T cell differentiation: a mechanistic view.

It has recently become clear that cytokine expression by T cells involves epigenetic changes in chromatin structure, locus accessibility and DNA methylation that occur during differentiation of naive T cells into mature effector T cells. These changes require the coordinate actions of antigen- and cytokine-induced transcription factors, chromatin remodeling complexes, histone-modifying enzymes and subset-specific transcription factors.

Cell-type-restricted binding of the transcription factor NFAT to a distal IL-4 enhancer in vivo.

By DNase I hypersensitivity analysis, we have identified an inducible, cyclosporin A-sensitive enhancer located 3' of the interleukin-4 (IL-4) gene. The enhancer binds the Th2-specific transcription factor GATA3 in vivo but is not perceptibly influenced by the absence of a second Th2-specific factor, cMaf. The antigen-inducible transcription factor NFAT1 binds the IL-4 enhancer and the IL-4 promoter only in stimulated Th2 cells; conversely, NFAT1 binds to the interferon (IFN)-gamma promoter only in stimulated Th1 cells. Our results support a model whereby transcription factors such as NFAT1, which are nonselectively induced in antigen-stimulated T cells, gain access to cytokine regulatory regions only in the appropriate subset of differentiated T cells in vivo. This restricted access enables antigen-dependent and subset-specific transcription of cytokine genes.

Molecular aspects of T-cell differentiation.

Differentiated T helper 1 (Th1) and T helper 2 (Th2) T-cells show striking differences in their patterns of cytokine expression. This process is initiated by stimulation with antigen and the cytokines IL-12 and IL-4, respectively, and requires antigen-induced transcription factors such as NFAT and cytokine-induced transcription factors such as STAT4, induced by IL-12, and STAT6, induced by IL-4. This results in induction and maintained expression of subset-specific transcription factors including T-bet in Th1 cells and GATA3 in Th2 cells, which are involved in ensuring the commitment of T-cells to Th1 or Th2 lineages. Here we review the signalling pathways and transcription factors that mediate T-cell differentiation, and describe the epigenetic changes in chromatin structure, locus accessibility and DNA methylation that are known to accompany this process.

Complement receptor 3 of macrophages is associated with galectin-1-like protein.

We have previously identified a 16-kDa protein with a pI of 5.1 (P16/5.1) that is associated with macrophage CR3. Microsequencing of P16/5.1 indicated exclusive homology to the beta-galactoside-binding lectin, galectin-1. Abs specific to a galectin-1 unique peptide reacted with P16/5.1. The association of P16/5.1 with CR3 was specifically inhibited by lactose, which binds with high affinity to galectin-1. These data together with similarities in molecular mass and pI suggest that P16/5.1 is galectin-1. Two-color immunofluorescence staining revealed the expression of galectin-1 on the macrophage surface and its colocalization with CR3. However, a surplus of CR3 was free of galectin-1, and some galectin-1 molecules were associated with cell surface receptors other than CR3. Based on these results we propose two models depicting the functional significance of CR3-galectin-1 association: 1) homodimeric galectin-1 possessing a divalent sugar binding site may act as an extracellular adapter molecule that cross-links CR3 with other receptors; and 2) association of galectin-1 with beta-galactosides on the extracellular domain of CR3 may modify the binding affinity of the receptor to its ligand. These possibilities are not mutually exclusive and can clarify the mode by which CR3 transmits signals in macrophages.

Clonal dominance of RadLV-induced lymphomas.

RadLV-induced leukemogenesis begins with the emergence of a pleioclonal population of preleukemic (PL) cells, which subsequently gives rise to a monoclonal lymphoma. We have recently found that the pleioclonal-->monoclonal transition may occur early during the PL latency and long before the eruption of a full blown lymphoma. We sought to find out what causes one PL clone to become dominant. Our working hypothesis was that a dominant clone(s) at the PL stage has the ability to inhibit the development of other, recessive clones. Since some premalignant characteristics of a progenitor clone are probably maintained in the descending lymphoma, we studied whether tumors that developed after injection of a high dose (HD) of PL cells were dominant over tumors that developed after injection of a limiting dose (LD) of PL cells. To identify dominant clones, HD and LD lymphomas were mixed in a co-culture and the outgrowth of one clone over the other was determined by T beta-TCR rearrangement analysis. A checker-board combination of seven lymphomas revealed a dominance hierarchy scale. Lymphomas induced directly by the virus (without transfer) were dominant over both HD and LD lymphomas. High dose lymphomas were dominant over LD lymphomas and LD lymphomas were always recessive. The speed at which a dominant lymphoma outgrew the co-culture suggested that dominance is acquired through the ability of the prevailing cells to actively suppress the growth of recessive cells.

Identification and characterization of a novel protein associated with macrophage complement receptor 3.

CR3 is a member of the beta 2 integrin family which functions as a bidirectional signaling receptor. The CR3 is composed of the alpha (CD11b) and beta (CD18) subunits, which contain a short intracytoplasmic domain devoid of catalytic activity. It was therefore postulated that CR3 is associated with intracellular molecules that link it to the cytoplasmic signal transduction apparatus. However, no direct association between such molecules and CR3 have been identified so far. We searched for CR3 co-associated molecules that might regulate the function of this receptor. For this purpose CR3 was immunoprecipitated from radiolabeled bone marrow macrophages using a combination of anti-CD11b and anti-CD18 mAbs. Two-dimensional isoelectric focusing analysis of the immunoprecipitates revealed the two CR3 subunits and an additional 16-kDa protein with an apparent isoelectric point of 5.1. This protein, designated p16/5.1, was intracellular, monomeric, nonglycosylated and noncovalently associated with CR3 but not with CR4. CR3-associated p16/5.1 was also detected in four of six macrophage lines as well as in thymic large macrophages, all of which express cell-surface CR3. We suggest that p16/5.1 may be involved in CR3-mediated function.

Radiation leukemogenesis: quantitative relationship between pre-leukemic cells in the thymus and lymphoma induction.

Fractionated irradiation of C57BL/6 mice induces a population of pre-leukemic (PL) cells that progress into mature thymic lymphomas after a latency of 4 to 6 months. Transfer of graded numbers of thymocytes from an irradiated mouse into recipient mice indicated that PL cells first appear in the thymus 6 weeks after irradiation. The initial proportion of the thymic PL cells is > or = 10(-5) and their frequency continuously increases with time, reaching > or = 10(-3) 10 weeks after irradiation. The PL cell population that emerges early during the pre-malignant latency consists of pleioclonal T lymphocytes. However, within 4 weeks a dominant PL clone can be detected which becomes the progenitor of a clonal lymphoma 9 to 15 weeks later. These results suggest that radiation leukemogenesis involves continuous accumulation of pleioclonal PL cells in the thymus, one of which is then selected for further maturation into frank lymphoma.