Restricted accessResearch articleFirst published online 2013-03
Application of Cyclic Strain for Accelerated Skeletal Myogenic Differentiation of Mouse Bone Marrow-Derived Mesenchymal Stromal Cells with Cell Alignment
The fabrication of biomimetic skeletal myocyte constructs continues to present a challenge to functional tissue engineering. The skeletal myogenesis of bone marrow-derived mesenchymal stromal cells (BMSCs) to mimic the native tissue architecture offers great therapeutic promise, but remains particularly difficult. The aim of this study was to examine the possibility of accelerating the skeletal myogenic differentiation of BMSCs with an aligned structure by applying cyclic strain. Mouse BMSCs (mBMSCs) were plated on silicone sheets that were coated with fibronectin and subjected to cyclic 10% uniaxial strain when they reached 80%–90% cell confluency. Cells cultured in a growth medium that were subjected to cyclic strain at a frequency of 0.17 Hz (10 times/min) demonstrated a shift of alignment within 48 h from a completely random orientation to a well-aligned morphology with well-organized actin stress fibers that were parallel to the strain vector. The cyclic strain restricted the motility and proliferation of the aligned mBMSCs in the growth medium, which resulted in tight cellular contact in the cell population. When mBMSCs were subjected to cyclic strain in a myogenic medium, reverse transcription–polymerase chain reaction analysis demonstrated the upregulation of skeletal myogenic marker genes (myogenic factor 5 [Myf5], myogenin, and myogenic regulatory factor 4 [MRF4]), but not smooth muscle marker genes (myocardin and α-smooth muscle actin). In addition, immunocytochemistry showed that the mBMSCs fused to form multinucleated myosin- and myogenin-positive myotubes in the direction of the applied tension within 5 days. These results demonstrate that our simple method of applying of cyclic strain to cells cultured in a myogenic medium greatly accelerates the skeletal myogenic differentiation of mBMSCs with an aligned structure, and they highlight the importance of cellular alignment for creating physiologically relevant environments to study the myogenesis of BMSCs and engineer skeletal muscle.
BiancoP., RobeyP.G.Stem cells in tissue engineering. Nature, 414:118. 2001.
9.
WakitaniS., SaitoT., CaplanA.I.Myogenic cells derived from rat bone marrow mesenchymal stem cells exposed to 5-azacytidine. Muscle Nerve, 18:1417. 1995.
10.
ReyesM., LundT., LenvikT., AguiarD., KoodieL., VerfaillieC.M.Purification and ex vivo expansion of postnatal human marrow mesodermal progenitor cells. Blood, 98:2615. 2001.
MugurumaY., ReyesM., NakamuraY., SatoT., MatsuzawaH., MiyatakeH., AkatsukaA., ItohJ., YahataT., AndoK., KatoS., HottaT.In vivo and in vitro differentiation of myocytes from human bone marrow-derived multipotent progenitor cells. Exp Hematol, 31:1323. 2003.
13.
YamamotoD.L., CsikaszR.I., LiY., SharmaG., HjortK., KarlssonR., BengtssonT.Myotube formation on micro-patterned glass: intracellular organization and protein distribution in C2C12 skeletal muscle cells. J Histochem Cytochem, 56:881. 2008.
WangP.Y., YuH.T., TsaiW.B.Modulation of alignment and differentiation of skeletal myoblasts by submicron ridges/grooves surface structure. Biotechnol Bioeng, 106:285. 2010.
16.
AhmedW.W., WolframT., GoldynA.M., BruellhoffK., RiojaB.A., MollerM., SpatzJ.P., SaifT.A., GrollJ., KemkemerR.Myoblast morphology and organization on biochemically micro-patterned hydrogel coatings under cyclic mechanical strain. Biomaterials, 31:250. 2010.
17.
PennisiC.P., OlesenC.G., de ZeeM., RasmussenJ., ZacharV.Uniaxial cyclic strain drives assembly and differentiation of skeletal myocytes. Tissue Eng Part A, 17:2543. 2011.
18.
GoldspinkG., ScuttA., LoughnaP.T., WellsD.J., JaenickeT., GerlachG.F.Gene expression in skeletal muscle in response to stretch and force generation. Am J Physiol, 262:R356. 1992.
19.
TomasekJ.J., GabbianiG., HinzB., ChaponnierC., BrownR.A.Myofibroblasts and mechano-regulation of connective tissue remodelling. Nat Rev Mol Cell Biol, 3:349. 2002.
20.
TatsumiR.Mechano-biology of skeletal muscle hypertrophy and regeneration: possible mechanism of stretch-induced activation of resident myogenic stem cells. Anim Sci J, 81:11. 2010.
21.
CheemaU., BrownR., MuderaV., YangS.Y., McGroutherG., GoldspinkG.Mechanical signals and IGF-I gene splicing in vitro in relation to development of skeletal muscle. J Cell Physiol, 202:67. 2005.
22.
TidballJ.G.Mechanical signal transduction in skeletal muscle growth and adaptation. J Appl Physiol, 98:1900. 2005.
23.
ChandranR., KnoblochT.J., AnghelinaM., AgarwalS.Biomechanical signals upregulate myogenic gene induction in the presence or absence of inflammation. Am J Physiol Cell Physiol, 293:C267. 2007.
24.
SoleimaniM., NadriS.A protocol for isolation and culture of mesenchymal stem cells from mouse bone marrow. Nat Protoc, 4:102. 2009.
25.
ReaM.A., ZhouL., QinQ., BarrandonY., EasleyK.W., GungnerS.F., PhillipsM.A., HollandW.S., GumerlockP.H., RockeD.M., RiceR.H.Spontaneous immortalization of human epidermal cells with naturally elevated telomerase. J Invest Dermatol, 126:2507. 2006.
26.
SasakiJ.I., MatsumotoT., EgusaH., MatsusakiM., NishiguchiA., NakanoT., AkashiM., ImazatoS., YataniH.In vitro reproduction of endochondral ossification using a 3D mesenchymal stem cell construct. Integr Biol, 4:1207. 2012.
27.
EgusaH., IidaK., KobayashiM., LinT.Y., ZhuM., ZukP.A., WangC.J., ThakorD.K., HedrickM.H., NishimuraI.Downregulation of extracellular matrix-related gene clusters during osteogenic differentiation of human bone marrow- and adipose tissue-derived stromal cells. Tissue Eng, 13:2589. 2007.
HamadaY., EgusaH., KanedaY., HirataI., KawaguchiN., HiraoT., MatsumotoT., YaoM., DaitoK., SuzukiM., YataniH., DaitoM., OkazakiM., MatsuuraN.Synthetic osteopontin-derived peptide SVVYGLR can induce neovascularization in artificial bone marrow scaffold biomaterials. Dent Mater J, 26:487. 2007.
30.
EgusaH., OkitaK., KayashimaH., YuG., FukuyasuS., SaekiM., MatsumotoT., YamanakaS., YataniH.Gingival fibroblasts as a promising source of induced pluripotent stem cells. PLoS One, 5:e12743. 2010.
31.
NaruseK., YamadaT., SaiX.R., HamaguchiM., SokabeM.Pp125FAK is required for stretch dependent morphological response of endothelial cells. Oncogene, 17:455. 1998.
32.
YanoY., GeibelJ., SumpioB.E.Tyrosine phosphorylation of pp125FAK and paxillin in aortic endothelial cells induced by mechanical strain. Am J Physiol, 271:C635. 1996.
33.
NaruseK., YamadaT., SokabeM.Involvement of SA channels in orienting response of cultured endothelial cells to cyclic stretch. Am J Physiol, 274:H1532. 1998.
34.
HamiltonD.W., MaulT.M., VorpD.A.Characterization of the response of bone marrow-derived progenitor cells to cyclic strain: implications for vascular tissue-engineering applications. Tissue Eng, 10:361. 2004.
35.
GhazanfariS., Tafazzoli-ShadpourM., ShokrgozarM.A.Effects of cyclic stretch on proliferation of mesenchymal stem cells and their differentiation to smooth muscle cells. Biochem Biophys Res Commun, 388:601. 2009.
36.
BayatiV., SadeghiY., ShokrgozarM.A., HaghighipourN., AzadmaneshK., AmanzadehA., AzariS.The evaluation of cyclic uniaxial strain on myogenic differentiation of adipose-derived stem cells. Tissue Cell, 43:359. 2011.
37.
WangJ.H., Goldschmidt-ClermontP., WilleJ., YinF.C.Specificity of endothelial cell reorientation in response to cyclic mechanical stretching. J Biomech, 34:1563. 2001.
NieponiceA., MaulT.M., CumerJ.M., SolettiL., VorpD.A.Mechanical stimulation induces morphological and phenotypic changes in bone marrow-derived progenitor cells within a three-dimensional fibrin matrix. J Biomed Mater Res A, 81:523. 2007.
40.
CevallosM., RihaG.M., WangX., YangH., YanS., LiM., ChaiH., YaoQ., ChenC.Cyclic strain induces expression of specific smooth muscle cell markers in human endothelial cells. Differentiation, 74:552. 2006.
41.
KookS.H., SonY.O., ChoiK.C., LeeH.J., ChungW.T., HwangI.H., LeeJ.C.Cyclic mechanical stress suppresses myogenic differentiation of adult bovine satellite cells through activation of extracellular signal-regulated kinase. Mol Cell Biochem, 309:133. 2008.
42.
HynesR.O.Integrins: versatility, modulation, and signaling in cell adhesion. Cell, 69:11. 1992.
43.
WeberG.F., BjerkeM.A., DeSimoneD.W.Integrins and cadherins join forces to form adhesive networks. J Cell Sci, 124:1183. 2011.
44.
ClarkC.B., McKnightN.L., FrangosJ.A.Stretch activation of GTP-binding proteins in C2C12 myoblasts. Exp Cell Res, 292:265. 2004.
45.
PownallM.E., GustafssonM.K., EmersonC.P.Jr.Myogenic regulatory factors and the specification of muscle progenitors in vertebrate embryos. Annu Rev Cell Dev Biol, 18:747. 2002.
46.
FreytagS.O.Enforced expression of the c-myc oncogene inhibits cell differentiation by precluding entry into a distinct predifferentiation state in G0/G1. Mol Cell Biol, 8:1614. 1988.
47.
YoungA.P., WagersA.J.Pax3 induces differentiation of juvenile skeletal muscle stem cells without transcriptional upregulation of canonical myogenic regulatory factors. J Cell Sci, 123:2632. 2011.
JakkarajuS., ZheX., PanD., ChoudhuryR., SchugerL.TIPs are tension-responsive proteins involved in myogenic versus adipogenic differentiation. Dev Cell, 9:39. 2005.
54.
ChengW.P., HungH.F., WangB.W., ShyuK.G.The molecular regulation of GADD153 in apoptosis of cultured vascular smooth muscle cells by cyclic mechanical stretch. Cardiovasc Res, 77:551. 2008.
55.
ZhangY.H., ZhaoC.Q., JiangL.S., DaiL.Y.Cyclic stretch-induced apoptosis in rat annulus fibrosus cells is mediated in part by endoplasmic reticulum stress through nitric oxide production. Eur Spine J, 20:1233. 2011.
56.
KaufmanR.J.Stress signaling from the lumen of the endoplasmic reticulum: coordination of gene transcriptional and translational controls. Genes Dev, 13:1211. 1999.
QuinlanA.M., SieradL.N., CapulliA.K., FirstenbergL.E., BilliarK.L.Combining dynamic stretch and tunable stiffness to probe cell mechanobiology in vitro. PLoS One, 6:e23272. 2011.
62.
ChoiY.S., VincentL.G., LeeA.R., DobkeM.K., EnglerA.J.Mechanical derivation of functional myotubes from adipose-derived stem cells. Biomaterials, 33:2482. 2012.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
