Analysis of the neuromuscular deficits caused by STAM1 deficiency

John W. McLean , Mary VanHart , Madilyn P. McWilliams , Charlene B. Farmer , David K. Crossman , Rita M. Cowell , Julie A. Wilson , Scott M. Wilson
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Abstract

The endosomal sorting complexes required for transport (ESCRT) pathway is composed of a series of protein complexes that are essential for sorting cargo through the endosome. In neurons, the ESCRT pathway is a key mediator of many cellular pathways that regulate neuronal morphogenesis as well as synaptic growth and function. The ESCRT-0 complex, consisting of HGS (hepatocyte growth factor-regulated tyrosine kinase substrate) and STAM (signal-transducing adaptor molecule), acts as a gate keeper to this pathway, ultimately determining the fate of the endosomal cargo. We previously showed that a single nucleotide substitution in Hgs results in structural and functional changes in the nervous system of teetering mice. To determine if these changes occurred as a function of HGS's role in the ESCRT pathway and its association with STAM1, we investigated if STAM1 deficiency also leads to a similar impairment of the nervous system. In contrast to teetering mice that die within 5 weeks of age and exhibit reduced body mass, 1-month-old Stam1 knockout mice were not visibly different from controls. However, by 3 months of age, STAM1 deficiency caused reduced muscle mass, strength, and motor performance. These changes in motor function did not correlate with either a loss in motor neuron number or abnormal myelination of peripheral nerves. Instead, the motor endplate structure was altered in the Stam1 knockout mice by 1 month of age and continued to degenerate over time, correlating with a significant reduction in muscle fiber size and increased expression of the embryonic γ acetylcholine receptor (AChR) subunit at 3 months of age. There was also a significant reduction in the levels of two presynaptic SNARE proteins, VTI1A and VAMP2, in the motor neurons of the Stam1 knockout mice. As loss of STAM1 expression replicates many of the structural changes at the motor endplates that we have previously reported with loss of HGS, these results suggest that the HGS/STAM1 complex plays a critical role in maintaining synaptic structure and function in the mammalian nervous system.

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分析 STAM1 缺乏症导致的神经肌肉缺陷
运输所需的内质体分拣复合物(ESCRT)途径由一系列蛋白质复合物组成,这些复合物对于通过内质体分拣货物至关重要。在神经元中,ESCRT 通路是许多细胞通路的关键媒介,这些通路调节神经元的形态发生以及突触的生长和功能。ESCRT-0复合物由HGS(肝细胞生长因子调控的酪氨酸激酶底物)和STAM(信号转导适配分子)组成,是该通路的守门员,最终决定内体货物的命运。我们以前的研究表明,Hgs 的单核苷酸置换会导致跷足小鼠神经系统的结构和功能发生变化。为了确定这些变化的发生是否与 HGS 在 ESCRT 通路中的作用及其与 STAM1 的关联有关,我们研究了 STAM1 缺乏是否也会导致神经系统的类似损伤。与5周龄内死亡并表现出体重减轻的跷足小鼠相比,1月龄的Stam1基因敲除小鼠与对照组没有明显差异。然而,到了 3 个月大时,STAM1 基因缺失会导致肌肉质量、力量和运动能力下降。运动功能的这些变化与运动神经元数量的减少或外周神经髓鞘化异常无关。相反,Stam1基因敲除小鼠的运动终板结构在1月龄时发生了改变,并随着时间的推移继续退化,这与3月龄时肌纤维尺寸显著缩小和胚胎γ乙酰胆碱受体(AChR)亚基表达增加有关。在 Stam1 基因敲除小鼠的运动神经元中,两种突触前 SNARE 蛋白 VTI1A 和 VAMP2 的水平也明显下降。由于 STAM1 表达的缺失复制了我们之前报道的 HGS 缺失时运动终板的许多结构变化,这些结果表明 HGS/STAM1 复合物在维持哺乳动物神经系统的突触结构和功能方面起着至关重要的作用。
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