Bao WanXue, Yamasaki Takahiro, Nakano Miyako, Nagae Masamichi, Kizuka Yasuhiko
Institute for Glyco-core Research (iGCORE), Gifu University, Gifu 501-1193, Japan.
Graduate School of Integrated Sciences for Life, Hiroshima University, Higashihiroshima 739-8530, Japan.
Biochim Biophys Acta Gen Subj. 2025 Jan;1869(1):130734. doi: 10.1016/j.bbagen.2024.130734. Epub 2024 Dec 9.
N-Glycan branching modulates the diversity of protein functions. β1,4-N-acetylglucosaminyltransferase III (GnT-III or MGAT3) produces a unique GlcNAc branch, "bisecting GlcNAc", in N-glycans, and is involved in Alzheimer's disease and cancer. However, the 3D structure and catalytic mechanism of GnT-III are unclear. According to AlphaFold-based structure prediction, GnT-III likely contains two putative disordered segments, a long middle loop (Loop) and a C-terminal tail (Tail). We hypothesized that these segments play important roles in regulating the activity or intracellular behaviors of GnT-III.
We expressed wild-type GnT-III (GnT-III-WT), GnT-III-Loop- and -Tail-deletion mutants in cells. Their in vitro catalytic activity and glycan biosynthesis in cells were examined using high-performance liquid chromatography, UDP-Glo glycosyltransferase assays, and glycomic analysis. Subcellular localization of WT and GnT-III mutants was investigated by immunostaining, and degradation rate and secretion were also examined.
The Loop-deletion mutant had higher in vitro and in cellulo activity than GnT-III-WT, indicating that Loop suppresses catalytic activity. In contrast, the Tail-deletion mutant showed weaker activity, increased ER localization, and faster degradation than GnT-III-WT, indicating that Tail is required for proper folding. In addition, deletion of Loop led to aberrant shedding of GnT-III, indicating that Loop contains the cleavage site or regulates GnT-III shedding.
Loop and Tail of GnT-III play important roles in catalytic activity, folding and shedding.
Our results provide further understanding of the catalysis and shedding mechanisms of GnT-III and can help in the development of methods for modifying the levels of bisecting GlcNAc on glycoproteins and in cells.
N-聚糖分支调节蛋白质功能的多样性。β1,4-N-乙酰氨基葡萄糖转移酶III(GnT-III或MGAT3)在N-聚糖中产生独特的GlcNAc分支“平分型GlcNAc”,并与阿尔茨海默病和癌症有关。然而,GnT-III的三维结构和催化机制尚不清楚。根据基于AlphaFold的结构预测,GnT-III可能包含两个假定的无序片段,一个长的中间环(环)和一个C末端尾巴(尾巴)。我们假设这些片段在调节GnT-III的活性或细胞内行为中起重要作用。
我们在细胞中表达野生型GnT-III(GnT-III-WT)、GnT-III环和尾巴缺失突变体。使用高效液相色谱、UDP-Glo糖基转移酶测定和糖组学分析检测它们在体外的催化活性和细胞内的聚糖生物合成。通过免疫染色研究WT和GnT-III突变体的亚细胞定位,并检测降解率和分泌情况。
环缺失突变体在体外和细胞内的活性高于GnT-III-WT,表明环抑制催化活性。相反,尾巴缺失突变体的活性较弱,内质网定位增加,降解速度比GnT-III-WT快,表明尾巴是正确折叠所必需的。此外,环的缺失导致GnT-III异常脱落,表明环包含切割位点或调节GnT-III的脱落。
GnT-III的环和尾巴在催化活性、折叠和脱落中起重要作用。
我们的结果进一步阐明了GnT-III的催化和脱落机制,并有助于开发调节糖蛋白和细胞中平分型GlcNAc水平的方法。
