Graduate School of Life Science and Research Center for Post-Genome Science and Technology, Hokkaido University, Sapporo 001-0021, Japan.
Biochemistry. 2010 Jul 20;49(28):5929-41. doi: 10.1021/bi100623g.
UDP-GalNAc:polypeptide alpha-N-acetylgalactosaminyltransferases (ppGalNAcTs, EC 2.4.1.41), a family of key enzymes that initiate posttranslational modification with O-glycans in mucin synthesis by introduction of alpha-GalNAc residues, are structurally composed of a catalytic domain and a lectin domain. It has been known that multiple Ser/Thr residues are assigned in common mucin glycoproteins as potential O-glycosylation sites and more than 20 distinct isoforms of this enzyme family contribute to produce densely O-glycosylated mucin glycoproteins. However, it seems that the functional role of the lectin domain of ppGalNAcTs remains unclear. We considered that electron capture dissociation mass spectrometry (ECD-MS), a promising method for highly selective fragmentation at peptide linkages of glycopeptides to generate unique c and z series of ions, should allow for precise structural characterization to uncover the mechanism in O-glycosylation of mucin peptides by ppGalNAcTs. In the present study, it was demonstrated that a system composed of an electrospray source, a linear RFQ ion trap that isolates precursor ions, the ECD device, and a TOF mass spectrometer is a nice tool to identify the preferential O-glycosylation sites without any decomposition of the carbohydrate moiety. It should be noted that electrons used for ECD are accelerated within a range from 1.75 to 9.75 eV depending on the structures of glycopeptides of interest. We revealed for the first time that additional installation of a alpha-GalNAc residue at potential glycosylation sites by ppGalNAcT2 proceeds smoothly in various unnatural glycopeptides having alpha-Man, alpha-Fuc, and beta-Gal residues as well as alpha-GalNAc residues. The results may suggest that ppGalNAcT2 did not differentiate totally presubstituted sugar residues in terms of configuration of functional groups, d-, l-configuration, and even alpha-, beta-stereochemistry at an anomeric carbon atom when relatively short synthetic peptides were employed for the acceptor substrates. Unexpected characteristics of ppGalNAcT2 motivated us to challenge site-directed installation of alpha-GalNAc residues at desired position(s) by protecting some hydroxyl groups of Thr/Ser residues with selectively removable sugars, notably a novel concept as "carbohydrate as protective groups", toward a goal of the systematic chemical and enzymatic synthesis of biologically important mucin glycopeptides.
UDP-GalNAc:多肽α-N-乙酰半乳糖胺转移酶(ppGalNAcTs,EC 2.4.1.41)是一类关键酶,通过引入α-GalNAc 残基,在粘蛋白合成中启动 O-聚糖的翻译后修饰,其结构由催化结构域和凝集素结构域组成。已知在共同的粘蛋白糖蛋白中,多个 Ser/Thr 残基被指定为潜在的 O-糖基化位点,并且该酶家族的 20 多种不同同工型有助于产生高度 O-糖基化的粘蛋白糖蛋白。然而,ppGalNAcTs 的凝集素结构域的功能作用似乎仍不清楚。我们认为,电子俘获解离质谱(ECD-MS)是一种很有前途的方法,可高度选择性地在糖肽的肽键处进行断裂,产生独特的 c 和 z 系列离子,这应该允许进行精确的结构表征,以揭示 ppGalNAcTs 对粘蛋白肽进行 O-糖基化的机制。在本研究中,我们证明了由电喷雾源、线性 RFQ 离子阱(用于分离前体离子)、ECD 装置和 TOF 质谱仪组成的系统是一种很好的工具,可在不分解碳水化合物部分的情况下识别优先的 O-糖基化位点。值得注意的是,用于 ECD 的电子在 1.75 到 9.75 eV 的范围内加速,具体取决于感兴趣的糖肽的结构。我们首次揭示,ppGalNAcT2 在具有α-Man、α-Fuc 和β-Gal 残基以及α-GalNAc 残基的各种非天然糖肽中,在潜在的糖基化位点上顺利地添加额外的α-GalNAc 残基。结果表明,当使用相对较短的合成肽作为受体底物时,ppGalNAcT2 并没有完全区分糖基化残基的取代基团在功能基团的构型、d-、l-构型、甚至在端基碳原子的α-、β-立体化学方面的差异。ppGalNAcT2 的意外特性促使我们通过用选择性可去除的糖保护 Thr/Ser 残基的一些羟基来挑战在所需位置(多个)定点安装α-GalNAc 残基,这是一种“糖作为保护基团”的新概念,是实现生物重要粘蛋白糖肽的系统化学和酶促合成的目标。
