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CO-Culture with Mesenchymal Cells Modulates TGF-Beta/Smad And Mapk Pathways in T Regulatory Cells

2008; Elsevier BV; Volume: 112; Issue: 11 Linguagem: Inglês

10.1182/blood.v112.11.676.676

1528-0020

Mauro Di Ianni, Beatrice Del Papa, Lorenzo Moretti, Simonetta Piattoni, Debora Cecchini, Ezio Bonifacio, Franca Falzetti, Antonio Tabilio,

Immune cells in cancer

Abstract We previously demonstrated that when human bone marrow-derived mesenchymal cells (hMSCs) were co-cultured with CD4+/CD25+ T regulatory cells (Tregs) they maintained the T regulatory phenotype and function over time. Here we studied the TGF-beta/Smad signalling and mitogen-activated protein kinase (MAPK) pathways after Tregs/hMSCs co-culture. After 7 days co-culture of highly purified, immuno-selected Tregs and hMSCs from healthy donors, TGF-beta and IL-10 concentrations were dosed and mRNA of a panel of genes (NFAT, Smad4, Smad7, AP-1, Foxp3 and CD127) was quantified on harvested lymphocytes. Western blotting was performed by incubation with antiSMAD2, anti-pSMAD2, anti-ERK1/2 and anti-pERK1/2 polyclonal antibodies. After immuno-magnetic cell separation the final Treg fraction showed a mean purity of 93.6%±1. The CD4+/CD25+bright constituted 29%±7 of Tregs, FoxP3 cells constituted 51.9%±15.1 and CD127+ cells 19%±11.5. CD4+/CD25+ cells inhibited CD4+/CD25− cells (mean inhibition percentage: 52.1±29.6% (ratio 1:1). Tregs produced no TGF-beta and only a small quantity of IL-10 (8.67±4 pg/ml). hMSCs produced high quantity of TGF-beta (229.3 ± 54.8 pg/ml) associated with little IL-10 (2.7 ± 1.2 pg/ml). After co-culture, the TGF-beta concentration was 91.5±48.5 pg/ml while the IL-10 concentration was no different to baseline. To identify TGF-beta signaling pathways, we focused on Smad2, a central element in the cascade. In Tregs the strongly expressed pSmad2 signal after selection rapidly decreased after 7 days culture. When Tregs were co-cultured in presence of hMSCs the phosphorylated form of Smad2 did not change, indicating TGF-beta signaling was up-regulated. After co-culture mRNA quantification showed hMSCs down-regulated expression of SMAD7 (−8.9± 4.4 times vs Tregs without hMSCs), a negative regulator of TGF-beta signaling. After co-culture with hMSCs non-regulatory CD4+/CD25− control cells did not show any differences in SMAD7 expression. To study the MAPK kinase pathways, harvested Tregs were assayed for ERK1/2 kinase activity by determining their phosphorylated forms. pERK1/2 was almost absent in selected Tregs; it rapidly increased after 7 days in vitro culture without hMSCs but remained low after co-culture with hMSCs, indicating impaired ERK1/2 activation. AP-1 activation was also reduced (AP-1 mRNA −32±29 times less than controls). In conclusion, co-cultures of hMSCs and Tregs have the potential to set up a positive feedback loop that heightens responsiveness to TFG-beta in Treg cells. In fact, hMSCs produce TGF-beta which is consumed in co-culture with Tregs; TGF-beta1 signaling in Tregs is maintained through pSMAD2 up-regulation and SMAD7 down-regulation; hMSCs also inhibit ERK phosphorylation which consequently down-regulates AP-1 mRNA. Thus Tregs signalling is maintained through culture on a layer of hMSCs. Manipulation of Tregs signaling through culture on a layer of hMSCs may represent a novel strategy for maintenance of Treg phenotype and function.