Controlled differentiation of multi-potent mesenchymal stem cells (MSCs) into vocal fold-specific, fibroblast-like cells in vitro is an attractive strategy for vocal fold repair and regeneration. The goal of the current study was to define experimental parameters that can be used to control the initial fibroblastic differentiation of MSCs in vitro. To this end, connective tissue growth factor (CTGF) and micro-structured, fibrous scaffolds based on poly(glycerol sebacate) (PGS) and poly(ɛ-caprolactone) (PCL) were used to create a three-dimensional, connective tissue-like microenvironment. MSCs readily attached to and elongated along the microfibers, adopting a spindle-shaped morphology during the initial 3 days of preculture in an MSC maintenance medium. The cell-laden scaffolds were subsequently cultivated in a conditioned medium containing CTGF and ascorbic acids for up to 21 days. Cell morphology, proliferation, and differentiation were analyzed collectively by quantitative PCR analyses, and biochemical and immunocytochemical assays. F-actin staining showed that MSCs maintained their fibroblastic morphology during the 3 weeks of culture. The addition of CTGF to the constructs resulted in an enhanced cell proliferation, elevated expression of fibroblast-specific protein-1, and decreased expression of mesenchymal surface epitopes without markedly triggering chondrogenesis, osteogenesis, adipogenesis, or apoptosis. At the mRNA level, CTGF supplement resulted in a decreased expression of collagen I and tissue inhibitor of metalloproteinase 1, but an increased expression of decorin and hyaluronic acid synthesase 3. At the protein level, collagen I, collagen III, sulfated glycosaminoglycan, and elastin productivity was higher in the conditioned PGS-PCL culture than in the normal culture. These findings collectively demonstrate that the fibrous mesh, when combined with defined biochemical cues, is capable of fostering MSC fibroblastic differentiation in vitro.
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References
1.
GrayS.D.Cellular physiology of the vocal folds. Otolaryngol Clin North Am, 33:679. 2000.
2.
TitzeI.R.Principles of Voice Production. NJ: Prentice-Hall, 1994.
3.
HiranoS.Current treatment of vocal fold scarring. Curr Opin Otolaryngol Head Neck Surg, 13:143. 2005.
4.
ChenX., ThibeaultS.L.Novel isolation and biochemical characterization of immortalized fibroblasts for tissue engineering vocal fold lamina propria. Tissue Eng Part C Methods, 15:201. 2009.
5.
ParekkadanB., MilwidJ.M.Mesenchymal stem cells as therapeutics. Annu Rev Biomed Eng, 12:87. 2010.
6.
PittengerM.F., MackayA.M., BeckS.C., JaiswalR.K., DouglasR., MoscaJ.D.et al.Multilineage potential of adult human mesenchymal stem cells. Science, 284:143. 1999.
7.
BaeS., AhnJ.H., ParkC.W., SonH.K., KimK.S., LimN.K.et al.Gene and microrna expression signatures of human mesenchymal stromal cells in comparison to fibroblasts. Cell Tissue Res, 335:565. 2009.
8.
HalfonS., AbramovN., GrinblatB., GinisI.Markers distinguishing mesenchymal stem cells from fibroblasts are downregulated with passaging. Stem Cells Dev, 20:53. 2011.
9.
IshiiM., KoikeC., IgarashiA., YamanakaK., PanH., HigashiY.et al.Molecular markers distinguish bone marrow mesenchymal stem cells from fibroblasts. Biochem Biophys Res Commun, 332:297. 2005.
10.
GraysonW.L., ZhaoF., IzadpanahR., BunnellB., MaT.Effects of hypoxia on human mesenchymal stem cell expansion and plasticity in 3d constructs. J Cell Physiol, 207:331. 2006.
11.
JunkerJ.P., SommarP., SkogM., JohnsonH., KratzG.Adipogenic, chondrogenic and osteogenic differentiation of clonally derived human dermal fibroblasts. Cells Tissues Organs, 191:105. 2010.
12.
KurpinskiK., ChuJ., HashiC., LiS.Anisotropic mechanosensing by mesenchymal stem cells. Proc Natl Acad Sci USA, 103:16095. 2006.
13.
LimS.H., MaoH.Q.Electrospun scaffolds for stem cell engineering. Adv Drug Deliv Rev, 61:1084. 2009.
14.
PlaceE.S., EvansN.D., StevensM.M.Complexity in biomaterials for tissue engineering. Nat Mater, 8:457. 2009.
15.
RenekerD.H., ChunI.Nanometre diameter fibres of polymer, produced by electrospinning. Nanotechnology, 7:216. 1996.
16.
MauckR.L., BakerB.M., NerurkarN.L., BurdickJ.A., LiW.J., TuanR.S.et al.Engineering on the straight and narrow: the mechanics of nanofibrous assemblies for fiber-reinforced tissue regeneration. Tissue Eng Part B Rev, 15:171. 2009.
17.
GoldbergM., LangerR., JiaX.Q.Nanostructured materials for applications in drug delivery and tissue engineering. J Biomater Sci Polym Ed, 18:241. 2007.
18.
KhademhosseiniA., VacantiJ.P., LangerR.Progress in tissue engineering. Sci Am, 300:64. 2009.
19.
SantS., HwangC.M., LeeS.H., KhademhosseiniA.Hybrid PGS-PCL microfibrous scaffolds with improved mechanical and biological properties. J Tissue Eng Regen Med, 5:283. 2011.
ChenQ.Z., BismarckA., HansenU., JunaidS., TranM.Q., HardingS.E.et al.Characterisation of a soft elastomer poly(glycerol sebacate) designed to match the mechanical properties of myocardial tissue. Biomaterials, 29:47. 2008.
22.
RadisicM., ParkH., MartensT.P., Salazar-LazaroJ.E., GengW., WangY.et al.Pre-treatment of synthetic elastomeric scaffolds by cardiac fibroblasts improves engineered heart tissue. J Biomed Mater Res A, 86:713. 2008.
23.
RedentiS., NeeleyW.L., RompaniS., SaigalS., YangJ., KlassenH.et al.Engineering retinal progenitor cell and scrollable poly(glycerol-sebacate) composites for expansion and subretinal transplantation. Biomaterials, 30:3405. 2009.
LeeC.H., ShahB., MoioliE.K., MaoJ.J.Ctgf directs fibroblast differentiation from human mesenchymal stem/stromal cells and defines connective tissue healing in a rodent injury model. J Clin Invest, 120:3340. 2010.
30.
StrutzF., OkadaH., LoC.W., DanoffT., CaroneR.L., TomaszewskiJ.E.et al.Identification and characterization of a fibroblast marker: Fsp1. J Cell Biol, 130:393. 1995.
31.
WiseJ.K., YarinA.L., MegaridisC.M., ChoM.Chondrogenic differentiation of human mesenchymal stem cells on oriented nanofibrous scaffolds: Engineering the superficial zone of articular cartilage. Tissue Eng Part A, 15:913. 2009.
32.
FarranA.J.E., TellerS.S., JhaA.K., JiaoT., HuleR.A., CliftonR.J.et al.Effects of matrix composition, microstructure, and viscoelasticity on the behaviors of vocal fold fibroblasts cultured in three-dimensional hydrogel networks. Tissue Eng Part A, 16:1247. 2010.
33.
ChomczynskiP., SacchiN.Single-step method of rna isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal Biochem, 162:156. 1987.
34.
ChomczynskiP.A reagent for the single-step simultaneous isolation of RNA, DNA and proteins from cell and tissue samples. Biotechniques, 15:532. 1993.
35.
PfafflM.W.A new mathematical model for relative quantification in real-time rt-pcr. Nucleic Acids Res, 29:e45. 2001.
36.
TanakaH., MurphyC.L., MurphyC., KimuraM., KawaiS., PolakJ.M.Chondrogenic differentiation of murine embryonic stem cells: effects of culture conditions and dexamethasone. J Cell Biochem, 93:454. 2004.
37.
CaplanA.I.Adult mesenchymal stem cells for tissue engineering versus regenerative medicine. J Cell Physiol, 213:341. 2007.
38.
EydenB.The myofibroblast: a study of normal, reactive and neoplastic tissues, with an emphasis on ultrastructure. Part 1—normal and reactive cells. J Submicrosc Cytol Pathol, 37:109. 2005.
39.
ChenC.C., LauL.F.Functions and mechanisms of action of ccn matricellular proteins. Int J Biochem Cell Biol, 41:771. 2009.
40.
DaleyW.P., PetersS.B., LarsenM.Extracellular matrix dynamics in development and regenerative medicine. J Cell Sci, 121:255. 2008.
41.
ItahanaK., DimriG.P., HaraE., ItahanaY., ZouY., DesprezP.Y.et al.A role for p53 in maintaining and establishing the quiescence growth arrest in human cells. J Biol Chem, 277:18206. 2002.
42.
ParkE., PatelA.N.Changes in the expression pattern of mesenchymal and pluripotent markers in human adipose-derived stem cells. Cell Biol Int, 34:979. 2010.
43.
SimmonsP.J., TorokstorbB.Identification of stromal cell precursors in human bone-marrow by a novel monoclonal-antibody, stro-1. Blood, 78:55. 1991.
44.
NakanishiT., NishidaT., ShimoT., KobayashiK., KuboT., TamataniT.et al.Effects of ctgf/hcs24, a product of a hypertrophic chondrocyte-specific gene, on the proliferation and differentiation of chondrocytes in culture. Endocrinology, 141:264. 2000.
45.
TsukadaT., TippensD., GordonD., RossR., GownA.M.Hhf35, a muscle-actin-specific monoclonal antibody. I. Immunocytochemical and biochemical characterization. Am J Pathol, 126:51. 1987.
46.
AlbertsB., JohnsonA., LewisJ., RaffM., RobertsK., WalterP.Molecular Biology of the Cell, 4th. NY: Garland Science, 2002.
ProckopD.J., KivirikkoK.I.Collagens—molecular-biology, diseases, and potentials for therapy. Annu Rev Biochem, 64:403. 1995.
50.
HengE.C., HuangY., BlackS.A.Jr., TrackmanP.C.Ccn2, connective tissue growth factor, stimulates collagen deposition by gingival fibroblasts via module 3 and alpha6- and beta1 integrins. J Cell Biochem, 98:409. 2006.
51.
HongH.H., UzelM.I., DuanC., SheffM.C., TrackmanP.C.Regulation of lysyl oxidase, collagen, and connective tissue growth factor by tgf-beta1 and detection in human gingiva. Lab Invest, 79:1655. 1999.
52.
OlegginiR., GastaldoN., Di DonatoA.Regulation of elastin promoter by lysyl oxidase and growth factors: cross control of lysyl oxidase on TGF-beta1 effects. Matrix Biol, 26:494. 2007.
53.
HahnM.S., JaoC.Y., FaquinW., Grande-AllenK.J.Glycosaminoglycan composition of the vocal fold lamina propria in relation to function. Ann Otol Rhinol Laryngol, 117:371. 2008.
54.
IwasakiS., HosakaY., IwasakiT., YamamotoK., NagayasuA., UedaH.et al.The modulation of collagen fibril assembly and its structure by decorin: an electron microscopic study. Arch Histol Cytol, 71:37. 2008.
55.
LujanT.J., UnderwoodC.J., JacobsN.T., WeissJ.A.Contribution of glycosaminoglycans to viscoelastic tensile behavior of human ligament. J Appl Physiol, 106:423. 2009.
WoessnerJ.F.Mmps and timps—an historical perspective. Mol Biotechnol, 22:33. 2002.
58.
JiaX., JiaM., JhaA.K., FarranA.J.E., TongZ.Dynamic vibrational method and device for vocal fold tissue growth. 2010.
59.
HartnickC.J., RehbarR., PrasadV.Development and maturation of the pediatric human vocal fold lamina propria. Laryngoscope, 115:4. 2005.
60.
SeoJ.Y., LeeS.H., YounC.S., ChoiH.R., RhieG.E., ChoK.H.et al.Ultraviolet radiation increases tropoelastin mrna expression in the epidermis of human skin in vivo. J Invest Dermatol, 116:915. 2001.
61.
ChenC.H., TsaiJ.L., WangY.H., LeeC.L., ChenJ.K., HuangM.H.Low-level laser irradiation promotes cell proliferation and mRNA expression of type I collagen and decorin in porcine Achilles tendon fibroblasts in vitro. J Orthop Res, 27:646. 2009.
62.
ChenX., ThibeaultS.L.Biocompatibility of a synthetic extracellular matrix on immortalized vocal fold fibroblasts in 3-d culture. Acta Biomater, 6:2940. 2010.
63.
RusterB., GottigS., LudwigR.J., BistrianR., MullerS., SeifriedE.et al.Mesenchymal stem cells display coordinated rolling and adhesion behavior on endothelial cells. Blood, 108:3938. 2006.
64.
ImaizumiT., ArikawaT., SatoT., UesatoR., MatsumiyaT., YoshidaH.et al.Involvement of retinoic acid-inducible gene-i in inflammation of rheumatoid fibroblast-like synoviocytes. Clin Exp Immunol, 153:240. 2008.
65.
AstoriG., VignatiF., BardelliS., TubioM., GolaM., AlbertiniV.et al.“In vitro” and multicolor phenotypic characterization of cell subpopulations identified in fresh human adipose tissue stromal vascular fraction and in the derived mesenchymal stem cells. J Transl Med, 5:55. 2007.
66.
ChungC., BurdickJ.A.Influence of three-dimensional hyaluronic acid microenvironments on mesenchymal stem cell chondrogenesis. Tissue Eng Part A, 15:243. 2009.
67.
WuertzK., GodburnK., IatridisJ.C.Msc response to ph levels found in degenerating intervertebral discs. Biochem Biophys Res Commun, 379:824. 2009.
68.
RyanD.H., NuccieB.L., RittermanI., LiesveldJ.L., AbboudC.N., InselR.A.Expression of interleukin-7 receptor by lineage-negative human bone marrow progenitors with enhanced lymphoid proliferative potential and b-lineage differentiation capacity. Blood, 89:929. 1997.
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