Antigen receptor-mediated depletion of FOXP3 in induced regulatory T-lymphocytes via PTPN2 and FOXO1.
Evita BothurHartmann RaiferClaudia HaftmannAnna-Barbara StittrichAnne BrüstleDirk BrennerNadine BolligMaria BieringerChol-Ho KangKatharina ReinhardBärbel CamaraMagdalena HuberAlexander VisekrunaUlrich SteinhoffAntje RepenningUta-Maria BauerVeronika SexlAndreas RadbruchTim SparwasserMir-Farzin MashreghiTak Wah MakMichael LohoffPublished in: Nature communications (2015)
Regulatory T-cells induced via IL-2 and TGFβ in vitro (iTreg) suppress immune cells and are potential therapeutics during autoimmunity. However, several reports described their re-differentiation into pathogenic cells in vivo and loss of their key functional transcription factor (TF) FOXP3 after T-cell antigen receptor (TCR)-signalling in vitro. Here, we show that TCR-activation antagonizes two necessary TFs for foxp3 gene transcription, which are themselves regulated by phosphorylation. Although the tyrosine phosphatase PTPN2 is induced to restrain IL-2-mediated phosphorylation of the TF STAT5, expression of the TF FOXO1 is downregulated and miR-182, a suppressor of FOXO1 expression, is upregulated. TGFβ counteracts the FOXP3-depleting TCR-signal by reassuring FOXO1 expression and by re-licensing STAT5 phosphorylation. Overexpressed phosphorylation-independent active versions of FOXO1 and STAT5 or knockdown of PTPN2 restores FOXP3 expression despite TCR-signal and absence of TGFβ. This study suggests novel targets for stabilisation and less dangerous application of iTreg during devastating inflammation.
Keyphrases
- regulatory t cells
- transcription factor
- poor prognosis
- dendritic cells
- cell proliferation
- signaling pathway
- high glucose
- pi k akt
- diabetic rats
- protein kinase
- long non coding rna
- transforming growth factor
- binding protein
- oxidative stress
- dna binding
- induced apoptosis
- genome wide identification
- drug induced
- cell death
- copy number
- immune response
- long noncoding rna
- cell cycle arrest
- genome wide
- endoplasmic reticulum stress