Pharmacological inhibition of astrocytic transglutaminase 2 facilitates the expression of a neurosupportive astrocyte reactive phenotype in association with increased histone acetylation.

Thomas Delgado, Jacen Emerson, Matthew Hong, Jeffrey W Keillor, Gail Vw Johnson
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Abstract

Astrocytes play critical roles in supporting structural and metabolic homeostasis in the central nervous system (CNS). CNS injury leads to the development of a range of reactive phenotypes in astrocytes whose molecular determinants are poorly understood. Finding ways to modulate astrocytic injury responses and leverage a pro-recovery phenotype holds promise in treating CNS injury. Recently, it has been demonstrated that ablation of astrocytic transglutaminase 2 (TG2) modulates the phenotype of reactive astrocytes in a way that improves neuronal injury outcomes both in vitro and in vivo. In an in vivo mouse model, pharmacological inhibition of TG2 with the irreversible inhibitor VA4 phenocopies the neurosupportive effects of TG2 deletion in astrocytes. In this study, we provide insights into the mechanisms by which TG2 deletion or inhibition result in a more neurosupportive astrocytic phenotype. Using a neuron-astrocyte co-culture model, we show that VA4 treatment improves the ability of astrocytes to support neurite outgrowth on an injury-relevant matrix. To better understand how pharmacologically altering TG2 affects its ability to regulate reactive astrocyte phenotypes, we assessed how VA4 inhibition impacts TG2's interaction with Zbtb7a, a transcription factor we have previously identified as a functionally relevant TG2 nuclear interactor. The results of these studies demonstrate that VA4 significantly decreases the interaction of TG2 and Zbtb7a. TG2's interactions with Zbtb7a, as well as a wide range of other transcription factors and chromatin regulatory proteins, suggest that TG2 may act as an epigenetic regulator to modulate gene expression. To begin to understand if TG2-mediated epigenetic modification may impact astrocytic phenotypes in our models, we interrogated the effect of TG2 deletion and VA4 treatment on histone acetylation and found significantly greater acetylation in both experimental groups. Consistent with these findings, previous RNA-sequencing and our present proteomic analysis also supported a predominant transcriptionally suppressive role of TG2 in astrocytes. Our proteomic data additionally unveiled pronounced changes in lipid and antioxidant metabolism in astrocytes with TG2 deletion or inhibition, which likely contribute to the enhanced neurosupportive function of these astrocytes.

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药理抑制星形胶质细胞转谷氨酰胺酶 2 可促进神经支持性星形胶质细胞反应表型的表达,同时增加组蛋白乙酰化。
星形胶质细胞在支持中枢神经系统(CNS)的结构和代谢平衡方面发挥着关键作用。中枢神经系统损伤会导致星形胶质细胞出现一系列反应表型,而星形胶质细胞的分子决定因素却鲜为人知。寻找调节星形胶质细胞损伤反应和利用促进恢复表型的方法有望治疗中枢神经系统损伤。最近有研究表明,消减星形胶质细胞转谷氨酰胺酶 2(TG2)可调节反应性星形胶质细胞的表型,从而改善体外和体内神经元损伤的结果。在一个体内小鼠模型中,用不可逆抑制剂 VA4 对 TG2 进行药理抑制,可以复制星形胶质细胞中 TG2 缺失对神经的支持作用。在本研究中,我们深入了解了 TG2 缺失或抑制导致神经支持性更强的星形胶质细胞表型的机制。通过神经元-星形胶质细胞共培养模型,我们发现 VA4 处理可提高星形胶质细胞在损伤相关基质上支持神经元生长的能力。为了更好地了解药理学上改变 TG2 如何影响其调节反应性星形胶质细胞表型的能力,我们评估了 VA4 抑制如何影响 TG2 与 Zbtb7a 的相互作用,Zbtb7a 是一种转录因子,我们之前已将其鉴定为功能相关的 TG2 核互作因子。这些研究结果表明,VA4 能显著降低 TG2 与 Zbtb7a 的相互作用。TG2与Zbtb7a以及其他多种转录因子和染色质调控蛋白的相互作用表明,TG2可能作为一种表观遗传调控因子调节基因表达。为了开始了解 TG2 介导的表观遗传修饰是否会影响我们模型中的星形胶质细胞表型,我们研究了 TG2 缺失和 VA4 处理对组蛋白乙酰化的影响,发现两个实验组的乙酰化程度都显著增加。与这些发现一致的是,先前的 RNA 序列分析和我们目前的蛋白质组分析也支持 TG2 在星形胶质细胞中的主要转录抑制作用。我们的蛋白质组数据还揭示了 TG2 缺失或抑制后星形胶质细胞中脂质和抗氧化剂代谢的明显变化,这可能是这些星形胶质细胞神经支持功能增强的原因。
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