Astrocyte HIF-2α supports learning in a passive avoidance paradigm under hypoxic stress.

Hypoxia (Auckland, N.Z.) Pub Date : 2018-11-08 eCollection Date: 2018-01-01 DOI:10.2147/HP.S173589
Cindy V Leiton, Elyssa Chen, Alissa Cutrone, Kristy Conn, Kennelia Mellanson, Dania M Malik, Michael Klingener, Ryan Lamm, Michael Cutrone, John Petrie, Joher Sheikh, Adriana DiBua, Betsy Cohen, Thomas F Floyd
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Abstract

Background: The brain is extensively vascularized, useŝ20% of the body's oxygen, and is highly sensitive to changes in oxygen. While synaptic plasticity and memory are impaired in healthy individuals by exposure to mild hypoxia, aged individuals appear to be even more sensitive. Aging is associated with progressive failure in pulmonary and cardiovascular systems, exposing the aged to both chronic and superimposed acute hypoxia. The HIF proteins, the "master regulators" of the cellular response to hypoxia, are robustly expressed in neurons and astrocytes. Astrocytes support neurons and synaptic plasticity via complex metabolic and trophic mechanisms. The activity of HIF proteins in the brain is diminished with aging, and the increased exposure to chronic and acute hypoxia with aging combined with diminished HIF activity may impair synaptic plasticity.

Purpose: Herein, we test the hypothesis that astrocyte HIF supports synaptic plasticity and learning upon hypoxia.

Materials and methods: An Astrocyte-specific HIF loss-of-function model was employed, where knock-out of HIF-1α or HIF-2α in GFAP expressing cells was accomplished by cre-mediated recombination. Animals were tested for behavioral (open field and rotarod), learning (passive avoidance paradigm), and electrophysiological (long term potentiation) responses to mild hypoxic challenge.

Results: In an astrocyte-specific HIF loss-of-function model followed by mild hypoxia, we identified that the depletion of HIF-2α resulted in an impaired passive avoidance learning performance. This was accompanied by an attenuated response to induction in long-term potentiation (LTP), suggesting that the hippocampal circuitry was perturbed upon hypoxic exposure following HIF-2α loss in astrocytes, and not due to hippocampal cell death. We investigated HIF-regulated trophic and metabolic target genes and found that they were not regulated by HIF-2α, suggesting that these specific targets may not be involved in mediating the phenotypes observed.

Conclusion: Together, these results point to a role for HIF-2α in the astrocyte's regulatory role in synaptic plasticity and learning under hypoxia and suggest that even mild, acute hypoxic challenges can impair cognitive performance in the aged population who harbor impaired HIF function.

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星形胶质细胞HIF-2α支持缺氧应激下被动回避模式下的学习。
背景:大脑广泛血管化,使用人体20%的氧气,对氧气的变化高度敏感。虽然健康人的突触可塑性和记忆会因轻度缺氧而受损,但老年人似乎更敏感。衰老与肺和心血管系统的进行性衰竭有关,使老年人暴露在慢性和叠加急性缺氧中。HIF蛋白是细胞对缺氧反应的“主要调节因子”,在神经元和星形胶质细胞中强烈表达。星形胶质细胞通过复杂的代谢和营养机制支持神经元和突触可塑性。大脑中HIF蛋白的活性随着年龄的增长而降低,随着年龄的增加,暴露于慢性和急性缺氧的程度增加,再加上HIF活性的降低,可能会损害突触的可塑性。目的:在此,我们验证了星形胶质细胞HIF支持缺氧时突触可塑性和学习的假设。材料和方法:采用星形胶质细胞特异性HIF功能丧失模型,通过cre介导的重组来敲除表达GFAP的细胞中的HIF-1α或HIF-2α。测试动物对轻度缺氧挑战的行为(开阔场地和旋转杆)、学习(被动回避范式)和电生理(长时程增强)反应。结果:在星形胶质细胞特异性HIF功能丧失伴轻度缺氧的模型中,我们发现HIF-2α的耗竭导致被动回避学习能力受损。这伴随着对长时程增强(LTP)诱导的反应减弱,表明星形胶质细胞中HIF-1α缺失后缺氧暴露会扰乱海马回路,而不是由于海马细胞死亡。我们研究了HIF调节的营养和代谢靶基因,发现它们不受HIF-2α的调节,这表明这些特异性靶可能与介导观察到的表型无关。结论:总之,这些结果表明HIF-2α在星形胶质细胞在缺氧条件下突触可塑性和学习的调节作用中发挥作用,并表明即使是轻度、急性缺氧挑战也会损害HIF功能受损的老年人的认知能力。
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