The derivation of osteogenic cells from human embryonic stem cells (hESCs) or from induced pluripotent stem cells for bone regeneration would be a welcome alternative to the use of adult stem cells. In an attempt to promote hESC osteogenic differentiation, cells of the HSF-6 line were cultured in differentiating conditions in vitro for prolonged periods of time ranging from 7 to 14.5 weeks, followed by in vivo transplantation into immunocompromised mice in conjunction with hydroxyapatite/tricalcium phosphate ceramic powder. Twelve different medium compositions were tested, along with a number of other variables in culture parameters. In differentiating conditions, HSF-6-derived cells demonstrated an array of diverse phenotypes reminiscent of multiple tissues, but after a few passages, acquired a more uniform, fibroblast-like morphology. Eight to 16 weeks post-transplantation, a group of transplants revealed the formation of histologically proven bone of human origin, including broad areas of multiple intertwining trabeculae, which represents by far the most extensive in vivo bone formation by the hESC-derived cells described to date. Knockout-Dulbecco's modified Eagle's medium-based media with fetal bovine serum, dexamethasone, and ascorbate promoted more frequent bone formation, while media based on α-modified minimum essential medium promoted teratoma formation in 12- to 20-week-old transplants. Transcription levels of pluripotency-related (octamer binding protein 4, Nanog), osteogenesis-related (collagen type I, Runx2, alkaline phosphatase, and bone sialoprotein), and chondrogenesis-related (collagen types II and X, and aggrecan) genes were not predictive of either bone or teratoma formation. The most extensive bone was formed by the strains that, following 4 passages in monolayer conditions, were cultured for 23 to 25 extra days on the surface of hydroxyapatite/tricalcium phosphate particles, suggesting that coculturing of hESC-derived cells with osteoconductive material may increase their osteogenic potential. While none of the conditions tested in this study, and elsewhere, ensured consistent bone formation by hESC-derived cells, our results may elucidate further directions toward the construction of bone on the basis of hESCs or an individual's own induced pluripotent stem cells.
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References
1.
RoitbergB.2003. Improvement in the ability to direct the differentiation of embryonic stem cells. Surg Neurol, 60:3–4.
2.
AhnSE., KimS., ParkKH.et al.2006. Primary bone-derived cells induce osteogenic differentiation without exogenous factors in human embryonic stem cells. Biochem Biophys Res Commun, 340:403–408.
3.
ArpornmaeklongP., BrownSE., WangZ., KrebsbachPH. 2009. Phenotypic characterization, osteoblastic differentiation, and bone regeneration capacity of human embryonic stem cell-derived mesenchymal stem cells. Stem Cells Dev, 18:955–968.
4.
BarberiT., WillisLM., SocciND., StuderL. 2005. Derivation of multipotent mesenchymal precursors from human embryonic stem cells. PLoS Med, 2:e161.
5.
BielbyRC., BoccacciniAR., PolakJM., ButteryLD. 2004. In vitro differentiation and in vivo mineralization of osteogenic cells derived from human embryonic stem cells. Tissue Eng, 10:1518–1525.
6.
KarnerE., UngerC., SloanAJ., Ahrlund-RichterL., SugarsRV., WendelM. 2007. Bone matrix formation in osteogenic cultures derived from human embryonic stem cells in vitro. Stem Cells Dev, 16:39–52.
7.
KarpJM., FerreiraLS., KhademhosseiniA., KwonAH., YehJ., LangerRS. 2006. Cultivation of human embryonic stem cells without the embryoid body step enhances osteogenesis in vitro. Stem Cells, 24:835–843.
8.
LianQ., LyeE., Suan YeoK.et al. 2007. Derivation of clinically compliant MSCs from CD105 + , CD24- differentiated human ESCs. Stem Cells, 25:425–436.
9.
OlivierEN., RybickiAC., BouhassiraEE. 2006. Differentiation of human embryonic stem cells into bipotent mesenchymal stem cells. Stem Cells, 24:1914–1922.
10.
SottileV., ThomsonA., McWhirJ. 2003. In vitro osteogenic differentiation of human ES cells. Cloning Stem Cells, 5:149–155.
11.
BennettJH., JoynerCJ., TriffittJT., OwenME. 1991. Adipocytic cells cultured from marrow have osteogenic potential. J Cell Sci, 99,Pt 1:131–139.
12.
Castano-IzquierdoH., Alvarez-BarretoJ., van den DolderJ., JansenJA., MikosAG., SikavitsasVI. 2007. Pre-culture period of mesenchymal stem cells in osteogenic media influences their in vivo bone forming potential. J Biomed Mater Res A, 82:129–138.
13.
De KokIJ., HicokKC., PadillaRJ., YoungRG., CooperLF. 2006. Effect of vitamin D pretreatment of human mesenchymal stem cells on ectopic bone formation. J Oral Implantol, 32:103–109.
14.
DerubeisAR., MastrogiacomoM., CanceddaR., QuartoR. 2003. Osteogenic potential of rat spleen stromal cells. Eur J Cell Biol, 82:175–181.
15.
MendesSC., TibbeJM., VeenhofM.et al. 2004. Relation between in vitro and in vivo osteogenic potential of cultured human bone marrow stromal cells. J Mater Sci Mater Med, 15:1123–1128.
16.
SabatiniF., PetecchiaL., TavianM., Jodon de VillerocheV., RossiGA., Brouty-BoyeD. 2005. Human bronchial fibroblasts exhibit a mesenchymal stem cell phenotype and multilineage differentiating potentialities. Lab Invest, 85:962–971.
17.
SacchettiB., FunariA., MichienziS.et al. 2007. Self-renewing osteoprogenitors in bone marrow sinusoids can organize a hematopoietic microenvironment. Cell, 131:324–336.
18.
SudoK., KannoM., MiharadaK.et al. 2007. Mesenchymal progenitors able to differentiate into osteogenic, chondrogenic, and/or adipogenic cells in vitro are present in most primary fibroblast-like cell populations. Stem Cells, 25:1610–1617.
19.
KimS., KimSS., LeeSH.et al. 2008. In vivo bone formation from human embryonic stem cell-derived osteogenic cells in poly(d,l-lactic-co-glycolic acid)/hydroxyapatite composite scaffolds. Biomaterials, 29:1043–1053.
20.
TremoledaJL., ForsythNR., KhanNS.et al. 2008. Bone tissue formation from human embryonic stem cells in vivo. Cloning Stem Cells, 10:119–132.
21.
KuznetsovSA., KrebsbachPH., SatomuraK.et al. 1997. Single-colony derived strains of human marrow stromal fibroblasts form bone after transplantation in vivo. J Bone Miner Res, 12:1335–1347.
22.
KrebsbachPH., KuznetsovSA., SatomuraK., EmmonsRV., RoweDW., RobeyPG. 1997. Bone formation in vivo: comparison of osteogenesis by transplanted mouse and human marrow stromal fibroblasts. Transplantation, 63:1059–1069.
23.
MankaniMH., KuznetsovSA., FowlerB., KingmanA., RobeyPG. 2001. In vivo bone formation by human bone marrow stromal cells: effect of carrier particle size and shape. Biotechnol Bioeng, 72:96–107.
24.
DasAK., PalR. 2010. Induced pluripotent stem cells (iPSCs): the emergence of a new champion in stem cell technology-driven biomedical applications. J Tissue Eng Regen Med[Epub ahead of print].
25.
FriedensteinAJ., ChailakhyanRK., GerasimovUV. 1987. Bone marrow osteogenic stem cells: in vitro cultivation and transplantation in diffusion chambers. Cell Tissue Kinet, 20:263–272.
26.
MankaniMH., KuznetsovSA., ShannonB.et al. 2006. Canine cranial reconstruction using autologous bone marrow stromal cells. Am J Pathol, 168:542–550.
27.
BiancoP., RiminucciM., GronthosS., RobeyPG. 2001. Bone marrow stromal stem cells: nature, biology, and potential applications. Stem Cells, 19:180–192.
28.
BradbeerJN., RiminucciM., BiancoP. 1994. Giemsa as a fluorescent stain for mineralized bone. J Histochem Cytochem, 42:677–680.
29.
de CarvalhoHF., TabogaSR. 1996. Fluorescence and confocal laser scanning microscopy imaging of elastic fibers in hematoxylin-eosin stained sections. Histochem Cell Biol, 106:587–592.
30.
KastenP., VogelJ., LuginbuhlR.et al. 2005. Ectopic bone formation associated with mesenchymal stem cells in a resorbable calcium deficient hydroxyapatite carrier. Biomaterials, 26:5879–5889.
31.
MendesSC., TibbeJM., VeenhofM.et al. 2002. Bone tissue-engineered implants using human bone marrow stromal cells: effect of culture conditions and donor age. Tissue Eng, 8:911–920.
32.
SongIH., CaplanAI., DennisJE. 2009. In vitro dexamethasone pretreatment enhances bone formation of human mesenchymal stem cells in vivo. J Orthop Res, 27:916–921.
33.
YamanouchiK., SatomuraK., GotohY.et al. 2001. Bone formation by transplanted human osteoblasts cultured within collagen sponge with dexamethasone in vitro. J Bone Miner Res, 16:857–867.
34.
KimCH., ChengSL., KimGS. 1999. Effects of dexamethasone on proliferation, activity, and cytokine secretion of normal human bone marrow stromal cells: possible mechanisms of glucocorticoid-induced bone loss. J Endocrinol, 162:371–379.
35.
ChoiKM., SeoYK., YoonHH.et al. 2008. Effect of ascorbic acid on bone marrow-derived mesenchymal stem cell proliferation and differentiation. J Biosci Bioeng, 105:586–594.
36.
TurgemanG., PittmanDD., MullerR.et al. 2001. Engineered human mesenchymal stem cells: a novel platform for skeletal cell mediated gene therapy. J Gene Med, 3:240–251.
37.
PradelW., EckeltU., LauerG. 2006. Bone regeneration after enucleation of mandibular cysts: comparing autogenous grafts from tissue-engineered bone and iliac bone. Oral Surg Oral Med Oral Pathol Oral Radiol Endod, 101:285–290.
38.
SchmelzeisenR., SchimmingR., SittingerM. 2003. Making bone: implant insertion into tissue-engineered bone for maxillary sinus floor augmentation-a preliminary report. J Craniomaxillofac Surg, 31:34–39.
39.
ArinzehTL., TranT., McAlaryJ., DaculsiG. 2005. A comparative study of biphasic calcium phosphate ceramics for human mesenchymal stem-cell-induced bone formation. Biomaterials, 26:3631–3638.
40.
DagaA., MuragliaA., QuartoR., CanceddaR., CorteG. 2002. Enhanced engraftment of EPO-transduced human bone marrow stromal cells transplanted in a 3D matrix in non-conditioned NOD/SCID mice. Gene Ther, 9:915–921.
41.
HarrisCT., CooperLF. 2004. Comparison of bone graft matrices for human mesenchymal stem cell-directed osteogenesis. J Biomed Mater Res A, 68:747–755.
42.
KhlusovIA., KarlovAV., SharkeevYP.et al. 2005. Osteogenic potential of mesenchymal stem cells from bone marrow in situ: role of physicochemical properties of artificial surfaces. Bull Exp Biol Med, 140:144–152.
43.
MastrogiacomoM., MuragliaA., KomlevV.et al. 2005. Tissue engineering of bone: search for a better scaffold. Orthod Craniofac Res, 8:277–284.
44.
WarrenSM., NacamuliRK., SongHM., LongakerMT. 2004. Tissue-engineered bone using mesenchymal stem cells and a biodegradable scaffold. J Craniofac Surg, 15:34–37.
45.
KuznetsovSA., FriedensteinAJ., RobeyPG. 1997. Factors required for bone marrow stromal fibroblast colony formation in vitro. Br J Haematol, 97:561–570.
46.
Perez-SanchezMJ., Ramirez-GlindonE., Lledo-GilM., Calvo-GuiradoJL., Perez-SanchezC. 2009. Biomaterials for bone regeneration. Med Oral Patol Oral Cir Bucal, 15:e517–e522.
47.
SchopperC., Ziya-GhazviniF., GoriwodaW.et al. 2005. HA/TCP compounding of a porous CaP biomaterial improves bone formation and scaffold degradation—a long-term histological study. J Biomed Mater Res B Appl Biomater, 74:458–467.
48.
BurnsJS., RasmussenPL., LarsenKH., SchroderHD., KassemM. 2010. Parameters in 3D “Osteospheroids” of telomerized human mesenchymal (stromal) stem cells grown on osteoconductive scaffolds that predict in vivo bone forming potential. Tissue Eng Part A, 16:2331–2342.
49.
AubinJE. 1998. Bone stem cells. J Cell Biochem Suppl, 30–31:73–82.
50.
Viguet-CarrinS., GarneroP., DelmasPD. 2006. The role of collagen in bone strength. Osteoporos Int, 17:319–336.
51.
ChevallierN., AnagnostouF., ZilberS.et al. 2009. Osteoblastic differentiation of human mesenchymal stem cells with platelet lysate. Biomaterials, 31:270–278.
52.
SchroederTM., JensenED, WestendorfJJ. 2005. Runx2: a master organizer of gene transcription in developing and maturing osteoblasts. Birth Defects Res C Embryo Today, 75:213–225.
53.
MillanJL. 2006. Alkaline phosphatases: structure, substrate specificity and functional relatedness to other members of a large superfamily of enzymes. Purinergic Signal, 2:335–341.
54.
OrimoH.2010. The mechanism of mineralization and the role of alkaline phosphatase in health and disease. J Nippon Med Sch, 77:4–12.
55.
BlumB., BenvenistyN. 2009. The tumorigenicity of diploid and aneuploid human pluripotent stem cells. Cell Cycle, 8:3822–3830.
OgataY.2008. Bone sialoprotein and its transcriptional regulatory mechanism. J Periodontal Res, 43:127–135.
58.
LarsenKH., FrederiksenCM., BurnsJS., AbdallahBM., KassemM. 2010. Identifying a molecular phenotype for bone marrow stromal cells with in vivo bone forming capacity. J Bone Miner Res, 25:796–808.
59.
BarryF., BoyntonRE., LiuB., MurphyJM. 2001. Chondrogenic differentiation of mesenchymal stem cells from bone marrow: differentiation-dependent gene expression of matrix components. Exp Cell Res, 268:189–200.
60.
HycA., Osiecka-IwanA., JozwiakJ., MoskalewskiS. 2001. The morphology and selected biological properties of articular cartilage. Orthop Traumatol Rehabil, 3:151–162.
61.
MwaleF., StachuraD., RoughleyP., AntoniouJ. 2006. Limitations of using aggrecan and type X collagen as markers of chondrogenesis in mesenchymal stem cell differentiation. J Orthop Res, 24:1791–1798.
62.
TewSR, MurdochAD., RauchenbergRP., HardinghamTE. 2008. Cellular methods in cartilage research: primary human chondrocytes in culture and chondrogenesis in human bone marrow stem cells. Methods, 45:2–9.
63.
MallonBS., ParkKY., ChenKG., HamiltonRS., McKayRD. 2006. Toward xeno-free culture of human embryonic stem cells. Int J Biochem Cell Biol, 38:1063–1075.
64.
DraperJS., SmithK., GokhaleP.et al. 2004. Recurrent gain of chromosomes 17q and 12 in cultured human embryonic stem cells. Nat Biotechnol, 22:53–54.
65.
PrzyborskiSA. 2005. Differentiation of human embryonic stem cells after transplantation in immune-deficient mice. Stem Cells, 23:1242–1250.
66.
ThomsonJA., Itskovitz-EldorJ., ShapiroSS.et al. 1998. Embryonic stem cell lines derived from human blastocysts. Science, 282:1145–1147.
67.
BrivanlouAH., GageFH., JaenischR., JessellT., MeltonD., RossantJ. 2003. Stem cells. Setting standards for human embryonic stem cells. Science, 300:913–916.
68.
HwangWS., RyuYJ., ParkJH.et al. 2004. Evidence of a pluripotent human embryonic stem cell line derived from a cloned blastocyst. Science, 303:1669–1674.
69.
LeesJG., LimSA., CrollT.et al. 2007. Transplantation of 3D scaffolds seeded with human embryonic stem cells: biological features of surrogate tissue and teratoma-forming potential. Regen Med, 2:289–300.
70.
LiZ., LeungM., HopperR., EllenbogenR., ZhangM. 2010. Feeder-free self-renewal of human embryonic stem cells in 3D porous natural polymer scaffolds. Biomaterials, 31:404–412.
71.
AbelevGI., EraiserTL. 1999. Cellular aspects of alpha-fetoprotein reexpression in tumors. Semin Cancer Biol, 9:95–107.
CarrellRW. 2004. What we owe to alpha(1)-antitrypsin and to Carl-Bertil Laurell. COPD, 1:71–84.
74.
SchweizerJ., BowdenPE., CoulombePA.et al. 2006. New consensus nomenclature for mammalian keratins. J Cell Biol, 174:169–174.
75.
PerrotR., BergesR., BocquetA., EyerJ. 2008. Review of the multiple aspects of neurofilament functions, and their possible contribution to neurodegeneration. Mol Neurobiol, 38:27–65.
76.
AmitM., CarpenterMK., InokumaMS.et al. 2000. Clonally derived human embryonic stem cell lines maintain pluripotency and proliferative potential for prolonged periods of culture. Dev Biol, 227:271–278.
77.
JukesJM., BothSK., LeusinkA., SterkLM., van BlitterswijkCA., de BoerJ. 2008. Endochondral bone tissue engineering using embryonic stem cells. Proc Natl Acad Sci USA, 105:6840–6845.
