Department of Neurology, Ulm University, Ulm, Germany.
J Neurochem. 2021 May;157(4):1284-1299. doi: 10.1111/jnc.15237. Epub 2020 Dec 3.
Diminished glutamate (Glu) uptake via the excitatory amino acid transporter EAAT2, which normally accounts for ~90% of total forebrain EAAT activity, may contribute to neurodegeneration via Glu-mediated excitotoxicity. C-terminal cleavage by caspase-3 (C3) was reported to mediate EAAT2 inactivation and down-regulation in the context of neurodegeneration. For a detailed analysis of C3-dependent EAAT2 degradation, we employed A172 glioblastoma as well as hippocampal HT22 cells and murine astrocytes over-expressing VSV-G-tagged EAAT2 constructs. C3 activation was induced by staurosporine (STR). In HT22 cells, STR-induced C3 activation-induced rapid EAAT2 protein degradation. The mutation of asparagine 504 to aspartate (D504N), which should inactivate the putative C3 cleavage site, increased EAAT2 activity in A172 cells. In contrast, the D504N mutation did not protect EAAT2 protein against STR-induced degradation in HT22 cells, whereas inhibition of caspases, ubiquitination and the proteasome did. Similar results were obtained in astrocytes. Phylogenetic analysis showed that C-terminal ubiquitin acceptor sites-but not the putative C3 cleavage site-exhibit a high degree of conservation. Moreover, C-terminal truncation mimicking C3 cleavage increased rather than decreased EAAT2 activity and stability as well as protected EAAT2 against STR-induced ubiquitination-dependent degradation. We conclude that cellular stress associated with endogenous C3 activation degrades EAAT2 via a pathway involving ubiquitination and the proteasome but not direct C3-mediated cleavage. In addition, C3 cleavage of EAAT2, described to occur in other models, is unlikely to inactivate EAAT2. However, mutation of the highly conserved D504 within the putative C3 cleavage site increases EAAT2 activity via an unknown mechanism.
谷氨酸(Glu)摄取减少通过兴奋性氨基酸转运体 EAAT2,这通常占~90%的总大脑前 EAAT 活性,可能通过 Glu 介导的兴奋性毒性导致神经退行性变。半胱氨酸蛋白酶-3(C3)的 C 端切割被报道介导 EAAT2 失活和下调在神经退行性变的情况下。对于 C3 依赖性 EAAT2 降解的详细分析,我们采用了 A172 神经胶质瘤以及海马 HT22 细胞和过表达 VSV-G 标记的 EAAT2 构建体的小鼠星形胶质细胞。C3 的激活是由 staurosporine(STR)诱导的。在 HT22 细胞中,STR 诱导的 C3 激活导致 EAAT2 蛋白快速降解。将天冬酰胺 504 突变为天冬氨酸(D504N),应该使潜在的 C3 切割位点失活,增加了 A172 细胞中的 EAAT2 活性。相反,D504N 突变不能保护 EAAT2 蛋白免受 STR 诱导的 HT22 细胞降解,而 caspase、泛素化和蛋白酶体的抑制则可以。在星形胶质细胞中也得到了类似的结果。系统发育分析表明,C 端泛素受体位点 - 而不是潜在的 C3 切割位点 - 表现出高度的保守性。此外,模拟 C3 切割的 C 端截断增加而不是降低 EAAT2 的活性和稳定性,并保护 EAAT2 免受 STR 诱导的依赖泛素化的降解。我们得出结论,与内源性 C3 激活相关的细胞应激通过涉及泛素化和蛋白酶体但不直接 C3 介导的切割的途径降解 EAAT2。此外,在其他模型中描述的 EAAT2 的 C3 切割不太可能使 EAAT2 失活。然而,在潜在的 C3 切割位点内高度保守的 D504 的突变通过未知机制增加了 EAAT2 的活性。
