Department of Medical Biochemistry, Leiden Institute of Chemistry, Leiden University, The Netherlands.
Department of Medical Biochemistry, Academic Medical Center, Amsterdam, The Netherlands.
J Lipid Res. 2021;62:100018. doi: 10.1194/jlr.RA120001043. Epub 2021 Jan 6.
Deficiency of glucocerebrosidase (GBA), a lysosomal β-glucosidase, causes Gaucher disease. The enzyme hydrolyzes β-glucosidic substrates and transglucosylates cholesterol to cholesterol-β-glucoside. Here we show that recombinant human GBA also cleaves β-xylosides and transxylosylates cholesterol. The xylosyl-cholesterol formed acts as an acceptor for the subsequent formation of di-xylosyl-cholesterol. Common mutant forms of GBA from patients with Gaucher disease with reduced β-glucosidase activity were similarly impaired in β-xylosidase, transglucosidase, and transxylosidase activities, except for a slightly reduced xylosidase/glucosidase activity ratio of N370S GBA and a slightly reduced transglucosylation/glucosidase activity ratio of D409H GBA. XylChol was found to be reduced in spleen from patients with Gaucher disease. The origin of newly identified XylChol in mouse and human tissues was investigated. Cultured human cells exposed to exogenous β-xylosides generated XylChol in a manner dependent on active lysosomal GBA but not the cytosol-facing β-glucosidase GBA2. We later sought an endogenous β-xyloside acting as donor in transxylosylation reactions, identifying xylosylated ceramide (XylCer) in cells and tissues that serve as donor in the formation of XylChol. UDP-glucosylceramide synthase (GCS) was unable to synthesize XylChol but could catalyze the formation of XylCer. Thus, food-derived β-D-xyloside and XylCer are potential donors for the GBA-mediated formation of XylChol in cells. The enzyme GCS produces XylCer at a low rate. Our findings point to further catalytic versatility of GBA and prompt a systematic exploration of the distribution and role of xylosylated lipids.
葡萄糖脑苷脂酶(GBA)的缺乏会导致戈谢病,这是一种溶酶体β-葡萄糖苷酶。该酶水解β-葡萄糖苷底物,并将胆固醇转葡糖基化形成胆固醇-β-葡萄糖苷。在这里,我们表明重组人 GBA 也能切割β-木糖苷并将胆固醇转木糖苷化。形成的木糖胆固醇可作为随后形成二木糖胆固醇的受体。戈谢病患者常见的 GBA 突变体形式,其β-葡萄糖苷酶活性降低,β-木糖苷酶、转葡糖基酶和转木糖苷酶活性也同样受损,除了 N370S GBA 的木糖苷酶/葡萄糖苷酶活性比略有降低,D409H GBA 的转葡糖基化/葡萄糖苷酶活性比略有降低。在戈谢病患者的脾脏中发现了木糖胆固醇的减少。我们研究了新发现的木糖胆固醇在小鼠和人组织中的来源。暴露于外源性β-木糖苷的培养人细胞以依赖于活性溶酶体 GBA 但不依赖于质膜面向的β-葡萄糖苷酶 GBA2 的方式生成木糖胆固醇。我们后来在转木糖苷化反应中寻找作为供体的内源性β-木糖苷,在细胞和组织中鉴定出作为木糖胆固醇形成供体的木糖化神经酰胺(XylCer)。UDP-葡萄糖神经酰胺合酶(GCS)不能合成木糖胆固醇,但可以催化 XylCer 的形成。因此,食物来源的β-D-木糖苷和 XylCer 是 GBA 介导的细胞中木糖胆固醇形成的潜在供体。酶 GCS 以低速率产生 XylCer。我们的发现指出了 GBA 的进一步催化多功能性,并促使对木糖化脂质的分布和作用进行系统探索。
