HDX-MS 来监测聚糖相互作用和动态提供了可能性。
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