脂质体包裹的 1-磷酸甘露糖疗法可改善不同先天性糖基化紊乱的全局 N-糖基化状况

IF 3.7 2区 生物学 Q2 ENDOCRINOLOGY & METABOLISM Molecular genetics and metabolism Pub Date : 2024-05-07 DOI:10.1016/j.ymgme.2024.108487
Rohit Budhraja , Silvia Radenkovic , Anu Jain , Irena J.J. Muffels , Moulay Hicham Alaoui Ismaili , Tamas Kozicz , Akhilesh Pandey , Eva Morava
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引用次数: 0

摘要

磷酸甘露糖突变酶 2(PMM2)可将 6-磷酸甘露糖转化为 1-磷酸甘露糖;甘露糖是糖基化生物合成途径的一个组成部分。PMM2 基因的致病变体已被证明与蛋白质糖基化不足有关,导致 PMM2 先天性糖基化紊乱(PMM2-CDG)。虽然甘露糖补充剂能改善体外糖基化,但不能改善体内糖基化,我们假设 1-磷酸甘露糖脂质体递送能增加活性糖的稳定性和递送,使其进入细胞的靶区。因此,我们研究了脂质体包裹的甘露糖-1-P(GLM101)对全局蛋白糖基化的影响,以及对PMM2-CDG患者和两种N-糖基化途径早期缺陷(即ALG2-CDG和ALG11-CDG)患者的皮肤成纤维细胞中细胞蛋白质组的影响。我们利用多重蛋白质组学和 N-糖蛋白组学研究了来自不同个体的成纤维细胞,这些成纤维细胞具有 PMM2、ALG2 和 ALG11 基因的各种致病变异。蛋白质组学数据显示,经 GLM101 处理后,所有 CDG 成纤维细胞中某些蛋白质的丰度发生了适度但显著的变化。另一方面,N-糖蛋白组学显示,在PMM2和ALG2基因缺陷的个体中,GLM101处理提高了许多细胞蛋白中几种高甘露糖和复合/杂交糖肽的表达水平。PMM2-CDG和ALG2-CDG中含有Man6和更高聚糖的糖肽都增加了数倍,而Man5和更小聚糖分子则减少了,这表明GLM101有助于形成成熟的糖型。无论基因变异情况如何,所有个体都能观察到蛋白质糖基化的这些变化。ALG11-CDG 成纤维细胞在治疗后也显示出高甘露糖糖肽的增加;然而,这种改善不如其他两种 CDG 那么显著。总之,我们的研究结果表明,用GLM101治疗可克服糖基化途径中的遗传阻滞,并可作为一种潜在的疗法,用于治疗在蛋白质N-糖基化早期步骤中存在酶缺陷的CDG。
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Liposome-encapsulated mannose-1-phosphate therapy improves global N-glycosylation in different congenital disorders of glycosylation

Phosphomannomutase 2 (PMM2) converts mannose-6-phospahate to mannose-1-phosphate; the substrate for GDP-mannose, a building block of the glycosylation biosynthetic pathway. Pathogenic variants in the PMM2 gene have been shown to be associated with protein hypoglycosylation causing PMM2-congenital disorder of glycosylation (PMM2-CDG). While mannose supplementation improves glycosylation in vitro, but not in vivo, we hypothesized that liposomal delivery of mannose-1-phosphate could increase the stability and delivery of the activated sugar to enter the targeted compartments of cells. Thus, we studied the effect of liposome-encapsulated mannose-1-P (GLM101) on global protein glycosylation and on the cellular proteome in skin fibroblasts from individuals with PMM2-CDG, as well as in individuals with two N-glycosylation defects early in the pathway, namely ALG2-CDG and ALG11-CDG. We leveraged multiplexed proteomics and N-glycoproteomics in fibroblasts derived from different individuals with various pathogenic variants in PMM2, ALG2 and ALG11 genes. Proteomics data revealed a moderate but significant change in the abundance of some of the proteins in all CDG fibroblasts upon GLM101 treatment. On the other hand, N-glycoproteomics revealed the GLM101 treatment enhanced the expression levels of several high-mannose and complex/hybrid glycopeptides from numerous cellular proteins in individuals with defects in PMM2 and ALG2 genes. Both PMM2-CDG and ALG2-CDG exhibited several-fold increase in glycopeptides bearing Man6 and higher glycans and a decrease in Man5 and smaller glycan moieties, suggesting that GLM101 helps in the formation of mature glycoforms. These changes in protein glycosylation were observed in all individuals irrespective of their genetic variants. ALG11-CDG fibroblasts also showed increase in high mannose glycopeptides upon treatment; however, the improvement was not as dramatic as the other two CDG. Overall, our findings suggest that treatment with GLM101 overcomes the genetic block in the glycosylation pathway and can be used as a potential therapy for CDG with enzymatic defects in early steps in protein N-glycosylation.

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来源期刊
Molecular genetics and metabolism
Molecular genetics and metabolism 生物-生化与分子生物学
CiteScore
5.90
自引率
7.90%
发文量
621
审稿时长
34 days
期刊介绍: Molecular Genetics and Metabolism contributes to the understanding of the metabolic and molecular basis of disease. This peer reviewed journal publishes articles describing investigations that use the tools of biochemical genetics and molecular genetics for studies of normal and disease states in humans and animal models.
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