Regenerative role of mast cells and mesenchymal stem cells in histopathology of the sciatic nerve and tibialis cranialis muscle, following denervation in rats

Articles in Press

Document Type : Original Article

Authors

1 Department of Basic Sciences, Faculty of Veterinary Medicine, Urmia University, Urmia, Iran

2 Department of Histology, Faculty of Veterinary Sciences, Ilam University, Ilam, Iran

3 Department of Pathobiology, Faculty of Veterinary Medicine, Urmia University, Urmia, Iran

4 Department of Surgery and Diagnostic Imaging, Faculty of Veterinary Medicine, Urmia University, Urmia, Iran

5 Department of Chemical Engineering, Sahand University of Technology, Tabriz, Iran

10.22038/ijbms.2024.78732.17030

Abstract

Objective(s): Atrophy of the muscles following denervation can lead to the death of myofibers. This study evaluated the sciatic nerve and tibialis cranialis muscle (TCM) regeneration using scaffold and cells. 
Materials and Methods: Ninety adult male Wistar rats were divided into six main groups (n=15) and three subgroups (2, 4, and 8 weeks). Groups: control; without surgery, Tr; sciatic nerve transected in silicone tube, S; collagen gel put inside the silicone tube, MC; placed 3×104 mast cells mixed with scaffold, MSC; placed 3×104 mesenchymal stem cells mixed with scaffold, and MC+MSC; 3×104 of each of the mast cell and mesenchymal stem cells along with scaffold. Animals were euthanized and sampled for muscle and nerve histological and nerve immunohistochemical evaluations. 
Results: Diameter of muscle fibers, ratio of the muscle fiber’s nuclei to the fibrocyte nuclei (mn/fn), ratio of the muscle fibers nuclei number to the muscle fiber’s number (mn/mf), and ratio of the blood vessels number to the number of muscle fibers (v/mf) in all treatment groups, especially the MC + MSC group, increased compared to the Tr group but the number of mast cells, the percentage of sarcoplasmolysis, and necrosis fibers decreased. Histomorphometric results of the nerve in its various parts and immunohistochemistry results also showed improved nerve conduction, especially in the MC + MSC group. 
Conclusion: In this study, nerve improvement happened mainly for two reasons: cells and time. So, the most obvious improvement occurred in the group with mast and mesenchymal cells in the 8th week.

Keywords

Main Subjects

References

1. Varejão AS, Melo-Pinto P, Meek MF, Filipe VM, Bulas-Cruz J. Methods for the experimental functional assessment of rat sciatic nerve regeneration. Neurol Res 2004; 26: 186-194.
2.    McKenna CF, Fry CS. Altered satellite cell dynamics accompany skeletal muscle atrophy during chronic illness, disuse, and aging. Curr Opin Clin Nutr Metab Care 2017; 20: 447-452.
3.    Batt JA, Bain JR. Tibial nerve transection-a standardized model for denervation-induced skeletal muscle atrophy in mice. J Vis Exp2013; 8: e50657.
4.    Carlson BM. The biology of long-term denervated skeletal muscle. Eur J Transl Myol 2014; 24: 5-11.
5.    Nakanishi R, Hirayama Y, Tanaka M, Maeshige N, Kondo H, Ishihara A, et al. Nucleoprotein supplementation enhances the recovery of rat soleus mass with reloading after hindlimb unloading-induced atrophy via myonuclei accretion and increased protein synthesis. Nutr Res 2016; 36: 1335–44
6.    Subramanian A, Krishnan UM, Sethuraman S. Development of biomaterial scaffold for nerve tissue engineering: Biomaterial mediated neural regeneration. J Biomed Sci 2009; 16: 1-11.
7.    Moon T, St Laurent CD, Morris KE, Marcet C, Yoshimura T, Sekar Y et al. Advances in mast cell biology: New understanding of heterogeneity and function. Mucosal Immunol 2010; 3: 111-128.
8.    Undem BJ, Myers AC, Weinreich D. Antigen-induced modulation of autonomic and sensory neurons in vitro. Inte Arch Allergy Immunol 1991; 94: 319-324.
9.    van der Kleij HP, Bienenstock J. Significance of conversation between mast cells and nerves. Allergy, Asthma Clin Immunol 2005; 1: 65-80.
10.    Murphy PG, Borthwick L S, Johnston RS, Kuchel G, Richardson PM, et al. Nature of the retrograde signal from injured nerves that induces interleukin-6 mRNA in neurons. J Neurosci 1999; 19: 3791-3800.
11.    Yang Y, Yuan X, Ding F, Yao D, Gu Y, Liu J, et al. Repair of rat sciatic nerve gap by a silk fibroin-based scaffold added with bone marrow mesenchymal stem cells. Tissue Eng Part A 2011; 17: 2231-2244.
12.    Ao Q, Fung CK, Tsui AYP, Cai S, Zuo HC, Chan YS et al. The regeneration of transected sciatic nerves of adult rats using chitosan nerve conduits seeded with bone marrow stromal cell-derived Schwann cells. Biomaterials 2011; 32: 787-796.
13.    Nazari M, Ni NC, Lüdke A, Li SH, Guo J, Weisel RD, et al. Mast cells promote proliferation and migration and inhibit differentiation of mesenchymal stem cells through PDGF. J Mol Cell Cardiol 2016; 94: 32-42.
14.    Lutolf M, Hubbell J. Synthetic biomaterials as instructive extracellular microenvironments for morphogenesis in tissue engineering. Nat Biotechnol 2005; 23: 47-55.
15.    Yoshii S, Oka M, Shima M, Taniguchi A, Akagi M. Bridging a 30‐mm nerve defect using collagen filaments. J Biomed Mater Res Part A Appl Biomater 2003; 67: 467-474.
16.    Madaghiele M, Sannino A, Yannas IV, Spector M. Collagen‐based matrices with axially oriented pores. J Biomed Mater Res Part A Appl Biomater 2008; 85: 757-767.
17.    Nakamura T, Inada Y, Fukuda S, Yoshitani M, Nakada A, Itoi SI, et al. Experimental study on the regeneration of peripheral nerve gaps through a polyglycolic acid–collagen (PGA–collagen) tube. Brain Res 2004; 1027: 18-29.
18.    Rigon F, Horst A, Kucharski LC, Silva RSMD, Faccioni-Heuser MC, Partata WA. Effects of sciatic nerve transection on glucose uptake in the presence and absence of lactate in the frog dorsal root ganglia and spinal cord. Braz J Biol 2014; 74: 191-198.
19.    Amani S, Shahrooz R, Mortaz E, Hobbenaghi R, Mohammadi R, Khoshfetrat AB. Histomorphometric and immunohistochemical evaluation of angiogenesis in ischemia by tissue engineering in rats: Role of mast cells. Vet Res Forum 2019; 10: 23-30.
20.    Bakhtiary Z, Shahrooz R, Hobbenaghi R, Azizi S, Soltanalinejad F, Khoshfetrat AB. Histomorphometrical evaluation of extensor digitorum longus muscle in sciatic nerve regeneration using tissue engineering in rats. Vet Res Forum 2021; 12: 451-457.  
21.    Ginis I, Grinblat B, Shirvan MH. Evaluation of bone marrow-derived mesenchymal stem cells after cryopreservation and hypothermic storage in clinically safe medium. Tissue Eng Part C Methods 2012; 18: 453-63. 
22.    Romeo-Guitart D, Forés J, Navarro X, Casas C. Boosted regeneration and reduced denervated muscle atrophy by NeuroHeal in a pre-clinical model of lumbar root avulsion with delayed reimplantation. Sci Rep 2017; 7: 1-12.
23.    Siu PM, Alway SE. Mitochondria-associated apoptotic signalling in denervated rat skeletal muscle. J Physiol 2005; 565: 309-323.
24.    Cea LA, Cisterna BA, Puebla C, Frank M, Figueroa XF, Cardozo C, et al. De novo expression of connexin hemichannels in denervated fast skeletal muscles leads to atrophy. Proc Natl Acad Sci USA 2013; 110: 16229-16234.
25.    Reidy PT, McKenzie AI, Brunker P, Nelson DS, Barrows KM, Supiano M, et al. Neuromuscular electrical stimulation combined with protein ingestion preserves thigh muscle mass but not muscle function in healthy older adults during 5 days of bed rest. Rejuvenation Res 2017; 20: 449-461.
26.    Schaakxs D, Kalbermatten DF, Raffoul W, Wiberg M, Kingham PJ. Regenerative cell injection in denervated muscle reduces atrophy and enhances recovery following nerve repair. Muscle Nerve 2013; 47: 691-701. 
27.    Xing H, Zhou M, Assinck P, Liu N. Electrical stimulation influences satellite cell differentiation after sciatic nerve crush injury in rats. Muscle Nerve 2015; 51: 400-411.
28.    Amani S, Shahrooz R, Hobbenaghi R, Mohammadi R, Baradar Khoshfetrat A, Karimi A, et al. Angiogenic effects of cell therapy within a biomaterial scaffold in a rat hind limb ischemia model. Sci Rep 2021; 11: 1-10.
29.    Purcell W, Atterwill C. Mast cells in neuroimmune function: Neurotoxicological and neuropharmacological perspectives. Neurochem Res 1995; 20: 521-532.
30.    Wakao S, Matsuse D, Dezawa M. Mesenchymal stem cells as a source of Schwann cells: their anticipated use in peripheral nerve regeneration. Cells Tissues Organs 2014; 200: 31-41.
31.    Chernukh A, Alekseeva N. Changes in the capillary bed of skeletal muscle at various times after nerve section. Bull Exp Biol Med 1975; 80: 1009-1012.
32.    Carmeliet P, Tessier-Lavigne M. Common mechanisms of nerve and blood vessel wiring. Nature 2005; 436: 193-200.
33.    Porter JD, Khanna S, Kaminski HJ, Rao JS, Merriam AP, Richmonds CR et al. A chronic inflammatory response dominates the skeletal muscle molecular signature in dystrophin-deficient mdx mice. Hum Mol Genet 2002; 11: 263-272.
34.    Trias E, Ibarburu S, Barreto-Núñez R, Varela V, Moura IC, Dubreuil P, et al. Evidence for mast cells contributing to neuromuscular pathology in an inherited model of ALS. JCI insight 2017; 2:e95934.
35.    Pereira T, Gärtner A, Amorim I, Armada-da-Silva P, Gomes R, Pereira C, et al. Advances in biomaterials science and biomedical applications. Croatia: Intech Open 2013; 23: 329-363.
36.    Charge SB, Rudnicki MA. Cellular and molecular regulation of muscle regeneration. Physiol Rev 2004; 84: 209-238.
37.    Leone, A. Myocardial Infarction. Pathological relevance and relationship with coronary risk factors. Curr Pharm Des 2017; 1;23:3205-3216.
38.    Veltri K, Kwiecien JM, Minet W, Fahnestock M, Bain JR. Contribution of the distal nerve sheath to nerve and muscle preservation following denervation and sensory protection. J Reconstr Microsurg 2005; 21: 57-70.
39.    Cai B, Spencer MJ, Nakamura G, Tseng-Ong L, Tidball JG. Eosinophilia of dystrophin-deficient muscle is promoted by perforin-mediated cytotoxicity by T cell effectors. Am J Pathol 2000; 156: 1789-1796.
40.    Aljaghthmi O, Zeid IA, Heba H, Hassan S. Histological difference of soleus muscle fibers due to sciatic nerve transection in rats. Pathophysiology 2018.
41.    Kerschensteiner M, Schwab ME, Lichtman JW, Misgeld T. In vivo imaging of axonal degeneration and regeneration in the injured spinal cord. Nat Med 2005; 11::572-757. 
42.    Yilmaz S, Gur C, Kucukler S, Akaras N, Kandemir FM. Zingerone attenuates sciatic nerve damage caused by sodium arsenite by inhibiting NF-κB, caspase-3, and ATF-6/CHOP pathways and activating the Akt2/FOXO1 pathway. Iran J Basic Med Sci 2024; 27: 485-491.
43.    Pan HC, Cheng FC, Chen CJ, Lai SZ, Lee CW, Yang DY et al. Post-injury regeneration in rat sciatic nerve facilitated by neurotrophic factors secreted by amniotic fluid mesenchymal stem cells. J Clin Neurosci 2007; 14: 1089-1098.
44.    Pan HC, Yang DY, Chiu YT, Lai SZ, Wang YC, Chang MH et al. Enhanced regeneration in injured sciatic nerve by human amniotic mesenchymal stem cell. J Clin Neurosci 2006; 13: 570-575.    
45.    Tamaki T, Hirata M, Soeda S, Nakajima N, Saito K, Nakazato K, et al. Preferential and comprehensive reconstitution of severely damaged sciatic nerve using murine skeletal muscle-derived multipotent stem cells. PLoS One 2014; 9: e91257.
46.    Mata M, Alessi D, Fink DJ. S100 is preferentially distributed in myelin-forming Schwann cells. J Neurocytol 1990; 19: 432-442.
47.    Svennigsen Å, Dahlin L. Repair of the peripheral nerve—remyelination that works. Brain Sci 2013; 3: 1182-1197.
48.    Somay H, Emon ST, Uslu S, Orakdogen M, Meric ZC, Ince U, et al. The histological effects of ozone therapy on sciatic nerve crush injury in rats. World Neurosurg 2017; 105: 702-708.
49.    Han GH, Peng J, Liu P, Ding X, Wei S, Lu S, et al. Therapeutic strategies for peripheral nerve injury: Decellularized nerve conduits and Schwann cell transplantation. Neural Regen Res 2019; 14: 1343-1351.
50.    Coleman M. Axon degeneration mechanisms: commonality amid diversity. Nat Rev Neurosci 2005; 6: 889.
51.    Moeller JJ, Macaulay RJ, Valdmanis PN, Weston LE, Rouleau GA, Dupré N. Autosomal dominant sensory ataxia: a neuroaxonal dystrophy. Acta Neuropathol 2008; 116: 331-336.
52.    Beirowski B, Adalbert R, Wagner D, Grumme DS, Addicks K, Ribchester RR, et al. The progressive nature of Wallerian degeneration in wild-type and slow Wallerian degeneration (Wld S) nerves. BMC Neurosci 2005; 6: 1-27.
53.    Olsson, Y. Mast cells in the nervous system. Int Rev Cytol 1968; 24: 27-70.
54.    Fox IK, Brenner MJ, Johnson PJ, Hunter DA, Mackinnon SE. Axonal regeneration and motor neuron survival after microsurgical nerve reconstruction. Microsurg 2012; 32: 552-562.
55.    Braga-Silva J, Gehlen D, Roman JA, Menta C, Atkinson EDA, Machado DC, et al. Efeitos das células tronco adultas de medula óssea e do plasma rico em plaquetas na regeneração e recuperação funcional nervosa em um modelo de defeito agudo em nervoso perfiférico em rato. Acta Ortop Bras 2006; 14: 273-275.
56.    Ammendola M, Sacco R, Sammarco G, Piardi T, Zuccalà V, Patruno R, et al. Mast cells positive to tryptase, endothelial cells positive to protease-activated receptor-2, and microvascular density correlate among themselves in hepatocellular carcinoma patients who have undergone surgery. OncoTargets Ther 2016; 9: 4465-4471.
57.    Lewis GM, Kucenas S. Perineurial glia are essential for motor axon regrowth following nerve injury. J Neurosci 2014; 34: 12762-12777.
58.    Hu C, Zhang T, Deng Z, Ren B, Cai L, Zhang Y, et al. Study on the effect of vacuum sealing drainage on the repair process of rabbit sciatic nerve injury. Int J Neurosci 2015; 125: 855-860.
59.    Albayrak BS, Ismailoglu O, Ilbay K, Yaka U, Tanriover G, Gorgulu A, et al. Doxorubicin for prevention of epineurial fibrosis in a rat sciatic nerve model: Outcome based on gross postsurgical, histopathological, and ultrastructural findings. J Neurosurg Spine 2010; 12: 327-333.
60.    Que J, Cao Q, Sui T, Du S, Zhang A, Kong D, et al. Tacrolimus reduces scar formation and promotes sciatic nerve regeneration. Neural Regen Res 2012; 7: 2500-2506. 
 
Iranian Journal of Basic Medical Sciences

Articles in Press, Accepted Manuscript
Available Online from 13 August 2024

Files

Share

How to cite

Statistics