Determinants of a transcriptionally competent environment at the GM-CSF promoter.

Granulocyte macrophage-colony stimulating factor (GM-CSF) is produced by T cells, but not B cells, in response to immune signals. GM-CSF gene activation in response to T-cell stimulation requires remodelling of chromatin associated with the gene promoter, and these changes do not occur in B cells. While the CpG methylation status of the murine GM-CSF promoter shows no correlation with the ability of the gene to respond to activation, we find that the basal chromatin environment of the gene promoter influences its ability to respond to immune signals. In unstimulated T cells but not B cells, the GM-CSF promoter is selectively marked by enrichment of histone acetylation, and association of the chromatin-remodelling protein BRG1. BRG1 is removed from the promoter upon activation concomitant with histone depletion and BRG1 is required for efficient chromatin remodelling and transcription. Increasing histone acetylation at the promoter in T cells is paralleled by increased BRG1 recruitment, resulting in more rapid chromatin remodelling, and an associated increase in GM-CSF mRNA levels. Furthermore, increasing histone acetylation in B cells removes the block in chromatin remodelling and transcriptional activation of the GM-CSF gene. These data are consistent with a model in which histone hyperacetylation and BRG1 enrichment at the GM-CSF promoter, generate a chromatin environment competent to respond to immune signals resulting in gene activation.

Deoxyribonucleic acid triplex formation inhibits granulocyte macrophage colony-stimulating factor gene expression and suppresses growth in juvenile myelomonocytic leukemic cells.

Juvenile myelomonocytic leukemia (JMML) is a severe childhood malignancy. The autocrine production of GMCSF is believed to be responsible for the spontaneous proliferation of JMML cells. A nuclear factor-kappaB (NF-kappaB)/Rel binding site within the GM-CSF gene promoter, termed the kappaB element, plays an important role in controlling transcription from the GM-CSF gene. We investigated the effect of an oligonucleotide GM3, directed to form a DNA triple helix across this kappaB element, on growth and GM-CSF production by JMML cells. Treatment of these cells, either unstimulated or induced by TNFalpha, with GM3 led to a significant and specific inhibition of both GM-CSF production and spontaneous colony formation. This constitutes the first report linking specific triplex-mediated inhibition of gene transcription with a functional outcome; i.e., cell growth. We observed the constitutive presence of NF-kappaB/Rel proteins in the nucleus of JMML cells. The constitutive and TNFalpha-induced NF-kappaB/Rel complexes were identical and were composed mainly of p50 and c-Rel proteins. Treatment of the cells with a neutralizing anti-TNFalpha monoclonal antibody completely abrogated constitutive nuclear expression of NF-kappaB/Rel proteins. These results indicate that the aberrant, constitutive GM-CSF gene activation in JMML is maintained by TNFalpha-mediated activation of NF-kappaB/Rel proteins. Our findings identify the molecular basis for the autocrine TNFalpha activation of the GM-CSF gene in JMML and suggest potential novel and specific approaches for the treatment of this aggressive childhood leukemia.

Human granulocyte-macrophage colony-stimulating factor enhancer function is associated with cooperative interactions between AP-1 and NFATp/c.

The promoter of the human granulocyte-macrophage colony-stimulating factor gene is regulated by an inducible upstream enhancer. The enhancer encompasses three previously defined binding sites for the transcription factor NFAT (GM170, GM330, and GM550) and a novel NFAT site defined here as the GM420 element. While there was considerable redundancy within the enhancer, the GM330, GM420, and GM550 motifs each functioned efficiently in isolation as enhancer elements and bound NFATp and AP-1 in a highly cooperative fashion. These three NFAT sites closely resembled the distal interleukin-2 NFAT site, and methylation interference assays further defined GGA(N)9TCA as a minimum consensus sequence for this family of NFAT sites. By contrast, the GM170 site, which also had conserved GGA and TCA motifs but in which these motifs were separated by 15 bases, supported strong independent but no cooperative binding of AP-1 and NFATp, and this site functioned poorly as an enhancer element. While both the GM330 and GM420 elements were closely associated with the inducible DNase I-hypersensitive site within the enhancer, the GM420 element was the only NFAT site located within a 160-bp HincII-BalI fragment defined by deletion analysis as the essential core of the enhancer. The GM420 element was unusual, however, in containing a high-affinity NFATp/c-binding sequence (TGGAAAGA) immediately upstream of the sequence TGACATCA which more closely resembled a cyclic AMP response-like element than an AP-1 site. We suggest that the cooperative binding of NFATp/c and AP-1 requires a particular spacing of sites and that their cooperativity and induction via independent pathways ensure very tight regulation of the granulocyte-macrophage colony-stimulating factor enhancer.

A novel tumor necrosis factor-responsive transcription factor which recognizes a regulatory element in hemopoietic growth factor genes.

A conserved DNA sequence element, termed cytokine 1 (CK-1), is found in the promoter regions of many hemopoietic growth factor (HGF) genes. Mutational analyses and modification interference experiments show that this sequence specifically binds a nuclear transcription factor, NF-GMa, which is a protein with a molecular mass of 43 kilodaltons. It interacts with different affinities with the CK-1-like sequence from a number of HGF genes, including granulocyte macrophage colony-stimulating factor (GM-CSF), granulocyte (G)-CSF, interleukin 3 (IL-3), and IL-5. We show here that the level of NF-GMa binding is induced in embryonic fibroblasts by tumor necrosis factor-alpha (TNF-alpha) treatment and that the CK-1 sequence from the G-CSF gene is a TNF-alpha-responsive enhancer in these cells. The NF-GMa protein is distinct from another TNF-alpha-responsive transcription factor, NF-kappa B, by several criteria. Firstly, several NF-kappa B-binding sites, although having sequence similarity with the CK-1 sequence, cannot compete efficiently for NF-GMa binding to CK-1. Secondly, the CK-1 sequence from both G-CSF and GM-CSF does not respond to phorbol ester treatment as would an NF-kappa B-binding element. These results demonstrate that NF-GMa is a novel transcription factor inducible by TNF-alpha and binds to a common element in HGF gene promoters.

HTLV-1 tax activation of the GM-CSF and G-CSF promoters requires the interaction of NF-kB with other transcription factor families.

The trans-activator protein, tax, from the human T leukemia virus type 1 (HTLV-1) trans-activates both viral and cellular genes. It has previously been shown that granulocyte macrophage-colony stimulating factor (GM-CSF) is constitutively expressed in HTLV-1 infected cells and in cells artificially expressing tax. We show here that the GM-CSF promoter is tax responsive in fibroblasts and T cells, whereas the granulocyte (G)-CSF promoter is tax responsive only in fibroblasts. The tax protein can activate cellular genes through a least two families of transcription factors; the NF-kB/rel and CREB/ATF families. We have used mutant tax proteins to show that the activation of NF-kB proteins is essential for tax trans-activation of both the GM-CSF and G-CSF promoters. The ability of tax to activate CREB/ATF proteins is also essential for GM-CSF transactivation. We have identified a 44 bp region of the GM-CSF promoter that contains tax responsive elements. This region contains a classical NF-kB site, a CK-1 element that can bind the NF-kB p65 protein, as well as a putative ATF binding site. The tax response of the G-CSF promoter requires not only the conserved CK-1 sequence but also an adjacent NF-IL6 binding site that may explain the cell restricted function of the G-CSF promoter.

ETS1, NFkappaB and AP1 synergistically transactivate the human GM-CSF promoter.

Activation of helper T cells results in coordinate expression of a number of cytokines involved in differentiation, proliferation and activation of the haematopoietic system. Granulocyte-macrophage colony stimulating factor (GM-CSF) is one such cytokine, whose increased expression results mostly from increases in transcription. Cis-acting elements with NFkappaB, AP1 and ETS-like binding motifs have been identified in the promoter region of the GM-CSF gene, and are important or essential for transcriptional activity following T cell activation. ETS1 is a transcription factor of the ETS family that is expressed in T cells. We have previously shown that ETS1 can transactivate GM-CSF in Jurkat T cells, but only after the cells have been stimulated by treatment with PMA and ionomycin, agents that mimic T cell activation. Thus we proposed that ETS1, which is expressed constitutively in Jurkat cells, may act in concert with PMA/ionomycin inducible factors. Here we show that ETS1 can transactivate a GM-CSF reporter construct in unstimulated Jurkat cells, providing that either NFkappaB or AP1 transcription factors are supplied by co-transfection. We confirm that binding of endogenous NFkappaB and AP1 is induced following PMA/ionomycin treatment of T cells. Transactivation by ETS1, NFkappaB and AP1 is synergistic, and mutation of the individual binding sites reveals that the transcriptional activities of these factors are interdependent. Our results suggest that constitutive ETS1, and inducible NFkappaB and AP1, cooperate as part of a higher order transcriptional complex in activated T cells.

ETS1 transactivates the human GM-CSF promoter in Jurkat T cells stimulated with PMA and ionomycin.

Activation of T helper cells results in coordinate expression of a number of cytokines involved in differentiation, proliferation and activation of the haematopoietic system. Granulocyte-macrophage colony-stimulating factor (GM-CSF) is one such cytokine whose increased expression results partly from increases in transcription. Cis-acting elements with NF kappa B, AP-1 and ETS-like motifs have been identified in the promoter region of the GM-CSF gene, which are important for transcriptional activity following PMA and ionomycin stimulation. A number of the ETS family of transcription factors are expressed in T cells, including ETS1 and ELF1. Here we describe the ability of these factors to interact with a site (GM5), located within the CLE0 element, -47 to -40 upstream of the GM-CSF transcription initiation site. Exogenous ETS1, but not ELF1, can transactivate GM-CSF, through the GM5 site, in a PMA/ionomycin dependent manner. Other unidentified ETS-like factors present in Jurkat cells are also capable of binding GM5. Mutation of the core ETS binding site from -GGAA- to -GGAT- prevents the binding of ETS-like factors with the exception of ETS1. The GM-CSF promoter, modified in this way to be ETS1 specific, is fully responsive to PMA/ionomycin induction, in addition to ETS1 transactivation in the presence of PMA and ionomycin. Together these data suggest that ETS1 may be involved in mediating the increased GM-CSF production associated with T cell activation.

Signals for activation of the GM-CSF promoter and enhancer in T cells.

Granulocyte-macrophage colony-stimulating factor (GM-CSF) is one of the many cytokines produced following T-cell activation. It is also produced in a variety of other cell types, in particular following activation by inflammatory mediators. Changes in the rate of transcription are important in the control of GM-CSF expression in T cells and in fibroblasts and endothelial cells. The GM-CSF gene contains two distinct transcriptional control regions. These are the proximal promoter consisting of the first 120 bp from the transcription start site and an enhancer located approximately 3 kb upstream from the proximal promoter. Distinct regions of the proximal promoter respond to a wide array of signals such as phorbol myristate acetate (PMA) and Ca2+ ionophore or phytohemaglutinin (PHA), CD28 activation, human T leukemia virus (HTLV)-1 tax, TNF, and interleukin 1 (IL-1). The transcription factors that mediate these responses have mainly been defined, with the major inducible proteins being the NF-kappa B/rel and AP-I families of transcription factors. In contrast to the promoter, the enhancer responds only to PMA and Ca2+ ionophore signals and binds NFAT/AP-1 complexes that appear to mediate its function.

Human GM-CSF receptor alpha-chain gene is highly polymorphic but not rearranged in AML.

Acute myeloid leukaemia (AML) blast cells express haemopoietic growth factor receptors. However, their presence does not predict response to the cognate ligand in vitro. This suggests that haemopoietic growth factor receptor structure or function may be abnormal in some cases of acute myeloid leukaemia. The granulocyte-macrophage colony-stimulating factor receptor alpha-chain gene (GM-CSF-R) has recently been localised to the pseudoautosomal region of the sex chromosomes. A sex chromosome is lost in 25% of cases of AML FAB subtype M2. The loss of one allele of this gene may have some aetiological significance in AML if the other allele is altered leading to abnormal receptor structure, function or number. In this initial study, we have examined DNA from leukaemic cells of 29 patients with AML, including three with FAB subtype M2 with deletion of an X or Y chromosome for evidence of gross rearrangement of this gene. We report that although the gene is highly polymorphic for a number of restriction enzymes, we have found no evidence of gross rearrangement in AML.

The role of architectural transcription factors in cytokine gene transcription.

The strict control of cytokine gene transcription is required for the correct regulation of an immune response. Cytokine gene transcription is generally inducible and can also be cell-type specific. Promoter and enhancer regions that control the expression of these genes assemble complex arrays of transcription factors known as enhanceosomes. One important aspect of the organization of these multi-protein complexes is the presence of proteins known as architectural transcription factors. Architectural proteins influence structural aspects of enhanceosomes through protein:DNA as well as protein:protein interactions. The high mobility group I(Y) and the cold shock domain families of architectural proteins have been shown to play roles in cytokine gene transcription and will be discussed here. These families of proteins interact with specific structural features of DNA, modulate transcription factor binding to DNA, and interact directly with other transcription factors. The mechanisms by which they affect inducible cytokine gene transcription will be discussed.

GM-CSF and IL-2 share common control mechanisms in response to costimulatory signals in T cells.

Antigen complexed with major histocompatibility complex class I or II molecules on the surface of antigen presenting cells interacts with the T cell receptor (TCR) on the surface of T cells and initiates an activation cascade. So called costimulatory signals, mediated by other cell surface interactions or soluble cytokines produced by antigen presenting cells, are also required for complete T cell activation. High levels of cytokine gene expression in T cells also required both TCR and costimulatory signals. The granulocyte-macrophage colony-stimulating factor requires sequences in the promoter as well as a powerful enhancer located 3kb upstream to respond to TCR-like signals. These promoter and enhancer regions are mainly activated by the transcription factor nuclear factor of activated T cells (NFAT). The activation of NFAT by TCR signals has been well described for interleukin-2 (IL-2) and IL-4 gene transcription in T cells. Costimulatory signals, such as activation of the CD28 cell surface molecule on T cells, lead to activation through a distinct region of the granulocyte-macrophage colony-stimulating factor (GM-CSF) promoter. This region is termed the CK-1 or CD28RE and appears to bind specific members of the NF-kappa B family of transcription factors. Human T leukemia virus type 1 (HTLV-1) infects T cells and can lead to increase GM-CSF expression. We have found that the HTLV-1 transactivator protein, tax, acts as a costimulatory signal for GM-CSF and IL-2 gene transcription, in that it can cooperate with TCR signals to mediate high level gene expression. Tax activates the GM-CSF promoter through the CK-1/CD28RE region and also activates nuclear factor-kappa B binding to this region. However, other transcription factors or coactivators of NF-kappa B are required for tax activation but these remain to be identified. The CK-1/CD28RE of GM-CSF shows a high degree of similarity to the IL-2 CD28RE and the IL-3 gene also contains a related region. This observation, together with the fact that both GM-CSF and IL-2 respond to TCR signals via NFAT, implies a high degree of conservation in the regulation of cytokine gene expression in T cells.

Interaction of GM-CSF and IL-3 with the common beta-chain of their receptors.

Human granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin (IL-3) are cytokines active in both normal and abnormal hemopoiesis, inflammation, and immunity. Their biological activity is mediated via receptors that comprise a ligand-specific alpha chain and a beta chain that is common to the GM-CSF, IL-3, and IL-5 receptors. To understand the mechanism of action of GM-CSF and IL-3 in both normal and pathological conditions, we are seeking to define the structural elements required for ligand/receptor and receptor/receptor contact and their role in cellular activation. To this end we have identified a conserved motif in the first helix of GM-CSF, Glu21 that is critical for high affinity binding and biological activity. Charge-reversal mutagenesis of this residue generates a GM-CSF analogue that is devoid of biological activity and can antagonize the activity of wild-type GM-CSF. This probably results from the selective deficiency in interaction with the beta chain of the receptor and suggests that similar antagonists for IL-3 and IL-5 are also feasible. Complementary mutagenesis studies on the receptor beta chain have identified the putative B'-C' loop in the membrane-proximal domain as being critical for the high affinity binding of GM-CSF but not IL-3. Characterization of the specificity of sites of interaction between the ligands and receptors may permit the design of specific or genetic antagonists that may have important therapeutic implications.

Regulation of cytokine gene transcription in the immune system.

The controlled expression of cytokine genes is an essential component of an immune response. The specific types of cytokines as well as the time and place of their production is important in generating an appropriate immune response to an infectious agent. Aberrant expression is associated with pathological conditions of the immune system such as autoimmunity, atopy and chronic inflammation. Cytokine gene transcription is generally induced in a cell-specific manner. Over the last 15 years, a large amount of information has been generated describing the transcriptional controls that are exerted on cytokine genes. Recently, efforts have been directed at understanding how these genes are transcribed in a chromatin context. This review will discuss the mechanisms by which cytokine genes become available for transcription in a cell-restricted manner as well as the mechanisms by which these genes sense their environment and activate high level transcription in a transient manner. Particular attention will be paid to the role of chromatin in allowing transcription factor access to appropriate genes.

Synthesis and expression of the gene encoding human interleukin-3.

To perform structure-function studies of human interleukin-3 (hIL-3) we have synthesized a cDNA encompassing the complete coding region of 484 bp. The strategy we employed involved construction of the cDNA in four sections. Each fragment contained six to ten oligodeoxyribonucleotides. Unique restriction sites were engineered to flank the natural sequence for cloning. Naturally occurring restriction sites were placed internally to these, to allow ligation of the four fragments. The gene was cloned into a modified pJL4 vector and expressed in COS cells. Biological assays of supernatants collected from these cells, for both mature cell function and proliferative activity, showed that synthetic hIL-3 had the same activity as that previously determined for recombinant hIL-3.

Histone H5 and H1 cross-reacting material is restricted to erythroid cells in chicken.

Monoclonal H5 antibodies and a polyclonal antiserum, raised against the globular domain of chicken H5 (GH5) but which cross-reacts with histone H1(0) from mouse liver, were used to search for H5 or H1 (0)-like proteins in chicken embryo and adult tissue sections by indirect immunofluorescence. Chicken cell lines in culture were examined for H5 protein and H5 mRNA. Histone H5 was detected only in erythroid cells in tissue sections of chicken embryos or adult livers. H5 protein and H5 mRNA were found only in erythroid cells in culture. No cross-reacting proteins were detected in any other tissue or cell line examined.

Characterization of the six chicken histone H1 proteins and alignment with their respective genes.

Six histone H1 subtypes and histone H5, isolated from chicken erythrocyte nuclei, were visualized on acid/urea polyacrylamide gels. Four of the H1 subtypes have been purified to homogeneity by fast protein liquid chromatography on a strong cation exchange column. The other two subtypes were obtained as enriched fractions from the same fast protein liquid chromatography experiments. Because six chicken H1 genes have been completely sequenced (Coles, L.S., Robins, A. J., Madley, L.K., and Wells, J. R. E. (1987) J. Biol. Chem. 262, 9656-9663), it was possible to assign each of the six H1 proteins to a specific gene after amino acid sequence analysis of peptides derived from the subtypes.

DNA triplex formation selectively inhibits granulocyte-macrophage colony-stimulating factor gene expression in human T cells.

Granulocyte-macrophage colony-stimulating factor (GM-CSF) is a hemopoietic growth factor that is expressed in activated T cells, fibroblasts, macrophages, and endothelial cells. Although GM-CSF does not appear to be essential for normal hemopoiesis, overexpression of GM-CSF has been implicated in the pathogenesis of some diseases such as myeloid leukemia and chronic inflammation. An NF-kappaB/Rel binding site within the GM-CSF promoter, termed the kappaB element appears to be important for controlling expression in reporter gene assays in response to a number of stimuli in T cells. We investigated oligonucleotide-directed triple helix formation across this regulatory sequence as a potential tool to inhibit GM-CSF gene transcription. A 15-base oligonucleotide, GM3, was targeted to a purine-rich region in the GM-CSF proximal promoter, which overlaps the kappaB element. Gel mobility shift assays and DNase I footprinting demonstrated that GM3 formed a sequence-specific collinear triplex with its double-stranded DNA target. Triplex formation by GM3 blocked recombinant and nuclear NF-kappaB proteins binding to the GM-CSF element. GM3 also caused selective inhibition of the human T-cell lymphotrophic virus-1 Tax transactivator-induced luciferase activity from a reporter construct driven by the GM-CSF promoter in Jurkat T cells. Finally, GM3 greatly reduced the concentration of endogenous GM-CSF mRNA induced by different stimuli in Jurkat T cells but did not affect interleukin 3 mRNA levels in the same cells. We conclude that the kappaB element in the GM-CSF promoter plays a central role in the transcriptional activation of the endogenous GM-CSF gene. Colinear triplex formation acts as a selective transcriptional repressor of the GM-CSF gene and may have potential therapeutic application in cases of undesirable overexpression of this protein.

T-cell functional regions of the human IL-3 proximal promoter.

The human interleukin-3 (IL-3) gene is expressed almost exclusively in activated T cells. Its expression is regulated at both the transcriptional and post-transcriptional level. We have previously shown that treatment of Jurkat T cells with phytohemaglutinin (PHA) and the phorbol ester, PMA, activated transcription initiation from the IL-3 gene. To define the regions of the gene required for transcription activation, we generated a series of reporter constructs containing different regions of the IL-3 gene 5' and 3' flanking sequences. Both positive and negative regulatory elements were identified in the proximal 5' flanking region of the IL-3 gene. The promoter region between -173 and -60 contained the strongest activating elements. The transcription factor AP-1 could bind to this positive activator region of the promoter. We also examined the function of the IL-3 CK-1/CK-2 elements that are present in many cytokine genes and found that they acted as a repressor of basal level expression when cloned upstream of a heterologous promoter but were also inducible by PMA/PHA.