Windwarder Markus, Altmann Friedrich
Department of Chemistry, University of Natural Resources and Life Sciences, Vienna (BOKU), Austria.
Department of Chemistry, University of Natural Resources and Life Sciences, Vienna (BOKU), Austria.
J Proteomics. 2014 Aug 28;108:258-68. doi: 10.1016/j.jprot.2014.05.022. Epub 2014 Jun 4.
Bovine fetuin often finds use as a test model for analytical methods, but the exact occupancy of its O-glycosylation sites has not yet been determined. An obstacle for a closer inspection of the five or six O-glycosylation sites is the close spacing of several sites on the same tryptic peptide. The advent of ion-trap instruments with electron-transfer dissociation (ETD) capability and - for the type of instrument - high resolution prompted us to probe this technology for the investigation of the intricate posttranslational modifications O-glycosylation and phosphorylation. Much information could be obtained by direct-infusion ETD analysis of the fully sialylated tryptic 61-residue peptide harboring 8 hydroxyl amino acids of which four were indeed found to be, if only partially, glycosylated. The middle-down approach allowed recognizing an order of action of O-GalNAc transferase(s). No such hierarchy could be observed for phosphorylation. ETD fragmentation on an ion trap thus allowed in-depth analysis of a large, multiply O-glycosylated peptide, however, only by data accumulation over several minutes by direct infusion of a prefractionated sample. O-glycosylation and phosphorylation sites re-defined and their occupancy including that of N-glycans were defined by this study.
O-glycosylation of natural or recombinant proteins poses a challenge because of the lack of unambiguous consensus sites, the agglomeration of several O-glycans in close proximity and the lack of efficient O-glycosidases. Even bovine fetuin, a frequently used test glycoprotein for glycosylation analysis, has hitherto not been fully characterized in terms of site occupancy. This gap shall hereby be closed by application of electron-transfer dissociation mass spectroscopy.
牛胎球蛋白常被用作分析方法的测试模型,但其O-糖基化位点的确切占据情况尚未确定。仔细检查五六个O-糖基化位点的一个障碍是同一胰蛋白酶肽段上几个位点的紧密间距。具有电子转移解离(ETD)能力且(就该仪器类型而言)具有高分辨率的离子阱仪器的出现促使我们探索该技术,以研究复杂的翻译后修饰——O-糖基化和磷酸化。通过对包含8个羟基氨基酸的61个残基的完全唾液酸化胰蛋白酶肽段进行直接进样ETD分析,可以获得很多信息,其中4个羟基氨基酸确实被发现(即使只是部分)发生了糖基化。中向下方法允许识别O-GalNAc转移酶的作用顺序。对于磷酸化,未观察到这样的层次结构。因此,离子阱上的ETD碎片化允许对一个大的、多重O-糖基化肽段进行深入分析,然而,这仅通过直接进样预分级样品并在几分钟内积累数据来实现。本研究重新定义了O-糖基化和磷酸化位点,并确定了它们的占据情况,包括N-聚糖的占据情况。
天然或重组蛋白的O-糖基化是一个挑战,因为缺乏明确的共有位点、几个O-聚糖紧密聚集以及缺乏有效的O-糖苷酶。即使是牛胎球蛋白,一种常用于糖基化分析的测试糖蛋白,迄今为止在位点占据方面也尚未得到充分表征。本文将通过应用电子转移解离质谱法填补这一空白。
