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衰老和慢性应激恢复后雌性 Sprague Dawley 大鼠神经塑性蛋白环境失调。

Disarranged neuroplastin environment upon aging and chronic stress recovery in female Sprague Dawley rats.

机构信息

Department of Medical Biology and Genetics, Faculty of Medicine, J. J. Strossmayer University of Osijek, Osijek, Croatia.

Department of Biology, J. J. Strossmayer University of Osijek, Osijek, Croatia.

出版信息

Eur J Neurosci. 2022 May;55(9-10):2474-2490. doi: 10.1111/ejn.15256. Epub 2021 May 14.

DOI:10.1111/ejn.15256
PMID:33909305
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9290558/
Abstract

Chronic stress produces long-term metabolic changes throughout the superfamily of nuclear receptors, potentially causing various pathologies. Sex hormones modulate the stress response and generate a sex-specific age-dependent metabolic imprint, especially distinct in the reproductive senescence of females. We monitored chronic stress recovery in two age groups of female Sprague Dawley rats to determine whether stress and/or aging structurally changed the glycolipid microenvironment, a milieu playing an important role in cognitive functions. Old females experienced memory impairment even at basal conditions, which was additionally amplified by stress. On the other hand, the memory of young females was not disrupted. Stress recovery was followed by a microglial decrease and an increase in astrocyte count in the hippocampal immune system. Since dysfunction of the brain immune system could contribute to disturbed synaptogenesis, we analyzed neuroplastin expression and the lipid environment. Neuroplastin microenvironments were explored by analyzing immunofluorescent stainings using a newly developed Python script method. Stress reorganized glycolipid microenvironment in the Cornu Ammonis 1 (CA1) and dentate gyrus (DG) hippocampal regions of old females but in a very different fashion, thus affecting neuroplasticity. The postulation of four possible neuroplastin environments pointed to the GD1a ganglioside enrichment during reproductive senescence of stressed females, as well as its high dispersion in both regions and to GD1a and GM1 loss in the CA1 region. A specific lipid environment might influence neuroplastin functionality and underlie synaptic dysfunction triggered by a combination of aging and chronic stress.

摘要

慢性应激会在核受体超家族中产生长期的代谢变化,从而可能导致各种病理变化。性激素调节应激反应,并产生性别特异性的年龄依赖性代谢印记,特别是在女性生殖衰老中表现得尤为明显。我们监测了两个年龄段的雌性 Sprague Dawley 大鼠的慢性应激恢复情况,以确定应激和/或衰老是否会在结构上改变糖脂微环境,该环境在认知功能中起着重要作用。老年雌性即使在基础条件下也会出现记忆障碍,而应激则会进一步加剧这种障碍。另一方面,年轻雌性的记忆并未受到干扰。应激恢复后,海马体免疫系统中的小胶质细胞减少,星形胶质细胞计数增加。由于大脑免疫系统功能障碍可能导致突触发生紊乱,因此我们分析了神经瘤蛋白的表达和脂质环境。使用新开发的 Python 脚本方法分析免疫荧光染色,探索了神经瘤蛋白微环境。应激改变了老年雌性 CA1 和齿状回(DG)海马区的糖脂微环境,但方式非常不同,从而影响了神经可塑性。提出的四种可能的神经瘤蛋白环境表明,在应激雌性的生殖衰老过程中 GD1a 神经节苷脂富集,并且在两个区域中高度分散,以及 CA1 区域中 GD1a 和 GM1 的丢失。特定的脂质环境可能会影响神经瘤蛋白的功能,并为衰老和慢性应激共同引发的突触功能障碍提供基础。

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