Isolation of human NURF: a regulator of Engrailed gene expression

A novel G-quadruplex-forming GGA repeat region in the c-myb promoter is a critical regulator of promoter activity

The c-myb promoter contains multiple GGA repeats beginning 17 bp downstream of the transcription initiation site. GGA repeats have been previously shown to form unusual DNA structures in solution. Results from chemical footprinting, circular dichroism and RNA and DNA polymerase arrest assays on oligonucleotides representing the GGA repeat region of the c-myb promoter demonstrate that the element is able to form tetrad:heptad:heptad:tetrad (T:H:H:T) G-quadruplex structures by stacking two tetrad:heptad G-quadruplexes formed by two of the three (GGA)(4) repeats. Deletion of one or two (GGA)(4) motifs destabilizes this secondary structure and increases c-myb promoter activity, indicating that the G-quadruplexes formed in the c-myb GGA repeat region may act as a negative regulator of the c-myb promoter. Complete deletion of the c-myb GGA repeat region abolishes c-myb promoter activity, indicating dual roles of the c-myb GGA repeat element as both a transcriptional repressor and an activator. Furthermore, we demonstrated that Myc-associated zinc finger protein (MAZ) represses c-myb promoter activity and binds to the c-myb T:H:H:T G-quadruplexes. Our findings show that the T:H:H:T G-quadruplex-forming region in the c-myb promoter is a critical cis-acting element and may repress c-myb promoter activity through MAZ interaction with G-quadruplexes in the c-myb promoter.

Sp1 and CREB regulate basal transcription of the human SNF2L gene

Imitation Switch (ISWI) is a member of the SWI2/SNF2 superfamily of ATP-dependent chromatin remodelers, which are involved in multiple nuclear functions, including transcriptional regulation, replication, and chromatin assembly. Mammalian genomes encode two ISWI orthologs, SNF2H and SNF2L. In order to clarify the molecular mechanisms governing the expression of human SNF2L gene, we functionally examined the transcriptional regulation of human SNF2L promoter. Reporter gene assays demonstrated that the minimal SNF2L promoter was located between positions -152 to -86 relative to the transcription start site. In this region we have identified a cAMP-response element (CRE) located at -99 to -92 and a Sp1-binding site at -145 to -135 that play a critical role in regulating basal activity of human SNF2L gene, which were proven by deletion and mutation of specific binding sites, EMSA, and down-regulating Sp1 and CREB via RNAi. This study provides the first insight into the mechanisms that control basal expression of human SNF2L gene.

How many remodelers does it take to make a brain? Diverse and cooperative roles of ATP-dependent chromatin-remodeling complexes in development

The development of a metazoan from a single-celled zygote to a complex multicellular organism requires elaborate and carefully regulated programs of gene expression. However, the tight packaging of genomic DNA into chromatin makes genes inaccessible to the cellular machinery and must be overcome by the processes of chromatin remodeling; in addition, chromatin remodeling can preferentially silence genes when their expression is not required. One class of chromatin remodelers, ATP-dependent chromatin-remodeling enzymes, can slide nucleosomes along the DNA to make specific DNA sequences accessible or inaccessible to regulators at a particular stage of development. While all ATPases in the SWI2/SNF2 superfamily share the fundamental ability to alter DNA accessibility in chromatin, they do not act alone, but rather, are subunits of a large assortment of protein complexes. Recent studies illuminate common themes by which the subunit compositions of chromatin-remodeling complexes specify the developmental roles that chromatin remodelers play in specific tissues and at specific stages of development, in response to specific signaling pathways and transcription factors. In this review, we will discuss the known roles in metazoan development of 3 major subfamilies of chromatin-remodeling complexes: the SNF2, ISWI, and CHD subfamilies.

Multivalent engagement of chromatin modifications by linked binding modules

Various chemical modifications on histones and regions of associated DNA play crucial roles in genome management by binding specific factors that, in turn, serve to alter the structural properties of chromatin. These so-called effector proteins have typically been studied with the biochemist's paring knife--the capacity to recognize specific chromatin modifications has been mapped to an increasing number of domains that frequently appear in the nuclear subset of the proteome, often present in large, multisubunit complexes that bristle with modification-dependent binding potential. We propose that multivalent interactions on a single histone tail and beyond may have a significant, if not dominant, role in chromatin transactions.

Mutation analysis of Drosophila dikar/CG32394, homologue of the chromatin-remodelling gene CECR2

The mammalian CECR2 protein contains a highly conserved bromodomain and forms a chromatin-remodelling complex with the ISWI homologue SNF2L. Mutation of the mouse CECR2 homologue results in a neural tube defect. Here we describe the characterization of the Drosophila melanogaster homologue of CECR2. Originally annotated as 2 genes, dikar and CG32394 now appear to encode both a long dikar/CG32394 transcript homologous to CECR2 and a truncated transcript missing the bromodomain. This truncated transcript may be specific to Diptera, as it is predicted from the genomic sequences of several other dipteran species but it is not predicted in the honey bee, Apis mellifera, and it is not found in mammals. Five different P element-mediated 5' deletions of the Drosophila dikar gene were generated. All mutants were homozygous-viable and the 3 mutants examined further displayed continued, albeit aberrant, transcription of dikar/CG32394. In a previous study, a dikar insertion mutation was associated with long-term memory deficits. However, the 2 deletion mutants tested here showed normal long-term memory, suggesting that the memory deficit associated with the dikar P element insertion is not due to disruption of dikar. No genetic interaction was seen between Iswi and dikar mutations. This study therefore suggests that the lack of a visible phenotype in dikar mutants is due to compensation by a second gene, possibly acf1.

DNA sequence- and conformation-directed positioning of nucleosomes by chromatin-remodeling complexes

Chromatin-remodeling complexes can translocate nucleosomes along the DNA in an ATP-coupled reaction. This process is an important regulator of all DNA-dependent processes because it determines whether certain DNA sequences are found in regions between nucleosomes with increased accessibility for other factors or wrapped around the histone octamer complex. In a comparison of seven different chromatin-remodeling machines (ACF, ISWI, Snf2H, Chd1, Mi-2, Brg1, and NURF), it is demonstrated that these complexes can read out DNA sequence features to establish specific nucleosome-positioning patterns. For one of the remodelers, ACF, we identified a 40-bp DNA sequence element that directs nucleosome positioning. Furthermore, we show that nucleosome positioning by the remodelers ACF and Chd1 is determined by a reduced affinity to the end product of the translocation reaction. The results suggest that the linkage of differential remodeling activities with the intrinsic binding preferences of nucleosomes can result in establishing distinct chromatin structures that depend on the DNA sequence and define the DNA accessibility for other protein factors.

ISWI chromatin remodeling in ovarian somatic and germ cells: revenge of the NURFs

Chromatin has emerged as an important regulator of gene expression, interposed between cell signaling pathways and transcriptional machinery. It participates in transmitting extra- and intra-cellular signals that coordinate ovarian events: ovarian follicle development, the meiotic maturation of the oocyte that precedes ovulation, and the ovulatory process and consequent luteinization. Recent evidence from model organisms and mammals suggests that chromatin signaling is achieved, in part, by imitation switch (ISWI) ATP-dependent chromatin-remodeling complexes. This review highlights a role for complexes containing the ISWI ATPase sucrose nonfermenting-2h (Snf2h) in proliferation in somatic and germ cells and also in meiosis in germ cells. Moreover, complexes containing the Snf2l ATPase dictate the differentiation of somatic cells and act in the induction of the terminal phases of meiosis in the oocyte.

Regional control of chromatin organization by noncoding roX RNAs and the NURF remodeling complex in Drosophila melanogaster

Dosage compensation in Drosophila is mediated by a histone-modifying complex that upregulates transcription of genes on the single male X chromosome. The male-specific lethal (MSL) complex contains at least five proteins and two noncoding roX (RNA on X) RNAs. The mechanism by which the MSL complex targets the X chromosome is not understood. Here we use a sensitized system to examine the function of roX genes on the X chromosome. In mutants that lack the NURF nucleosome remodeling complex, the male polytene X chromosome is severely distorted, appearing decondensed. This aberrant morphology is dependent on the MSL complex. Strikingly, roX mutations suppress the Nurf mutant phenotype regionally on the male X chromosome. Furthermore, a roX transgene induces disruption of local flanking autosomal chromatin in Nurf mutants. Taken together, these results demonstrate the potent capability of roX genes to organize large chromatin domains in cis, on the X chromosome. In addition to interacting functions at the level of chromosome morphology, we also find that NURF complex and MSL proteins have opposing effects on roX RNA transcription. Together, these results demonstrate the importance of a local balance between modifying activities that promote and antagonize chromatin compaction within defined chromatin domains in higher organisms.

Focal adhesions regulate Abeta signaling and cell death in Alzheimer's disease

Alzheimer's disease (AD) is a neurodegenerative disorder that results from a loss of synaptic transmission and ultimately cell death. The presenting pathology of AD includes neuritic plaques composed of beta-amyloid peptide (Abeta) and neurofibrillary tangles composed of hyperphosphorylated tau, with neuronal loss in specific brain regions. However, the mechanisms that induce neuronal cell loss remain elusive. Focal adhesion (FA) proteins assemble into intracellular complexes involved in integrin-mediated communication between the extracellular matrix and the actin cytoskeleton, regulating many cell physiological processes including the cell cycle. Interestingly, recent studies report that integrins bind to Abeta fibrils, mediating Abeta signal transmission from extracellular sites of Abeta deposits into the cell and ultimately to the nucleus. In this review, we will discuss the Abeta induced integrin/FA signaling pathways that mediate cell cycle activation and cell death.

Physical and Functional Association of a Trimethyl H3K4 Demethylase and Ring6a/MBLR, a Polycomb-like Protein

Histone methylation is a posttranslational modification regulating chromatin structure and gene regulation. BHC110/LSD1 was the first histone demethylase described to reverse dimethyl histone H3 lysine 4 (H3K4). Here we show that JARID1d, a JmjC-domain-containing protein, specifically demethylates trimethyl H3K4. Detailed mapping analysis revealed that besides the JmjC domain, the BRIGHT and zinc-finger-like C(5)HC(2) domains are required for maximum catalytic activity. Importantly, isolation of native JARID1d complexes from human cells revealed the association of the demethylase with a polycomb-like protein Ring6a/MBLR. Ring6a/MBLR not only directly interacts with JARID1d but also regulates its enzymatic activity. We show that JARID1d and Ring6a occupy human Engrailed 2 gene and regulate its expression and H3K4 methylation levels. Depletion of JARID1d enhanced recruitment of the chromatin remodeling complex, NURF, and the basal transcription machinery near the transcriptional start site, revealing a role for JARID1d in regulation of transcriptional initiation through H3K4 demethylation.

Isolation and characterization of histone H3 lysine 4 demethylase-containing complexes

Histone methylation is involved in the regulation of many cellular processes. In the past 2 years, several histone demethylases including BHC110/LSD1 have been characterized. BHC110, the first known histone lysine demethylase, removes methyl groups from methylated histone H3 lysine 4 and has been found in many multi-protein complexes. Using one-step affinity purification, we have isolated enzymatically active BHC110-containing complexes. Here, we detail the methods used for the isolation and characterization of these histone demethylase complexes from a human stable cell line.

The engrailed transcription factors and the mesencephalic dopaminergic neurons

The engrailed genes belong to a large family of homeobox transcription factors. They are found throughout the animal kingdom, are highly conserved in the DNA binding domain and have been investigated for more than half a century. In the murine genome, two engrailed genes exist, called Engrailed-1 and Engrailed-2. Here, we summarize the properties of the engrailed genes and their functions, such as conserved structures, cellular localisation, secretion and internalisation, transcription factor activity, potential target genes and review their role in the development of mesencephalic dopaminergic neurons. During early development, they take part in the regionalization event, which specifies the neuroepithelium that provides the precursor cells of the mesencephalic dopaminergic neurons with the necessary signals for their induction. Later in the post-mitotic neurons, the two transcription factors participate in their specification and are cell-autonomously required for their survival.

Functional interplay between histone demethylase and deacetylase enzymes

Histone deacetylase (HDAC) inhibitors are a promising class of anticancer agents for the treatment of solid and hematological malignancies. The precise mechanism by which HDAC inhibitors mediate their effects on tumor cell growth, differentiation, and/or apoptosis is the subject of intense research. Previously we described a family of multiprotein complexes that contain histone deacetylase 1/2 (HDAC1/2) and the histone demethylase BHC110 (LSD1). Here we show that HDAC inhibitors diminish histone H3 lysine 4 (H3K4) demethylation by BHC110 in vitro. In vivo analysis revealed an increased H3K4 methylation concomitant with inhibition of nucleosomal deacetylation by HDAC inhibitors. Reconstitution of recombinant complexes revealed a functional connection between HDAC1 and BHC110 only when nucleosomal substrates were used. Importantly, while the enzymatic activity of BHC110 is required to achieve optimal deacetylation in vitro, in vivo analysis following ectopic expression of an enzymatically dead mutant of BHC110 (K661A) confirmed the functional cross talk between the demethylase and deacetylase enzymes. Our studies not only reveal an intimate link between the histone demethylase and deacetylase enzymes but also identify histone demethylation as a secondary target of HDAC inhibitors.

Chromatin remodelling in mammalian differentiation: lessons from ATP-dependent remodellers

The initiation of cellular differentiation involves alterations in gene expression that depend on chromatin changes, at the level of both higher-order structures and individual genes. Consistent with this, chromatin-remodelling enzymes have key roles in differentiation and development. The functions of ATP-dependent chromatin-remodelling enzymes have been studied in several mammalian differentiation pathways, revealing cell-type-specific and gene-specific roles for these proteins that add another layer of precision to the regulation of differentiation. Recent studies have also revealed a role for ATP-dependent remodelling in regulating the balance between proliferation and differentiation, and have uncovered intriguing links between chromatin remodelling and other cellular processes during differentiation, including recombination, genome organization and the cell cycle.

Histone H3 Lysine 4 Demethylation Is a Target of Nonselective Antidepressive Medications

Demethylation of histone H3 lysine 4 is carried out by BHC110/LSD1, an enzyme with close homology to monoamine oxidases (MAO). Monoamine oxidase A or B are frequent targets of selective and nonselective small molecular inhibitors used for treatment of depression. Here we show that in contrast to selective monoamine oxidase inhibitors such as pargyline, nonselective monoamine oxidase inhibitors potently inhibit nucleosomal demethylation of histone H3 lysine 4. Tranylcypromine (brand name Parnate) displayed the best inhibitory activity with an IC50 of less than 2 microM. Treatment of P19 embryonal carcinoma cells with tranylcypromine resulted in global increase in H3K4 methylation as well as transcriptional derepression of two BHC110 target genes, Egr1 and the pluripotent stem cell marker Oct4. These results attest to the effectiveness of tranylcypromine as a small molecular inhibitor of histone demethylation.

The imitation switch protein SNF2L regulates steroidogenic acute regulatory protein expression during terminal differentiation of ovarian granulosa cells

Luteinization is a complex process, stimulated by gonadotropins, that promotes ovulation and development of the corpus luteum through terminal differentiation of granulosa cells. The pronounced expression of the mammalian imitation switch (ISWI) genes, SNF2H and SNF2L, in adult ovaries prompted us to investigate the role of these chromatin remodeling proteins during follicular development and luteinization. SNF2H expression is highest during growth of preovulatory follicles and becomes less prevalent during luteinization. In contrast, both SNF2L transcript and SNF2L protein levels are rapidly increased in granulosa cells of the mouse ovary 8 h after human chorionic gonadotropin treatment, and continue to be expressed 36 h later within the functional corpus luteum. We demonstrate a physical interaction between SNF2L and the progesterone receptor A isoform, which regulates progesterone receptor-responsive genes required for ovulation. Moreover, chromatin immunoprecipitation demonstrated that, after gonadotropin stimulation, SNF2L is associated with the proximal promoter of the steroidogenic acute regulatory protein (StAR) gene, a classic marker of luteinization in granulosa cells. Interaction of SNF2L with the StAR promoter is required for StAR expression, because small interfering RNA knockdown of SNF2L prevents the activation of the StAR gene. Our results provide the first indication that ISWI chromatin remodeling proteins are responsive to the LH surge and that this response is required for the activation of the StAR gene and the overall development of a functional luteal cell.

A PHD finger of NURF couples histone H3 lysine 4 trimethylation with chromatin remodelling

Lysine methylation of histones is recognized as an important component of an epigenetic indexing system demarcating transcriptionally active and inactive chromatin domains. Trimethylation of histone H3 lysine 4 (H3K4me3) marks transcription start sites of virtually all active genes. Recently, we reported that the WD40-repeat protein WDR5 is important for global levels of H3K4me3 and control of HOX gene expression. Here we show that a plant homeodomain (PHD) finger of nucleosome remodelling factor (NURF), an ISWI-containing ATP-dependent chromatin-remodelling complex, mediates a direct preferential association with H3K4me3 tails. Depletion of H3K4me3 causes partial release of the NURF subunit, BPTF (bromodomain and PHD finger transcription factor), from chromatin and defective recruitment of the associated ATPase, SNF2L (also known as ISWI and SMARCA1), to the HOXC8 promoter. Loss of BPTF in Xenopus embryos mimics WDR5 loss-of-function phenotypes, and compromises spatial control of Hox gene expression. These results strongly suggest that WDR5 and NURF function in a common biological pathway in vivo, and that NURF-mediated ATP-dependent chromatin remodelling is directly coupled to H3K4 trimethylation to maintain Hox gene expression patterns during development. We also identify a previously unknown function for the PHD finger as a highly specialized methyl-lysine-binding domain.

Imitation switch complexes

The imitation switch (ISWI) family of chromatin remodelling ATPases is found in organisms ranging from yeast to mammals. ISWI ATPases assemble chromatin and slide and space nucleosomes, making the chromatin template fluid and allowing appropriate regulation of events such as transcription, DNA replication, recombination and repair. The site of action of the ATPases is determined, in part by the tissue type in which the enzyme is expressed and in part by the nature of the proteins associated with the enzyme. The ISWI complexes are generally conserved in composition and function across species. Roles in gene expression and DNA replication in heterochromatin, gene activation and repression in euchromatin, and functions related to maintaining chromosome architecture are associated with different complexes. Defects in ISWI-associated proteins may be associated with neurodegenerative disease, anencephaly, William's syndrome and melanotic tumours. Finally, the mechanism by which yeast Isw Ib influences gene transcription is discussed.

The role of Snf2-related proteins in cancer

Several HDAC inhibitors that exhibit impressive anti-tumour activity are now in clinical trials. Proteins that function in the same pathways might also serve as valuable therapeutic targets. A subset of histone deacetylase activities are found to be physically associated with ATP-dependent remodelling enzymes and may assist their function. This raises the possibility that ATP-dependent remodelling enzymes should be considered as therapeutic targets. Here some of the links between ATP-dependent chromatin remodelling enzymes and cancer are reviewed.

The WSTF-SNF2h chromatin remodeling complex interacts with several nuclear proteins in transcription

The WSTF (Williams syndrome transcription factor) protein is involved in vitamin D-mediated transcription and replication as a component of two distinct ATP-dependent chromatin remodeling complexes, WINAC and WICH, respectively. We show here that the WICH complex (WSTF-SNF2h) interacts with several nuclear proteins as follows: Sf3b155/SAP155, RNA helicase II/Gualpha, Myb-binding protein 1a, CSB, the proto-oncogene Dek, and nuclear myosin 1 in a large 3-MDa assembly, B-WICH, during active transcription. B-WICH also contains RNAs, 45 S rRNA, 5 S rRNA, 7SL RNA, and traces of the U2 small nuclear RNA. The core proteins, WSTF, SNF2h, and nuclear myosin 1, are associated with the RNA polymerase III genes 5 S rRNA genes and 7SL, and post-transcriptional silencing of WSTF reduces the levels of these transcripts. Our results show that a WSTF-SNF2h assembly is involved in RNA polymerase III transcription, and we suggest that WSTF-SNF2h-NM1 forms a platform in transcription while providing chromatin remodeling.

The roles of chromatin remodelling factors in replication

Dynamic changes of chromatin structure control DNA-dependent events, including DNA replication. Along with DNA, chromatin organization must be replicated to maintain genetic and epigenetic information through cell generations. Chromatin remodelling is important for several steps in replication: determination and activation of origins of replication, replication machinery progression, chromatin assembly and DNA repair. Histone chaperones such as the FACT complex assist DNA replication within chromatin, probably by facilitating both nucleosome disassembly and reassembly. ATP-dependent nucleosome remodelling enzymes of the SWI/SNF family, in particular imitation switch (ISWI)-containing complexes, have been linked to DNA and chromatin replication. They are targeted to replication sites to facilitate DNA replication and subsequent chromatin assembly.

Expression of the fetal Alz-50 clone 1 protein induces apoptotic cell death

The fetal Alz-50 clone 1 (FAC1) protein exhibits altered expression patterns in neurodegenerative disease. Though it has been shown to bind DNA in a site-specific, phosphorylation-dependent manner, its cellular function remains unknown. Here, we demonstrate that overexpression of FAC1 in PT67 fibroblasts induces nuclear condensation and cleavage of caspase 3 to its active form indicating induction of apoptosis. The amino-terminal domain of FAC1 is necessary and sufficient to induce both nuclear condensation and activation of caspase 3. Disruption of FAC1 interaction with a known binding partner, kelch-like ECH-associated protein 1 (Keap1), enhances activation of caspase 3. Keap1 is known to block activation of the antioxidant response gene products by direct interaction with the transcriptional activator, Nrf2. Disruption of the Keap1:Nrf2 interaction enhances FAC1 induction of apoptosis. These findings suggest a role for FAC1 in apoptosis following release of Nrf2 from Keap1 in response to oxidative stress.

Chromatin remodeling complexes: ATP-dependent machines in action

Since the initial characterization of chromatin remodeling as an ATP-dependent process, many studies have given us insight into how nucleosome-remodeling complexes can affect various nuclear functions. However, the multistep DNA-histone remodeling process has not been completely elucidated. Although new studies are published on a nearly weekly basis, the nature and roles of interactions of the individual SWI/SNF- and ISWI-based remodeling complexes and DNA, core histones, and other chromatin-associated proteins are not fully understood. In addition, the potential changes associated with ATP recruitment and its subsequent hydrolysis have not been fully characterized. This review explores possible mechanisms by which chromatin-remodeling complexes are recruited to specific loci, use ATP hydrolysis to achieve actual remodeling through disruption of DNA-histone interactions, and are released from their chromatin template. We propose possible roles for ATP hydrolysis in a chromatin-release/target-scanning process that offer an alternative to or complement the often overlooked function of delivering the energy required for sliding or dislodging specific subsets of core histones.

The Drosophila nucleosome remodeling factor NURF is required for Ecdysteroid signaling and metamorphosis

Drosophila NURF is an ISWI-containing ATP-dependent chromatin remodeling complex that regulates transcription by catalyzing nucleosome sliding. To determine in vivo gene targets of NURF, we performed whole genome expression analysis on mutants lacking the NURF-specific subunit NURF301. Strikingly, a large set of ecdysone-responsive targets is included among several hundred NURF-regulated genes. Null Nurf301 mutants do not undergo larval to pupal metamorphosis, and also enhance dominant-negative mutations in ecdysone receptor. Moreover, purified NURF binds EcR in an ecdysone-dependent manner, suggesting it is a direct effector of nuclear receptor activity. The conservation of NURF in mammals has broad implications for steroid signaling.

Smads and chromatin modulation

Smad proteins are critical intracellular effector proteins and regulators of transforming growth factor type beta (TGFbeta) modulated gene transcription. They directly convey signals that initiate at ligand-bound receptor complexes and end in the nucleus with changes in programs of gene expression. Activated Smad proteins seem to recruit chromatin modifying proteins to target genes besides cooperating with DNA-bound transcription factors. We survey here the current and still emerging knowledge on Smad-binding factors, and their different mechanisms of chromatin modification in particular, in Smad-dependent TGFbeta signaling.

Neural and eye-specific defects associated with loss of the imitation switch (ISWI) chromatin remodeler in Xenopus laevis

Imitation Switch (ISWI) is a member of the SWI2/SNF2 superfamily of ATP-dependent chromatin remodelers, which regulate transcription and maintain chromatin structure by mobilizing nucleosomes using the energy of ATP. Four distinct ISWI complexes have been identified in Xenopus oocytes. The developmental role of Xenopus ISWI, however, has not previously been investigated in vivo. Here we report the tissue specificity, developmental expression, and requirement of ISWI for development of Xenopus embryos. Whole mount in situ hybridization shows ISWI localized in the lateral sides of the neural plate, brain, eye, and in later stages, the spinal cord. Injection of antisense ISWI RNA, morpholino oligonucleotides or dominant-negative ISWI mutant mRNA into fertilized eggs inhibits gastrulation and neural fold closure. Genes involved in neural patterning and development, such as BMP4 and Sonic hedgehog (Shh), are misregulated in the absence of functional ISWI, and ISWI binds to the BMP4 gene in vivo. Developmental and transcriptional defects caused by dominant-negative ISWI are rescued by co-injection of wild-type ISWI mRNA. Inhibition of ISWI function results in aberrant eye development and the formation of cataracts. These data suggest a critical role for ISWI chromatin remodeling complexes in neural development, including eye differentiation, in the Xenopus laevis embryo.

An essential role for CoREST in nucleosomal histone 3 lysine 4 demethylation

We have previously described a multiprotein complex termed the BHC or BRAF-HDAC complex, which is required for the repression of neuronal-specific genes. We have shown that the BHC complex is recruited by a neuronal silencer, REST (RE1-silencing transcription factor), and mediates the repression of REST-responsive genes. BHC is a multiprotein complex consisting of two enzymatic activities: a histone deacetylase (HDAC1 or 2) and a recently described histone demethylase (BHC110, also known as LSD1 or AOF2). Here we show that BHC110-containing complexes show a nearly fivefold increase in demethylation of histone H3 lysine 4 (H3K4) compared to recombinant BHC110. Furthermore, recombinant BHC110 is unable to demethylate H3K4 on nucleosomes, but BHC110-containing complexes readily demethylate nucleosomes. In vitro reconstitution of the BHC complex using recombinant subunits reveals an essential role for the REST corepressor CoREST, not only in stimulating demethylation on core histones but also promoting demethylation of nucleosomal substrates. We find that nucleosomal demethylation is the result of CoREST enhancing the association between BHC110 and nucleosomes. Depletion of CoREST in in vivo cell culture results in de-repression of REST-responsive gene expression and increased methylation of H3K4. Together, these results highlight an essential role for CoREST in demethylation of H3K4 both in vitro and in vivo.

Changes in attitude, changes in latitude: nuclear receptors remodeling chromatin to regulate transcription

Nuclear receptors (NRs) are a large family of ligand-dependent transcription factors that regulate important physiological processes. To activate or repress genes assembled naturally as chromatin, NRs recruit two distinct enzymatic activities, namely histone-modifying enzymes and ATP-dependent chromatin remodeling complexes, to alter local chromatin structure at target gene promoters. In this review, we examine the functional relationship between ATP-dependent chromatin remodeling complexes and NRs in the context of transcriptional regulation. Using the steroid-responsive mouse mammary tumor virus promoter as a model system, we discuss in detail the molecular mechanisms underlying the recruitment of these complexes and subsequent chromatin structure changes catalyzed by this group of enzymes. In addition, we extend the discussion to other NR-regulated promoters including the pS2 promoter. Finally, we summarize specific principles governing this critical relationship, identify unanswered questions and discuss the potential application of these principles in rational drug design.

mSin3A corepressor regulates diverse transcriptional networks governing normal and neoplastic growth and survival

mSin3A is a core component of a large multiprotein corepressor complex with associated histone deacetylase (HDAC) enzymatic activity. Physical interactions of mSin3A with many sequence-specific transcription factors has linked the mSin3A corepressor complex to the regulation of diverse signaling pathways and associated biological processes. To dissect the complex nature of mSin3A's actions, we monitored the impact of conditional mSin3A deletion on the developmental, cell biological, and transcriptional levels. mSin3A was shown to play an essential role in early embryonic development and in the proliferation and survival of primary, immortalized, and transformed cells. Genetic and biochemical analyses established a role for mSin3A/HDAC in p53 deacetylation and activation, although genetic deletion of p53 was not sufficient to attenuate the mSin3A null cell lethal phenotype. Consistent with mSin3A's broad biological activities beyond regulation of the p53 pathway, time-course gene expression profiling following mSin3A deletion revealed deregulation of genes involved in cell cycle regulation, DNA replication, DNA repair, apoptosis, chromatin modifications, and mitochondrial metabolism. Computational analysis of the mSin3A transcriptome using a knowledge-based database revealed several nodal points through which mSin3A influences gene expression, including the Myc-Mad, E2F, and p53 transcriptional networks. Further validation of these nodes derived from in silico promoter analysis showing enrichment for Myc-Mad, E2F, and p53 cis-regulatory elements in regulatory regions of up-regulated genes following mSin3A depletion. Significantly, in silico promoter analyses also revealed specific cis-regulatory elements binding the transcriptional activator Stat and the ISWI ATP-dependent nucleosome remodeling factor Falz, thereby expanding further the mSin3A network of regulatory factors. Together, these integrated genetic, biochemical, and computational studies demonstrate the involvement of mSin3A in the regulation of diverse pathways governing many aspects of normal and neoplastic growth and survival and provide an experimental framework for the analysis of essential genes with diverse biological functions.

Functional diversity of ISWI complexes

The yeast SWI/SNF ATP-dependent chromatin remodeling complex was first identified and characterized over 10 years ago (F. Winston and M. Carlson. 1992. Trends Genet. 8: 387-391.) Since then, the number of distinct ATP-dependent chromatin remodeling complexes and the variety of roles they play in nuclear processes have become dizzying (J.A. Martens and F. Winston. 2003. Curr. Opin. Genet. Dev. 13: 136-142; A. Vacquero et al. 2003. Sci. Aging Knowledge Environ. 2003: RE4)--and that does not even include the companion suite of histone modifying enzymes, which exhibit a comparable diversity in both number of complexes and variety of functions (M.J. Carrozza et al. 2003. Trends Genet. 19: 321-329; W. Fischle et al. 2003. Curr. Opin. Cell Biol. 15: 172-183; M. Iizuka and M.M. Smith. 2003. Curr. Opin. Genet. Dev. 13: 1529-1539). This vast complexity is hardly surprising, given that all nuclear processes that involve DNA--transcription, replication, repair, recombination, sister chromatid cohesion, etc.--must all occur in the context of chromatin. The SWI/SNF-related ATP-dependent remodelers are divided into a number of subfamilies, all related by the SWI2/SNF2 ATPase at their catalytic core. In nearly every species where researchers have looked for them, one or more members of each subfamily have been identified. Even the budding yeast, with its comparatively small genome, contains eight different chromatin remodelers in five different subfamilies. This review will focus on just one subfamily, the Imitation Switch (ISWI) family, which is proving to be one of the most diverse groups of chromatin remodelers in both form and function.

CECR2, a protein involved in neurulation, forms a novel chromatin remodeling complex with SNF2L

Chromatin remodeling complexes play critical roles in development. Here we describe a transcription factor, CECR2, which is involved in neurulation and chromatin remodeling. CECR2 shows complex alternative splicing, but all variants contain DDT and bromodomain motifs. A mutant mouse line was generated from an embryonic stem cell line containing a genetrap within Cecr2. Reporter gene expression demonstrated Cecr2 expression to be predominantly neural in the embryo. Mice homozygous for the Cecr2 genetrap-induced mutation show a high penetrance of the neural tube defect exencephaly, the human equivalent of anencephaly, in a strain-dependent fashion. Biochemical isolation of CECR2 revealed the presence of this protein as a component of a novel heterodimeric complex termed CECR2-containing remodeling factor (CERF). CERF comprises CECR2 and the ATP-dependent chromatin remodeler SNF2L, a mammalian ISWI ortholog expressed predominantly in the central nervous system. CERF is capable of remodeling chromatin in vitro and displays an ATP hydrolyzing activity that is stimulated by nucleosomes. Together, these data identify a novel chromatin remodeling complex with a critical role in neurulation.

Chromatin modifiers and carcinogenesis

Access of gene regulatory factors to the eukaryotic genome is modulated by chromatin. The organization of this nucleoprotein complex is highly dynamic and tightly regulated. The control of wide-ranging nuclear processes through the configuration of chromatin is achieved by the concerted actions of ATP-dependent chromatin-remodeling complexes and histone-modifying enzymes, and by the incorporation of specialized histone variants. It is becoming clear that perturbation of these chromatin modifiers can lead to cancer. Recent findings illustrate the mechanisms by which chromatin influences cancer development, and aid understanding of the regulation of chromatin organization, cellular transformation and the connections between tumor suppressor and oncogene function.

A Tissue-specific, Naturally Occurring Human SNF2L Variant Inactivates Chromatin Remodeling

Mammalian genomes encode two imitation switch family chromatin remodeling proteins, SNF2H and SNF2L. In the mouse, SNF2H is expressed ubiquitously, whereas SNF2L expression is limited to the brain and gonadal tissue. This pattern of SNF2L expression suggests a critical role for SNF2L in neuronal physiology. Indeed, SNF2L was shown to promote neurite outgrowth as well as regulate the human engrailed homeotic genes, important regulators of brain development. Here we identify a novel splice variant of human SNF2L we call SNF2L+13, which contains a nonconserved in-frame exon within the conserved catalytic core domain of SNF2L. SNF2L+13 retains the ability to incorporate into multiprotein complexes; however, it is devoid of enzymatic activity. Most interestingly, unlike mouse SNF2L, human SNF2L is expressed ubiquitously, and regulation is mediated by isoform variation. The human SNF2L+13 null variant is predominant in non-neuronal tissue, whereas the human wild type active SNF2L isoform is expressed in neurons. Thus, like the mouse, active human SNF2L is limited to neurons and a few other tissues.

Midbrain dopaminergic neurons: control of their cell fate by the engrailed transcription factors

As for any other cell population, the development, cell fate, and properties of mesencephalic dopaminergic (mesDA) neurons are ultimately controlled at the transcriptional level. The genes for two transcription factors Engrailed-1 ( En1) and Engrailed-2 ( En2) play an essential role in the development and maintenance of these cells. They belong to a family of genes that have been investigated in Drosophila for more than half a century. The products of these genes are all characterized by homeotic tissue transformation and a highly conserved protein sequence, the homeobox. En1 and En2 act upon at least two steps of the differentiation of mesDA neurons. They take part in the regionalization event, which gives rise to the neuroepithelium that provides the precursor cells in the ventral midbrain with the fibroblast growth factor 8 signal necessary for their induction. Additionally, these genes are required in postmitotic mesDA neurons in which they are expressed from embryonic day 12 continuously into adulthood. In mutant mice homozygous null for En1 and En2, the neurons are generated in the ventral midbrain, become postmitotic, and begin to express their neurotransmitter phenotype. However, thereafter, they rapidly die by apoptosis. Cell mixing experiments in vitro and in vivo have demonstrated that the engrailed requirement for the survival of mesDA neurons is cell-autonomous. The inactivation of engrailed by RNA interference induces apoptosis in less than 24 h. These data suggest that the engrailed genes control an essential mechanism for the survival of mesDA neurons.

Selective regulation of 14-3-3? in primary culture of cerebral cortical neurons and astrocytes during development

The 14-3-3 proteins exist predominantly in the brain and may play regulatory roles in cellular processes of growth, differentiation, survival, and apoptosis. The biological functions, however, of the various 14-3-3 isoforms (beta, epsilon, eta, gamma, and zeta) in the brain remain unclear. We have reported previously upregulation of 14-3-3gamma in ischemic astrocytes. In the present study, we report selective regulation of 14-3-3eta in cultured cerebral cortical neurons and astrocytes during in vitro development. In cultured neurons, gene expression levels of 14-3-3eta increase with culture age (0-10 days). Brain-derived neurotrophic factor and neurotrophin-3 upregulate 14-3-3eta gene expression. In cultured astrocytes, 14-3-3eta is downregulated with culture age (1-5 weeks). The gene expression level of 14-3-3eta is not affected by scratch injury in astrocytes or by ischemia in neurons. These data suggest a possible role of 14-3-3eta in growth and differentiation of neurons and astrocytes, indicating an intricate mechanism governing coordinated and well-controlled developmental events in the brain to ensure normal neural functions.