Transcriptional control. Sinful repression

A new member of the Sin3 family of corepressors is essential for cell viability and required for retroelement propagation in fission yeast

Tf1 is a long terminal repeat (LTR)-containing retrotransposon that propagates within the fission yeast Schizosaccharomyces pombe. LTR-retrotransposons possess significant similarity to retroviruses and therefore serve as retrovirus models. To determine what features of the host cell are important for the proliferation of this class of retroelements, we screened for mutations in host genes that reduced the transposition activity of Tf1. We report here the isolation and characterization of pst1(+), a gene required for Tf1 transposition. The predicted amino acid sequence of Pst1p possessed high sequence homology with the Sin3 family of proteins, known for their interaction with histone deacetylases. However, unlike the SIN3 gene of Saccharomyces cerevisiae, pst1(+) is essential for cell viability. Immunofluorescence microscopy indicated that Pst1p was localized in the nucleus. Consistent with the critical role previously reported for Sin3 proteins in the histone acetylation process, we found that the growth of the strain with the pst1-1 allele was supersensitive to the specific histone deacetylase inhibitor trichostatin A. However, our analysis of strains with the pst1-1 mutation was unable to detect any changes in the acetylation of specific lysines of histones H3 and H4 as measured in bulk chromatin. Interestingly, the pst1-1 mutant strain produced wild-type levels of Tf1-encoded proteins and cDNA, indicating that the defect in transposition occurred after reverse transcription. The results of immunofluorescence microscopy showed that the nuclear localization of the Tf1 capsid protein was disrupted in the strain with the pst1-1 mutation, indicating an important role of pst1(+) in modulating the nuclear import of Tf1 virus-like particles.

Chromatin disruption and modification

Chromatin disruption and modification are associated with transcriptional regulation by diverse coactivators and corepressors. Here we discuss the possible structural basis and functional consequences of the observed alterations in chromatin associated with transcriptional activation and repression. Recent advances in defining the roles of individual histones and their domains in the assembly and maintenance of regulatory architectures provide a framework for understanding how chromatin remodelling machines, histone acetyltransferases and deacetylases function.

Retinoid isomers differ in the ability to induce release of SMRT corepressor from retinoic acid receptor-alpha

Nuclear hormone receptors are ligand-regulated transcription factors that modulate the expression of specific target genes in response to the binding of small, hydrophobic hormone ligands. Many nuclear hormone receptors, such as the retinoic acid receptors, can both repress and activate target gene expression; these bimodal transcription properties are mediated by the ability of these receptors to tether auxiliary factors, denoted corepressors and coactivators. Corepressors are typically bound by receptors in the absence of cognate hormone, whereas binding of an appropriate hormone agonist induces an allosteric alteration in the receptor resulting in release of the corepressor and recruitment of coactivator. Structural analysis indicates that there is a close induced fit between the hormone ligand and the receptor polypeptide chain. This observation suggests that different ligands, once bound, may confer distinct conformations on the receptor that may invoke, in turn, distinct functional consequences. We report here that different retinoids do differ in the ability to release corepressor once bound to retinoic acid receptor and suggest that these differences in corepressor release may manifest as differences in transcriptional regulation.

Thyroid hormone effects on Krox-24 transcription in the post-natal mouse brain are developmentally regulated but are not correlated with mitosis

Krox-24 (NGFI-A, Egr-1) is an immediate-early gene encoding a zinc finger transcription factor. As Krox-24 is expressed in brain areas showing post-natal neurogenesis during a thyroid hormone (T3)-sensitive period, we followed T3 effects on Krox-24 expression in newborn mice. We analysed whether regulation was associated with changes in mitotic activity in the subventricular zone and the cerebellum. In vivo T3-dependent Krox-24 transcription was studied by polyethylenimine-based gene transfer. T3 increased transcription from the Krox-24 promoter in both areas studied at post-natal day 2, but was without effect at day 6. An intact thyroid hormone response element (TRE) in the Krox-24 promoter was necessary for these inductions. These stage-dependent effects were also seen in endogenous Krox-24 mRNA levels: activation at day 2 and no effect at day 6. Moreover, similar results were obtained by examining beta-galactosidase expression in heterozygous mice in which one allele of the Krox-24 gene was disrupted with an inframe Lac-Z insertion. However, bromodeoxyuridine incorporation showed mitosis to continue through to day 6. We conclude first, that T3 activates Krox-24 transcription during early post-natal mitosis but that this effect is extinguished as development proceeds and second, loss of T3-dependent Krox-24 expression is not correlated with loss of mitotic activity.

Reappraisal of the role of heat shock proteins as regulators of steroid receptor activity

Almost 30 years have passed since the original demonstration that steroid receptors, comprising a subfamily of the nuclear receptor (NR) superfamily, exist as large (6-8S) non-DNA-binding complexes in hypotonic extracts (cytosol) of target cells; later such complexes were shown to correspond to a heterooligomer composed of receptor, heat shock (Hsp), and other proteins. Subsequently, an impressive number of studies have dealt with the composition of the "nonactive" complex, its dissociation and/or reassembly in vitro, possible functions of the non-receptor components, and their subcellular compartmentalization. While there is little dispute about the chaperoning role of some Hsps in such a complex, there is still no final proof of an association in vivo of NRs and Hsps in the nuclei of target cells, which is requisite for a direct regulatory involvement of Hsps in NR function. Here we critically review the various models that have been put forward to attribute a biological function to the NR-Hsp90 interaction, evaluate the corresponding experimental data, and integrate recent concepts originating from the structural and functional analyses of NRs.

CIR, a corepressor linking the DNA binding factor CBF1 to the histone deacetylase complex

CBF1 is a member of the CSL family of DNA binding factors, which mediate either transcriptional repression or transcriptional activation. CSL proteins play a central role in Notch signaling and in Epstein-Barr virus-induced immortalization. Notch is a transmembrane protein involved in cell-fate decisions, and the cytoplasmic domain of Notch (NotchIC) targets CBF1. The Epstein-Barr virus-immortalizing protein EBNA2 activates both cellular and viral gene expression by targeting CBF1 and mimicking NotchIC. We have examined the mechanism of CBF1-mediated repression and show that CBF1 binds to a unique corepressor, CBF1 interacting corepressor (CIR). A CIR homolog is encoded by Caenorhabditis elegans, indicating that CIR is evolutionarily conserved. Two CBF1 mutants that were unable to bind CIR did not function as repressors, suggesting that targeting of CIR to CBF1 is an important component of repression. When expressed as a Gal4 fusion protein, CIR repressed reporter gene expression. CIR binds to histone deacetylase and to SAP30 and serves as a linker between CBF1 and the histone deacetylase complex.

E2F and histone deacetylase mediate transforming growth factor beta repression of cdc25A during keratinocyte cell cycle arrest

cdc25A is a tyrosine phosphatase that activates G1 cyclin-dependent kinases (Cdk's). In human keratinocytes, cdc25A expression is down-regulated after the initial drop in Cdk activity caused by cell exposure to the antimitogenic cytokine transforming growth factor beta (TGF-beta) or removal of serum factors. Here we show that the TGF-beta-inhibitory-response element in the cdc25A promoter maps to an E2F site at nucleotides -62 to -55 from the transcription start site. This site is not required for basal transcription in keratinocytes. We provide evidence that the cell cycle arrest program activated by TGF-beta in human keratinocytes includes the generation of E2F4-p130 complexes that in association with histone deacetylase HDAC1 inhibit the activity of the cdc25A promoter from this repressor E2F site. This mechanism is part of a program that places keratinocytes in the quiescent state following the initial drop in Cdk activity caused by cell exposure to TGF-beta.

PRDI-BF1/Blimp-1 repression is mediated by corepressors of the Groucho family of proteins

The PRDI-BF1/Blimp-1 protein is a transcriptional repressor required for normal B-cell differentiation, and it has been implicated in the repression of beta-interferon (IFN-beta) and c-myc gene expression. Here, we show that PRDI-BF1 represses transcription of the IFN-beta promoter and of an artificial promoter through an active repression mechanism. We also identified a minimal repression domain in PRDI-BF1 that is sufficient for transcriptional repression when tethered to DNA as a Gal4 fusion protein. Remarkably, this repression domain interacts specifically with hGrg, TLE1, and TLE2 proteins, all of which are members of the Groucho family of transcriptional corepressors. In addition, the hGrg protein itself can function as a potent repressor when tethered to DNA through the Gal4 DNA-binding domain. We also find that the amino-terminal glutamine-rich domains of hGrg and TLE1 are sufficient to mediate dimerization of the two Groucho family proteins. Proteins containing only this domain can function as a dominant-negative inhibitor of PRDI-BF1 repression, and can significantly increase the IFN-beta promoter activity after virus induction. We conclude that PRDI-BF1/Blimp-1 represses transcription by recruiting a complex of Groucho family proteins to DNA, and suggest that such corepressor complexes are required for the postinduction repression of the IFN-beta promoter.

Template activating factor-I remodels the chromatin structure and stimulates transcription from the chromatin template

To study the mechanisms of replication and transcription on chromatin, we have been using the adenovirus DNA complexed with viral basic core proteins, called Ad core. We have identified template activating factor (TAF)-I from uninfected HeLa cells as the factor that stimulates replication and transcription from the Ad core. The nuclease sensitivity assays have revealed that TAF-I remodels the Ad core, thereby making transcription and replication apparatus accessible to the template DNA. To examine whether TAF-I remodels the chromatin consisting of histones, the chromatin structure was reconstituted on the DNA fragment with core histones by the salt dialysis method. The transcription from the reconstituted chromatin was completely repressed, while TAF-I remodeled the chromatin and stimulated the transcription. TAF-I was found to interact with histones. Furthermore, it was shown that TAF-I is capable not only of disrupting the chromatin structure but also of preventing the formation of DNA-histone aggregation and transferring histones to naked DNA. The possible function of TAF-I in conjunction with a histone chaperone activity is discussed.

Coinduction of Embryonic and Adult-Type Globin mRNAs by Sodium Butyrate and Trichostatin A in Two Murine Interleukin-3–Dependent Bone Marrow–Derived Cell Lines

Using an RNase protection assay, globin mRNA species expressed in clones derived from Ba/F3 and B6SUtA cells transfected with the erythropoietin receptor (EpoR) and selected with erythropoietin (Epo) were compared with globin mRNA species induced in corresponding parental cells by sodium butyrate (SB) and trichostatin A (TSA). βMajor/βminor- and -1/-2–globin mRNAs were the major species, with trace amounts of ɛ-globin mRNA, formed in Epo-stimulated EpoR+ Ba/F3 clones, whereas SB and TSA allowed expression of all species of globin mRNAs, ie, ɛ, βh1, βmajor/βminor, ζ, and -1/-2, in parental Ba/F3 cells. In contrast, ɛ- and -1/-2–globin mRNAs were the major species present in Epo-stimulated EpoR+ B6SUtA clones, whereas SB and TSA activated ɛ-, βh1-, βS/βT-, and -1/-2–globin genes in parental B6SUtA cells; ζ-globin mRNA was not detected in SB- and TSA-treated B6SUtA cells. Because TSA is a specific inhibitor of histone deacetylase, the mimicry of action exhibited by SB and TSA suggests that the effects of SB are mediated through its ability to inhibit histone deacetylase and that histone deacetylase is an integral part of the repression of globin genes in these interleukin-3–dependent cells. Efficient coinduction of embryonic and adult types of globin mRNA in bone marrow cell lines derived from adult mice indicates that adult hematopoietic precursors possess an embryonic nature. These cell lines are useful models to study the mechanism(s) of developmental globin gene switching.

Histone deacetylase mRNA temporally and spatially regulated in its expression in sea urchin embryos

SpHDAC1, a cDNA homolog of the yeast Rpd3 and higher eukaryotic histone deacetylases (HDAC), was cloned from the sea urchin Strongylocentrotus purpuratus. Its predicted polypeptide and the Rpd3 homologs were highly identical in two-thirds of their lengths, but diverged in their carboxyl-terminal regions in both length and sequence. SpHDAC1 transcripts, which reached maximal concentration at the blastula stages, and diminished thereafter, were neither ubiquitously expressed nor restricted to particular cell lineages, but appeared successively in distinct embryonic regions. In the blastula, transcripts were concentrated in a ring within the vegetal plate, comprising primordial endoderm, and, at the outset of gastrulation, in primordial hindgut endoderm. However, in early to mid-gastrula transcripts, they also appeared in oral ectoderm. In the late-stage gastrula, expression developed in the foregut. These shifts in spatial expression, together with an observed developmental blockage prior to sea urchin gastrulation by the histone deacetylase inhibitor trichostatin A, suggest a stepwise involvement of SpHDAC1 gene expression or SpHDAC1 functionality in the events of normal gastrulation.

Physiological regulation of hypothalamic TRH transcription in vivo is T3 receptor isoform specific

Thyroid hormone (tri-iodo-thyronine, T3) exerts transcriptional effects on target genes in responsive cells. These effects are determined by DNA/protein interactions governed by the type of T3 receptors (TRs) in the cell. As TRs show tissue and developmental variations, regulation is best addressed in an integrated in vivo model. We examined TR subtype effects on thyrotropin-releasing hormone (TRH) transcription and on the pituitary/thyroid axis end point: thyroid hormone secretion. Polyethylenimine served to transfect a TRH-luciferase construct containing 554 bp of the rat TRH promoter into the hypothalami of newborn mice. Transcription from the TRH promoter was regulated in a physiologically faithful manner, being significantly increased in hypothyroidism and decreased in T3-treated animals. Moreover, when various ligand binding forms of mouse or chicken TRbeta and TRalpha were expressed with TRH-luciferase, all forms of TRbeta gave T3-dependent regulation of TRH transcription, whereas transcription was T3 insensitive with each TRalpha tested. Moreover, chicken TRalpha increased TRH transcription sixfold, whereas mouse TRalpha decreased transcription. These transcriptional effects had correlated physiological consequences: expression of the chicken TRalpha in the hypothalamus of newborn mice raised circulating T4 levels by fourfold, whereas mouse TRalpha had opposite effects. Thus, TR subtypes have distinct, physiologically relevant effects on TRH transcription.

Coinduction of Embryonic and Adult-Type Globin mRNAs by Sodium Butyrate and Trichostatin A in Two Murine Interleukin-3–Dependent Bone Marrow–Derived Cell Lines

Using an RNase protection assay, globin mRNA species expressed in clones derived from Ba/F3 and B6SUtA cells transfected with the erythropoietin receptor (EpoR) and selected with erythropoietin (Epo) were compared with globin mRNA species induced in corresponding parental cells by sodium butyrate (SB) and trichostatin A (TSA). βMajor/βminor- and -1/-2–globin mRNAs were the major species, with trace amounts of ɛ-globin mRNA, formed in Epo-stimulated EpoR+ Ba/F3 clones, whereas SB and TSA allowed expression of all species of globin mRNAs, ie, ɛ, βh1, βmajor/βminor, ζ, and -1/-2, in parental Ba/F3 cells. In contrast, ɛ- and -1/-2–globin mRNAs were the major species present in Epo-stimulated EpoR+ B6SUtA clones, whereas SB and TSA activated ɛ-, βh1-, βS/βT-, and -1/-2–globin genes in parental B6SUtA cells; ζ-globin mRNA was not detected in SB- and TSA-treated B6SUtA cells. Because TSA is a specific inhibitor of histone deacetylase, the mimicry of action exhibited by SB and TSA suggests that the effects of SB are mediated through its ability to inhibit histone deacetylase and that histone deacetylase is an integral part of the repression of globin genes in these interleukin-3–dependent cells. Efficient coinduction of embryonic and adult types of globin mRNA in bone marrow cell lines derived from adult mice indicates that adult hematopoietic precursors possess an embryonic nature. These cell lines are useful models to study the mechanism(s) of developmental globin gene switching.

Auto-silencing by the retinoid X receptor

Gene transcription is often regulated by small ligands, enabling cells to respond to external and metabolic stimuli. Of particular interest are the mechanisms by which hydrophobic hormones modulate the transcriptional activities of proteins of the nuclear receptor superfamily. It was previously shown that, in the absence of ligand, the retinoid X receptor (RXRalpha) forms tetramers with a high affinity and a pronounced positive co-operativity such that tetramers become the receptor's predominant species tat concentrations as low as 60-70 nM. It was shown further that while RXR tetramers are remarkably stable in the absence of ligand, ligand-binding induces their rapid dissociation into smaller species, dimers and monomers. Here, the functional consequences of the self-association properties of RXR were studied by examining two point mutants of RXR that displayed aberrant oligomerization behaviors. One mutant, mRXRalpha-R321A, was found to form tetramers with a wild-type affinity, but these tetramers failed to dissociate upon ligand-binding. This mutant was found to be impaired in its ability to associate with the nuclear receptor co-activator p/CIP and to activate transcription in response to the RXR ligand 9-cis-retinoic acid. The other mutant, mRXRalpha-F318A, self-associated into dimers with a wild-type affinity, but was unable to form tetramers. This mutant displayed substantial transcriptional activity even in the absence of ligand. We previously proposed, based on in vitro studies that RXR acts as an auto-silencer by sequestering itself into tetramers, and that an important role for the ligand in activating this receptor is to release active species, dimers and monomers, from the transcriptionally inactive tetrameric pool. The observations reported here provide in-cell evidence in support of this model and indicate that ligand induced dissociation of tetramers is the first step in signalling by RXR.

Long-distance transcriptional enhancement by the histone acetyltransferase PCAF

Enhancers are defined by their ability to stimulate gene activity from remote sites and their requirement for promoter-proximal upstream activators to activate transcription. Here we demonstrate that recruitment of the p300/CBP-associated factor PCAF to a reporter gene is sufficient to stimulate promoter activity. The PCAF-mediated stimulation of transcription from either a distant or promoter-proximal position depends on the presence of an upstream activator (Sp1). These data suggest that acetyltransferase activity may be a primary component of enhancer function, and that recruitment of polymerase and enhancement of transcription are separable. Transcriptional activation by PCAF requires both its acetyltransferase activity and an additional activity within its N terminus. We also show that the simian virus 40 enhancer and PCAF itself are sufficient to counteract Mad-mediated repression. These results are compatible with recent models in which gene activity is regulated by the competition between deacetylase-mediated repression and enhancer-mediated recruitment of acetyltransferases.

Molecular and structural biology of thyroid hormone receptors

1. Thyroid hormone receptors (TR) are expressed from two separate genes (alpha and beta) and belong to the nuclear receptor superfamily, which also contains receptors for steroids, vitamins and prostaglandins. 2. Unliganded TR are bound to DNA thyroid hormone response elements (TRE) predominantly as homodimers, or as heterodimers with retinoid X-receptors (RXR), and are associated with a complex of proteins containing corepressor proteins. Ligand binding promotes corepressor dissociation and binding of a coactivator. 3. Recent studies from our group have focused on the acquisition and use of X-ray crystallographic structures of ligand-binding domains (LBD) of both the rat (r) TR alpha and the human (h) TR beta bound to several different ligands. We have also developed ligands that bind selectively to the TR beta, which may provide ways to explore the differential functions of TR alpha compared with TR beta isoforms. 4. The LBD is comprised mostly of alpha-helices. The ligand is completely buried in the receptor and forms part of its hydrophobic core. Kinetic studies suggest that the limiting step in formation of high-affinity ligand-receptor complexes is the rate of folding of the receptor around the ligand. Ligands can be fitted tightly in the ligand-binding pocket and small differences in this fitting may explain many structure-activity relationships. Interestingly, analysis of the structures of antagonists suggests that they have chemical groups, 'extensions', that could impair receptor folding around them and, thus, prevent the agonist-induced conformation changes in the receptor. 5. The TR structures allowed us to see that the mutations that occur in the syndrome of generalized resistance to thyroid hormone are located in the vicinity of the ligand-binding pocket. 6. X-ray structure of the TR has also been used to guide construction of mutations in the TR surface that block binding of various proteins important for receptor function. Studies with these TR mutants reveal that the interfaces for homo- and heterodimerization map to similar residues in helix 10 and 11 and also allow the definition of the surface for binding of coactivators, which appears to be general for nuclear receptors. Formation of this surface, which involves packing of helix 12 of the TR into a scaffold formed by helices 3 and 5, appears to be the major change in the receptor structure induced by hormone occupancy.

Dynamics of histone acetylation in Chlamydomonas reinhardtii

The dynamic character of core histone post-translational acetylation in the unicellular green alga Chlamydomonas reinhardtii was studied by tritiated acetate incorporation. Histone H3 is the major target of acetylation, steady state, and in pulse and pulse-chase analyses. Acetylation turnover rates were measured by tracer labeling under steady-state conditions. Half-lives of 1.5-3 min were found for penta- to mono-acetylation of H3, dynamically acetylated to the 30% level. Twenty percent of H3 was multi-acetylated, on average with 3. 2 acetyl-lysines, all with rapid turnover. Deacetylase inhibitor trichostatin A (TSA) caused doubling of average acetylation levels, primarily as penta-acetylated H3, but half of H3 was not acetylated at all. The level of histone H4 acetylation was only half that of H3 and a major fraction of mono- and di-acetylated forms appeared static. The dynamic fraction had an average half-life of 3.5 min with higher turnover rates for more highly acetylated H4 forms. TSA, inhibiting less effectively deacetylases active on H4, strongly increased multi-acetylated H4 levels and doubled average acetylation. As for H3, half of histone H4 remained unacetylated. Acetylation of histone H2B was low and of H2A was barely measurable. Despite turnover with half-lives of approximately 2 min, no increase beyond di-acetylation was seen upon TSA treatment.

Components of the SMRT corepressor complex exhibit distinctive interactions with the POZ domain oncoproteins PLZF, PLZF-RARalpha, and BCL-6

Many transcription factors function by repressing gene transcription. For a variety of these transcription factors the ability to physically recruit auxiliary proteins, denoted corepressors, is crucial for the ability to silence gene expression. We and others have previously implicated the SMRT corepressor in the actions of the PLZF transcription factor and in the function of its oncogenic derivative, PLZF-retinoic acid receptor (RARalpha), in promyelocytic leukemia. We report here that PLZF, and a structurally similar transcriptional repressor, BCL-6, can interact with a variety of corepressor proteins in addition to SMRT, including the mSin3A protein and (for PLZF) histone deacetylase-1. Unexpectedly, these additional interactions with corepressor components are nonequivalent for these otherwise similar oncoproteins, suggesting that transcriptional repression by BCL-6 and by PLZF may differ in mechanism. Furthermore, we demonstrate that the oncogenic PLZF-RARalpha chimera lacks several important corepressor interaction sites that are present in the native PLZF protein. Thus the t(11;17) translocation that creates the PLZF-RARalpha chimera generates an oncoprotein with potentially novel regulatory properties distinct from those of either parental protein. Our results demonstrate that otherwise similar transcription factors can differ notably in their interactions with the corepressor machinery.

The LAZ3(BCL-6) oncoprotein recruits a SMRT/mSIN3A/histone deacetylase containing complex to mediate transcriptional repression

Recent works demonstrated that some transcriptional repressors recruit histone deacetylases (HDACs) either through direct interaction, or as a member of a multisubunit repressing complex containing other components referred to as corepressors. For instance, the bHLH-Zip transcriptional repressors MAD/MXI recruit HDACs together with the mSIN3 corepressors, whereas unliganded nuclear receptors contact another corepressor, SMRT (or its relative N-CoR), which, in turn, associates with both mSIN3 and HDACs to form the repressor complex. Recently, we reported that SMRT also directly associates with LAZ3(BCL-6), a POZ/Zn finger transcriptional repressor involvedin the pathogenesis of non-Hodgkin lymphomas. However, whether LAZ3 recruits the HDACs-containing repression complex is currently unknown. We report here that LAZ3 associates with corepressor mSIN3A both in vivo and in vitro , and found that a central region, which harbours autonomous repression activity, is mainly responsible for this interaction. Conversely, the N-terminal half of mSIN3A is both necessary and sufficient to bind LAZ3. Moreover, we show that LAZ3 also interacts with an HDAC (HDAC-1) through its POZ domain in vitro while the immunoprecipitation of LAZ3 results in the coretention of an endogenous HDAC activity in vivo . Finally, inhibitors of HDACs significantly reduce the LAZ3-mediated repression. Taken together, we conclude that LAZ3 recruits a repressing complex containing SMRT, mSIN3A and a HDAC, and that its full repressing potential on transcription requires HDACs activity. Our results identify HDACs as molecular targets of LAZ3 oncogene and further strengthen the connection between aberrant chromatin acetylation and human cancers.

Transcriptional silencing is defined by isoform- and heterodimer-specific interactions between nuclear hormone receptors and corepressors

Nuclear hormone receptors are ligand-regulated transcription factors that play critical roles in metazoan homeostasis, development, and reproduction. Many nuclear hormone receptors exhibit bimodal transcriptional properties and can either repress or activate the expression of a given target gene. Repression appears to require a physical interaction between a receptor and a corepressor complex containing the SMRT/TRAC or N-CoR/RIP13 polypeptides. We wished to better elucidate the rules governing the association of receptors with corepressors. We report here that different receptors interact with different domains in the SMRT and N-CoR corepressors and that these divergent interactions may therefore contribute to distinct repression phenotypes. Intriguingly, different isoforms of a single nuclear hormone receptor class also differ markedly in their interactions with corepressors, indicative of their nonidentical actions in cellular regulation. Finally, we present evidence that combinatorial interactions between different receptors can, through the formation of heterodimeric receptors, result in novel receptor-corepressor interactions not observed for homomeric receptors.

Regulation of the spatiotemporal pattern of expression of the glutamine synthetase gene

Glutamine synthetase, the enzyme that catalyzes the ATP-dependent conversion of glutamate and ammonia into glutamine, is expressed in a tissue-specific and developmentally controlled manner. The first part of this review focuses on its spatiotemporal pattern of expression, the factors that regulate its levels under (patho)physiological conditions, and its role in glutamine, glutamate, and ammonia metabolism in mammals. Glutamine synthetase protein stability is more than 10-fold reduced by its product glutamine and by covalent modifications. During late fetal development, translational efficiency increases more than 10-fold. Glutamine synthetase mRNA stability is negatively affected by cAMP, whereas glucocorticoids, growth hormone, insulin (all positive), and cAMP (negative) regulate its rate of transcription. The signal transduction pathways by which these factors may regulate the expression of glutamine synthetase are briefly discussed. The second part of the review focuses on the evolution, structure, and transcriptional regulation of the glutamine synthetase gene in rat and chicken. Two enhancers (at -6.5 and -2.5 kb) were identified in the upstream region and two enhancers (between +156 and +857 bp) in the first intron of the rat glutamine synthetase gene. In addition, sequence analysis suggests a regulatory role for regions in the 3' untranslated region of the gene. The immediate-upstream region of the chicken glutamine synthetase gene is responsible for its cell-specific expression, whereas the glucocorticoid-induced developmental appearance in the neural retina is governed by its far-upstream region.

CpG methylation, chromatin structure and gene silencing-a three-way connection

The three-way connection between DNA methylation, gene activity and chromatin structure has been known for almost two decades. Nevertheless, the molecular link between methyl groups on the DNA and the positioning of nucleosomes to form an inactive chromatin configuration was missing. This review discusses recent experimental data that may, for the first time, shed light on this molecular link. MeCP2, which is a known methylcytosine-binding protein, has been shown to possess a transcriptional repressor domain (TRD) that binds the corepressor mSin3A. This corepressor protein constitutes the core of a multiprotein complex that includes histone deacetylases (HDAC1 and HDAC2). Transfection and injection experiments with methylated constructs have revealed that the silenced state of a methylated gene, which is associated with a deacetylated nucleosomal structure, could be relieved by the deacetylase inhibitor, trichostatin A. Thus, methylation plays a pivotal role in establishing and maintaining an inactive state of a gene by rendering the chromatin structure inaccessible to the transcription machinery.

Spe3, which encodes spermidine synthase, is required for full repression through NRE(DIT) in Saccharomyces cerevisiae

We previously identified a transcriptional regulatory element, which we call NRE(DIT), that is required for repression of the sporulation-specific genes, DIT1 and DIT2, during vegetative growth of Saccharomyces cerevisiae. Repression through this element is dependent on the Ssn6-Tup1 corepressor. In this study, we show that SIN4 contributes to NRE(DIT)-mediated repression, suggesting that changes in chromatin structure are, at least in part, responsible for regulation of DIT gene expression. In a screen for additional genes that function in repression of DIT (FRD genes), we recovered alleles of TUP1, SSN6, SIN4, and ROX3 and identified mutations comprising eight complementation groups of FRD genes. Four of these FRD genes appeared to act specifically in NRE(DIT)mediated repression, and four appeared to be general regulators of gene expression. We cloned the gene complementing the frd3-1 phenotype and found that it was identical to SPE3, which encodes spermidine synthase. Mutant spe3 cells not only failed to support complete repression through NRE(DIT) but also had modest defects in repression of some other genes. Addition of spermidine to the medium partially restored repression to spe3 cells, indicating that spermidine may play a role in vivo as a modulator of gene expression. We suggest various mechanisms by which spermidine could act to repress gene expression.

Transcriptional repression by the SMRT-mSin3 corepressor: multiple interactions, multiple mechanisms, and a potential role for TFIIB

A variety of eukaryotic transcription factors, including the nuclear hormone receptors, Max-Mad, BCL-6, and PLZF, appear to mediate transcriptional repression through the ability to recruit a multiprotein corepressor complex to the target promoter. This corepressor complex includes the SMRT/N-CoR polypeptides, mSin3A or -B, and histone deacetylase 1 or 2. The presence of a histone-modifying activity in the corepressor complex has led to the suggestion that gene silencing is mediated by modification of the chromatin template, perhaps rendering it less accessible to the transcriptional machinery. We report here, however, that the corepressor complex actually appears to exhibit multiple mechanisms of transcriptional repression, only one of which corresponds with detectable recruitment of the histone deacetylase. We provide evidence instead of an alternative pathway of repression that may be mediated by direct physical interactions between components of the corepressor complex and the general transcription factor TFIIB.

Absence of MHC class II antigen expression in trophoblast cells results from a lack of class II transactivator (CIITA) gene expression

Although the mechanism(s) underlying the failure of the maternal immune system to reject the semiallogeneic fetus have not been clearly defined, the absence of MHC class II antigen expression by fetal trophoblast cells very likely plays a critical role in the maintenance of normal pregnancy. However, the regulation of class II antigen expression in trophoblast cells is poorly understood. Class II transactivator (CIITA) is a transacting factor that is required for both constitutive and IFN-gamma-inducible class II gene transcription. In this report we demonstrate that the inability of trophoblast cells to express class II antigens is due to a lack of CIITA gene expression. Trophoblast cell lines derived from human, mouse, and rat do not express CIITA, and expression is not inducible by IFN-gamma. The absence of CIITA gene expression in trophoblasts treated with IFN-gamma does not result from a defect in the IFN-gamma receptor or the JAK/STAT pathway, because the classical IFN-gamma inducible gene encoding the guanylate-binding protein is expressed. Transfection of CIITA expression vectors into trophoblast cells results in activation of class II promoters, endogenous class II mRNA expression, and subsequent expression of class II antigens on the cell surface. In contrast, class I mRNA is not expressed in human trophoblast cells transfected with CIITA expression vectors. Thus, trophoblast cells contain all of the DNA binding factors necessary for class II transcription, and ectopic expression of CIITA is sufficient to activate class II, but not class I expression. The failure of trophoblast cells to express CIITA, and therefore class II antigens, provides a potential mechanism by which the fetus is protected from the maternal immune system during pregnancy.

The thyroid hormone receptor functions as a ligand-operated developmental switch between proliferation and differentiation of erythroid progenitors

The avian erythroblastosis virus (AEV) oncoprotein v-ErbA represents a mutated, oncogenic thyroid hormone receptor alpha (c-ErbA/ TRalpha). v-ErbA cooperates with the stem cell factor-activated, endogenous receptor tyrosine kinase c-Kit to induce self-renewal and to arrest differentiation of primary avian erythroblasts, the AEV transformation target cells. In this cooperation, v-ErbA substitutes for endogenous steroid hormone receptor function required for sustained proliferation of non-transformed erythroid progenitors. In this paper, we propose a novel concept of how v-ErbA transforms erythroblasts. Using culture media strictly depleted from thyroid hormone (T3) and retinoids, the ligands for c-ErbA/TRalpha and its co-receptor RXR, we show that overexpressed, unliganded c-ErbA/ TRalpha closely resembles v-ErbA in its activity on primary erythroblasts. In cooperation with ligand-activated c-Kit, c-ErbA/ TRalpha causes steroid-independent, long-term proliferation and tightly blocks differentiation. Activation of c-ErbA/ TRalpha by physiological T3 levels causes the loss of self-renewal capacity and induces synchronous, terminal differentiation under otherwise identical conditions. This T3-induced switch in erythroid progenitor development is correlated with a decrease of c-ErbA-associated histone deacetylase activity. Our results suggest that the crucial role of the mutations activating v-erbA as an oncogene is to 'freeze' c-ErbA/ TRalpha in its non-liganded, repressive conformation and to facilitate its overexpression.

Signaling by tyrosine kinases negatively regulates the interaction between transcription factors and SMRT (silencing mediator of retinoic acid and thyroid hormone receptor) corepressor

Nuclear hormone receptors are hormone-regulated transcription factors that bind to specific sites on DNA and modulate the expression of adjacent target genes. Many nuclear hormone receptors display bimodal transcriptional properties; thyroid hormone receptors, for example, typically repress target gene expression in the absence of hormone, but activate target gene expression in the presence of hormone. The ability to repress is closely linked to the ability of the apo-receptor to physically bind to auxiliary corepressor proteins denoted SMRT (silencing mediator of retinoic acid and thyroid hormone receptor) and N-CoR (nuclear receptor corepressor), which, in turn, help mediate the actual molecular events involved in transcriptional silencing. We report here that repression by thyroid hormone receptors can be regulated not only by cognate hormone, but also by certain tyrosine kinase signal transduction pathways, such as that represented by the epidermal growth factor-receptor. Activation of tyrosine kinase signaling leads to inhibition of T3R-mediated repression with relatively little effect on activation. These effects appear to be mediated by a kinase-initiated disruption of the ability of T3R to interact with SMRT corepressor. Intriguingly, tyrosine kinase signaling similarly disrupted the interactions of SMRT with v-Erb A, with retinoic acid receptors, and with PLZF, a nonreceptor transcriptional repressor. We conclude that tyrosine kinase signaling exerts potentially important regulatory effects on transcriptional silencing mediated by a variety of transcription factors that operate through the SMRT corepressor complex.

Analyzing chromatin structure and transcription factor binding in yeast

The study of chromatin, once thought to be a purely structural matrix serving to compact the DNA of the genome into the nucleus, is of increasing value for our understanding of how DNA functions in the cell. This article provides two basic procedures for the study of chromatin in vivo. The first is a DNase I-based method for the treatment of isolated nuclei to resolve the chromatin structure of a particular region; the second employs dimethyl sulfate footprinting of whole cells in vivo to determine the binding of factors to cis elements in the locus of interest. Specific examples illustrating the techniques described are given from our work on the regulation of the yeast PHO8 gene, but have also been successfully and reliably applied to the study of many other yeast loci. These procedures make it possible to correlate the binding of a transactivator with an altered or perturbed chromatin organization at a specific locus.

Biochemical methods for analysis of histone deacetylases

Specific lysine residues in the N-terminal extensions of core histones can be posttranslationally modified by acetylation of the epsilon-amino group. The dynamic equilibrium of core histone acetylation is established and maintained by histone acetyltransferases and deacetylases. Both enzymes exist as multiple enzyme forms. Histone acetyltransferases and deacetylases have recently been identified as transcriptional regulators as well as nucleolar phosphoproteins, and have therefore attracted considerable research interest. Analysis of the functional significance of histone deacetylases for nuclear processes in certain cases demands the separation and biochemical analysis of different members of the histone deacetylase families. We have characterized three different histones deacetylases in maize embryos and subsequently purified these enzymes to homogeneity. Here we describe methods for extraction, enzymatic assay, chromatographic and electrophoretic separation, and purification of deacetylases. A novel one-step procedure for large-scale preparation of individual histones and their acetylated isoforms for the analysis of substrate and site specificity of the enzymes is presented.

Roles of histone acetyltransferases and deacetylases in gene regulation

Acetylation of internal lysine residues of core histone N-terminal domains has been found correlatively associated with transcriptional activation in eukaryotes for more than three decades. Recent discoveries showing that several transcriptional regulators possess intrinsic histone acetyltransferase (HAT) and deacetylase (HDAC) activities strongly suggest that histone acetylation and deacetylation each plays a causative role in regulating transcription. Intriguingly, several HATs have been shown an ability to acetylate nonhistone protein substrates (e.g., transcription factors) in vitro as well, suggesting the possibility that internal lysine acetylation of multiple proteins exists as a rapid and reversible regulatory mechanism much like protein phosphorylation. This article reviews recent developments in histone acetylation and transcriptional regulation. We also discuss several important, yet unanswered, questions.

Thyroid hormone receptor coactivators and corepressors

In the absence of triiodothyronine (T3), thyroid hormone receptors (TRs) repress transcription of many genes; in the presence of T3, TRs activate transcription of those same genes. Both of these events are dependent on interactions between TRs and other nuclear proteins. TRs bind to specific DNA sequences, generally found in the 5' flanking regions of target genes. In the unliganded state, TRs interact with one of several corepressor proteins. These proteins, in turn, interact with a series of other proteins, which includes histone deacetylases. Histone deacetylation tightens chromatin structure, thus impairing access of critical transcription factors and thereby repressing transcription. In addition, corepressors may invoke mechanisms of gene repression independent of histone deacetylation. The binding of T3 causes a conformational change in the TR that results in release of the corepressor and recruitment of coactivator proteins. Several coactivator proteins appear to bind the ligand-occupied TR as a multiprotein complex. Opposite to corepressors, coactivators acetylate histones, thereby loosening chromatin structure and facilitating access of key transcription factors. Again, mechanisms independent of histone acetylation also may be involved. Overall, gene activation by T3 is a two-step process; removal of active repression, and induction of transcription to levels above the "neutral" state.

Transcriptional regulation of the MDR1 gene by histone acetyltransferase and deacetylase is mediated by NF-Y

Recent studies have shown that the histone-modifying enzymes histone acetyltransferase (HAT) and histone deacetylase (HDAC) are involved in transcriptional activation and repression, respectively. However, little is known about the endogenous genes that are regulated by these enzymes or how specificity is achieved. In the present report, we demonstrate that HAT and HDAC activities modulate transcription of the P-glycoprotein-encoding gene, MDR1. Incubation of human colon carcinoma SW620 cells in 100-ng/ml trichostatin A (TSA), a specific HDAC inhibitor, increased the steady-state level of MDR1 mRNA 20-fold. Furthermore, TSA treatment of cells transfected with a wild-type MDR1 promoter/luciferase construct resulted in a 10- to 15-fold induction of promoter activity. Deletion and point mutation analysis determined that an inverted CCAAT box was essential for this activation. Consistent with this observation, overexpression of p300/CREB binding protein-associated factor (P/CAF), a transcriptional coactivator with intrinsic HAT activity, activated the wild-type MDR1 promoter but not a promoter containing a mutation in the CCAAT box; deletion of the P/CAF HAT domain abolished activation. Gel shift and supershift analyses identified NF-Y as the CCAAT-box binding protein in these cells, and cotransfection of a dominant negative NF-Y expression vector decreased the activation of the MDR1 promoter by TSA. Moreover, NF-YA and P/CAF were shown to interact in vitro. This is the first report of a natural promoter that is modulated by HAT and HDAC activities in which the transcription factor mediating this regulation has been identified.

Two distinct nuclear receptor interaction domains in NSD1, a novel SET protein that exhibits characteristics of both corepressors and coactivators

NSD1, a novel 2588 amino acid mouse nuclear protein that interacts directly with the ligand-binding domain (LBD) of several nuclear receptors (NRs), has been identified and characterized. NSD1 contains a SET domain and multiple PHD fingers. In addition to these conserved domains found in both positive and negative Drosophila chromosomal regulators, NSD1 contains two distinct NR interaction domains, NID-L and NID+L, that exhibit binding properties of NIDs found in NR corepressors and coactivators, respectively. NID-L, but not NID+L, interacts with the unliganded LBDs of retinoic acid receptors (RAR) and thyroid hormone receptors (TR), and this interaction is severely impaired by mutations in the LBD alpha-helix 1 that prevent binding of corepressors and transcriptional silencing by apo-NRs. NID+L, but not NID-L, interacts with the liganded LBDs of RAR, TR, retinoid X receptor (RXR), and estrogen receptor (ER), and this interaction is abrogated by mutations in the LBD alpha-helix 12 that prevent binding of coactivators of the ligand-induced transcriptional activation function AF-2. A novel variant (FxxLL) of the NR box motif (LxxLL) is present in NID+L and is required for the binding of NSD1 to holo-LBDs. Interestingly, NSD1 contains separate repression and activation domains. Thus, NSD1 may define a novel class of bifunctional transcriptional intermediary factors playing distinct roles in both the presence and absence of ligand.

The nuclear receptor ligand-binding domain: structure and function

In the past few years our understanding of nuclear receptor action has dramatically improved as a result of the elucidation of the crystal structures of the empty (apo) ligand-binding domains of the nuclear receptor and of complexes formed by the nuclear receptor's ligand-binding domain bound to agonists and antagonists. Furthermore, the concomitant identification and functional analysis of co-regulators (transcriptional intermediary factors [TIFs], comprising co-activators and co-repressors) previously predicted from squelching studies, have deepened this understanding. Recent data have provided the structural basis for the specific recognition of ligands and the molecular mechanisms of agonism and antagonism, enabling us to gain a comprehensive view of the early steps of nuclear receptor action.

DNA methylation, nucleosomes and the inheritance of chromatin structure and function

The replication of the genome during S phase is a crucial period for the establishment and maintenance of programmes of differential gene activity. Existing chromosomal structures are disrupted during replication and reassembled on both daughter chromatids. The capacity to reassemble a particular chromatin structure with defined functional properties reflects the commitment of a cell type to a particular state of determination. The core and linker histones and their modifications, enzymes that modify the histones, DNA methylation and proteins that recognize methylated DNA within chromatin may all play independent or interrelated roles in defining the functional properties of chromatin. Pre-existing protein-DNA interactions and DNA methylation in a parental chromosome will influence the structure and function of daughter chromosomes generating an epigenetic imprint. In this chapter we consider the events occurring at the eukaryotic replication fork, their consequences for pre-existing chromosomal structures and how an epigenetic imprint might be maintained.

The switch in the helical handedness of the histone (H3-H4)2 tetramer within a nucleoprotein particle requires a reorientation of the H3-H3 interface

It has recently been proposed that the histone (H3-H4)2 tetramer undergoes structural changes, which allow the particle to accommodate both negatively and positively constrained DNA. To investigate this process, we modified histone H3 at the H3-H3 interface, within the histone (H2A-H2B-H3-H4)2 octamer or the histone (H3-H4)2 tetramer, by forming adducts on the single cysteine of duck histone H3. We used three sulfhydryl reagents, iodoacetamide, N-ethylmaleimide, and 5,5'-dithiobis(2-nitrobenzoic acid). Torsionally constrained DNA was assembled on the modified histones. The H3 adducts, which have no effect on the structure of the nucleosome, dramatically affected the structural transitions that the (H3-H4)2 tetrameric nucleoprotein particle can undergo. Iodoacetamide and N-ethylmaleimide treatment prevented the assembly of positively constrained DNA on the tetrameric particle, whereas 5, 5'-dithiobis(2-nitrobenzoic acid) treatment strongly favored it. Determination of DNA topoisomer equilibrium after relaxation of the tetrameric nucleoprotein particles with topoisomerase I demonstrated that the structural transition occurs without histone dissociation. Incorporation of H2A-H2B dimers into the tetrameric particle containing modified or unmodified cysteines allowed nucleosomes to reform and blocked the structural transition of the particle. We demonstrate the importance of the histone H3-H3 contact region in the conformational changes of the histone tetramer nucleoprotein particle and the role of H2A-H2B in preventing a structural transition of the nucleosome.

Covalent modifications of histones: expression from chromatin templates

Recent advances highlight the involvement of histone acetyltransferases in transcriptional activation and histone deacetylases in transcriptional repression. Transcription factors loaded onto regulatory DNA elements may recruit either coactivators with histone acetyltransferase activity or corepressors associated with histone deacetylases. The recruited enzymes may either acetylate or deacetylate proximal nucleosomal histones or nonhistone chromosomal proteins.

X-ray crystallographic and functional studies of thyroid hormone receptor

We have solved several X-ray crystallographic structures of TR ligand-binding domains (LBDs), including the rat (r) TR alpha and the human (h) TR beta bound to diverse ligands. The TR-LBD folding, comprised mostly of alpha-helices, is likely to be general for the superfamily. The ligand, buried in the receptor, forms part of its hydrophobic core. Tight fitting of ligand into the receptor explains its high affinity for the TR, although the structure suggests that ligands with even higher affinities might be generated. The kinetics of 3,5,3'-triiodo-L-thyronine (T3) and 3,5,3',5'-tetraiodo-L-thyronine (T4) binding suggest that folding around the ligand, rather than receptor opening, is rate-limiting for high affinity binding. TR beta mutations in patients with resistance to T3 cluster around the ligand; these different locations could differentially affect on other receptor functions and explain the syndrome's clinical diversity. Guided by the structure, mutations have been placed on the TR surface to define interactions with other proteins. They suggest that a similar surface in the LBD is utilized for homo- or heterodimerization on direct repeats and inverted palindromes but not on palindromes. Coactivator proteins that mediate TR transcriptional activation bind to a small surface comprised of residues on four helices with a well-defined hydrophobic cleft, which may be a target for pharmaceuticals. The coactivator-binding surface appears to form upon ligand-binding by the folding of helix 12 into the scaffold formed by helices 3, 4 and 5. The analysis of most currently used antagonists suggest that although they probably fit into the ligand-binding pocket, they possess a group that may alter proper folding of the receptor, with disruption of the coactivator-binding surface (the 'extension model').

The receptor-associated coactivator 3 activates transcription through CREB-binding protein recruitment and autoregulation

Transcriptional coactivators are involved in gene activation by nuclear hormone receptors. The receptor-associated coactivator 3 (RAC3) was recently identified to be highly related to the steroid receptor coactivator-1 and transcriptional intermediate factor 2, thereby establishing a novel family of nuclear receptor coactivators. In this study, we identified a RAC3 fragment containing three LXXLL motifs conserved among this family, which is sufficient to mediate nuclear receptor interaction in vivo and in vitro. Point mutations that disrupt ligand-dependent activation function of the receptor inhibited the interaction. We found that a 162-amino acid fragment of RAC3 conferred transcriptional activation and recruited the CREB-binding protein and that three distinct LXXLL motifs mediated the transcriptional activation. A trimeric far Western analysis demonstrated the formation of a ternary complex containing CREB-binding protein, RAC3, and the receptor. In addition, we showed that RAC3, transcriptional intermediate factor 2, and steroid receptor coactivator-1 are expressed in specific tissues and cancer cells and that RAC3 transcript is directly up-regulated by retinoid treatment. These results suggest that RAC3 may contribute to amplified transcriptional responses through both recruitment of additional coactivators and autoregulation by the receptor-coactivator complex.

Histone acetyltransferase activity of yeast Gcn5p is required for the activation of target genes in vivo

Gcn5p is a transcriptional coactivator required for correct expression of various genes in yeast. Several transcriptional regulators, including Gcn5p, possess intrinsic histone acetyltransferase (HAT) activity in vitro. However, whether the HAT activity of any of these proteins is required for gene activation remains unclear. Here, we demonstrate that the HAT activity of Gcn5p is critical for transcriptional activation of target genes in vivo. Core histones are hyperacetylated in cells overproducing functional Gcn5p, and promoters of Gcn5p-regulated genes are associated with hyperacetylated histones upon activation by low-copy Gcn5p. Point mutations within the Gcn5p catalytic domain abolish both promoter-directed histone acetylation and Gcn5p-mediated transcriptional activation. These data provide the first in vivo evidence that promoter-specific histone acetylation, catalyzed by functional Gcn5p, plays a critical role in gene activation.

Albuterol does not antagonize the inhibitory effect of dexamethasone on monocyte cytokine release

Beta2-adrenoceptor agonists given by the inhaled route are the most effective bronchodilators known, yet high doses of these drugs may be associated with an increase in asthma mortality and morbidity. One theory for this paradox is that chronic use of beta2-adrenoceptor agonists compromises the anti-inflammatory action of glucocorticosteroids. This hypothesis derives from the ability of albuterol and fenoterol to inhibit the interaction of the glucocorticosteroid receptor (GR) with proinflammatory transcriptional activators acting on the promoter region of certain target genes that encode cytokines such as tumor necrosis factor-alpha (TNF alpha) and granulocyte/macrophage colony-stimulating factor (GM-CSF). However, the functional relevance of these results has not been formally investigated. We have tested the hypothesis that albuterol reduces the ability of dexamethasone to inhibit the generation of TNF alpha and GM-CSF from lipopolysaccharide (LPS)-stimulated human monocytes. Pretreatment of human monocytes with albuterol (1 and 100 microM) for 5 and for 180 min inhibited maximally TNF alpha generation by approximately 25%. However, regardless of the concentration of albuterol, or the time of preincubation, the inhibitory effect of dexamethasone was not significantly affected with respect to the EC50 or the maximal effect produced. Qualitatively identical data were obtained when GM-CSF release was used as an index of monocyte activation. We conclude that high concentrations of albuterol do not compromise the ability of dexamethasone to suppress the generation of TNF alpha and GM-CSF from LPS-stimulated human monocytes.

Fusion proteins of the retinoic acid receptor-alpha recruit histone deacetylase in promyelocytic leukaemia

The transforming proteins of acute promyelocytic leukaemias (APL) are fusions of the promyelocytic leukaemia (PML) and the promyelocytic leukaemia zinc-finger (PLZF) proteins with retinoic acid receptor-alpha (RARalpha). These proteins retain the RARalpha DNA- and retinoic acid (RA)-binding domains, and their ability to block haematopoietic differentiation depends on the RARalpha DNA-binding domain. Thus RA-target genes are downstream effectors. However, treatment with RA induces differentiation of leukaemic blast cells and disease remission in PML-RARalpha APLs, whereas PLZF-RARa APLs are resistant to RA. Transcriptional regulation by RARs involves modifications of chromatin by histone deacetylases, which are recruited to RA-target genes by nuclear co-repressors. Here we show that both PML-RARalpha and PLZF-RARalpha fusion proteins recruit the nuclear co-repressor (N-CoR)-histone deacetylase complex through the RARalpha CoR box. PLZF-RARalpha contains a second, RA-resistant binding site in the PLZF amino-terminal region. High doses of RA release histone deacetylase activity from PML-RARalpha, but not from PLZF-RARalpha. Mutation of the N-CoR binding site abolishes the ability of PML-RARalpha to block differentiation, whereas inhibition of histone deacetylase activity switches the transcriptional and biological effects of PLZF-RARalpha from being an inhibitor to an activator of the RA signalling pathway. Therefore, recruitment of histone deacetylase is crucial to the transforming potential of APL fusion proteins, and the different effects of RA on the stability of the PML-RARalpha and PLZF-RARalpha co-repressor complexes determines the differential response of APLs to RA.

A novel function of poly(ADP-ribosyl)ation: silencing of RNA polymerase II-dependent transcription

Poly(ADP-ribosyl) transferase (ADPRT) is a nuclear enzyme that catalyzes the synthesis of ADP-ribose polymers from NAD+ as well as the transfer of these polymers onto acceptor proteins. The predominant acceptor of the poly(ADP-ribose) chains appears to be the enzyme itself. The function of ADPRT is thought to be related to a number of nuclear processes, including DNA repair and transcription. In this study, it was found that polymerase II-dependent transcription in nuclear HeLa extracts was repressed in the presence of NAD+ at concentrations as low as 1 microM. This repression was strictly dependent on the activity of ADPRT and correlated with the auto(ADP-ribosyl)ation of the enzyme. Subsequent degradation of the ADP-ribose polymers by enzymatic activities present in the nuclear extracts restored transcriptional activity. It would appear from these results that poly(ADP-ribosyl)ation represents the key event of the mechanism underlying NAD(+)-dependent silencing of transcription. Importantly, ADPRT- and NAD(+)-dependent silencing was observed only if poly(ADP-ribosyl)ation had taken place before formation of the transcription complex was completed. That is, if the nuclear extract was preincubated for more than 15 min in the presence of template DNA, transcription was rendered entirely insensitive to NAD+. These results suggest that poly(ADP-ribosyl)ation may prevent polymerase II-dependent transcription, but does not interfere with ongoing transcription. Taking into account the known function of ADPRT, this enzyme may facilitate recovery from DNA damage by stimulating DNA repair and silencing transcription.

Transcriptional repression by v-Ski and c-Ski mediated by a specific DNA binding site

The Ski oncoprotein has been shown to bind DNA and activate transcription in conjunction with other cellular factors. Because tumor cells or myogenic cells were used for those studies, it is not clear that those activities of Ski are related to its transforming ability. In this study, we use a nuclear extract of c-ski-transformed cells to identify a specific DNA binding site for Ski with the consensus sequence GTCTAGAC. We demonstrate that both c-Ski and v-Ski in nuclear extracts are components of complexes that bind specifically to this site. By evaluating the features of the sequence that are critical for binding, we show that binding is cooperative. Although Ski cannot bind to this sequence on its own, we use cross-linking with ultraviolet light to show that Ski binds to this site along with several unidentified cellular proteins. Furthermore, we find that Ski represses transcription either through upstream copies of this element or when brought to the promoter by a heterologous DNA binding domain. This is the first demonstration that Ski acts as a repressor rather than an activator and could provide new insights into regulation of gene expression by Ski.

Thyroid hormone response element architecture affects corepressor release from thyroid hormone receptor dimers

Thyroid hormone receptors are ligand-modulated transcription factors that can repress or activate transcription depending upon the absence or presence of thyroid hormone and the nature of the hormone response element to which the receptors are bound. The ability of thyroid hormone receptors to repress transcription in the absence of ligand is thought to be due to associations with nuclear hormone receptor corepressors. Ligand binding by the thyroid hormone receptor is believed to dissociate these corepressors and recruit coactivators to promote transcription from target promoters. We hypothesize that variations in response element architecture may influence both the association and dissociation of corepressors from DNA-bound thyroid hormone receptors. Using a chimeric corepressor, we find that ligand alone does not fully relieve corepressor-mediated repression, particularly in the presence of thyroid hormone receptor and its heterodimerization partner, the retinoid X receptor. Interestingly, the steroid receptor coactivator 1 together with ligand is able to mediate full release of corepression, but this relief is dependent upon the architecture of the response element to which the nuclear receptor dimer-corepressor complex is bound. These studies suggest that other cellular factors in addition to ligand may be required for the release of corepressors from thyroid hormone receptor dimers.