高强度训练对CREB激活以改善大脑健康：关于可能的分子机制的叙述性综述

High-intensity training on CREB activation for improving brain health: a narrative review of possible molecular talks.

作者信息

Li Ping, Hu Yan, Tong Ligang, Bi Xuecui

机构信息

Faculty of Sports Science, Ningbo University, Ningbo, China.

Ningbo High-tech Zone Playing Kindergarten, Ningbo, China.

出版信息

Front Endocrinol (Lausanne). 2025 Jan 20;15:1498495. doi: 10.3389/fendo.2024.1498495. eCollection 2024.

DOI:10.3389/fendo.2024.1498495

PMID:39902166

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11788139/

Abstract

Although physical exercise has obvious benefits in brain physiology, the molecular biomarkers induced by exercise protocols are inconclusive. Evidence indicates that exercise interventions are effective in shaping brain physiology. However, the potential mediator for improving brain functions is uncertain. CREB is one of the potential targets of exercise that triggers various molecular cross-talk to improve neurogenesis, long-term potentiation, and synaptogenesis. Therefore, CREB may be situated on the causal path between maintaining brain health and exercising. To support this, studies have shown that exercise-mediated CREB phosphorylation improves cognitive functions and memory. In addition, among the protocols of exercise (types, duration, and frequency), the intensity has been reported to be the most effective in triggering CREB-mediated molecular signaling. For example, HIT increases the synthesis of CREB, which may not only induce brain physiology but also induce brain pathology by higher activation of its downstream targets, such as BDNF. Therefore, this review aims to understand the effects of HIT on CREB function and how HIT can mediate the CREB-induced molecular cross-talk for maintaining brain health.

摘要

尽管体育锻炼对大脑生理有明显益处，但运动方案所诱导的分子生物标志物尚无定论。有证据表明，运动干预对塑造大脑生理有效。然而，改善大脑功能的潜在介质尚不确定。CREB是运动的潜在靶点之一，它触发各种分子间的相互作用以改善神经发生、长时程增强和突触形成。因此，CREB可能处于维持大脑健康与运动之间的因果路径上。为支持这一点，研究表明运动介导的CREB磷酸化可改善认知功能和记忆。此外，在运动方案（类型、持续时间和频率）中，据报道强度在触发CREB介导的分子信号传导方面最为有效。例如，高强度间歇训练（HIT）会增加CREB的合成，这不仅可能诱导大脑生理变化，还可能因其下游靶点（如脑源性神经营养因子，BDNF）的更高激活而诱发脑部病变。因此，本综述旨在了解高强度间歇训练对CREB功能的影响，以及高强度间歇训练如何介导CREB诱导的分子间相互作用以维持大脑健康。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/59b7/11788139/a2a9ce367dde/fendo-15-1498495-g001.jpg

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高强度训练对CREB激活以改善大脑健康：关于可能的分子机制的叙述性综述

High-intensity training on CREB activation for improving brain health: a narrative review of possible molecular talks.

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