The role of clock gene BMAL1 in exercise-induced skeletal muscle  injury recovery

doi:10.12047/j.cjap.6243.2022.041

Abstract

Abstract: Objective: To investigate the role of clock gene BMAL1 in exercise-induced skeletal muscle injury recovery. Methods: Two hundred and eight 8-week-old SD rats were randomly divided into the control group (Group C, n=104) and the exercise group (Group E, n=104). Group E performed a 90-minute downhill run on the treadmill. After exercise, the gastrocnemius muscle of 8 rats in Group C and Group E were collected at 0 h, 6 h, 12 h, 18 h, 24 h, 30 h, 36 h, 42 h, 48 h, 54 h, 60 h, 66 h and 72 h. The expression of skeletal muscle core clock gene, BMAL1 was measured by real-time fluorescence quantitative PCR. The parameters of fitting cosine curve were obtained by cosine analysis software circacompare (R package), and the change trend of rhythmic oscillation was analyzed. The ultrastructure of skeletal muscle fibers was observed by transmission electron microscope. The expressions of skeletal muscle BMAL1 and DESMIN were detected by Western blot; Immunofluorescence was used to observe the localization and contents of BMAL1 and DESMIN. Results: In Group C, three complete circadian rhythm cycles of mRNA BMAL1 were observed within 72 hours; in Group E, the circadian rhythm of BMAL1 mRNA disappeared at 0 h～24 h. Compared with Group C, the expression level of BMAL1 mRNA was significantly increased at 0 h, 6 h, 12 h, and 18 h after exercise in Group E (P＜0.05), and the expression of BMAL1 protein was significantly increased at 0 h and 12 h after exercise(P＜0.05), and recovered to the level of that in Group C from 24 h to 72 h(P＞0.05). The expression of DESMIN protein was decreased at 0 h and 12 h after exercise(P＜0.05), gradually increased at 24 h, increased significantly at 48 h(P＜0.01), and recovered to the control level at 72 h (P＞0.05). In Group E, BMAL1 and DESMIN were co-localized at 0 h, 12 h, and 24 h after exercise; the colocalization at 0 h～24 h showed a trend of first decreasing and then increasing, and the fluorescence intensity at 24 h reached the highest value. Conclusion: The post-exercise clock gene BMAL1 may be involved in the enhanced synergy of regulating the cytoskeletal protein DESMIN, it is thus related to the promotion of muscle fiber structure recovery.

Key words: brain and muscle ARNT- like1, clock gene, exercise-induced skeletal muscle injury, DESMIN, skeleton protein, rat

CLC Number:

G804.2

FU Ze-ting, XIA Yu, DING Hai-li. The role of clock gene BMAL1 in exercise-induced skeletal muscle injury recovery[J]. CJAP, 2022, 38(3): 220-226.

References

[1] Chatterjee S, Yin H, Nam D, et al. Brain and muscle Arnt-like 1 promotes skeletal muscle regeneration through satellite cell expansion[J]. Exp Cell Res, 2015, 331(1): 200-210.
[2] 高前进, 李壮志, 马新东, 等. 骨骼肌细胞骨架蛋白研究综述[J]. 北京体育大学学报, 2005(10): 1382-1385.
[3] Clemen CS, Herrmann H, Strelkov SV, et al. Desminopathies: pathology and mechanisms[J]. Acta Neuropathol, 2013, 125(1): 47-75.
[4] 丁海丽, 黄增浩, 任在方, 等. 针刺对大鼠运动性骨骼肌损伤内质网应激的干预作用及机制[J]. 中国应用生理学杂志, 2021, 37(4): 359-364.
[5] Kemler D, Wolff CA, Esser KA. Time-of-day dependent effects of contractile activity on the phase of the skeletal muscle clock[J]. J Physiol, 2020, 598(17): 3631-3644.
[6] Harfmann BD, Schroder EA, Esser KA. Circadian rhythms, the molecular clock, and skeletal muscle[J]. J Biol Rhythms, 2015, 30(2): 84-94.
[7] Dickinson JM, D'Lugos AC, Naymik MA, et al. Transcriptome response of human skeletal muscle to divergent exercise stimuli[J]. J Appl Physiol (1985), 2018, 124(6): 1529-1540.
[8] Armstrong RB, Ogilvie RW, Schwane JA. Eccentric exercise-induced injury to rat skeletal muscle[J]. J Appl Physiol Respir Environ Exerc Physiol, 1983, 54(1): 80-93.
[9] Ezagouri S, Zwighaft Z, Sobel J, et al. Physiological and molecular dissection of daily variance in exercise capacity[J]. Cell Metab, 2019, 30(1): 78-91.
[10] van Moorsel D, Hansen J, Havekes B, et al. Demonstration of a day-night rhythm in human skeletal muscle oxidative capacity[J]. Mol Metab, 2016, 5(8): 635-645.
[11] Pastore S, Hood DA. Endurance training ameliorates the metabolic and performance characteristics of circadian Clock mutant mice[J]. J Appl Physiol (1985), 2013, 114(8): 1076-1084.
[12] Choi Y, Cho J, No MH, et al. Re-setting the circadian clock using exercise against sarcopenia[J]. Int J Mol Sci, 2020, 21(9): 3106-3117.
[13] 马涛, 李世昌. 细胞骨架及运动性骨骼肌微损伤研究进展[J]. 体育学刊, 2006(5): 48-52.
[14] 段立公, 李国平, 李肃反. 结蛋白和波形蛋白在运动性肌肉损伤和再生过程中表达及意义的实验研究[J]. 中国运动医学杂志, 2001(2): 167-170.
[15] 李世成, 吴维, 杨则宜. 运动后骨骼肌微结构的损伤及修复与蛋白质补充[J]. 中国运动医学杂志, 2004(2): 216-219.
[16] Zambon AC, McDearmon EL, Salomonis N, et al. Time- and exercise-dependent gene regulation in human skeletal muscle[J]. Genome Biol, 2003, 4(10): R61.
[17] 宋卫红, 汤长发, 刘文锋. 离心运动对大鼠骨骼肌细胞凋亡和增殖的影响[J]. 中国应用生理学杂志, 2013, 29(1): 86-90.
[18] Andrews JL, Zhang X, McCarthy JJ, et al. CLOCK and BMAL1 regulate MyoD and are necessary for maintenance of skeletal muscle phenotype and function[J]. Proc Natl Acad Sci U S A, 2010, 107(44): 19090-19095.
[19] McCarthy JJ, Andrews JL, McDearmon EL, et al. Identification of the circadian transcriptome in adult mouse skeletal muscle[J]. Physiol Genomics, 2007, 31(1): 86-95.
[20] Li H, Choudhary SK, Milner DJ, et al. Inhibition of desmin expression blocks myoblast fusion and interferes with the myogenic regulators MyoD and myogenin[J]. Cell Biol, 1994, 124(5): 827-841.

The role of clock gene BMAL1 in exercise-induced skeletal muscle injury recovery

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