The transcription factor Foxp3 is involved in the differentiation, function and survival of CD4+CD25+ regulatory T (T(reg)) cells. Details of the mechanism underlying the induction of Foxp3 expression remain unknown, because studies of the transcriptional regulation of the Foxp3 gene are limited by the small number of T(reg) cells in mononuclear cell populations. Here we have generated a model system for analyzing Foxp3 induction and, by using this system with primary T cells, we have identified an enhancer element in this gene. The transcription factors Smad3 and NFAT are required for activity of this Foxp3 enhancer, and both factors are essential for histone acetylation in the enhancer region and induction of Foxp3. These biochemical properties that define Foxp3 expression explain many of the effects of transforming growth factor-beta on the function of Foxp3+ T(reg) cells.
Protein engineering of cell surfaces is a potentially powerful technology through which the surface protein composition of cells can be manipulated without gene transfer. This technology exploits the fact that proteins that are anchored by glycoinositol phospholipids (GPIs), when purified and added to cells in vitro, incorporate into their surface membranes and are fully functional. By substituting 3'-mRNA end sequence of naturally GPI-anchored proteins (i.e., a sequence that contains the signals that direct GPI anchoring) for endogenous 3'-mRNA end sequence, virtually any protein of interest can be expressed as a GPI-anchored derivative. The GPI-anchored product then can be purified from transfectants and the purified protein used to "paint" any target cell. Such protein engineering or "painting" of the cell surface offers several advantages over conventional gene transfer. Among these advantages are that 1) GPI-anchored proteins can be painted onto cells that are difficult to transfect, 2) cells can be altered immediately without previous culturing, 3) the amount of protein added to the surface can be precisely controlled, and 4) multiple GPI-anchored proteins can be sequentially or concurrently inserted into the same cells. Emerging applications for the technology include its use for the analysis of complex cell-surface interactions, the engineering of antigen presenting cells, the development of cancer vaccines, and possibly the protection against graft rejection.
CD1 proteins present various glycolipid antigens to T cells, but the cellular mechanisms that control which particular glycolipids generate T cell responses are not understood. We show here that T cell recognition of glucose monomycolate antigens with long (C(80)) alkyl chains involves the delivery of CD1b proteins and antigens to late endosomes in a process that takes several hours. In contrast, analogs of the same antigen with shorter (C(32)) alkyl chains are rapidly, but inefficiently, presented by cell surface CD1b proteins. Dendritic cells (DCs) preferentially present long-chain glycolipids, which results, in part, from their rapid internalization and selective delivery of antigens to endosomal compartments. Nonprofessional antigen-presenting cells, however, preferentially present short-chain glycolipids because of their lack of prominent endosomal presentation pathways. Because long alkyl chain length distinguishes certain microbial glycolipids from common mammalian glycolipids, these findings suggest that DCs use a specialized endosomal-loading pathway to promote preferential recognition of glycolipids with a more intrinsically foreign structure.
ABSTRACTcDNAs encoding the complement decay-accelerating factor (DAF) were isolated from HeLa and differentiated HL-60 kgt cDNA libraries by screening with a codon preference oligonucleotide corresponding to DAF NH2-terminal amino acids 3-14. The composite cDNA sequence showed a 347-amino acid protein preceded by an NH2-terminal leader peptide sequence. The translated sequence beginning at the DAF NH2 terminus encodes four contiguous %61-amino acid long repetitive units of internal homology. The repetitive regions contain four conserved cysteines, one proline, one glycine, one glycine/alanine, four leucines/isoleucines/valines, one serine, three tyrosines/phenylalanines, and one tryptophan and show striking homology to similar regions previously identified in factor B, C2, C4 binding protein, factor H, COr, factor XM, interleukin 2 receptor, and serum f82-glycoprotein I. The consensus repeats are attached to a 70-amino acid long segment rich in serine and threonine (potential 0-glycosylation sites), which is in turn followed by a stretch of hydrophobic amino acids. RNA blot analysis of HeLa and HL-60 RNA revealed three DAF mRNA species of 3.1, 2.7, and 2.0 kilobases. The results indicate that portions of the DAF gene may have evolved from a DNA element common to the above proteins, that DAF cDNA predicts a COOH-terminal anchoring polypeptide, and that distinct species of DAF message are elaborated in cells.
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