Neoplastic epithelia may remain dormant and clinically unapparent in human patients for decades. Multiple risk factors including mutations in tumor cells or the stromal cells may affect the switch from dormancy to malignancy. Gene mutations, including p53 mutations, within the stroma of tumors are associated with a worse clinical prognosis; however, it is not known if these stromal mutations can promote tumors in genetically at-risk tissue. To address this question, ApcMin/+ and ApcMin/+ Rag2−/− mice, which have a predilection to mammary carcinoma (as well as wild-type (wt) mice), received mesenchymal stem cells (MSC) with mutant p53 (p53MSC) transferred via tail vein injection. In the wt mouse, p53MSC circulated in the periphery and homed to the marrow cavity where they could be recovered up to a year later without apparent effect on the health of the mouse. No mammary tumors were found. However, in mice carrying the ApcMin/+ mutation, p53MSC homed to mammary tissue and significantly increased the incidence of mammary carcinoma. Tumor necrosis factor (TNF)-α-dependent factors elaborated from mesenchymal cells converted quiescent epithelia into clinically apparent disease. The increased cancer phenotype was completely preventable with neutralization of TNF-α or by transfer of CD4+ regulatory T cells from immune competent donors, demonstrating that immune competency to regulate inflammation was sufficient to maintain neoplastic dormancy even in the presence of oncogenic epithelial and stromal mutations. The significant synergy between host immunity and mesenchymal cells identified here may restructure treatments to restore an anticancer microenvironment.
Get full access to this article
View all access options for this article.
References
1.
FolkmanJ, KalluriR. 2004. Cancer without disease. Nature, 427:787.
2.
NielsenM, ThomsenJL, PrimdahlS, DyreborgU, AndersenJA. 1987. Breast cancer and atypia among young and middle-aged women: a study of 110 medicolegal autopsies. Br J Cancer, 56:814–819.
3.
MontieJE, WoodDPJr, PontesJE, BoyettJM, LevinHS. 1989. Adenocarcinoma of the prostate in cystoprostatectomy specimens removed for bladder cancer. Cancer, 63:381–385.
4.
HarachHR, FranssilaKO, WaseniusVM. 1985. Occult papillary carcinoma of the thyroid. A “normal”. finding in Finland. A systematic autopsy study. Cancer, 56:531–538.
5.
BrittanM, ChanceV, EliaG, PoulsomR, AlisonMR, MacDonaldTT, WrightNA. 2005. A regenerative role for bone marrow following experimental colitis: contribution to neovasculogenesis and myofibroblasts. Gastroenterology, 128:1984–1995.
6.
NakagawaH, LiyanarachchiS, DavuluriRV, AuerH, MartinEWJr, de la ChapelleA, FrankelWL. 2004. Role of cancer-associated stromal fibroblasts in metastatic colon cancer to the liver and their expression profiles. Oncogene, 23:7366–7377.
7.
KarnoubAE, DashAB, VoAP, SullivanA, BrooksMW, BellGW, RichardsonAL, PolyakK, TuboR, WeinbergRA. 2007. Mesenchymal stem cells within tumour stroma promote breast cancer metastasis. Nature, 449:557–563.
8.
MaffiniMV, SotoAM, CalabroJM, UcciAA, SonnenscheinC. 2004. The stroma as a crucial target in rat mammary gland carcinogenesis. J Cell Sci, 117,Pt 8:1495–1502.
9.
HillR, SongY, CardiffRD, Van DykeT. 2005. Selective evolution of stromal mesenchyme with p53 loss in response to epithelial tumorigenesis. Cell, 123:1001–1011.
10.
BierieB, MosesHL. 2005. Under pressure: stromal fibroblasts change their ways. Cell, 123:985–987.
11.
KiarisH, ChatzistamouI, TrimisG, Frangou-PlemmenouM, Pafiti-KondiA, KalofoutisA. 2005. Evidence for nonautonomous effect of p53 tumor suppressor in carcinogenesis. Cancer Res, 65:1627–1630.
12.
HoughtonJ, StoicovC, NomuraS, RogersAB, CarlsonJ, LiH, CaiX, FoxJG, GoldenringJR, WangTC. 2004. Gastric cancer originating from bone marrow-derived cells. Science, 306:1568–1571.
13.
LiH, FanX, KoviRC, JoY, MoquinB, KonzR, StoicovC, Kurt-JonesE, GrossmanSR, LyleS, RogersAB, MontroseM, HoughtonJ. 2007. Spontaneous expression of embryonic factors and p53 point mutations in aged mesenchymal stem cells: a model of age-related tumorigenesis in mice. Cancer Res, 67:10889–10898.
14.
KuroseK, GilleyK, MatsumotoS, WatsonPH, ZhouXP, EngC. 2002. Frequent somatic mutations in PTEN and TP53 are mutually exclusive in the stroma of breast carcinomas. Nat Genet, 32:355–357.
15.
PatocsA, ZhangL, XuY, WeberF, CaldesT, MutterGL, PlatzerP, EngC. 2007. Breast-cancer stromal cells with TP53 mutations and nodal metastases. N Engl J Med, 357:2543–2551.
CampbellIG, QiuW, PolyakK, HavivI. 2008. Breast-cancer stromal cells with TP53 mutations. N Engl J Med, 358:1634–5author reply 1636.
18.
ZanderCS, SoussiT. 2008. Breast-cancer stromal cells with TP53 mutations. N Engl J Med, 358:1635author reply 1636.
19.
ZalcmanG, BergotE, HainautP. 2008. Breast-cancer stromal cells with TP53 mutations. N Engl J Med, 358:1635–6author reply 1636.
20.
PetitjeanA, MatheE, KatoS, IshiokaC, TavtigianSV, HainautP, OlivierM. 2007. Impact of mutant p53 functional properties on TP53 mutation patterns and tumor phenotype: lessons from recent developments in the IARC TP53 database. Hum Mutat, 28:622–629.
21.
MoserAR, LuongoC, GouldKA, McNeleyMK, ShoemakerAR, DoveWF. 1995. ApcMin: a mouse model for intestinal and mammary tumorigenesis. Eur J Cancer, 31A:1061–1064.
22.
RaoVP, PoutahidisT, GeZ, NambiarPR, HorwitzBH, FoxJG, ErdmanSE. 2006. Proinflammatory CD4+ CD45RB(hi) lymphocytes promote mammary and intestinal carcinogenesis in Apc(Min/+) mice. Cancer Res, 66:57–61.
23.
RaoVP, PoutahidisT, GeZ, NambiarPR, BoussahmainC, WangYY, HorwitzBH, FoxJG, ErdmanSE. 2006. Innate immune inflammatory response against enteric bacteria Helicobacter hepaticus induces mammary adenocarcinoma in mice. Cancer Res, 66:7395–7400.
24.
DunnGP, BruceAT, IkedaH, OldLJ, SchreiberRD. 2002. Cancer immunoediting: from immunosurveillance to tumor escape. Nat Immunol, 3:991–998.
25.
DunnGP, OldLJ, SchreiberRD. 2004. The three Es of cancer immunoediting. Annu Rev Immunol, 22:329–360.
26.
KoebelCM, VermiW, SwannJB, ZerafaN, RodigSJ, OldLJ, SmythMJ, SchreiberRD. 2007. Adaptive immunity maintains occult cancer in an equilibrium state. Nature, 450:903–907.
27.
ErdmanSE, RaoVP, PoutahidisT, IhrigMM, GeZ, FengY, TomczakM, RogersAB, HorwitzBH, FoxJG. 2003. CD4(+)CD25(+) regulatory lymphocytes require interleukin 10 to interrupt colon carcinogenesis in mice. Cancer Res, 63:6042–6050.
28.
PowrieF, MaloyKJ. 2003. Immunology. Regulating the regulators. Science, 299:1030–1031.
ErdmanSE, PoutahidisT, TomczakM, RogersAB, CormierK, PlankB, HorwitzBH, FoxJG. 2003. CD4+ CD25+ regulatory T lymphocytes inhibit microbially induced colon cancer in Rag2-deficient mice. Am J Pathol, 162:691–702.
31.
ErdmanSE, SohnJJ, RaoVP, NambiarPR, GeZ, FoxJG, SchauerDB. 2005. CD4+CD25+ regulatory lymphocytes induce regression of intestinal tumors in ApcMin/+ mice. Cancer Res, 65:3998–4004.
32.
GounarisE, ErdmanSE, RestainoC, GurishMF, FriendDS, GounariF, LeeDM, ZhangG, GlickmanJN, ShinK, RaoVP, PoutahidisT, WeisslederR, McNagnyKM, KhazaieK. 2007. Mast cells are an essential hematopoietic component for polyp development. Proc Natl Acad Sci USA, 104:19977–19982.
33.
HoKY, KalleWH, LoTH, LamWY, TangCM. 1999. Reduced expression of APC and DCC gene protein in breast cancer. Histopathology, 35:249–256.
34.
SchlosshauerPW, BrownSA, EisingerK, YanQ, GuglielminettiER, ParsonsR, EllensonLH, KitajewskiJ. 2000. APC truncation and increased β-catenin levels in a human breast cancer cell line. Carcinogenesis, 21:1453–1456.
35.
ClaytonA, EvansRA, PettitE, HallettM, WilliamsJD, SteadmanR. 1998. Cellular activation through the ligation of intercellular adhesion molecule-1. J Cell Sci, 111,Pt 4:443–453.
36.
ZeisbergM, StrutzF, MülerGA. 2000. Role of fibroblast activation in inducing interstitial fibrosis. J Nephrol, 13,Suppl 3:S111–S120.
37.
Rønov-JessenL, PetersenOW. 1993. Induction of alpha-smooth muscle actin by transforming growth factor-beta 1 in quiescent human breast gland fibroblasts. Implications for myofi broblast generation in breast neoplasia. Lab Invest, 68:696–707.
38.
IwanoM, PliethD, DanoffTM, XueC, OkadaH, NeilsonEG. 2002. Evidence that fibroblasts derive from epithelium during tissue fibrosis. J Clin Invest, 110:341–350.
39.
DirekzeNC, ForbesSJ, BrittanM, HuntT, JefferyR, PrestonSL, PoulsomR, Hodivala-DilkeK, AlisonMR, WrightNA. 2003. Multiple organ engraftment by bone-marrow-derived myofi broblasts and fibroblasts in bone-marrow-transplanted mice. Stem Cells, 21:514–520.
40.
DirekzeNC, Hodivala-DilkeK, JefferyR, HuntT, PoulsomR, OukrifD, AlisonMR, WrightNA. 2004. Bone marrow contribution to tumor-associated myofi broblasts and fibroblasts. Cancer Res, 64:8492–8495.
41.
DesmoulièreA, GuyotC, GabbianiG. 2004. The stroma reaction myofi broblast: a key player in the control of tumor cell behavior. Int J Dev Biol, 48:509–517.
42.
JodeleS, ChantrainCF, BlavierL, LutzkoC, CrooksGM, ShimadaH, CoussensLM, DeclerckYA. 2005. The contribution of bone marrow-derived cells to the tumor vasculature in neuroblastoma is matrix metalloproteinase-9 dependent. Cancer Res, 65:3200–3208.
OverallCM, DeanRA. 2006. Degradomics: systems biology of the protease web. Pleiotropic roles of MMPs in cancer. Cancer Metastasis Rev, 25:69–75.
45.
PeiD. 2005. Matrix metalloproteinases target protease-activated receptors on the tumor cell surface. Cancer Cell, 7:207–208.
46.
RubioD, Garcia-CastroJ, MartínMC, de la FuenteR, CigudosaJC, LloydAC, BernadA. 2005. Spontaneous human adult stem cell transformation. Cancer Res, 65:3035–3039.
47.
SerakinciN, GuldbergP, BurnsJS, AbdallahB, SchrøderH, JensenT, KassemM. 2004. Adult human mesenchymal stem cell as a target for neoplastic transformation. Oncogene, 23:5095–5098.
48.
SpaethE, KloppA, DembinskiJ, AndreeffM, MariniF. 2008. Inflammation and tumor microenvironments: defining the migratory itinerary of mesenchymal stem cells. Gene Ther, 15:730–738.
49.
KrauseDS, TheiseND, CollectorMI, HenegariuO, HwangS, GardnerR, NeutzelS, SharkisSJ. 2001. Multi-organ, multi-lineage engraftment by a single bone marrow-derived stem cell. Cell, 105:369–377.
MariónRM, StratiK, LiH, MurgaM, BlancoR, OrtegaS, Fernandez-CapetilloO, SerranoM, BlascoMA. 2009. A p53-mediated DNA damage response limits reprogramming to ensure iPS cell genomic integrity. Nature, 460:1149–1153.
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.
