Two independent calcineurin-binding regions in the N-terminal domain of murine NF-ATx1 recruit calcineurin to murine NF-ATx1

Intracellular calcium regulates events controlling nuclear translocation of nuclear factor of activated T cells (NF-AT). Calcium-dependent phosphatase calcineurin (CN) plays a central role in this process. Structural and functional analyses of the N-terminal domain of murine NF-ATx1, a member of the NF-AT family, have defined two distinct CN binding regions (CNBRs), CNBR1 and CNBR2, which are located in the region preceding the SP boxes of serine/proline-rich sequences and the region between the SP boxes and Rel similarity domain, respectively. The binding of murine NF-ATx1 (mNF-ATx1) to CN was abolished by deletion of these two regions, yet was unaffected by the individual deletion. In contrast, the nuclear translocation of mNF-ATx1 was much reduced when only CNBR2 was removed. Luciferase assay revealed that both regions are required for mNF-ATx1-dependent activation of the murine IL-2 promoter. Most importantly, recombinant CNBR2 bound CN with a higher affinity, and when expressed in Jurkat cells, it functioned as a dominant negative mutant that prevented the transcription driven by exogenous mNF-ATx1, probably by interfering with the function of CN. We propose that activation of mNF-ATx1 can be modulated through two distinct CN target regions. Our findings provide a new opportunity for pharmacological intervention with Ca2+-dependent signaling events.

Transcriptional control of cytokine genes

With antigen stimulation, cytokine genes are coordinately expressed in T cells. However, the optimal signals or helper T cell subset specificity for each cytokine gene expression differ. Mechanisms probably exist that transmit extracellular signals into the nucleus, thereby coordinately turning on and off transcriptional machinery in a signal-specific or cell type-specific manner. We compare here the regulation of cytokine genes and discuss possible mechanisms of coordinated and differential regulation of cytokine genes.

Molecular cloning and functional characterization of murine cDNA encoding transcription factor NFATc

Transcription factors of the NFAT (nuclear factor of activated T cells) family play important roles in immune and inflammatory responses by regulating the expression of genes encoding cytokines and immunoregulatory proteins. Here we describe cloning and characterization of full-length cDNA encoding murine (m) NFATc which predicts that the protein has all the conserved structural motifs of NFAT family members, including the rel homology domain, the NFAT homology domain and the nuclear translocation signals. mNFATc complexed with AP-1 bound specifically to the murine IL-2 NFAT recognition sequence and activated transcription from the co-transfected IL-2 promoter in COS-7 cells. Northern blot analysis showed that the cDNA probe hybridized with a 4.5 kb transcript which is highly inducible in murine T cells. By Northern and in situ hybridization, mNFATc transcript was detected from the early stage of development. In the mouse embryo, mNFATc transcript was strongly expressed in thymus, lung and submandibular gland and weakly in skeletal muscle and heart suggesting that mNFATc may have a role both in embryogenesis and in mature T cells.

Cytokine signal networks and a new era in biomedical research

Elucidation of the biochemical nature of the signal transduction pathway that regulate transcription and replication is the focus of attention in molecular biology. This research may make feasible manipulation of growth and differentiation of mammalian cells, which in turn would have profound implication in biomedical research on cell and gene therapy, and development of pharmaceutical products. Cytokines control growth, differentiation, death, and function of cells of lymphocytic, hemopoietic systems, and together with nerve cells provide a pertinent model to study intercellular communications and intercellular signal networks. This review outlines general features of signal transduction and several aspects of cytokine networks are discussed with emphasis on: transcriptional regulation of Th1 and Th2-specific cytokine genes in T cells, the roles of cytokines and their receptors in growth and differentiation of hemopoietic cells, and the manipulation of cytokine networks.

Regulation of expression of the IL-2 and IL-5 genes and the role of proteins related to nuclear factor of activated T cells

Cyclic adenosine monophosphate (cAMP) inhibits phorbol 12-myristate 13-acetate (PMA)-induced IL-2 production while it inhibits IL-5 production at the transcriptional level in EL-4, a mouse lymphoma line. The -321 to +46 region of the mouse IL-2 promoter is required for activation by PMA and inhibition by cAMP. This promoter region contains several elements that interact with transcription factors, such as nuclear factor of activated T cells (NF-AT), NF-kappa B, AP-1, and octamer. With use of reporter plasmid carrying multiple copies of each element, we found that the construct that contained the NF-AT site was most effective for responding to PMA activation and cAMP inhibition. In electrophoretic mobility shift assay (EMSA), PMA-induced NF-AT binding complex was altered by cAMP. Furthermore, overexpression of the cytoplasmic component of NF-AT abrogated the inhibitory action of cAMP. These results indicate that the NF-AT site is a target of the inhibitory action of cAMP. We have previously reported that the -1200 to +33 region of the mouse IL-5 promoter can mediate transcriptional stimulation by PMA and cAMP in EL-4 cells. Here we identified the element IL-5P, which is required for maximal activation of the IL-5 promoter. We found that this element is homologous to the binding site for NF-AT and interacted with NF-AT-related factors induced by PMA and cAMP. Thus it appears that an NF-AT factor is involved in the regulation of IL-5 gene transcription.

Cyclic AMP inhibits expression of the IL-2 gene through the nuclear factor of activated T cells (NF-AT) site, and transfection of NF-AT cDNAs abrogates the sensitivity of EL-4 cells to cyclic AMP

cAMP inhibits PMA-induced IL-2 production at the transcriptional level in EL-4, a mouse lymphoma line. The region of the mouse IL-2 promoter covering positions from -321 to +46 relative to the transcription initiation site is required for activation by PMA and inhibition by cAMP. This region contains the nuclear factor of activated T cells (NF-AT), nuclear factor-kappa B (NF-kappa B), AP-1, and Oct binding sites, and the role of each element in responding to PMA and/or cAMP signals was characterized. The IL-2 promoter carrying mutations in each element reduced response to PMA while it retained sensitivity to cAMP, thereby suggesting that multiple elements contribute to positive and negative responses to PMA and cAMP, respectively. Using reporter plasmid carrying multiple copies of each element, we then found that the NF-AT construct was most effective in responding to PMA activation and to cAMP inhibition. Electrophoretic mobility shift assay revealed that, after exposure of cells to Bt2cAMP, NF-AT binding complex changed in amount or in mobility as a function of time. Furthermore, overexpression of the cytoplasmic component of NF-AT abrogated the inhibitory action of cAMP. These results indicate that the NF-AT site is a target of the inhibitory action of cAMP. In addition, binding of the NF-kappa B (p50/p65) heterodimer to the NF-kappa B site was inhibited by cAMP. Taken together, our data show that cAMP in EL-4 cells inhibits mouse IL-2 gene transcription through cis regulatory elements that include the NF-AT site as well as the NF-kappa B site.

Cyclic AMP inhibits expression of the IL-2 gene through the nuclear factor of activated T cells (NF-AT) site, and transfection of NF-AT cDNAs abrogates the sensitivity of EL-4 cells to cyclic AMP

cAMP inhibits PMA-induced IL-2 production at the transcriptional level in EL-4, a mouse lymphoma line. The region of the mouse IL-2 promoter covering positions from -321 to +46 relative to the transcription initiation site is required for activation by PMA and inhibition by cAMP. This region contains the nuclear factor of activated T cells (NF-AT), nuclear factor-kappa B (NF-kappa B), AP-1, and Oct binding sites, and the role of each element in responding to PMA and/or cAMP signals was characterized. The IL-2 promoter carrying mutations in each element reduced response to PMA while it retained sensitivity to cAMP, thereby suggesting that multiple elements contribute to positive and negative responses to PMA and cAMP, respectively. Using reporter plasmid carrying multiple copies of each element, we then found that the NF-AT construct was most effective in responding to PMA activation and to cAMP inhibition. Electrophoretic mobility shift assay revealed that, after exposure of cells to Bt2cAMP, NF-AT binding complex changed in amount or in mobility as a function of time. Furthermore, overexpression of the cytoplasmic component of NF-AT abrogated the inhibitory action of cAMP. These results indicate that the NF-AT site is a target of the inhibitory action of cAMP. In addition, binding of the NF-kappa B (p50/p65) heterodimer to the NF-kappa B site was inhibited by cAMP. Taken together, our data show that cAMP in EL-4 cells inhibits mouse IL-2 gene transcription through cis regulatory elements that include the NF-AT site as well as the NF-kappa B site.