Although the mechanisms that contribute to the development of traumatic brain injury (TBI)-related deficits are not fully understood, it has been proposed that altered energy utilization may be a contributing factor. The tuberous sclerosis complex, a heterodimer composed of hamartin/Tsc-1 and tuberin/Tsc-2, is a critical regulatory node that integrates nutritional and growth signals to govern energy using processes by regulating the activity of mechanistic Target of Rapamycin complex 1 (mTORC1). mTORC1 activation results in enhanced protein synthesis, an energy consuming process. We show that mice that have a heterozygous deletion of Tsc2 exhibit elevated basal mTORC1 activity in the cortex and the hippocampus while still exhibiting normal motor and neurocognitive functions. In addition, a mild closed head injury (mCHI) that did not activate mTORC1 in wild-type mice resulted in a further increase in mTORC1 activity in Tsc2+/KO mice above the level of activity observed in uninjured Tsc2+/KO mice. This enhanced level of increased mTORC1 activity was associated with worsened cognitive function as assessed using the Morris water maze and context discrimination tasks. These results suggest that there is a threshold of increased mTORC1 activity after a TBI that is detrimental to neurobehavioral performance, and interventions to inhibit excessive mTORC1 activation may be beneficial to neurocognitive outcome.
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机译:尽管导致创伤性脑损伤(TBI)相关缺陷发展的机制尚不完全清楚,但已提出改变能量利用可能是一个促成因素。结节性硬化复合物是由hamartin / Tsc-1和tuberin / Tsc-2组成的异二聚体,是一个关键的调节节点,通过调节雷帕霉素复合物1(mTORC1)的机械靶标的活性,整合营养和生长信号以利用过程控制能量)。 mTORC1激活可增强蛋白质合成,这是一个耗能的过程。我们显示具有Tsc2杂合缺失的小鼠在皮质和海马体中表现出升高的基础mTORC1活性,同时仍表现出正常的运动和神经认知功能。此外,未激活野生型小鼠中的mTORC1的轻度闭合性颅脑损伤(mCHI)导致Tsc2 + / KO 小鼠中mTORC1的活性进一步增加,高于未受伤的小鼠所观察到的活性水平。 Tsc2 + / KO 小鼠。如使用莫里斯水迷宫和情境歧视任务所评估的,mTORC1活动增加的这种增强水平与认知功能恶化有关。这些结果表明,TBI后存在mTORC1活性增加的阈值,这不利于神经行为表现,抑制mTORC1过度激活的干预措施可能对神经认知结局有益。
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