Na Zhang, Fuchen Liu, Yuying Zhao, Xiaohan Sun, Bing Wen, Jian-qiang Lu, Chuanzhu Yan, Duoling Li
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Abstract
Pompe disease is a lysosomal storage disorder that preferentially affects muscles, and it is caused by GAA mutation coding acid alpha-glucosidase in lysosome and glycophagy deficiency. While the initial pathology of Pompe disease is glycogen accumulation in lysosomes, the special role of the lysosomal pathway in glycogen degradation is not fully understood. Hence, we investigated the characteristics of accumulated glycogen and the mechanism underlying glycophagy disturbance in Pompe disease. Skeletal muscle specimens were obtained from the affected sites of patients and mouse models with Pompe disease. Histological analysis, immunoblot analysis, immunofluorescence assay, and lysosome isolation were utilized to analyze the characteristics of accumulated glycogen. Cell culture, lentiviral infection, and the CRISPR/Cas9 approach were utilized to investigate the regulation of glycophagy accumulation. We demonstrated residual glycogen, which was distinguishable from mature glycogen by exposed glycogenin and more α-amylase resistance, accumulated in the skeletal muscle of Pompe disease. Lysosome isolation revealed glycogen-free glycogenin in wild type mouse lysosomes and variously sized glycogenin in Gaa −/− mouse lysosomes. Our study identified that a defect in the degradation of glycogenin-exposed residual glycogen in lysosomes was the fundamental pathological mechanism of Pompe disease. Meanwhile, glycogenin-exposed residual glycogen was absent in other glycogen storage diseases caused by cytoplasmic glycogenolysis deficiencies. In vitro , the generation of residual glycogen resulted from cytoplasmic glycogenolysis. Notably, the inhibition of glycogen phosphorylase led to a reduction in glycogenin-exposed residual glycogen and glycophagy accumulations in cellular models of Pompe disease. Therefore, the lysosomal hydrolysis pathway played a crucial role in the degradation of residual glycogen into glycogenin, which took place in tandem with cytoplasmic glycogenolysis. These findings may offer a novel substrate reduction therapeutic strategy for Pompe disease. © 2024 The Pathological Society of Great Britain and Ireland.
溶酶体中糖原蛋白暴露的残余糖原降解缺陷是庞贝氏症的基本病理机制。
庞贝氏症是一种溶酶体贮积症,好发于肌肉,是由溶酶体中编码酸性α-葡萄糖苷酶的GAA突变和糖吞噬缺陷引起的。虽然庞贝病的最初病理变化是溶酶体中的糖原累积,但溶酶体途径在糖原降解中的特殊作用尚未完全明了。因此,我们研究了庞贝氏症中积累的糖原的特征和糖吞噬障碍的机制。我们从庞贝病患者和小鼠模型的患病部位获取了骨骼肌标本。利用组织学分析、免疫印迹分析、免疫荧光检测和溶酶体分离来分析累积糖原的特征。我们利用细胞培养、慢病毒感染和 CRISPR/Cas9 方法研究了糖原累积的调控。我们发现在庞贝氏症患者的骨骼肌中积累了残余糖原,它与成熟糖原的区别在于暴露的糖原蛋白和更多的α-淀粉酶抗性。溶酶体分离显示,野生型小鼠溶酶体中不含糖原的糖原蛋白,而 Gaa-/- 小鼠溶酶体中的糖原蛋白大小不一。我们的研究发现,溶酶体中暴露于糖原蛋白的残留糖原降解缺陷是庞贝氏症的基本病理机制。同时,在其他由细胞质糖原分解缺陷引起的糖原贮积病中,糖原蛋白暴露的残留糖原并不存在。在体外,残留糖原的产生是细胞质糖原分解的结果。值得注意的是,在庞贝氏症的细胞模型中,抑制糖原磷酸化酶可减少糖原蛋白暴露的残留糖原和糖噬积。因此,溶酶体水解途径在将残余糖原降解为糖原蛋白的过程中发挥了至关重要的作用,这种降解与细胞质糖原分解同步进行。这些发现可能会为庞贝氏症提供一种新的减少底物的治疗策略。© 2024 大不列颠及爱尔兰病理学会。
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