Transcriptional repression by the zinc finger protein REST is mediated by titratable nuclear factors

RE-1 silencing transcription factor (REST): a regulator of neuronal development and neuronal/endocrine function

RE-1 silencing transcription factor (REST) is a transcriptional repressor that has been proposed to function as a master negative regulator of neurogenesis, as REST target genes encode neuronal receptors, ion channels, neuropeptides and synaptic proteins. During neuronal differentiation, REST expression levels are reduced, allowing expression of selected REST target genes. The analysis of neural stem/progenitor cells that are either devoid of REST or overexpress REST revealed that REST is not the master regulator that is solely responsible for the acquisition of the neuronal fate. Rather, REST provides a regulatory hub that coordinately regulates multiple tiers of neuronal development in vitro. In addition, REST may play an important role for maintaining the integrity of adult neurons. REST confers oxidative stress resistance and is essential for maintaining neuronal viability. Furthermore, the concentration of REST has been reported to influence the pathogenic outcome by neuronal diseases, including stroke, epilepsy and Alzheimer's disease. Experiments performed with PC12 pheochromocytoma cells indicate that REST may function as a key regulator of the neurosecretory phenotype. Moreover, transgenic mice overexpressing REST in pancreatic β-cells showed impaired insulin secretion leading to significantly reduced plasma insulin levels. Based on the fact that REST plays a prominent role in controlling stimulus-induced secretion in endocrine cells, we propose that REST may also be important for neurotransmitter release via regulation of genes that encode important proteins of the exocytotic machinery.

The repressor element 1-silencing transcription factor regulates heart-specific gene expression using multiple chromatin-modifying complexes

Cardiac hypertrophy is associated with a dramatic change in the gene expression profile of cardiac myocytes. Many genes important during development of the fetal heart but repressed in the adult tissue are reexpressed, resulting in gross physiological changes that lead to arrhythmias, cardiac failure, and sudden death. One transcription factor thought to be important in repressing the expression of fetal genes in the adult heart is the transcriptional repressor REST (repressor element 1-silencing transcription factor). Although REST has been shown to repress several fetal cardiac genes and inhibition of REST function is sufficient to induce cardiac hypertrophy, the molecular mechanisms employed in this repression are not known. Here we show that continued REST expression prevents increases in the levels of the BNP (Nppb) and ANP (Nppa) genes, encoding brain and atrial natriuretic peptides, in adult rat ventricular myocytes in response to endothelin-1 and that inhibition of REST results in increased expression of these genes in H9c2 cells. Increased expression of Nppb and Nppa correlates with increased histone H4 acetylation and histone H3 lysine 4 methylation of promoter-proximal regions of these genes. Furthermore, using deletions of individual REST repression domains, we show that the combined activities of two domains of REST are required to efficiently repress transcription of the Nppb gene; however, a single repression domain is sufficient to repress the Nppa gene. These data provide some of the first insights into the molecular mechanism that may be important for the changes in gene expression profile seen in cardiac hypertrophy.

Transcriptional repression activity of PAX3 is modulated by competition between corepressor KAP1 and heterochromatin protein 1

Pax3 is a transcription factor crucial for normal development and tumorigenesis. Pax3 has been known to cause Waardenburg syndrome and pediatric alveolar rhabdomyosarcoma, but how Pax3 regulates transcription is not clear. Here, we report that Pax3 represses transcription and selectively interacts with heterochromatin protein 1 (HP1) and KAP1. KAP1 functions as a transcriptional corepressor by recruiting HP1 to facilitate the formation of a closed chromatin through histone deacetylation and methylation. We found that KAP1 is a corepressor for Pax3 by augmenting the repressional activity of Pax3. Unexpectedly, HP1gamma diminishes the repressional activity of Pax3. On target promoters, KAP1 and HP1gamma compete for binding with Pax3 on the N-terminal paired domain, and the C-terminal domain of Pax3 governs the subcellular localization of Pax3. Taken together, our results indicate that Pax3 represses transcription through a novel mechanism involving competition between corepressor KAP1 and the heterochromatin-binding protein HP1gamma.

RE-1 silencing transcription factor-4 (REST4) is neither a transcriptional repressor nor a de-repressor

The zinc finger protein RE-1 silencing transcription factor (REST) is a transcriptional repressor that represses neuronal genes in non-neuronal tissues. A neuronal splice form of REST, termed REST4, has been described in the rat. It encompasses the N-terminus of REST, including the N-terminal repressor domain and five of the eight zinc fingers of the DNA-binding domain. The biological function of REST4 is controversial. Transcriptional repression as well as transcriptional de-repression activity has been attributed to the REST4 protein of rat. Here, we have expressed a 'humanized' version of REST4 (hREST4) to facilitate a comparison of the biological functions of hREST4 and REST. The biological activity the human REST protein has been extensively studied in the past. Additionally, hREST4 has a high degree of homology with the REST4 protein of rat. An immunofluorescence analysis showed that hREST4 is expressed in the nucleus, indicating that the protein may have a potential impact on gene regulation. We analyzed the biological function of hREST4 in NS20Y neuroblastoma cells using human synapsin I promoter/reporter gene constructs. The human synapsin I gene is negatively regulated by REST. The results show that hREST4, in contrast to the full-length human REST protein, does not impair human synapsin I promoter activity. Moreover, co-transfection experiments with expression vectors encoding REST and hREST4 did not reveal any evidence that REST4 blocks the transcriptional repression activity of REST.

Biological activity of RE-1 silencing transcription factor (REST) towards distinct transcriptional activators

The zinc finger protein RE-1 silencing transcription factor (REST) is a transcriptional repressor that represses neuronal genes in non-neuronal tissues. We have analyzed the ability of REST and the REST mutants, RESTDeltaN and RESTDeltaC lacking either the N-terminal or C-terminal repression domains of REST, to inhibit transcription mediated by distinct transcriptional activator proteins. For this purpose we have designed an activator specific assay where transcription is activated as a result of only one distinct activation domain. In addition, binding sites for REST were inserted in the 5'-untranslated region or at a distant position downstream of the polyadenylation signal. The results show that REST or the REST mutants containing only one repression domain were able to block transcriptional activation mediated by the transcriptional activation domains derived from p53, AP2, Egr-1, and GAL4. Moreover, REST, as well as the REST mutants, blocked the activity of the phosphorylation-dependent activation domain of Elk1. However, the activity of the activation domain derived from cAMP response element binding protein 2 (CREB2), was not inhibited by REST, RESTDeltaN or RESTDeltaC, suggesting that REST is able to distinguish between distinct transcriptional activation domains. Additionally, the activator specific assay, together with a positive-dominant mutant of REST that activated instead of repressed transcription, was used in titration experiments to show that REST has transcriptional repression and no transcriptional activation properties when bound to the 5'-untranslated region of a gene.

Biological activity of mammalian transcriptional repressors

Research on the regulation of transcription in mammals has focused in recent years mainly on the mechanism of transcriptional activation. However, transcriptional repression mediated by repressor proteins is a common regulatory mechanism in mammals and might play an important role in many biological processes. To understand the molecular mechanism of transcriptional repression, the activity of eight mammalian repressors or repressor domains was investigated using a set of model promoters in combination with two different transcriptional detection methods. The repressors studied were: REST, the thyroid hormone receptors alpha and beta, the zinc finger protein NK10 containing a 'krüppel-associated box' (KRAB), repressor domains derived from the proteins Egr-1, Oct2A and Dr1 and the repressor/activator protein YY1. Here we show that the repressor domains of REST, Egr-1, the thyroid hormone receptors alpha< and beta and NK10 were transferable to a heterologous DNA-binding domain and repressed transcription from proximal and distal positions. Moreover, these repressor domains also blocked the activity of a strong viral enhancer in a 'remote position'. Thus, these domains are 'general' transcriptional repressor domains. The 'krüppel-associated box' was the most powerful repressor domain tested. In contrast, the repressor domains derived from Oct2A and Dr1 were inactive when fused to a heterologous DNA-binding domain. The repressor domain of YY1 exhibited transcriptional repression activity only in one of the transcriptional assay systems. The recruitment of histone deacetylases to the proximity of the basal transcriptional apparatus was recently discussed as a mechanism for some mammalian transcriptional repressor proteins. Here we show here that histone deacetylase 2, targeted to the reporter gene via DNA-protein interaction, functions as a transcriptional repressor protein regardless of the location of its binding site within the transcription unit.

Modular structure of cAMP response element binding protein 2 (CREB2)

The transcription factor cAMP-response element binding protein 2 (CREB2), a member of the family of basic region leucine zipper proteins, has been suggested to function in the brain as a repressor of long-term memory. Using recombinant proteins we show that CREB2 binds in vitro to the palindromic cAMP response element derived from the secretogranin II gene. Recent studies of the chromogranin B, secretogranin II and enkephalin genes showed that CREB2 functioned as a repressor of cAMP-induced transcription. We analyzed the ability of CREB2 to repress transcription using model promoters. A molecular dissection of the CREB2 molecule revealed that CREB2 lacks a transferable repressor domain suggesting that CREB2 may function solely as a "passive" transcriptional repressor. In contrast, "active" repressor domains derived from the thyroid hormone receptor alpha or the NK10 zinc finger protein containing a "Krüppel associated box" could be transfered to a heterologous DNA-binding domain and functioned as fusion proteins in repressing transcription of a reporter gene. In addition, a strong activation domain located at the N-terminus was identified in the CREB2 protein suggesting that CREB2 may act as an activator of transcription by binding to different genetic regulatory elements.

The Neuron Restrictive Silencer Factor Can Act as an Activator for Dynamin I Gene Promoter Activity in Neuronal Cells

The neuron restrictive silencer element (NRSE) has been identified in several neuronal genes and confers neuron specificity by silencing transcription in nonneuronal cells. We have previously reported that Sp1 and an NF-kappaB-like element (NE-1) are required for the promoter activity of mouse dynamin I gene. In the present study, we found that the upstream regulatory region of the dynamin I promoter has an NRSE-like sequence and showed that neuron restrictive silencer factor (NRSF) binds to this element in neuronal cells as well as in nonneuronal cells. We also showed that NRSF activates the promoter activity of dynamin I gene in neuronal cells. From the results in this study, we suggest that NRSE might be involved in the neuron restriction of dynamin I expression, and NRSF could act as an activator for promoter activity of dynamin I gene in neuronal cells.

Is RE1/NRSE a common cis-regulatory sequence for ChAT and VAChT genes?

Choline acetyltransferase (ChAT), the biosynthetic enzyme of acetylcholine, and the vesicular acetylcholine transporter (VAChT) are both required for cholinergic neurotransmission. These proteins are encoded by two embedded genes, the VAChT gene lying within the first intron of the ChAT gene. In the nervous system, both ChAT and VAChT are synthesized only in cholinergic neurons, and it is therefore likely that the cell type-specific expression of their genes is coordinately regulated. It has been suggested that a 2336-base pair genomic region upstream from the ChAT and VAChT coding sequences drives ChAT gene expression in cholinergic structures. We investigated whether this region also regulates VAChT gene transcription. Transfection assays showed that this region strongly represses the activity of the native VAChT promoters in non-neuronal cells, but has no major effect in neuronal cells whether or not they express the endogenous ChAT and VAChT genes. The silencer activity of this region is mediated solely by a repressor element 1 or neuron-restrictive silencer element (RE1/NRSE). Moreover, several proteins, including RE1-silencing transcription factor or neuron-restrictive silencer factor, are recruited by this regulatory sequence. These data suggest that this upstream region and RE1/NRSE co-regulate the expression of the ChAT and VAChT genes.

The human transcriptional repressor protein NAB1: expression and biological activity

The zinc finger protein early growth response 1 (Egr-1) is a transcriptional activator involved in the regulation of growth and differentiation. Egr-1 has a large activating domain and three zinc finger motifs that function as a DNA binding region. We show here that a third functional domain of the Egr-1 protein, localized between the extended activation domain and the zinc finger DNA binding region, acts as a transcriptional repressor domain when fused to a heterologous DNA binding domain (DBD). Through protein-protein interaction this inhibitory domain of Egr-1 brings the transcriptional corepressor NAB1 in close proximity to the transcription unit. NAB1 is expressed ubiquitously in human cell lines as shown by RNase protection mapping. Overexpression studies revealed that NAB1 is able to completely block transcription mediated by Egr-1. In addition, the transcriptional repression activity of a fusion protein containing the inhibitory domain of Egr-1 and the DBD of the yeast transcription factor GAL4 was increased by overexpression of NAB1. A fusion protein consisting of the DBD of GAL4 and the coding region of human NAB1 repressed transcription from model promoters with engineered upstream GAL4 binding sites. The GAL4-NAB1 fusion protein functioned from proximal and distal positions indicating that NAB1 displays transcriptional repressor activity at any position within the transcription unit. Thus, the biological function of the inhibitory domain of Egr-1 is solely to provide a docking site for NAB1 via protein-protein interaction.

The co-repressor mSin3A is a functional component of the REST-CoREST repressor complex

The repressor REST/NRSF restricts expression of a large set of genes to neurons by suppressing their expression in non-neural tissues. We find that REST repression involves two distinct repressor proteins. One of these, CoREST, interacts with the COOH-terminal repressor domain of REST (Andres, M. E., Burger, C., Peral-Rubio, M. J., Battaglioli, E., Anderson, M. E., Grimes, J., Dallmanm J., Ballas, N. , and Mandel, G. (1999) Proc. Natl. Acad. Sci. U. S. A. 96, 9873-9878). Here we show that the co-repressor mSin3A also interacts with REST. The REST-mSin3A association involves the NH(2)-terminal repressor domain of REST and the paired amphipathic helix 2 domain of mSin3A. REST forms complexes with endogenous mSin3A in mammalian cells, and both mSin3A and CoREST interact with REST in intact mammalian cells. REST repression is blocked in yeast lacking Sin3 and rescued in its presence. In mammalian cells, repression by REST is reduced when binding to mSin3A is inhibited. In mouse embryos, the distribution of mSin3A and REST transcripts is largely coincident. The pattern of CoREST gene expression is more restricted, suggesting that mSin3A is required constitutively for REST repression, whereas CoREST is recruited for more specialized repressor functions.

Transcriptional repression by neuron-restrictive silencer factor is mediated via the Sin3-histone deacetylase complex

A large number of neuron-specific genes characterized to date are under the control of negative transcriptional regulation. Many promoter regions of neuron-specific genes possess the repressor element repressor element 1/neuron-restrictive silencing element (RE1/NRSE). Its cognate binding protein, REST/NRSF, is an essential transcription factor; its null mutations result in embryonic lethality, and its dominant negative mutants produce aberrant expression of neuron-specific genes. REST/NRSF acts as a regulator of neuron-specific gene expression in both nonneuronal tissue and developing neurons. Here, we shown that heterologous expression of REST/NRSF in Saccharomyces cerevisiae is able to repress transcription from yeast promoters engineered to contain RE1/NRSEs. Moreover, we have taken advantage of this observation to show that this repression requires both yeast Sin3p and Rpd3p and that REST/NRSF physically interacts with the product of the yeast SIN3 gene in vivo. Furthermore, we show that REST/NRSF binds mammalian SIN3A and HDAC-2 and requires histone deacetylase activity to repress neuronal gene transcription in both nonneuronal and neuronal cell lines. We show that REST/NRSF binding to RE1/NRSE is accompanied by a decrease in the acetylation of histones around RE1/NRSE and that this decrease requires the N-terminal Sin3p binding domain of REST/NRSF. Taken together, these data suggest that REST/NRSF represses neuronal gene transcription by recruiting the SIN3/HDAC complex.

Identification of nuclear orphan receptors as regulators of expression of a neurotransmitter receptor gene

Nuclear orphan receptors are known to be important mediators of neurogenesis, but the target genes of these transcription factors in the vertebrate nervous system remain largely undefined. We have previously shown that a 500-base pair fragment in the first intron of the GRIK5 gene, which encodes the kainate-preferring glutamate receptor subunit KA2, down-regulates gene expression. In our present studies, mutation of an 11-base pair element within this fragment resulted in a loss of nuclear protein binding and reverses negative regulation by the intron. Using yeast one-hybrid screening, we have identified intron-binding proteins from rat brain as COUP-TFI, EAR2, and NURR1. Gel shift studies with postnatal day 2 rat brain extract indicate the presence of COUP-TFs, EAR2, and NURR1 in the DNA-protein complex. Competition assays with GRIK5-binding site mutations show that the recombinant clones exhibit differential binding characteristics and suggest that the DNA-protein complex from postnatal day 2 rat brain may consist primarily of EAR2. The DNA binding activity was also observed to be enriched in rat neural tissue and developmentally regulated. Co-transfection assays showed that recombinant nuclear orphan receptors function as transcriptional repressors in both CV1 cells and rat CG4 oligodendrocyte cells. Direct interaction of the orphan receptors with and relief of repression by TFIIB indicate likely role(s) in active and/or transrepression. Our findings are thus consistent with the notion that multiple nuclear orphan receptors can regulate the transcription of a widely expressed neurotransmitter receptor gene by binding a common element in an intron and directly modulating the activity of the transcription machinery.

Transcriptional repression by REST: recruitment of Sin3A and histone deacetylase to neuronal genes

Many genes whose expression is restricted to neurons in the brain contain a silencer element (RE1/NRSE) that limits transcription in nonneuronal cells by binding the transcription factor REST (also named NRSF or XBR). Although two independent domains of REST are known to confer repression, the mechanisms of transcriptional repression by REST remain obscure. We provide multiple lines of evidence that the N-terminal domain of REST represses transcription of the GluR2 and type II sodium-channel genes by recruiting the corepressor Sin3A and histone deacetylase (HDAC) to the promoter region in nonneuronal cells. These results identify a general mechanism for controlling the neuronal expression pattern of a specific set of genes via the RE1 silencer element.

Nuclear targeting of cAMP response element binding protein 2 (CREB2)

The transcription factor cAMP response element binding protein 2 (CREB2) belongs to a family of proteins containing a basic region as DNA-binding domain and a leucine zipper as a dimerization domain in its C-terminus. Using indirect immunofluorescence labeling of cells we show that CREB2 is a nuclear protein. To identify the signal(s) required for nuclear targeting of CREB2, various domains of the protein were expressed in COS cells as fusion proteins with glutathione S-transferase and their cellular location assayed by indirect immunofluorescence using antibodies directed against the glutathione S-transferase moiety of the fusion proteins. The results show that the nuclear targeting signal is located in the C-terminal part of the molecule. Deletion mutagenesis revealed that the basic region of CREB2, encompassing amino acids 280 to 300, is sufficient for sorting CREB2 to the nucleus. Single point mutations of basic amino acids within the basic region of CREB2 identified the sequence KKLKK (amino acids 280 to 284) as important for nuclear targeting. Thus, the basic region of CREB2 is necessary not only for tethering CREB2 to DNA but also for sorting CREB2 to the nucleus. However, sequences outside the basic region are additionally required for efficient nuclear sorting of CREB2.