Research on the repair mechanism of wingless MMTV integration site family member 5a, glycogen synthase kinase 3/β-catenin axis regulation of blunt contusion injury of the gastrocnemius muscle by pressing and kneading method_West China Medical Journal

Authors：

XU Yao ¹ , LUO Jian ¹ , LI Hui ² ,  LU Qunwen ¹

1. Department of Tuina, Hospital of Chengdu University of Traditional Chinese Medicine, Chengdu, Sichuan 610072, P. R. China;
2. Department of Training / Sports Injury Prevention and Treatment Clinic, General Hospital of Western Theater Command, Chengdu, Sichuan 610083, P. R. China;

Corresponding?author：

LU Qunwen, Email: zqx-9@163.com

Keywords：

Skeletal muscle injury; pressing and kneading method; gastrocnemius; wingless-type MMTV integration site family member 5a; glycogen synthase kinase 3; β-catenin; fat differentiation

DOI：

10.7507/1002-0179.202408329

Video：

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Abstract Full text Figures/Tables Video References Cited by

Objective To observe the mRNA and protein expression of wingless-type MMTV integration site family member 5a (Wnt5a), glycogen synthase kinase 3 (GSK3), and β-catenin, as well as the muscle fibers and adipose tissue presented in pathological staining in the gastrocnemius muscle of white rabbits with blunt gastrocnemius contusion injuries, and provide a basis for revealing the repair mechanism of the pressing and kneading method in treating skeletal muscle injury. Methods Forty-two healthy male and female New Zealand white rabbits were selected. They were randomly divided into blank group, model 3-day group, model 7-day group, model 14-day group, press-and-knead 3-day group, press-and-knead 7-day group, and press-and-knead 14-day group, by using a random number table method, with 6 rabbits in each group. Samples of the model groups and the press-and-knead groups were taken on the 4th, 8th and 15th days after operation. The mRNA and protein expression of Wnt5a, GSK3, and β-catenin were detected by quantitative polymerase chain reaction and Western blot; the muscle tissue myofibers and adipose tissue were observed by hematoxylin and eosin (HE) staining and oil red O staining. Results The HE staining results showed that significant fibrous tissue proliferation and inflammatory cell infiltration occurred in the model 7-day group; in the model 14-day group, some muscle fibers were degenerated, necrotic, and regenerated, accompanied by fibrous tissue proliferation, slight inflammatory cell infiltration, and slight calcification; in the press-and-knead groups, obvious muscle fiber degeneration, necrosis, and regeneration, and inflammatory cell infiltration were observed, accompanied by significant fibrous tissue proliferation. The oil red O staining results showed that adipocyte deposition was visible in the model groups, which was the heaviest in the model 7-day group; in the press-and-knead groups, muscle fibers and sequences were not significantly damaged, and a small amount of adipocyte infiltration was visible in the interstitial space. There were statistically significant differences in the mRNA expression and protein expression of Wnt5a, GSK3, and β-catenin in the gastrocnemius among groups (P<0.001). Conclusions The histopathological changes of gastrocnemius muscle injury recover gradually over time, and the pressing and kneading method stimulates the mRNA expression activities of Wnt5a, GSK3, and β-catenin, which may slow down the degradation of β-catenin protein by the scaffolding protein complex (of which GSK3 is an important component), so that the protein level of β-catenin is maintained in the stable range at all times. This leads to a reduction of fatty degeneration in the gastrocnemius muscle after the intervention of pressing and kneading method, and promotes the functional repair of the injured skeletal muscle.

Citation： XU Yao, LUO Jian, LI Hui, LU Qunwen. Research on the repair mechanism of wingless MMTV integration site family member 5a, glycogen synthase kinase 3/β-catenin axis regulation of blunt contusion injury of the gastrocnemius muscle by pressing and kneading method. West China Medical Journal, 2025, 40(5): 770-776. doi: 10.7507/1002-0179.202408329 Copy

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4.	黃博, 阮磊, 王蘭蘭, 等. 推拿?法介導機械敏感性離子通道 Piezo1 對骨骼肌損傷模型大鼠細胞凋亡的影響. 湖南中醫藥大學學報, 2023, 43(12): 2249-2255.
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6.	王涵, 厲洋洋, 菅曉婷, 等. CaMKⅣ信號缺失促進肌損傷炎癥并影響肌再生. 中國臨床解剖學雜志, 2023, 41(6): 692-697, 703.
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8.	林建平, 王浩, 劉海潮, 等. 推拿對大鼠骨骼肌鈍挫傷內質網應激和炎癥的影響. 中國醫藥導報, 2022, 19(35): 8-11, 22.
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10.	Ross SE, Hemati N, Longo KA, et al. Inhibition of adipogenesis by Wnt signaling. Science, 2000, 289(5481): 950-953.
11.	王浩, 劉海潮, 陳少清, 等. 骨骼肌鈍挫傷大鼠模型的構建與評價. 中國康復醫學雜志, 2024, 39(1): 24-30.
12.	盧群文, 萬義文, 羅才貴, 等. 三種不同推拿流派拇指揉法力學采集與參數對比分析. 遼寧中醫雜志, 2017, 44(12): 2611-2613, 2701.
13.	陳世益. 外用非甾體抗炎藥治療肌肉骨骼系統疼痛的中國專家共識. 中國醫學前沿雜志(電子版), 2016, 8(7): 24-27.
14.	Qazi TH, Duda GN, Ort MJ, et al. Cell therapy to improve regeneration of skeletal muscle injuries. J Cachexia Sarcopenia Muscle, 2019, 10(3): 501-516.
15.	Wilde JM, Gumucio JP, Grekin JA, et al. Inhibition of p38 mitogen-activated protein kinase signaling reduces fibrosis and lipid accumulation after rotator cuff repair. J Shoulder Elbow Surg, 2016, 25(9): 1501-1508.
16.	Liu X, Ning AY, Chang NC, et al. Investigating the cellular origin of rotator cuff muscle fatty infiltration and fibrosis after injury. Muscles Ligaments Tendons J, 2016, 6(1): 6-15.
17.	康夏. 肌肉因子調控成纖維/成脂前體細胞影響肌肉慢性損傷修復的機制研究. 重慶: 中國人民解放軍陸軍軍醫大學, 2019.
18.	Joe AW, Yi L, Natarajan A, et al. Muscle injury activates resident fibro/adipogenic progenitors that facilitate myogenesis. Nat Cell Biol, 2010, 12(2): 153-163.
19.	Turner NJ, Badylak SF. Regeneration of skeletal muscle. Cell Tissue Res, 2012, 347(3): 759-774.
20.	Molina T, Fabre P, Dumont NA. Fibro-adipogenic progenitors in skeletal muscle homeostasis, regeneration and diseases. Open Biol, 2021, 11(12): 210110.
21.	Davies MR, Liu X, Lee L, et al. TGF-β small molecule inhibitor SB431542 reduces rotator cuff muscle fibrosis and fatty infiltration by promoting fibro/adipogenic progenitor apoptosis. PLoS One, 2016, 11(5): e155486.
22.	Parker E, Hamrick MW. Role of fibro-adipogenic progenitor cells in muscle atrophy and musculoskeletal diseases. Curr Opin Pharmacol, 2021, 58: 1-7.
23.	Wosczyna MN, Perez Carbajal EE, Wagner MW, et al. Targeting microRNA-mediated gene repression limits adipogenic conversion of skeletal muscle mesenchymal stromal cells. Cell Stem Cell, 2021, 28(7): 1323-1334. e8.
24.	Giuliani G, Rosina M, Reggio A. Signaling pathways regulating the fate of fibro/adipogenic progenitors (FAPs) in skeletal muscle regeneration and disease. FEBS J, 2021, 289(21): 6484-6517.
25.	Astudillo P. Extracellular matrix stiffness and Wnt/β-catenin signaling in physiology and disease. Biochem Soc Trans, 2020, 48(3): 1187-1198.
26.	Warboys CM. Mechanoactivation of Wnt/β-catenin pathways in health and disease. Emerg Top Life Sci, 2018, 2(5): 701-712.
27.	Contreras O, Rossi FMV, Theret M. Origins, potency, and heterogeneity of skeletal muscle fibro-adipogenic progenitors-time for new definitions. Skelet Muscle, 2021, 11(1): 16.
28.	Baarsma HA, Engelbertink LH, van Hees LJ, et al. Glycogen synthase kinase-3 (GSK-3) regulates TGF-β₁-induced differentiation of pulmonary fibroblasts. Br J Pharmacol, 2013, 169(3): 590-603.
29.	Best TM, Gharaibeh B, Huard J. Stem cells, angiogenesis and muscle healing: a potential role in massage therapies. Br J Sports Med, 2013, 47(9): 556-560.
30.	Hunt ER, Confides AL, Abshire SM, et al. Massage increases satellite cell number independent of the age-associated alterations in sarcolemma permeability. Physiol Rep, 2019, 7(17): e14200.
31.	謝嬌, 鄧多喜, 陳英, 等. 推拿手法對骨骼肌損傷干預研究的進展. 湖南中醫雜志, 2018, 34(4): 199-201.
32.	Seo BR, Payne CJ, McNamara SL, et al. Skeletal muscle regeneration with robotic actuation-mediated clearance of neutrophils. Sci Transl Med, 2021, 13(614): eabe8868.
33.	閻博華, 盧群文, 豐芬, 等. 杵針點穴對單純性肥胖大鼠體質量、血脂和血糖的影響. 河北中醫, 2019, 41(5): 730-734.
34.	范志勇, 查和萍, 陳利國, 等. 細胞推拿模型的構建及作用機制研究進展. 上海中醫藥大學學報, 2011, 25(5): 100-103.
35.	吳安林, 葉平, 謝嬌, 等. 推拿對骨骼肌損傷修復相關生長因子影響研究進展. 世界中醫藥, 2019, 14(3): 548-552.

1. Kim W, Kim J, Park HS, et al. Development of microfluidic stretch system for studying recovery of damaged skeletal muscle cells. Micromachines (Basel), 2018, 9(12): 671.
2. Laumonier T, Menetrey J. Muscle injuries and strategies for improving their repair. J Exp Orthop, 2016, 3(1): 15.
3. 程春芳, 黨彩霞, 高霄飛, 等. 蟲草素在骨骼肌損傷修復中的作用研究進展. 生命科學, 2024, 36(5): 684-690.
4. 黃博, 阮磊, 王蘭蘭, 等. 推拿?法介導機械敏感性離子通道 Piezo1 對骨骼肌損傷模型大鼠細胞凋亡的影響. 湖南中醫藥大學學報, 2023, 43(12): 2249-2255.
5. 袁培根, 陳順利, 單鴛露, 等. 艾司氯胺酮減輕大鼠骨骼肌缺血再灌注損傷. 基礎醫學與臨床, 2023, 43(12): 1822-1826.
6. 王涵, 厲洋洋, 菅曉婷, 等. CaMKⅣ信號缺失促進肌損傷炎癥并影響肌再生. 中國臨床解剖學雜志, 2023, 41(6): 692-697, 703.
7. 張紅波. 植物源性芥子酸對運動性骨骼肌損傷大鼠骨骼肌氧化應激和線粒體功能的影響. 分子植物育種, 2023, 21(24): 8227-8233.
8. 林建平, 王浩, 劉海潮, 等. 推拿對大鼠骨骼肌鈍挫傷內質網應激和炎癥的影響. 中國醫藥導報, 2022, 19(35): 8-11, 22.
9. Reggio A, Rosina M, Palma A, et al. Adipogenesis of skeletal muscle fibro/adipogenic progenitors is affected by the WNT5a/GSK3/β-catenin axis. Cell Death Differ, 2020, 27(10): 2921-2941.
10. Ross SE, Hemati N, Longo KA, et al. Inhibition of adipogenesis by Wnt signaling. Science, 2000, 289(5481): 950-953.
11. 王浩, 劉海潮, 陳少清, 等. 骨骼肌鈍挫傷大鼠模型的構建與評價. 中國康復醫學雜志, 2024, 39(1): 24-30.
12. 盧群文, 萬義文, 羅才貴, 等. 三種不同推拿流派拇指揉法力學采集與參數對比分析. 遼寧中醫雜志, 2017, 44(12): 2611-2613, 2701.
13. 陳世益. 外用非甾體抗炎藥治療肌肉骨骼系統疼痛的中國專家共識. 中國醫學前沿雜志(電子版), 2016, 8(7): 24-27.
14. Qazi TH, Duda GN, Ort MJ, et al. Cell therapy to improve regeneration of skeletal muscle injuries. J Cachexia Sarcopenia Muscle, 2019, 10(3): 501-516.
15. Wilde JM, Gumucio JP, Grekin JA, et al. Inhibition of p38 mitogen-activated protein kinase signaling reduces fibrosis and lipid accumulation after rotator cuff repair. J Shoulder Elbow Surg, 2016, 25(9): 1501-1508.
16. Liu X, Ning AY, Chang NC, et al. Investigating the cellular origin of rotator cuff muscle fatty infiltration and fibrosis after injury. Muscles Ligaments Tendons J, 2016, 6(1): 6-15.
17. 康夏. 肌肉因子調控成纖維/成脂前體細胞影響肌肉慢性損傷修復的機制研究. 重慶: 中國人民解放軍陸軍軍醫大學, 2019.
18. Joe AW, Yi L, Natarajan A, et al. Muscle injury activates resident fibro/adipogenic progenitors that facilitate myogenesis. Nat Cell Biol, 2010, 12(2): 153-163.
19. Turner NJ, Badylak SF. Regeneration of skeletal muscle. Cell Tissue Res, 2012, 347(3): 759-774.
20. Molina T, Fabre P, Dumont NA. Fibro-adipogenic progenitors in skeletal muscle homeostasis, regeneration and diseases. Open Biol, 2021, 11(12): 210110.
21. Davies MR, Liu X, Lee L, et al. TGF-β small molecule inhibitor SB431542 reduces rotator cuff muscle fibrosis and fatty infiltration by promoting fibro/adipogenic progenitor apoptosis. PLoS One, 2016, 11(5): e155486.
22. Parker E, Hamrick MW. Role of fibro-adipogenic progenitor cells in muscle atrophy and musculoskeletal diseases. Curr Opin Pharmacol, 2021, 58: 1-7.
23. Wosczyna MN, Perez Carbajal EE, Wagner MW, et al. Targeting microRNA-mediated gene repression limits adipogenic conversion of skeletal muscle mesenchymal stromal cells. Cell Stem Cell, 2021, 28(7): 1323-1334. e8.
24. Giuliani G, Rosina M, Reggio A. Signaling pathways regulating the fate of fibro/adipogenic progenitors (FAPs) in skeletal muscle regeneration and disease. FEBS J, 2021, 289(21): 6484-6517.
25. Astudillo P. Extracellular matrix stiffness and Wnt/β-catenin signaling in physiology and disease. Biochem Soc Trans, 2020, 48(3): 1187-1198.
26. Warboys CM. Mechanoactivation of Wnt/β-catenin pathways in health and disease. Emerg Top Life Sci, 2018, 2(5): 701-712.
27. Contreras O, Rossi FMV, Theret M. Origins, potency, and heterogeneity of skeletal muscle fibro-adipogenic progenitors-time for new definitions. Skelet Muscle, 2021, 11(1): 16.
28. Baarsma HA, Engelbertink LH, van Hees LJ, et al. Glycogen synthase kinase-3 (GSK-3) regulates TGF-β₁-induced differentiation of pulmonary fibroblasts. Br J Pharmacol, 2013, 169(3): 590-603.
29. Best TM, Gharaibeh B, Huard J. Stem cells, angiogenesis and muscle healing: a potential role in massage therapies. Br J Sports Med, 2013, 47(9): 556-560.
30. Hunt ER, Confides AL, Abshire SM, et al. Massage increases satellite cell number independent of the age-associated alterations in sarcolemma permeability. Physiol Rep, 2019, 7(17): e14200.
31. 謝嬌, 鄧多喜, 陳英, 等. 推拿手法對骨骼肌損傷干預研究的進展. 湖南中醫雜志, 2018, 34(4): 199-201.
32. Seo BR, Payne CJ, McNamara SL, et al. Skeletal muscle regeneration with robotic actuation-mediated clearance of neutrophils. Sci Transl Med, 2021, 13(614): eabe8868.
33. 閻博華, 盧群文, 豐芬, 等. 杵針點穴對單純性肥胖大鼠體質量、血脂和血糖的影響. 河北中醫, 2019, 41(5): 730-734.
34. 范志勇, 查和萍, 陳利國, 等. 細胞推拿模型的構建及作用機制研究進展. 上海中醫藥大學學報, 2011, 25(5): 100-103.
35. 吳安林, 葉平, 謝嬌, 等. 推拿對骨骼肌損傷修復相關生長因子影響研究進展. 世界中醫藥, 2019, 14(3): 548-552.

West China Medical Journal

Research on the repair mechanism of wingless MMTV integration site family member 5a, glycogen synthase kinase 3/β-catenin axis regulation of blunt contusion injury of the gastrocnemius muscle by pressing and kneading method

Abstract Full text Figures/Tables Video References Cited by

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