Chronic back pain is related to intervertebral disc (IVD) degeneration and dogs are employed as animal models to develop growth factor- and cell-based regenerative treatments. In this respect, the differential effects of transforming growth factor beta-1 (TGF-β1) and bone morphogenetic protein-2 (BMP2) on canine and human chondrocyte-like cells (CLCs) derived from the nucleus pulposus of degenerated IVDs were studied. Human and canine CLCs were cultured in 3D microaggregates in basal culture medium supplemented with/without TGF-β1 (10 ng/mL) or BMP2 (100 or 250 ng/mL). Both TGF-β1 and BMP2 increased proliferation and glycosaminoglycan (GAG) deposition of human and canine CLCs. TGF-β1 induced collagen type I deposition and fibrotic (re)differentiation, whereas BMP2 induced more collagen type II deposition. In dogs, TGF-β1 induced Smad1 and Smad2 signaling, whereas in humans, it only tended to induce Smad2 signaling. BMP2 supplementation increased Smad1 signaling in both species. This altogether indicates that Smad1 signaling was associated with collagen type II production, whereas Smad2 signaling was associated with fibrotic CLC (re)differentiation. As a step toward preclinical translation, treatment with BMP2 alone and combined with mesenchymal stromal cells (MSCs) was further investigated. Canine male CLCs were seeded in albumin-based hydrogels with/without female bone marrow-derived MSCs (50:50) in basal or 250 ng/mL BMP2-supplemented culture medium. Although the results indicate that a sufficient amount of MSCs survived the culture period, total GAG production was not increased and GAG production per cell was even decreased by the addition of MSCs, implying that MSCs did not exert additive regenerative effects on the CLCs.
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References
1.
FreburgerJ.K., HolmesG.M., AgansR.P., JackmanA.M., DarterJ.D., WallaceA.S., CastelL.D., KalsbeekW.D., and CareyT.S.The rising prevalence of chronic low back pain. Arch Intern Med, 169, 251, 2009.
2.
MokF.P., SamartzisD., KarppinenJ., FongD.Y., LukK.D., and CheungK.M.Modic changes of the lumbar spine: prevalence, risk factors, and association with disc degeneration and low back pain in a large-scale population-based cohort. Spine J, 16, 32, 2016.
3.
BennekerL.M., AnderssonG., IatridisJ.C., SakaiD., HartlR., ItoK., and GradS.Cell therapy for intervertebral disc repair: advancing cell therapy from bench to clinics. Eur Cells Mater, 27, 5, 2014.
4.
MahlawatP., IlangovanU., BiswasT., SunL.Z., and HinckA.P.Structure of the Alk1 extracellular domain and characterization of its bone morphogenetic protein (BMP) binding properties. Biochemistry, 51, 6328, 2012.
5.
JainA.P., PundirS., and SharmaA.Bone morphogenetic proteins: the anomalous molecules. J Indian Soc Periodontol, 17, 583, 2013.
6.
GilbertsonL., AhnS.H., TengP.N., StuderR.K., NiyibiziC., and KangJ.D.The effects of recombinant human bone morphogenetic protein-2, recombinant human bone morphogenetic protein-12, and adenoviral bone morphogenetic protein-12 on matrix synthesis in human annulus fibrosis and nucleus pulposus cells. Spine J, 8, 449, 2008.
7.
KimD.J., MoonS.H., KimH., KwonU.H., ParkM.S., HanK.J., HahnS.B., and LeeH.M.Bone morphogenetic protein-2 facilitates expression of chondrogenic, not osteogenic, phenotype of human intervertebral disc cells. Spine (Phila Pa 1976), 28, 2679, 2003.
8.
MoonS.H., NishidaK., GilbertsonL.G., LeeH.M., KimH., HallR.A., RobbinsP.D., and KangJ.D.Biologic response of human intervertebral disc cells to gene therapy cocktail. Spine (Phila Pa 1976), 33, 1850, 2008.
9.
WalshA.J., BradfordD.S., and LotzJ.C.In vivo growth factor treatment of degenerated intervertebral discs. Spine (Phila Pa 1976), 29, 156, 2004.
10.
HuangK.Y., YanJ.J., HsiehC.C., ChangM.S., and LinR.M.The in vivo biological effects of intradiscal recombinant human bone morphogenetic protein-2 on the injured intervertebral disc: an animal experiment. Spine (Phila Pa 1976), 32, 1174, 2007.
11.
PeetersM., DetigerS.E., Karfeld-SulzerL.S., SmitT.H., YayonA., WeberF.E., and HelderM.N.BMP-2 and BMP-2/7 heterodimers conjugated to a fibrin/hyaluronic acid hydrogel in a large animal model of mild intervertebral disc degeneration. Biores Open Access, 4, 398, 2015.
12.
SakaiD., NakaiT., MochidaJ., AliniM., and GradS.Differential phenotype of intervertebral disc cells: microarray and immunohistochemical analysis of canine nucleus pulposus and anulus fibrosus. Spine (Phila Pa 1976), 34, 1448, 2009.
13.
MwaleF., WangH.T., RoughleyP., AntoniouJ., and HaglundL.Link N and mesenchymal stem cells can induce regeneration of the early degenerate intervertebral disc. Tissue Eng Part A, 20, 2942, 2014.
14.
ChenW.H., LiuH.Y., LoW.C., WuS.C., ChiC.H., ChangH.Y., HsiaoS.H., WuC.H., ChiuW.T., ChenB.J., and DengW.P.Intervertebral disc regeneration in an ex vivo culture system using mesenchymal stem cells and platelet-rich plasma. Biomaterials, 30, 5523, 2009.
15.
BucherC., GazdharA., BennekerL.M., GeiserT., and Gantenbein-RitterB.Nonviral gene delivery of growth and differentiation factor 5 to human mesenchymal stem cells injected into a 3D bovine intervertebral disc organ culture system. Stem Cells Int, 2013, 326828, 2013.
16.
MalagolaE., TeunissenM., van der LaanL.J., VerstegenM., SchotanusB.A., van SteenbeekF.G., PenningL.C., van WolferenM.E., TryfonidouM.A., and SpeeB.Characterization and comparison of canine multipotent stromal cells derived from liver and bone marrow. Stem Cells Dev, 25, 139, 2016.
17.
MoM., WangS., ZhouY., LiH., and WuY.Mesenchymal stem cell subpopulations: phenotype, property and therapeutic potential. Cell Mol Life Sci, 73, 3311, 2016.
18.
MeirellesLda, S., FontesA.M., CovasD.T., and CaplanA.I.Mechanisms involved in the therapeutic properties of mesenchymal stem cells. Cytokine Growth Factor Rev, 20, 419, 2009.
19.
SakaiD., MochidaJ., IwashinaT., HiyamaA., OmiH., ImaiM., NakaiT., AndoK., and HottaT.Regenerative effects of transplanting mesenchymal stem cells embedded in atelocollagen to the degenerated intervertebral disc. Biomaterials, 27, 335, 2006.
20.
YangF., LeungV.Y., LukK.D., ChanD., and CheungK.M.Mesenchymal stem cells arrest intervertebral disc degeneration through chondrocytic differentiation and stimulation of endogenous cells. Mol Ther, 17, 1959, 2009.
21.
SakaiD., MochidaJ., IwashinaT., WatanabeT., NakaiT., AndoK., and HottaT.Differentiation of mesenchymal stem cells transplanted to a rabbit degenerative disc model: potential and limitations for stem cell therapy in disc regeneration. Spine (Phila Pa 1976), 30, 2379, 2005.
22.
ChunH.J., KimY.S., KimB.K., KimE.H., KimJ.H., DoB.R., HwangS.J., HwangJ.Y., and LeeY.K.Transplantation of human adipose-derived stem cells in a rabbit model of traumatic degeneration of lumbar discs. World Neurosurg, 78, 364, 2012.
23.
GaneyT., HuttonW.C., MoseleyT., HedrickM., and MeiselH.J.Intervertebral disc repair using adipose tissue-derived stem and regenerative cells: experiments in a canine model. Spine (Phila Pa 1976), 34, 2297, 2009.
24.
HiyamaA., MochidaJ., IwashinaT., OmiH., WatanabeT., SeriganoK., TamuraF., and SakaiD.Transplantation of mesenchymal stem cells in a canine disc degeneration model. J Orthop Res, 26, 589, 2008.
25.
SeriganoK., SakaiD., HiyamaA., TamuraF., TanakaM., and MochidaJ.Effect of cell number on mesenchymal stem cell transplantation in a canine disc degeneration model. J Orthop Res, 28, 1267, 2010.
26.
BergknutN., RutgesJ.P., KranenburgH.J., SmoldersL.A., HagmanR., SmidtH.J., LagerstedtA.S., PenningL.C., VoorhoutG., HazewinkelH.A., GrinwisG.C., CreemersL.B., MeijB.P., and DhertW.J.The dog as an animal model for intervertebral disc degeneration? Spine (Phila Pa 1976), 37, 351, 2012.
27.
SmoldersL.A., BergknutN., GrinwisG.C., HagmanR., LagerstedtA.S., HazewinkelH.A., TryfonidouM.A., and MeijB.P.Intervertebral disc degeneration in the dog. Part 2: chondrodystrophic and non-chondrodystrophic breeds. Vet J, 195, 292, 2013.
28.
BenzK., StippichC., FischerL., MohlK., WeberK., LangJ., SteffenF., BeintnerB., GaissmaierC., and MollenhauerJ.A.Intervertebral disc cell- and hydrogel-supported and spontaneous intervertebral disc repair in nucleotomized sheep. Eur Spine J, 21, 1758, 2012.
29.
BachF.C., de VriesS.A., KrouwelsA., CreemersL.B., ItoK., MeijB.P., and TryfonidouM.A.The species-specific regenerative effects of notochordal cell-conditioned medium on chondrocyte-like cells derived from degenerated human intervertebral discs. Eur Cells Mater, 30, 132, 2015.
30.
LeeK.I., MoonS.H., KimH., KwonU.H., KimH.J., ParkS.N., SuhH., LeeH.M., KimH.S., ChunH.J., KwonI.K., and JangJ.W.Tissue engineering of the intervertebral disc with cultured nucleus pulposus cells using atelocollagen scaffold and growth factors. Spine (Phila Pa 1976), 37, 452, 2012.
31.
NothU., RackwitzL., HeymerA., WeberM., BaumannB., SteinertA., SchutzeN., JakobF., and EulertJ.Chondrogenic differentiation of human mesenchymal stem cells in collagen type I hydrogels. J Biomed Mater Res A, 83, 626, 2007.
32.
FarndaleR.W., SayersC.A., and BarrettA.J.A direct spectrophotometric microassay for sulfated glycosaminoglycans in cartilage cultures. Connect Tissue Res, 9, 247, 1982.
33.
BenzK., StippichC., OsswaldC., GaissmaierC., LembertN., BadkeA., SteckE., AicherW.K., and MollenhauerJ.A.Rheological and biological properties of a hydrogel support for cells intended for intervertebral disc repair. BMC Musculoskelet Disord, 13, 54, 2012.
34.
BertoloA., SteffenF., Malonzo-MartyC., and StoyanovJ.Canine mesenchymal stem cell potential and the importance of dog breed: implication for cell-based therapies. Cell Transplant, 24, 1969, 2015.
35.
Blaney DavidsonE.N., RemstD.F., VittersE.L., van BeuningenH.M., BlomA.B., GoumansM.J., van den BergW.B., and van der KraanP.M.Increase in ALK1/ALK5 ratio as a cause for elevated MMP-13 expression in osteoarthritis in humans and mice. J Immunol, 182, 7937, 2009.
36.
Munoz-FelixJ.M., Gonzalez-NunezM., and Lopez-NovoaJ.M.ALK1-Smad1/5 signaling pathway in fibrosis development: friend or foe? Cytokine Growth Factor Rev, 24, 523, 2013.
37.
KimH., LeeJ.U., MoonS.H., KimH.C., KwonU.H., SeolN.H., KimH.J., ParkJ.O., ChunH.J., KwonI.K., and LeeH.M.Zonal responsiveness of the human intervertebral disc to bone morphogenetic protein-2. Spine (Phila Pa 1976), 34, 1834, 2009.
38.
vanCaam, A., BlaneyDavidson, E., Garcia deVinuesa, A., vanGeffen, E., van denBerg, W., GoumansM.J., tenDijke, P., and van der KraanP.The high affinity ALK1-ligand BMP9 induces a hypertrophy-like state in chondrocytes that is antagonized by TGFbeta1. Osteoarthritis Cartilage, 23, 985, 2015.
39.
CrevenstenG., WalshA.J., AnanthakrishnanD., PageP., WahbaG.M., LotzJ.C., and BervenS.Intervertebral disc cell therapy for regeneration: mesenchymal stem cell implantation in rat intervertebral discs. Ann Biomed Eng, 32, 430, 2004.
40.
WuL., PrinsH.J., HelderM.N., van BlitterswijkC.A., and KarperienM.Trophic effects of mesenchymal stem cells in chondrocyte co-cultures are independent of culture conditions and cell sources. Tissue Eng Part A, 18, 1542, 2012.
41.
VadalaG., StuderR.K., SowaG., SpieziaF., IucuC., DenaroV., GilbertsonL.G., and KangJ.D.Coculture of bone marrow mesenchymal stem cells and nucleus pulposus cells modulate gene expression profile without cell fusion. Spine (Phila Pa 1976), 33, 870, 2008.
42.
SobajimaS., VadalaG., ShimerA., KimJ.S., GilbertsonL.G., and KangJ.D.Feasibility of a stem cell therapy for intervertebral disc degeneration. Spine J, 8, 888, 2008.
43.
BekkersJ.E.J., SarisD.B.F., TsuchidaA.I., VerraW., DhertW.J.A., and CreemersL.B.Co-culturing of Human Bone Marrow Mononuclear Cells and Primary Chondrocytes to Improve Cartilage Formation. Barcelona: ICRS Congress, 2010.
44.
RisbudM.V., SchipaniE., and ShapiroI.M.Hypoxic regulation of nucleus pulposus cell survival: from niche to notch. Am J Pathol, 176, 1577, 2010.
45.
WangF., ShiR., CaiF., WangY.T., and WuX.T.Stem Cell Approaches to Intervertebral Disc Regeneration: Obstacles from the Disc Microenvironment. Stem Cells Dev, 24, 2479, 2015.
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