Department of Pediatrics, Medical University of Graz, Graz, Austria.
Mol Genet Metab. 2010 Jul;100(3):262-8. doi: 10.1016/j.ymgme.2010.03.019. Epub 2010 Mar 28.
G(M1)-gangliosidosis (GM1) and Morquio B disease (MBD) are rare lysosomal storage disorders caused by mutations in the gene GLB1. Its main gene product, human acid beta-galactosidase (beta-Gal) degrades two functionally important molecules, G(M1)-ganglioside and keratan sulfate in brain and connective tissues, respectively. While GM1 is a severe, phenotypically heterogenous neurodegenerative disorder, MBD is a systemic bone disease without effects on the central nervous system. A MBD-specific mutation, p.W273L, was shown to produce stable beta-Gal precursors, normally transported and processed to mature, intralysosomal beta-Gal. In accordance with the MBD phenotype, elevated residual activity against G(M1)-ganglioside, but strongly reduced affinity towards keratan sulfate was found. Most GM1 alleles, in contrast, were shown to affect precursor stability and intracellular transport. Specific alleles, p.R201C and p.R201H result in misfolded, unstable precursor proteins rapidly degraded by endoplasmic reticulum-associated protein degradation (ERAD). They may therefore be sensitive to stabilization by small molecules which bind at the active site and provide proper conformation. Thus the stabilized protein may escape from ERAD processes, and reach the lysosomes in an active state, as proposed for enzyme enhancement therapy (EET). This paper demonstrates that a novel iminosugar, DLHex-DGJ, has potent effects as competitive inhibitor of human acid beta-galactosidase in vitro, and describes its effects on activity, protein expression, maturation and intracellular transport in vivo in 13 fibroblasts lines with GLB1 mutations. Beside p.R201C and p.R201H, two further alleles, p.C230R and p.G438E, displayed significant sensitivity against DLHex-DGJ, with an increase of catalytic activity, and a normalization of transport and lysosomal processing of beta-Gal precursors.
GM1 神经节苷脂贮积症(GM1)和莫尔奎氏 B 型黏多糖贮积症(MBD)是由 GLB1 基因突变引起的两种罕见溶酶体贮积症。其主要基因产物,人酸性β-半乳糖苷酶(β-Gal)分别降解脑和结缔组织中两种具有重要功能的分子,GM1-神经节苷脂和硫酸角质素。GM1 是一种严重的、表型异质性神经退行性疾病,而 MBD 是一种系统性骨病,对中枢神经系统没有影响。研究表明,MBD 特异性突变 p.W273L 产生稳定的β-Gal 前体,这些前体通常被转运并加工成成熟的、溶酶体内的β-Gal。与 MBD 表型一致,发现对 GM1-神经节苷脂的残留活性升高,但对硫酸角质素的亲和力明显降低。相比之下,大多数 GM1 等位基因被证明会影响前体的稳定性和细胞内转运。特定的等位基因,p.R201C 和 p.R201H 导致错误折叠、不稳定的前体蛋白被内质网相关蛋白降解(ERAD)迅速降解。因此,它们可能对结合在活性部位并提供适当构象的小分子稳定剂敏感。这样,稳定的蛋白可能会逃避 ERAD 过程,并以活性状态到达溶酶体,正如酶增强治疗(EET)所提出的那样。本文证明了一种新型亚氨基糖,DLHex-DGJ,在体外对人酸性β-半乳糖苷酶具有很强的竞争性抑制作用,并描述了它对 13 种带有 GLB1 突变的成纤维细胞系中β-Gal 前体的活性、蛋白表达、成熟和细胞内转运的影响。除了 p.R201C 和 p.R201H 之外,另外两个等位基因 p.C230R 和 p.G438E 对 DLHex-DGJ 也表现出显著的敏感性,催化活性增加,并使β-Gal 前体的转运和溶酶体加工正常化。
