Regional health and function in the hippocampus: Evolutionary compromises for a critical brain region

Bioscience hypotheses Pub Date : 2009-01-01 DOI:10.1016/j.bihy.2009.02.013

Travis C. Jackson, Thomas C. Foster

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引用次数: 15

Abstract

The hippocampus is especially vulnerable to damage caused by metabolic dysregulation. However distinct sub-regions within the hippocampus differ by their relative susceptibility to such damage. Region CA1 pyramidal neurons are most sensitive to metabolic perturbations while region CA3 pyramidal neurons show more resistance, and these unique profiles of susceptibility are but one example that differentiates CA1/CA3 neurons. We present here a hypothesis that inextricably links the unique biochemistries of learning and memory in region CA1, to that of cell survival signaling, and in so doing, suggest an explanation for region CA1 susceptibility to metabolic dysfunction. Further, we propose a signaling mechanism to explain how both pathways can be simultaneously regulated. Critical to this process is the protein phosphatase PHLPP1. Finally we discuss the implications of this hypothesis and the inherent challenges it poses for treatment of neurological disorders resulting in reduced hippocampal function by increased neuron death.

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海马体的区域健康和功能:一个关键大脑区域的进化妥协

海马体特别容易受到代谢失调引起的损伤。然而，海马体中不同的子区域对这种损伤的相对易感性不同。CA1区锥体神经元对代谢扰动最敏感，而CA3区锥体神经元表现出更强的抵抗力，这些独特的易感性特征只是CA1/CA3神经元分化的一个例子。我们在这里提出了一个假设，将CA1区域独特的学习和记忆的生物化学与细胞生存信号的生物化学不可分割地联系起来，并以此为CA1区域对代谢功能障碍的易感性提供了解释。此外，我们提出了一种信号机制来解释如何同时调节这两种途径。这个过程的关键是蛋白磷酸酶PHLPP1。最后，我们讨论了这一假设的含义，以及它对神经系统疾病的治疗提出的固有挑战，这些疾病通过增加神经元死亡导致海马功能降低。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bioscience hypotheses

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