Human mesenchymal stromal cells, whether from the bone marrow or adipose tissue (hASCs), are promising cell therapy agents. However, generation of abundant cells for therapy remains to be a challenge, due to the need of lengthy expansion and the risk of accumulating genomic defects during the process. We show that hASCs can be easily induced to a reversible fast-proliferating phenotype (FP-ASCs) that allows rapid generation of a clinically useful quantity of cells in <2 weeks of culture. Expanded FP-ASCs retain their finite expansion capacity and pluripotent properties. Despite the high proliferation rate, FP-ASCs show genomic stability by array-comparative genomic hybridization, and did not generate tumors when implanted for a long time in an SCID mouse model. Comparative analysis of gene expression patterns revealed a set of genes that can be used to characterize FP-ASCs and distinguish them from hASCs. As potential candidate therapeutic agents, FP-ASCs displayed high vasculogenic capacity in Matrigel assays. Moreover, application of hASCs and FP-ASCs in a fibrin scaffold over a myocardium infarct model in SCID mice showed that both cell types can differentiate to endothelial and myocardium lineages, although FP-ASCs were more potent angiogenesis inducers than hASCs, at promoting myocardium revascularization.
Get full access to this article
View all access options for this article.
References
1.
BernardoME, PagliaraD and LocatelliF. (2012). Mesenchymal stromal cell therapy: a revolution in regenerative medicine?. Bone Marrow Transplant, 47:164–171.
2.
LinCS, XinZC, DengCH, NingH, LinG and LueTF. (2010). Defining adipose tissue-derived stem cells in tissue and in culture. Histol Histopathol, 25:807–815.
3.
LinG, GarciaM, NingH, BanieL, GuoYL, LueTF and LinCS. (2008). Defining stem and progenitor cells within adipose tissue. Stem Cells Dev, 17:1053–1063.
4.
KernS, EichlerH, StoeveJ, KluterH and BiebackK. (2006). Comparative analysis of mesenchymal stem cells from bone marrow, umbilical cord blood, or adipose tissue. Stem Cells, 24:1294–1301.
5.
NakanishiC, NagayaN, OhnishiS, YamaharaK, TakabatakeS, KonnoT, HayashiK, KawashiriMA, TsubokawaT and YamagishiM. (2011). Gene and protein expression analysis of mesenchymal stem cells derived from rat adipose tissue and bone marrow. Circ J, 75:2260–2268.
6.
ChandraV, SwethaG, PhadnisS, NairPD and BhondeRR. (2009). Generation of pancreatic hormone-expressing islet-like cell aggregates from murine adipose tissue-derived stem cells. Stem Cells, 27:1941–1953.
RasmussenJG, FrobertO, Holst-HansenC, KastrupJ, BaandrupU, ZacharV, FinkT and SimonsenU. (2012). Comparison of human adipose-derived stem cells and bone marrow-derived stem cells in a myocardial infarction model. Cell Transplant, 23:195–206.
9.
IzadpanahR, TryggC, PatelB, KriedtC, DufourJ, GimbleJM and BunnellBA. (2006). Biologic properties of mesenchymal stem cells derived from bone marrow and adipose tissue. J Cell Biochem, 99:1285–1297.
10.
LazarusHM, KocON, DevineSM, CurtinP, MaziarzRT, HollandHK, ShpallEJ, McCarthyP, AtkinsonK, et al. (2005). Cotransplantation of HLA-identical sibling culture-expanded mesenchymal stem cells and hematopoietic stem cells in hematologic malignancy patients. Biol Blood Marrow Transplant, 11:389–398.
11.
RingdenO, UzunelM, RasmussonI, RembergerM, SundbergB, LonniesH, MarschallHU, DlugoszA, SzakosA, et al. (2006). Mesenchymal stem cells for treatment of therapy-resistant graft-versus-host disease. Transplantation, 81:1390–1397.
12.
CrapnellK, BlaesiusR, HastingsA, LennonDP, CaplanAI and BruderSP. (2013). Growth, differentiation capacity, and function of mesenchymal stem cells expanded in serum-free medium developed via combinatorial screening. Exp Cell Res, 319:1409–1418.
13.
PatrikoskiM, JuntunenM, BoucherS, CampbellA, VemuriMC, MannerstromB and MiettinenS. (2013). Development of fully defined xeno-free culture system for the preparation and propagation of cell therapy-compliant human adipose stem cells. Stem Cell Res Ther, 4:27
14.
ChieregatoK, CastegnaroS, MadeoD, AstoriG, PegoraroM and RodeghieroF. (2011). Epidermal growth factor, basic fibroblast growth factor and platelet-derived growth factor-bb can substitute for fetal bovine serum and compete with human platelet-rich plasma in the ex vivo expansion of mesenchymal stromal cells derived from adipose tissue. Cytotherapy, 13:933–943.
15.
FeketeN, RojewskiMT, LotfiR and SchrezenmeierH. (2014). Essential components for ex vivo proliferation of mesenchymal stromal cells. Tissue Eng Part C Methods, 20:129–139.
16.
GharibiB and HughesFJ. (2012). Effects of medium supplements on proliferation, differentiation potential, and in vitro expansion of mesenchymal stem cells. Stem Cells Transl Med, 1:771–782.
17.
SchallmoserK, RohdeE, ReinischA, BartmannC, ThalerD, DrexlerC, ObenaufAC, LanzerG, LinkeschW and StrunkD. (2008). Rapid large-scale expansion of functional mesenchymal stem cells from unmanipulated bone marrow without animal serum. Tissue Eng Part C Methods, 14:185–196.
18.
SeoJP, TsuzukiN, HanedaS, YamadaK, FuruokaH, TabataY and SasakiN. (2013). Comparison of allogeneic platelet lysate and fetal bovine serum for in vitro expansion of equine bone marrow-derived mesenchymal stem cells. Res Vet Sci, 95:693–698.
19.
ChiouM, XuY and LongakerMT. (2006). Mitogenic and chondrogenic effects of fibroblast growth factor-2 in adipose-derived mesenchymal cells. Biochem Biophys Res Commun, 343:644–652.
20.
KoellenspergerE, von HeimburgD, MarkowiczM and PalluaN. (2006). Human serum from platelet-poor plasma for the culture of primary human preadipocytes. Stem Cells, 24:1218–1225.
21.
KrasKM, HausmanDB and MartinRJ. (2000). Tumor necrosis factor-alpha stimulates cell proliferation in adipose tissue-derived stromal-vascular cell culture: promotion of adipose tissue expansion by paracrine growth factors. Obes Res, 8:186–193.
22.
MiranvilleA, HeeschenC, SengenesC, CuratCA, BusseR and BouloumieA. (2004). Improvement of postnatal neovascularization by human adipose tissue-derived stem cells. Circulation, 110:349–355.
23.
QuartoN and LongakerMT. (2006). FGF-2 inhibits osteogenesis in mouse adipose tissue-derived stromal cells and sustains their proliferative and osteogenic potential state. Tissue Eng, 12:1405–1418.
24.
ZaragosiLE, AilhaudG and DaniC. (2006). Autocrine fibroblast growth factor 2 signaling is critical for self-renewal of human multipotent adipose-derived stem cells. Stem Cells, 24:2412–2419.
25.
MarchalJA, PiconM, PeranM, BuenoC, Jimenez-NavarroM, CarrilloE, BoulaizH, RodriguezN, AlvarezP, et al. (2012). Purification and long-term expansion of multipotent endothelial-like cells with potential cardiovascular regeneration. Stem Cells Dev, 21:562–574.
26.
VilaltaM, DeganoIR, BagoJ, AguilarE, GambhirSS, RubioN and BlancoJ. (2009). Human adipose tissue-derived mesenchymal stromal cells as vehicles for tumor bystander effect: a model based on bioluminescence imaging. Gene Ther, 16:547–557.
27.
SanzL, Santos-ValleP, Alonso-CaminoV, SalasC, SerranoA, VicarioJL, CuestaAM, CompteM, Sanchez-MartinD and Alvarez-VallinaL. (2008). Long-term in vivo imaging of human angiogenesis: critical role of bone marrow-derived mesenchymal stem cells for the generation of durable blood vessels. Microvasc Res, 75:308–314.
28.
RigolaMA, FusterC, CasadevallC, BernuesM, CaballinMR, GelabertA, EgozcueJ and MiroR. (2001). Comparative genomic hybridization analysis of transitional cell carcinomas of the renal pelvis. Cancer Genet Cytogenet, 127:59–63.
29.
IrizarryRA, BolstadBM, CollinF, CopeLM, HobbsB and SpeedTP. (2003). Summaries of Affymetrix GeneChip probe level data. Nucleic Acids Res, 31:e15
30.
BagoJR, AguilarE, AlievaM, Soler-BotijaC, VilaOF, ClarosS, AndradesJA, BecerraJ, RubioN and BlancoJ. (2013). In vivo bioluminescence imaging of cell differentiation in biomaterials: a platform for scaffold development. Tissue Eng Part A, 19:593–603.
31.
BagoJR, Soler-BotijaC, CasaniL, AguilarE, AlievaM, RubioN, Bayes-GenisA and BlancoJ. (2013). Bioluminescence imaging of cardiomyogenic and vascular differentiation of cardiac and subcutaneous adipose tissue-derived progenitor cells in fibrin patches in a myocardium infarct model. Int J Cardiol, 169:288–295.
32.
Bayes-GenisA, Soler-BotijaC, FarreJ, SepulvedaP, RayaA, RouraS, Prat-VidalC, Galvez-MontonC, MonteroJA, BuscherD and Izpisua BelmonteJC. (2010). Human progenitor cells derived from cardiac adipose tissue ameliorate myocardial infarction in rodents. J Mol Cell Cardiol, 49:771–780.
33.
de la FuenteR, BernadA, Garcia-CastroJ, MartinMC and CigudosaJC. (2010). Retraction: spontaneous human adult stem cell transformation. Cancer Res, 70:6682
34.
RubioD, Garcia-CastroJ, MartinMC, de la FuenteR, CigudosaJC, LloydAC and BernadA. (2005). Spontaneous human adult stem cell transformation. Cancer Res, 65:3035–3039.
35.
TarteK, GaillardJ, LatailladeJJ, FouillardL, BeckerM, MossafaH, TchirkovA, RouardH, HenryC, et al. (2010). Clinical-grade production of human mesenchymal stromal cells: occurrence of aneuploidy without transformation. Blood, 115:1549–1553.
36.
SugaH, ShigeuraT, MatsumotoD, InoueK, KatoH, AoiN, MuraseS, SatoK, GondaK, KoshimaI and YoshimuraK. (2007). Rapid expansion of human adipose-derived stromal cells preserving multipotency. Cytotherapy, 9:738–745.
37.
SpragueL, MuccioliM, PateM, MelesE, McGintyJ, NandigamH, VenkateshAK, GuMY, MansfieldK, et al. (2011). The interplay between surfaces and soluble factors define the immunologic and angiogenic properties of myeloid dendritic cells. BMC Immunol, 12:35
38.
SimperD, StalboergerPG, PanettaCJ, WangS and CapliceNM. (2002). Smooth muscle progenitor cells in human blood. Circulation, 106:1199–1204.
39.
XieSZ, FangNT, LiuS, ZhouP, ZhangY, WangSM, GaoHY and PanLF. (2008). Differentiation of smooth muscle progenitor cells in peripheral blood and its application in tissue engineered blood vessels. J Zhejiang Univ Sci B, 9:923–930.
40.
YangS, PilgaardL, ChaseLG, BoucherS, VemuriMC, FinkT and ZacharV. (2012). Defined xenogeneic-free and hypoxic environment provides superior conditions for long-term expansion of human adipose-derived stem cells. Tissue Eng Part C Methods, 18:593–602.
41.
HaunerH, RohrigK and PetruschkeT. (1995). Effects of epidermal growth factor (EGF), platelet-derived growth factor (PDGF) and fibroblast growth factor (FGF) on human adipocyte development and function. Eur J Clin Invest, 25:90–96.
42.
RehmanJ, TraktuevD, LiJ, Merfeld-ClaussS, Temm-GroveCJ, BovenkerkJE, PellCL, JohnstoneBH, ConsidineRV and MarchKL. (2004). Secretion of angiogenic and antiapoptotic factors by human adipose stromal cells. Circulation, 109:1292–1298.
43.
AndersonP, Carrillo-GalvezAB, Garcia-PerezA, CoboM and MartinF. (2013). CD105 (endoglin)-negative murine mesenchymal stromal cells define a new multipotent subpopulation with distinct differentiation and immunomodulatory capacities. PLoS One, 8:e76979
44.
ElicesMJ, OsbornL, TakadaY, CrouseC, LuhowskyjS, HemlerME and LobbRR. (1990). VCAM-1 on activated endothelium interacts with the leukocyte integrin VLA-4 at a site distinct from the VLA-4/fibronectin binding site. Cell, 60:577–584.
45.
OhtaniN, MannDJ and HaraE. (2009). Cellular senescence: its role in tumor suppression and aging. Cancer Sci, 100:792–797.
46.
BellayrIH, CatalanoJG, LababidiS, YangAX, Lo SurdoJL, BauerSR and PuriRK. (2014). Gene markers of cellular aging in human multipotent stromal cells in culture. Stem Cell Res Ther, 5:59
47.
MendicinoM, BaileyAM, WonnacottK, PuriRK and BauerSR. (2014). MSC-based product characterization for clinical trials: an FDA perspective. Cell Stem Cell, 14:141–145.
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.
