Scurfin (FOXP3) acts as a repressor of transcription and regulates T cell activation.

We have recently identified and cloned Foxp3, the gene defective in mice with the scurfy mutation. The immune dysregulation documented in these mice and in humans with mutations in the orthologous gene indicates that the foxp3 gene product, scurfin, is involved in the regulation of T cell activation and differentiation. The autoimmune state observed in these patients with the immune dysregulation polyendocrinopathy, enteropathy, X-linked syndrome, or X-linked autoimmunity-allergic dysregulation syndrome also points to a critical role for scurfin in the regulation of T cell homeostasis. FOXP3 encodes a novel member of the forkhead family of transcription factors. Here we demonstrate that this structural domain is required for nuclear localization and DNA binding. Scurfin, transiently expressed in heterologous cells, represses transcription of a reporter containing a multimeric forkhead binding site. Upon overexpression in CD4 T cells, scurfin attenuates activation-induced cytokine production and proliferation. We have identified FKH binding sequences adjacent to critical NFAT regulatory sites in the promoters of several cytokine genes whose expression is sensitive to changes in SFN abundance. Our findings indicate that the ability of scurfin to bind DNA, and presumably repress transcription, plays a paramount role in determining the amplitude of the response of CD4 T cells to activation.

Consistent transient transfection of DNA into non-transformed human and murine T-lymphocytes.

The ability to analyze transcriptional regulation in non-transformed T-cells has been hampered by the inability to reproducibly transiently transfect these cells with DNA constructs. We have previously demonstrated that normal human whole mononuclear and CD4 T-cells can be consistently transiently transfected with plasmid DNA. Human cells were most receptive to plasmid DNA uptake between 19.5 and 20 h after prestimulation with a submitogenic dose of the polyclonal T-cell activator, PHA. Here we report an alteration and optimization of this protocol for non-transformed murine splenic T-cells, using concanavalin A instead of PHA as the preactivation stimulus. When coupled with the high sensitivity of luciferase reporter gene constructs, this protocol facilitates the analysis of a variety of T-cell-specific promoters in non-transformed T-cells. In addition, we directly demonstrate that murine T-cells are specifically transiently transfected among a population of whole mononuclear cells by using an expression vector for green fluorescent protein.

The human gp39 promoter. Two distinct nuclear factors of activated T cell protein-binding elements contribute independently to transcriptional activation.

gp39, a cytokine expressed on the surface of activated T cells, is essential for T cell-dependent antibody responses in vivo. We cloned and sequenced 1.2 kilobases of the 5' flank region of the human gp39 gene promoter and determined its transcription start site. When used in reporter gene assays, this DNA segment conferred promoter activity in response to T cell activation. gp39 promoter function in transfectants was inhibited by cyclosporin A, as is expression of the endogenous gp39 gene in T-lineage cells. At least 0.5 kilobase of the 5' flank region was required for promoter activity. Two putative binding sites for the NF-AT family of transcriptional activator proteins were identified at -259 to -265 and -62 to -69 with respect to the transcription start site. Both sites contributed significantly and independently to promoter activity in response to T cell activation. Additionally, when incubated in vitro with nuclear protein purified from activated human CD4 T cells, both of these sites preferentially bound the NF-AT family member, NF-ATp. These results suggest that NF-ATp, via binding to at least two cis-elements, is essential for the induction of gp39 gene expression in response to T cell activation.