Establishing a new animal model for muscle regeneration studies

Pourghadamyari, Hossein; Rezaei, Mohammad; Ipakchi-Azimi, Ali; Eisa-Beygi, Shahram; Basiri, Mohsen; Tahamtani, Yaser; Baharvand, Hossein

doi:10.22099/mbrc.2019.34611.1433

Establishing a new animal model for muscle regeneration studies

Document Type : Original article

Authors

¹ Student Research Committee, Kerman University of Medical Sciences, Kerman, Iran

² Department of Clinical Biochemistry, Afzalipour School of Medicine, Kerman University of Medical Sciences, Iran

³ Department of Stem Cells and Developmental Biology, Cell Science Research Center, Royan Institute for Stem Cell Biology and Technology, ACECR, Tehran, Iran

⁴ Department of Medical Laboratory Science, Medical Science Faculty Babol Islamic Azad University, Babol, Iran

⁵ Department of Radiology, Medical College of Wisconsin, Milwaukee, USA

⁶ Department of Developmental Biology, University of Science and Culture, Tehran, Iran

10.22099/mbrc.2019.34611.1433

Abstract

Skeletal muscle injuries are one of the most common problems in the worldwide which impose a substantial financial burden to the health care system. Accordingly, it widely accepted that muscle regeneration is a promising approach that can be used to treat muscle injury patients. However, the underlying mechanisms of muscle regeneration have yet to be elucidated. The muscle structure and muscle-related gene expression are highly conserved between human and zebrafish. Therefore, the zebrafish can be considered as an ideal animal model in muscle regeneration studies. In this study, Tol2 transposase was applied to produce Tg(mylpfa: cfp-nfsB) zebrafish model that express a fusion protein composed of cyan fluorescent protein (CFP) and nitrorudactase (NTR) under control of mylpfa promoter. The results showed that MTZ (Metronidazole) treatment of Tg(mylpfa:cfp-nfsB) zebrafish larvae can lead to muscle injury by selective ablation of muscle cells. And also, results confirmed the muscle regeneration ability of the transgenic larvae after withdrawal of Mtz for three days. Overall, The results of this study suggest that the Tg(mylpfa:cfp-nfsB) zebrafish model can be used in muscle regeneration study in order to elucidate the mechanisms of this process.

Keywords

References

1. Curtis E, Litwic A, Cooper C, Dennison E. Determinants of muscle and bone aging. J Cell Physiol 2015;230:2618-2625.

2. Stehlíková K, Skálová D, Zídková J, Haberlová J, Voháňka S, Mazanec R, Mrázová L, Vondráček P, Ošlejšková H, Zámečník J, Honzík T, Zeman J, Magner M, Šišková D, Langová M, Gregor V, Godava M, Smolka V, Fajkusová L. Muscular dystrophies and myopathies: the spectrum of mutated genes in the Czech Republic Clin Genet 2017;91:463-469.

3. Plank C, Hofmann P, Gruber M, Bollwein G, Graf BM, Zink W, Metterlein T. Modification of bupivacaine-induced myotoxicity with dantrolene and caffeine in vitro. Anesth Analg 2016;122:418-423.

4. Corona BT, Rathbone CR. Accelerated functional recovery after skeletal muscle ischemia-reperfusion injury using freshly isolated bone marrow cells. J Surg Res 2014;188:100-109.

5. Berardi E, Annibali D, Cassano M, Crippa S, Sampaolesi M. Molecular and cell-based therapies for muscle degenerations: road under construction. Front Physiol 2014;5:119.

6. Schulz N, Liu K-C, Charbord J, Mattsson CL, Tao L, Tworus D, Andersson O. Critical role for adenosine receptor A2a in β-cell proliferation. Mol Metab 2016;5:1138-1146.

7. Manis JP, Knock Out, knock In, knock down-genetically manipulated mice and the Nobel Prize. N Engl J Med 2007;357:2426-2429.

8. Trøstrup H, Thomsen K, Calum H, Hoiby N, Moser C. Animal models of chronic wound care: the application of biofilms in clinical research. Chronic Wound Care Manag Res 2016; 3:123-132.

9. McGonigle P, Ruggeri B. Animal models of human disease: Challenges in enabling translation. Biochem Pharmacol 2014;87:162-171.

10. Berberoglu MA, Gallagher TL, Morrow ZT, Talbot JC, Hromowyk KJ, Tenente IM, Langenau DM, Amacher SL. Satellite-like cells contribute to pax7-dependent skeletal muscle repair in adult zebrafish. Dev Biol 2017;424:162-180.

11. Knappe S, Zammit PS, Knight RD. A population of Pax7-expressing muscle progenitor cells show differential responses to muscle injury dependent on developmental stage and injury extent. Front Aging Neurosci 2015;25:161.

12. Seger C, Hargrave M, Wang X, Chai RJ, Elworthy S, Ingham PW. Analysis of Pax7 expressing myogenic cells in zebrafish muscle development, injury, and models of disease. Dev Dyn 2011;240:2440-2451.

13. Cezar CA, Roche ET, Vandenburgh HH, Duda GN, Walsh CJ, Mooney DJ. Biologic-free mechanically induced muscle regeneration. Proc Natl Acad Sci USA 2016;113:1534-1539.

14. Guardiola O, Andolfi G, Tirone M, Iavarone F, Brunelli S, Minchiotti G. Induction of acute skeletal muscle regeneration by cardiotoxin injection. J Vis Exp 2017;1:e54515.

15. Pereira T, Armada-de Silva PA, Amorim I, Rêma A, Caseiro AR, Gärtner A, Rodrigues M, Lopes MA, Bártolo PJ, Santos JD, Luís AL, Maurício AC. Effects of human mesenchymal stem cells isolated from Wharton’s Jelly of the umbilical cord and conditioned media on skeletal muscle regeneration using a myectomy model. Stem Cells Int 2014;2014:376918.

16. Assis L, Moretti AI, Abrahão TB, De Souza HP, Hamblin MR, Parizotto NA. Low-level laser therapy (808 nm) contributes to muscle regeneration and prevents fibrosis in rat tibialis anterior muscle after cryolesion. Lasers Med Sci 2013;28:947-955.

17. Pertille A, Moura KF, Matsumura CY, Ferretti R, Ramos DM, Petrini AC, Oliveira PC, Silva CA. Evaluation of skeletal muscle regeneration in experimental model after malnutrition. Braz J Biol 2017;77:2010:83-91.

18. Andersson O, Adams BA, Yoo D, Ellis GC, Gut P, Anderson RM, German MS, Stainier DY. Adenosine signaling promotes regeneration ofpancreatic β- cells in vivo. Cell Metab 2012;15:885-894.

19. Fang Y, Lei X, Li X, Chen Y, Xu F, Feng X, Wei S, Li Y. A novel model of demyelination and remyelination in a GFP-transgenic zebrafish. Biol Open 2014;4:62-68.

20. Gut P, Reischauer S, Stainier DYR, Arnaout R. Little fish, big data: Zebrafish as a model for cardiovascular and metabolic disease. Physiol Rev 2017;97:889-938.

21. Kojić S, Bošković S, Jasnić J, Stamenković N, Radojković D. Zebrafish (Danio rerio) in deciphering molecular mechanisms of human diseases. Biol Serbica 2017;39.

22. Li M, Hromowyk KJ, Amacher SL, Currie PD. Muscular dystrophy modeling in zebrafish. Methods Cell Biol 2017;138:347-380.

23. Pisharath H, Rhee JM, Swanson MA, Leach SD, Parsons MJ. Targeted ablation of beta cells in the embryonic zebrafish pancreas using E.coli nitroreductase. Mech Dev 2008;124:218-229.

24. Curado S, Anderson RM, Jungblut B, Mumm J, Schroeter E, Stainier DY. Conditional targeted cell ablation in zebrafish: A new tool for regeneration studies. Dev Dyn 2007;236: 1025-1035.

25. Zang L, Shimada Y, Nishimura N. Development of a novel zebrafish model for type 2 diabetes mellitus. Sci Rep 2017;7:1461.

26. Kawakami K, Takeda H, Kawakami N, Kobayashi M, Matsuda N, Mishina M. A transposon-mediated gene trap approach identifies developmentally regulated genes in zebrafish. Dev Cell 2004;7:133-144.

27. Kwan KM, Fujimoto E, Grabher C, Mangum BD, Hardy ME, Campbell DS, Parant JM, Yost HJ, Kanki JP, Chien CB. The Tol2kit: a multisite gateway‐based construction kit for Tol2 transposon transgenesis constructs. Dev Dyn 2007;236:3088-3099.

28. Rembold M, Lahiri K, Foulkes NS, Wittbrodt J. Transgenesis in fish: efficient selection of transgenic fish by co-injection with a fluorescent reporter construct. Nat Protoc 2006;1:1133-1139.

29. Smith LL, Beggs AH, Gupta VA. Analysis of skeletal muscle defects in larval zebrafish by birefringence and touch-evoke escape response assays. J Vis Exp 2013;82:e50925.

30. Otten C, Abdelilah-Seyfried S. Laser-inflicted injury of zebrafish embryonic skeletal muscle. J Vis Exp 2013;30:e4351.