Protective effects of apigenin on the brain transcriptome with aging

IF 5.3 3区医学 Q2 CELL BIOLOGY Mechanisms of Ageing and Development Pub Date : 2023-11-24 DOI:10.1016/j.mad.2023.111889

Alyssa N. Cavalier , Zachary S. Clayton , Devin Wahl , David A. Hutton , Cali M. McEntee , Douglas R. Seals , Thomas J. LaRocca

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Abstract

Brain aging is associated with reduced cognitive function that increases the risk for dementia. Apigenin is a bioactive plant compound that inhibits cellular aging processes and could protect against age-related cognitive dysfunction, but its mechanisms of action in the brain have not been comprehensively studied. We characterized brain transcriptome changes in young and old mice treated with apigenin in drinking water. We observed improved learning/memory in old treated mice, and our transcriptome analyses indicated that differentially expressed genes with aging and apigenin were primarily related to immune responses, inflammation, and cytokine regulation. Moreover, we found that genes/transcripts that were increased in old vs. young mice but downregulated with apigenin treatment in old animals were associated with immune activation/inflammation, whereas transcripts that were reduced with aging but increased with apigenin were related neuronal function and signaling. We also found that these transcriptome differences with aging and apigenin treatment were driven in part by glial cells. To follow up on these in vivo transcriptome findings, we studied aged astrocytes in vitro, and we found that apigenin reduced markers of inflammation and cellular senescence in these cells. Collectively, our data suggest that apigenin may protect against age-related cognitive dysfunction by suppressing neuro-inflammatory processes.

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芹菜素对衰老脑转录组的保护作用。

大脑老化与认知功能下降有关，从而增加患痴呆症的风险。芹菜素是一种具有生物活性的植物化合物，可以抑制细胞衰老过程，防止与年龄相关的认知功能障碍，但其在大脑中的作用机制尚未得到全面的研究。我们描述了在饮用水中使用芹菜素处理的年轻和年老小鼠的脑转录组变化。我们观察到老年小鼠的学习/记忆得到改善，我们的转录组分析表明，随着衰老和芹菜素的差异表达基因主要与免疫反应、炎症和细胞因子调节有关。此外，我们发现在老年小鼠中与年轻小鼠相比，基因/转录本增加，但在老年动物中芹菜素治疗后下调，这与免疫激活/炎症有关，而随着年龄增长而减少，但在芹菜素治疗后增加的转录本与神经元功能和信号传导有关。我们还发现，随着衰老和芹菜素治疗，这些转录组差异部分是由神经胶质细胞驱动的。为了跟进这些体内转录组的发现，我们在体外研究了衰老的星形胶质细胞，我们发现芹菜素减少了这些细胞中的炎症和细胞衰老标志物。总的来说，我们的数据表明芹菜素可能通过抑制神经炎症过程来预防与年龄相关的认知功能障碍。

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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来源期刊

Mechanisms of Ageing and Development 医学-老年医学

CiteScore

11.10

自引率

1.90%

发文量

审稿时长

32 days

期刊介绍： Mechanisms of Ageing and Development is a multidisciplinary journal aimed at revealing the molecular, biochemical and biological mechanisms that underlie the processes of aging and development in various species as well as of age-associated diseases. Emphasis is placed on investigations that delineate the contribution of macromolecular damage and cytotoxicity, genetic programs, epigenetics and genetic instability, mitochondrial function, alterations of metabolism and innovative anti-aging approaches. For all of the mentioned studies it is necessary to address the underlying mechanisms. Mechanisms of Ageing and Development publishes original research, review and mini-review articles. The journal also publishes Special Issues that focus on emerging research areas. Special issues may include all types of articles following peered review. Proposals should be sent directly to the Editor-in-Chief.