Cooling-induced changes in intracellular hydrogen peroxide and gene expression in mouse skeletal muscle in vivo.

IF 2.2 3区医学 Q3 PHYSIOLOGY

American journal of physiology. Regulatory, integrative and comparative physiology Pub Date : 2025-06-01 Epub Date: 2025-05-07 DOI:10.1152/ajpregu.00014.2025

Ryotaro Kano, Reo Takeda, Yuta Sotani, Ryo Takagi, Ayaka Tabuchi, Hideki Shirakawa, David C Poole, Yutaka Kano, Daisuke Hoshino

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引用次数: 0

Abstract

Changes in intracellular hydrogen peroxide concentration ([H₂O₂]) constitute an important signal-controlling cellular adaptations. In response to cooling, decreases in [H₂O₂] and changes in antioxidant-related gene expression have been observed in skeletal muscle. However, the specific temperature dependence of cooling-induced [H₂O₂] changes and their quantitative relationship to induced gene expression are unknown. This investigation tested the hypothesis that differences in muscle cytosolic and mitochondrial [H₂O₂] changes during cooling/rewarming determine the pattern of H₂O₂-related gene expression. H₂O₂-sensitive cytosolic (HyPer7) and mitochondrial (MLS-HyPer7) fluorescent proteins were expressed into tibialis anterior (TA) muscle of male C57BL/6J mice. The temperature dependence of [H₂O₂] was determined via in vivo imaging during a 3-min cooling protocol from 35°C to 0°C. Two cooling patterns [6 bouts of intermittent cooling (I-Cool) vs. sustained cooling (S-Cool); both to 13°C] were applied over 60 min. Three hours after cooling, the muscles were removed, and gene expression was evaluated using real-time PCR. The decrease in [H₂O₂] was observed in both cytosolic and mitochondrial compartments from 35°C to 13°C but was of greater magnitude in the cytosol; in contrast, further cooling from 12°C to 0°C induced a rebound increase especially in cytosolic [H₂O₂]. I-Cool increased the mRNA level of Nrf2 (+15%, P < 0.001). S-Cool decreased the mRNA levels of Sod2, Cat, and Ucp3 (i.e., -20, -23, and -30%, respectively, P < 0.05). In conclusion, the greatest decrease in temperature-dependent [H₂O₂] occurred at 13°C in the cytosolic and mitochondrial compartments of muscle fibers, and I-Cool increased Nrf2 mRNA expression, whereas S-Cool decreased several antioxidant-related genes.NEW & NOTEWORTHY This in vivo model successfully characterized the effects of cooling on cytosolic and mitochondrial [H₂O₂] in mouse tibialis anterior skeletal muscle. Cooling decreased [H₂O₂] down to ∼13°C, but the effect was reversed at still lower temperatures. Sustained cooling decreased mRNA levels of antioxidant-related genes (Sod2, Cat, and Ucp3), whereas intermittent cooling increased Nrf mRNA expression. These results help elucidate the mechanistic bases for skeletal muscle adaptation to cooling.

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冷却诱导小鼠骨骼肌细胞内过氧化氢和基因表达的变化。

细胞内过氧化氢浓度（[H2O2]）的变化是控制细胞适应性的重要信号。在冷却下，骨骼肌中观察到[H2O2]的减少和抗氧化相关基因表达的变化。然而，冷却诱导的[H2O2]变化的具体温度依赖性及其与诱导基因表达的定量关系尚不清楚。本研究验证了在冷却/再暖过程中肌肉细胞质和线粒体[H2O2]变化的差异决定了H2O2相关基因表达模式的假设。在雄性C57BL/6J小鼠胫骨前肌（TA）中表达对h2o2敏感的胞浆（HyPer7）和线粒体（MLS-HyPer7）荧光蛋白。在35°C至0°C的3分钟冷却过程中，通过体内成像确定[H2O2]的温度依赖性。两种冷却模式(6次间歇冷却，I-Cool vs.持续冷却，S-Cool；冷却3小时后，取出肌肉，使用实时荧光定量PCR评估基因表达。从35°C到13°C，在细胞质和线粒体区室中都观察到[H2O2]的减少，但在细胞质中减少的幅度更大；相比之下，从12°C进一步冷却到0°C会导致反弹增加，尤其是细胞质[H2O2]。I-Cool使Nrf2 mRNA水平升高15% （p < 0.001）。S-Cool降低了Sod2、Cat和Ucp3的mRNA水平（分别为-20%、-23%和-30%），13°C时肌纤维胞质和线粒体区室中的p2O2发生，I-Cool增加了Nrf2 mRNA的表达，而S-Cool则降低了几个抗氧化相关基因的表达。

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来源期刊

American journal of physiology. Regulatory, integrative and comparative physiology 医学-生理学

CiteScore

5.30

自引率

3.60%

发文量

145

审稿时长

2 months

期刊介绍： The American Journal of Physiology-Regulatory, Integrative and Comparative Physiology publishes original investigations that illuminate normal or abnormal regulation and integration of physiological mechanisms at all levels of biological organization, ranging from molecules to humans, including clinical investigations. Major areas of emphasis include regulation in genetically modified animals; model organisms; development and tissue plasticity; neurohumoral control of circulation and hypertension; local control of circulation; cardiac and renal integration; thirst and volume, electrolyte homeostasis; glucose homeostasis and energy balance; appetite and obesity; inflammation and cytokines; integrative physiology of pregnancy-parturition-lactation; and thermoregulation and adaptations to exercise and environmental stress.