The many faces of chromatin remodeling: SWItching beyond transcription

XBP-1 increases ERalpha transcriptional activity through regulation of large-scale chromatin unfolding

Human X box binding protein 1 (XBP-1) is a transcription factor essential for hepatocyte growth, the differentiation of plasma cells, and the unfolded protein response. Recently, we have demonstrated that two forms of XBP-1, XBP-1S, and XBP-1U, enhance estrogen receptor alpha (ERalpha)-dependent transcriptional activity in a ligand-independent manner. However, how XBP-1S and XBP-1U regulate ERalpha transcriptional activity remains unknown. Here, we report that XBP-1S and XBP-1U induce large-scale chromatin unfolding by targeting the XBP-1 proteins to an amplified, lac operator-containing chromosome region in mammalian cells. This unfolding activity maps to the transactivation domains of XBP-1S and XBP-1U. Wild-type XBP-1S and XBP-1U, but not the mutants that completely abolished the ERalpha transcriptional activation, increased the chromatin unfolding activity of ERalpha. These data identify a novel function of XBP-1 and suggest that regulation of large-scale chromatin unfolding by XBP-1 may be responsible for the enhancement of ERalpha transcriptional activity.

Human Rad54 protein stimulates DNA strand exchange activity of hRad51 protein in the presence of Ca2+

Rad51 and Rad54 proteins play a key role in homologous recombination in eukaryotes. Recently, we reported that Ca2+ is required in vitro for human Rad51 protein to form an active nucleoprotein filament that is important for the search of homologous DNA and for DNA strand exchange, two critical steps of homologous recombination. Here we find that Ca2+ is also required for hRad54 protein to effectively stimulate DNA strand exchange activity of hRad51 protein. This finding identifies Ca2+ as a universal cofactor of DNA strand exchange promoted by mammalian homologous recombination proteins in vitro. We further investigated the hRad54-dependent stimulation of DNA strand exchange. The mechanism of stimulation appeared to include specific interaction of hRad54 protein with the hRad51 nucleoprotein filament. Our results show that hRad54 protein significantly stimulates homology-independent coaggregation of dsDNA with the filament, which represents an essential step of the search for homologous DNA. The results obtained indicate that hRad54 protein serves as a dsDNA gateway for the hRad51-ssDNA filament, promoting binding and an ATP hydrolysis-dependent translocation of dsDNA during the search for homologous sequences.

Functional and Physical Interactions between Autonomously Replicating Sequence-Binding Factor 1 and the Nuclear Transport Machinery

Autonomously replicating sequence-binding factor 1 (Abf1p) is a site-specific DNA binding protein in Saccharomyces cerevisiae that functions to regulate multiple nuclear events including DNA replication, transcriptional activation, and gene silencing. Previous work indicates that the multiple functions of Abf1p are conferred by the carboxy-terminus of the protein, which can be further dissected into two important clusters of amino acid residues (CS1 and CS2). Here we present genetic and cell biological evidence for a critical role of CS1 in proper nuclear localization of Abf1p. Mutations in CS1 cause severe defects in cell growth, nuclear translocation, and Abf1p-mediated gene regulation, which can be rescued by a heterologous nuclear localization sequence (NLS). In addition, the CS1-domain can mediate the import of a CS1-GFP fusion protein. Importantly, the CS1-mediated nuclear import depends on the Ran guanine nucleotide exchange factor Prp20p. Interestingly, a single amino acid change in CS1 (K625I) also causes the protein to be exported out of the nucleus via the Crm1p-dependent pathway. The temperature-sensitive growth phenotype of this particular mutant can be overcome by overexpression of Kap121p/Pse1p, a well-established nuclear transport receptor. Biochemical studies indicate that Pse1p binds to a region of Abf1p upstream of CS1 in a RanGTP-sensitive manner, suggesting that Abf1p has a second distinct NLS and can be imported into the nucleus by several overlapping pathways. We propose that the link between Abf1p and the nuclear transport machinery may also be important for partitioning multiple Abf1p-mediated nuclear processes.

In vitro assembly of the characteristic chromatin organization at the yeast PHO5 promoter by a replication-independent extract system

An extensive set of analyses of the yeast PHO5 gene, mostly performed in vivo, has made this gene a model for the role of chromatin structure in gene regulation. In the repressed state, the PHO5 promoter shows a characteristic chromatin organization with four positioned nucleosomes and a short hypersensitive site. So far the basis for this nucleosome positioning has remained unresolved. We have therefore decided to complement the in vivo studies by an in vitro approach. As a first step, we have asked whether the characteristic PHO5 promoter chromatin structure depends on the cellular context including replication or higher order nuclear chromatin organization or whether it can be reconstituted in vitro in a cell-free system. To this end we have established an in vitro chromatin assembly system based on yeast extracts. It is capable of generating extensive regular nucleosomal arrays with physiological spacing. Assembly requires supplementation with exogenous histones and is dependent on energy leading to chromatin with dynamic properties due to ATP-dependent activities of the extract. Using the PHO5 promoter sequence as template in this replication independent system, we obtain a nucleosomal pattern over the PHO5 promoter region that is very similar to the in vivo pattern of the repressed state. This shows that the chromatin structure at the PHO5 promoter represents a self-organizing system in cell-free yeast extracts and provides a promising substrate for in vitro studies with a direct in vivo correlate.

In UV-irradiated Saccharomyces cerevisiae, overexpression of Swi2/Snf2 family member Rad26 increases transcription-coupled repair and repair of the non-transcribed strand

Nucleotide excision repair (NER) in eukaryotes is a pathway conserved from yeast to humans that removes many bulky chemical adducts and UV-induced photoproducts from DNA in a relatively error-free manner. In addition to the recognition and excision of DNA damage throughout the genome (GGR), there exists a mechanism, transcription-coupled nucleotide excision repair (TCR), for recognizing some types of DNA damage in the transcribed strand of genes in Escherichia coli, yeast and mammalian cells. An obstacle in the repair of the transcribed strand of active genes is the RNA polymerase complex stalled at sites of DNA damage. The stalled RNA polymerase complex may then mediate recruitment of repair proteins to damage in the transcribed strand. Proteins enabling TCR are the Cockayne syndrome B (CSB) protein in humans and its yeast homologue Rad26. Both CSB and Rad26 belong to the Swi2/Snf2 family of DNA-dependent ATPases, which change DNA accessibility to proteins by altering chromatin structure. To address how Rad26 functions in yeast repair, we used the genetic approach of overexpressing Rad26 and examined phenotypic changes, i.e. changes in NER. We found that repair of both the transcribed and the non-transcribed strands is increased. In addition, overexpression of Rad26 partially bypasses the requirement for Rad7 in GGR, specifically in the repair of non-transcribed sequences. As TCR takes place in very localized regions of DNA (i.e. within genes) in wild-type cells, we propose that overexpression of recombinant Rad26 increases accessibility of the damaged DNA in chromatin for interaction with repair proteins.

Genetic re-engineering of Saccharomyces cerevisiae RAD51 leads to a significant increase in the frequency of gene repair in vivo

Oligonucleotides can be used to direct the alteration of single nucleotides in chromosomal genes in yeast. Rad51 protein appears to play a central role in catalyzing the reaction, most likely through its DNA pairing function. Here, we re-engineer the RAD51 gene in order to produce proteins bearing altered levels of known activities. Overexpression of wild-type ScRAD51 elevates the correction of an integrated, mutant hygromycin resistance gene approximately 3-fold. Overexpression of an altered RAD51 gene, which encodes a protein that has a higher affinity for ScRad54, enhances the targeting frequency nearly 100-fold. Another mutation which increases the affinity of Rad51 for DNA was also found to increase gene repair when overexpressed in the cell. Other mutations in the Rad51 protein, such as one that reduces interaction with Rad52, has little or no effect on the frequency of gene repair. These data provide the first evidence that the Rad51 protein can be modified so as to increase the frequency of gene repair in yeast.

Transcription Factors and Nuclear Receptors Interact with the SWI/SNF Complex through the BAF60c Subunit

Transcriptional activity relies on coregulators that modify chromatin structure or serve as bridging factors between transcription factors and the basal transcription machinery. We identified a new coregulator of peroxisome proliferator-activated receptor gamma, BRG1/Brm-associated factor of 60 kDa, subunit c2 (BAF60c2), in a yeast two-hybrid screen of a human adipose tissue cDNA library. BAF60c2 represents a new isoform of BAF60c, a component of the SWI/SNF (mating type switching/sucrose non-fermenting) chromatin remodeling complex. This new isoform as well as the previously identified protein, renamed BAF60c1, is localized primarily in the cell nucleus and is expressed in a wide variety of tissues. Both BAF60c isoforms bind to several nuclear receptors and transcription factors of various families. BAF60c proteins interact in a ligand-independent manner with peroxisome proliferator-activated receptor gamma and enhance its transcriptional activity. Both isoforms are enriched in the central nervous system and also modulate the transcriptional activity of retinoic acid-related orphan receptor alpha1. In conclusion, BAF60c represents a new coregulator that constitutes an important anchoring point by which the SWI/SNF complex is recruited to nuclear receptors and other transcription factors.

Plant actin-related proteins

Actin-related proteins (ARPs) constitute a family of divergent and evolutionarily ancient eukaryotic proteins whose primary sequences display homology to conventional actins. Whereas actins play well-characterized cytoskeletal roles, the ARPs are implicated in various cellular functions in both the cytoplasm and in the nucleus. Cytoplasmic ARPs, for example, are known to participate in the assembly of branched actin filaments and dynein-mediated movement of vesicles in many eukaryotes. Nuclear ARPs, by contrast, are enigmatic components of various chromatin-modifying complexes involved in transcriptional regulation. Here, we review homologs to several known classes of ARPs and two distinct ARP classes in plants, and summarize recent work elucidating the biological functions of ARPs in eukaryotes.

The effect of hydroxyurea and trichostatin a on targeted nucleotide exchange in yeast and Mammalian cells

Targeted nucleotide exchange (TNE) is a process by which a synthetic DNA oligonucleotide, partially complementary to a site in a chromosomal or an episomal gene directs the reversal of a single nucleotide at a specific site. To protect against nuclease digestion, the oligonucleotide is modified with derivative linkages among the terminal bases. We have termed these molecules modified single-stranded oligonucleotides (MSOs). Current models suggest that the reaction occurs in two steps. The first, DNA pairing, involves the alignment of the MSO with the target site and its assimilation into the target helix forming a D-loop. The second phase centers around the repair of a single base mismatch formed between the MSO and its complementary strand in the D-loop. Nucleotide exchange is promoted in all likelihood by the mismatch repair system. A critical feature of successful TNE is the accessibility of the target site for the MSO and the factors that increase the dynamic nature of the chromatin that will likely increase the frequency. Here, we report that two factors, trichostatin A and hydroxyurea, elevate gene repair of a mutant hygromycin gene in Saccharomyces cerevisiae and a mutant eGFP gene in a mammalian cell line, MCF-10AT1 cells. Trichostatin A (TSA) acts by preventing the deacetylation of histones while hydroxyurea (HU) reduces the rate of replication. Both of these activities, by their very nature, create a more open configuration of the MSO into the target site.

The RSC nucleosome-remodeling complex is required for Cohesin's association with chromosome arms

The fidelity of chromosome segregation requires that the cohesin protein complex bind together newly replicated sister chromatids both at centromeres and at discrete sites along chromosome arms. Segregation of the yeast 2 micro plasmid also requires cohesin, which is recruited to the plasmid partitioning locus. Here we report that the RSC chromatin-remodeling complex regulates the differential association of cohesin with centromeres and chromosome arms. RSC cycles on and off chromosomal arm and plasmid cohesin binding sites in a cell cycle-regulated manner 15 min preceding Mcd1p, the central cohesin subunit. We show that in rsc mutants Mcd1p fails to associate with chromosome arms but still binds to centromeres, and that consequently, the arm regions of mitotic sister chromosomes separate precociously while cohesion at centromeres is unaffected. Our data suggest a role for RSC in facilitating the loading of cohesin specifically onto chromosome arms, thereby ensuring sister chromatid cohesion and proper chromosome segregation.

The activities of eukaryotic replication origins in chromatin

DNA replication initiates at chromosomal positions called replication origins. This review will focus on the activity, regulation and roles of replication origins in Saccharomyces cerevisiae. All eukaryotic cells, including S. cerevisiae, depend on the initiation (activity) of hundreds of replication origins during a single cell cycle for the duplication of their genomes. However, not all origins are identical. For example, there is a temporal order to origin activation with some origins firing early during the S-phase and some origins firing later. Recent studies provide evidence that posttranslational chromatin modifications, heterochromatin-binding proteins and nucleosome positioning can control the efficiency and/or timing of chromosomal origin activity in yeast. Many more origins exist than are necessary for efficient replication. The availability of excess replication origins leaves individual origins free to evolve distinct forms of regulation and/or roles in chromosomes beyond their fundamental role in DNA synthesis. We propose that some origins have acquired roles in controlling chromatin structure and/or gene expression. These roles are not linked obligatorily to replication origin activity per se, but instead exploit multi-subunit replication proteins with the potential to form context-dependent protein-protein interactions.

The ctf13-30/CTF13 genomic haploinsufficiency modifier screen identifies the yeast chromatin remodeling complex RSC, which is required for the establishment of sister chromatid cohesion

The budding yeast centromere-kinetochore complex ensures high-fidelity chromosome segregation in mitosis and meiosis by mediating the attachment and movement of chromosomes along spindle microtubules. To identify new genes and pathways whose function impinges on chromosome transmission, we developed a genomic haploinsufficiency modifier screen and used ctf13-30, encoding a mutant core kinetochore protein, as the reference point. We demonstrate through a series of secondary screens that the genomic modifier screen is a successful method for identifying genes that encode nonessential proteins required for the fidelity of chromosome segregation. One gene isolated in our screen was RSC2, a nonessential subunit of the RSC chromatin remodeling complex. rsc2 mutants have defects in both chromosome segregation and cohesion, but the localization of kinetochore proteins to centromeres is not affected. We determined that, in the absence of RSC2, cohesin could still associate with chromosomes but fails to achieve proper cohesion between sister chromatids, indicating that RSC has a role in the establishment of cohesion. In addition, numerous subunits of RSC were affinity purified and a new component of RSC, Rtt102, was identified. Our work indicates that only a subset of the nonessential RSC subunits function in maintaining chromosome transmission fidelity.

The DNA chaperone HMGB1 facilitates ACF/CHRAC-dependent nucleosome sliding

Nucleosome remodelling complexes CHRAC and ACF contribute to chromatin dynamics by converting chemical energy into sliding of histone octamers on DNA. Their shared ATPase subunit ISWI binds DNA at the sites of entry into the nucleosome. A prevalent model assumes that DNA distortions catalysed by ISWI are converted into relocation of DNA relative to a histone octamer. HMGB1, one of the most abundant nuclear non-histone proteins, binds with preference to distorted DNA. We have now found that transient interaction of HMGB1 with nucleosomal linker DNA overlapping ISWI-binding sites enhances the ability of ACF to bind nucleosomal DNA and accelerates the sliding activity of limiting concentrations of remodelling factor. By contrast, an HMGB1 mutant with increased binding affinity was inhibitory. These observations are consistent with a role for HMGB1 as a DNA chaperone facilitating the rate-limiting DNA distortion during nucleosome remodelling.

Acf1 confers unique activities to ACF/CHRAC and promotes the formation rather than disruption of chromatin in vivo

Chromatin assembly is required for the duplication of chromosomes. ACF (ATP-utilizing chromatin assembly and remodeling factor) catalyzes the ATP-dependent assembly of periodic nucleosome arrays in vitro, and consists of Acf1 and the ISWI ATPase. Acf1 and ISWI are also subunits of CHRAC (chromatin accessibility complex), whose biochemical activities are similar to those of ACF. Here we investigate the in vivo function of the Acf1 subunit of ACF/CHRAC in Drosophila. Although most Acf1 null animals die during the larval-pupal transition, Acf1 is not absolutely required for viability. The loss of Acf1 results in a decrease in the periodicity of nucleosome arrays as well as a shorter nucleosomal repeat length in bulk chromatin in embryos. Biochemical experiments with Acf1-deficient embryo extracts further indicate that ACF/CHRAC is a major chromatin assembly factor in Drosophila. The phenotypes of flies lacking Acf1 suggest that ACF/CHRAC promotes the formation of repressive chromatin. The acf1 gene is involved in the establishment and/or maintenance of transcriptional silencing in pericentric heterochromatin and in the chromatin-dependent repression by Polycomb group genes. Moreover, cells in animals lacking Acf1 exhibit an acceleration of progression through S phase, which is consistent with a decrease in chromatin-mediated repression of DNA replication. In addition, acf1 genetically interacts with nap1, which encodes the NAP-1 nucleosome assembly protein. These findings collectively indicate that ACF/CHRAC functions in the assembly of periodic nucleosome arrays that contribute to the repression of genetic activity in the eukaryotic nucleus.

Chromatin remodeling by ATP-dependent molecular machines

The eukaryotic genome is packaged into a periodic nucleoprotein structure termed chromatin. The repeating unit of chromatin, the nucleosome, consists of DNA that is wound nearly two times around an octamer of histone proteins. To facilitate DNA-directed processes in chromatin, it is often necessary to rearrange or to mobilize the nucleosomes. This remodeling of the nucleosomes is achieved by the action of chromatin-remodeling complexes, which are a family of ATP-dependent molecular machines. Chromatin-remodeling factors share a related ATPase subunit and participate in transcriptional regulation, DNA repair, homologous recombination and chromatin assembly. In this review, we provide an overview of chromatin-remodeling enzymes and discuss two possible mechanisms by which these factors might act to reorganize nucleosome structure.

EMSY links the BRCA2 pathway to sporadic breast and ovarian cancer

The BRCA2 gene is mutated in familial breast and ovarian cancer, and its product is implicated in DNA repair and transcriptional regulation. Here we identify a protein, EMSY, which binds BRCA2 within a region (exon 3) deleted in cancer. EMSY is capable of silencing the activation potential of BRCA2 exon 3, associates with chromatin regulators HP1beta and BS69, and localizes to sites of repair following DNA damage. EMSY maps to chromosome 11q13.5, a region known to be involved in breast and ovarian cancer. We show that the EMSY gene is amplified almost exclusively in sporadic breast cancer (13%) and higher-grade ovarian cancer (17%). In addition, EMSY amplification is associated with worse survival, particularly in node-negative breast cancer, suggesting that it may be of prognostic value. The remarkable clinical overlap between sporadic EMSY amplification and familial BRCA2 deletion implicates a BRCA2 pathway in sporadic breast and ovarian cancer.

Local action of the chromatin assembly factor CAF-1 at sites of nucleotide excision repair in vivo

DNA damage and its repair can cause both local and global rearrangements of chromatin structure. In each case, the epigenetic information contained within this structure must be maintained. Using the recently developed method for the localized UV irradiation of cells, we analysed responses that occur locally to damage sites and global events triggered by local damage recognition. We thus demonstrate that, within a single cell, the recruitment of chromatin assembly factor 1 (CAF-1) to UV-induced DNA damage is a strictly local phenomenon, restricted to damage sites. Concomitantly, proliferating cell nuclear antigen (PCNA) locates to the same sites. This localized recruitment suggests that CAF-1 participates directly in chromatin structural rearrangements that occur in the vicinity of the damage. Use of nucleotide excision repair (NER)-deficient cells shows that the NER pathway--specifically dual incision--is required for recruitment of CAF-1 and PCNA. This in vivo demonstration of the local role of CAF-1, depending directly on NER, supports the hypothesis that CAF-1 ensures the maintenance of epigenetic information by acting locally at repair sites.

The ISWI ATPase Snf2h is required for early mouse development

Chromatin assembly and remodeling complexes alter histone-DNA interactions by using the energy of ATP hydrolysis catalyzed by nucleosome-dependent ATPase subunits. Several classes of ATP-dependent chromatin remodeling complexes exist, including the ISWI family. ISWI complexes disrupt histone-DNA interactions in vitro by facilitating nucleosome sliding. Snf2h is a widely expressed ISWI ATPase. We investigated the role of the Snf2h gene in mammalian development by generating a null mutation in mice. Snf2h heterozygous mutant mice are born at the expected frequency and appear normal. Snf2h-/- embryos die during the periimplantation stage. Blastocyst outgrowth experiments indicate that loss of Snf2h results in growth arrest and cell death of both the trophectoderm and inner cell mass. To investigate the effect of decreased Snf2h levels in adult cells, we performed antisense inhibition of Snf2h in human hematopoietic progenitors. Reducing Snf2h levels inhibited CD34+ progenitors from undergoing cytokine-induced erythropoiesis in vitro. Our results indicate that Snf2h is required for proliferation of early blastocyst-derived stem cells and adult human hematopoietic progenitors. Cells lacking Snf2h are thus prevented from further embryonic development and differentiation.

Schizosaccharomyces pombe Rdh54 (TID1) acts with Rhp54 (RAD54) to repair meiotic double-strand breaks

We report the characterization of rdh54+, the second fission yeast Schizosaccharomyces pombe Rad54 homolog. rdh54+ shares sequence and functional homology to budding yeast RDH54/TID1. Rdh54p is present during meiosis with appropriate timing for a meiotic recombination factor. It interacts with Rhp51 and the meiotic Rhp51 homolog Dmc1 in yeast two-hybrid assays. Deletion of rdh54+ has no effect on DNA damage repair during the haploid vegetative cell cycle. In meiosis, however, rdh54Delta shows decreased spore viability and homologous recombination with a concomitant increase in sister chromatid exchange. The rdh54Delta single mutant repairs meiotic breaks with similar timing to wild type, suggesting redundancy of meiotic recombination factors. Consistent with this, the rdh54Delta rhp54Delta double mutant fails to repair meiotic double strand breaks. Live cell analysis shows that rdh54Delta rhp54Delta asci do not arrest, but undergo both meiotic divisions with near normal timing, suggesting that failure to repair double strand breaks in S. pombe meiosis does not result in checkpoint arrest.

The development and regulation of gene repair

A technique that can direct the repair of a genetic mutation in a human chromosome using the DNA repair machinery of the cell is under development. Although this approach is not as mature as other forms of gene therapy and fundamental problems continue to arise, it promises to be the ultimate therapy for many inherited disorders. There is a continuing effort to understand the potential and the limitations of this controversial approach.

Involvement of actin-related proteins in ATP-dependent chromatin remodeling

Actin-related proteins (Arps) and conventional actin are enigmatic components of many chromatin-remodeling enzyme complexes. The yeast INO80 ATP-dependent chromatin-remodeling complex contains stoichiometric amounts of Arp4, Arp5, Arp8, and actin. Here we have revealed functions of Arp5 and Arp8 by analysis of mutants. arp5 Delta and arp8 Delta mutants display an ino80 Delta phenotype. Purification of INO80 complexes from arp5 Delta and arp8 Delta cells shows that protein complexes remain intact but are compromised for INO80 ATPase activity, DNA binding, and nucleosome mobilization. The INO80 (arp8 Delta) complex is strikingly deficient, not only for the Arp8 subunit, but also for Arp4 and actin, suggesting an ordered assembly of Arps. Binding of Arp8 to the INO80 complex requires an N-terminal region of Ino80 adjacent to the conserved ATPase domain. GST-Arp8 binds preferentially to histones H3 and H4 in vitro, suggesting a histone chaperone function. These findings show direct involvement of Arps in the chromatin-remodeling process.

Chromatin remodeling activities act on UV-damaged nucleosomes and modulate DNA damage accessibility to photolyase

Nucleosomes inhibit DNA repair in vitro, suggesting that chromatin remodeling activities might be required for efficient repair in vivo. To investigate how structural and dynamic properties of nucleosomes affect damage recognition and processing, we investigated repair of UV lesions by photolyase on a nucleosome positioned at one end of a 226-bp-long DNA fragment. Repair was slow in the nucleosome but efficient outside. No disruption or movement of the nucleosome was observed after UV irradiation and during repair. However, incubation with the nucleosome remodeling complex SWI/SNF and ATP altered the conformation of nucleosomal DNA as judged by UV photo-footprinting and promoted more homogeneous repair. Incubation with yISW2 and ATP moved the nucleosome to a more central position, thereby altering the repair pattern. This is the first demonstration that two different chromatin remodeling complexes can act on UV-damaged nucleosomes and modulate repair. Similar activities might relieve the inhibitory effect of nucleosomes on DNA repair processes in living cells.

Distinct strategies to make nucleosomal DNA accessible

One hallmark of ATP-dependent remodeling complexes is the ability to make nucleosomal DNA accessible to regulatory factors. We have compared two prominent human ATP-dependent remodelers, BRG1 from the SWI/SNF family and SNF2h from the ISWI family, for their abilities to make a spectrum of nucleosomal sites accessible. By measuring rates of remodeling at seven different sites on a mononucleosome and at six different sites on the central nucleosome of a trinucleosome, we have found that BRG1 opens centrally located sites more than an order of magnitude better than SNF2h. We provide evidence that this capability of BRG1 is caused by its ability to create DNA loops on the surface of a nucleosome, even when that nucleosome is constrained by adjacent nucleosomes. This specialized ability to make central sites accessible should allow SWI/SNF family complexes to facilitate binding of nuclear factors in chromatin environments where adjacent nucleosomes might otherwise constrain mobility.

The yeast RSC chromatin-remodeling complex is required for kinetochore function in chromosome segregation

The accurate segregation of chromosomes requires the kinetochore, a complex protein machine that assembles onto centromeric DNA to mediate attachment of replicated sister chromatids to the mitotic spindle apparatus. This study reveals an important role for the yeast RSC ATP-dependent chromatin-remodeling complex at the kinetochore in chromosome transmission. Mutations in genes encoding two core subunits of RSC, the ATPase Sth1p and the Snf5p homolog Sfh1p, interact genetically with mutations in genes encoding kinetochore proteins and with a mutation in centromeric DNA. RSC also interacts genetically and physically with the histone and histone variant components of centromeric chromatin. Importantly, RSC is localized to centromeric and centromere-proximal chromosomal regions, and its association with these loci is dependent on Sth1p. Both sth1 and sfh1 mutants exhibit altered centromeric and centromere-proximal chromatin structure and increased missegregation of authentic chromosomes. Finally, RSC is not required for centromeric deposition of the histone H3 variant Cse4p, suggesting that RSC plays a role in reconfiguring centromeric and flanking nucleosomes following Cse4p recruitment for proper chromosome transmission.

A novel function of Rad54 protein. Stabilization of the Rad51 nucleoprotein filament

Homologous recombination is important for the repair of double-stranded DNA breaks in all organisms. Rad51 and Rad54 proteins are two key components of the homologous recombination machinery in eukaryotes. In vitro, Rad51 protein assembles with single-stranded DNA to form the helical nucleoprotein filament that promotes DNA strand exchange, a basic step of homologous recombination. Rad54 protein interacts with this Rad51 nucleoprotein filament and stimulates its DNA pairing activity, suggesting that Rad54 protein is a component of the nucleoprotein complex involved in the DNA homology search. Here, using physical criteria, we demonstrate directly the formation of Rad54-Rad51-DNA nucleoprotein co-complexes that contain equimolar amounts of each protein. The binding of Rad54 protein significantly stabilizes the Rad51 nucleoprotein filament formed on either single-stranded DNA or double-stranded DNA. The Rad54-stabilized nucleoprotein filament is more competent in DNA strand exchange and acts over a broader range of solution conditions. Thus, the co-assembly of an interacting partner with the Rad51 nucleoprotein filament represents a novel means of stabilizing the biochemical entity central to homologous recombination, and reveals a new function of Rad54 protein.

Selective gene regulation by SWI/SNF-related chromatin remodeling factors

Chromatin is a highly dynamic structure that plays a key role in the orchestration of gene expression patterns during cellular differentiation and development. The packaging of DNA into chromatin generates a barrier to the transcription machinery. The two main strategies by which cells alleviate chromatin-mediated repression are through the action of ATP-dependent chromatin remodeling complexes and enzymes that covalently modify the histones. Various signaling pathways impinge upon the targeting and activity of these enzymes, thereby controlling gene expression in response to physiological and developmental cues. Chromatin structure also underlies many so-called epigenetic phenomena, leading to the mitotically stable propagation of differential expression of genetic information. Here, we will focus on the role of SWI/SNF-related ATP-dependent chromatin remodeling complexes in developmental gene regulation. First, we compare different models for how remodelers can act in a gene-selective manner, and either cooperate or antagonize other chromatin-modulating systems in the cell. Next, we discuss their functioning during the control of developmental gene expression programs.

Rad54 protein possesses chromatin-remodeling activity stimulated by the Rad51-ssDNA nucleoprotein filament

In Saccharomyces cerevisiae, the Rad54 protein participates in the recombinational repair of double-strand DNA breaks together with the Rad51, Rad52, Rad55 and Rad57 proteins. In vitro, Rad54 interacts with Rad51 and stimulates DNA strand exchange promoted by Rad51 protein. Rad54 is a SWI2/SNF2-related protein that possesses double-stranded DNA-dependent ATPase activity and changes DNA topology in an ATP hydrolysis-dependent manner. Here we show that Rad54 catalyzes bidirectional nucleosome redistribution by sliding nucleosomes along DNA. Nucleosome redistribution is greatly stimulated by the Rad51 nucleoprotein filament but does not require the presence of homologous single-stranded DNA within the filament. On the basis of these data, we propose that Rad54 facilitates chromatin remodeling and, perhaps more generally, protein clearing at the homology search step of genetic recombination.

Histone chaperones and nucleosome assembly

Recent structures of the nucleosome core particle reveal details of histone-histone and histone-DNA interactions. These structures have now set the stage for understanding chromatin assembly and dynamics during replication and transcription. Histone chaperones and chromatin remodeling complexes are important in both of these processes. The nucleosome and its protein core, the histone octamer, have twofold symmetry, which histone chaperones may use to bind core histones. Recent studies suggest that the nucleoplasmin pentamer may mediate histone storage, sperm chromatin decondensation and nucleosome assembly, by dimerizing to form a decamer. In this model, histone binding on the lateral surface of the chaperone involves stereospecific interactions and a shared twofold axis.

Bromodomains mediate an acetyl-histone encoded antisilencing function at heterochromatin boundaries

Bromodomains bind acetylated histone H4 peptides in vitro. Since many chromatin remodeling complexes and the general transcription factor TFIID contain bromodomains, they may link histone acetylation to increased transcription. Here we show that yeast Bdf1 bromodomains recognize endogenous acetyl-histone H3/H4 as a mechanism for chromatin association in vivo. Surprisingly, deletion of BDF1 or a Bdf1 mutation that abolishes histone binding leads to transcriptional downregulation of genes located at heterochromatin-euchromatin boundaries. Wild-type Bdf1 protein imposes a physical barrier to the spreading of telomere- and mating-locus-proximal SIR proteins. Biochemical experiments indicate that Bdf1 competes with the Sir2 deacetylase for binding to acetylated histone H4. These data suggest an active role for Bdf1 in euchromatin maintenance and antisilencing through a histone tail-encoded boundary function.

Modulation of ATP-dependent chromatin-remodeling complexes by inositol polyphosphates

Eukaryotes use adenosine triphosphate (ATP)-dependent chromatin-remodeling complexes to regulate gene expression. Here, we show that inositol polyphosphates can modulate the activities of several chromatin-remodeling complexes in vitro. Inositol hexakisphosphate (IP6) inhibits nucleosome mobilization by NURF, ISW2, and INO80 complexes. In contrast, nucleosome mobilization by the yeast SWI/SNF complex is stimulated by inositol tetrakisphosphate (IP4) and inositol pentakisphosphate (IP5). We demonstrate that mutations in genes encoding inositol polyphosphate kinases that produce IP4, IP5, and IP6 impair transcription in vivo. These results provide a link between inositol polyphosphates, chromatin remodeling, and gene expression.

Mechanisms of Insulator Function in Gene Regulation and Genomic Imprinting

Correct temporal and spatial patterns of gene expression are required to establish unique cell types. Several levels of genome organization are involved in achieving this intricate regulatory feat. Insulators are elements that modulate interactions between other cis-acting sequences and separate chromatin domains with distinct condensation states. Thus, they are proposed to play an important role in the partitioning of the genome into discrete realms of expression. This review focuses on the roles that insulators have in vivo and reviews models of insulator mechanisms in the light of current understanding of gene regulation.

Yeast Isw1p forms two separable complexes in vivo

There are several classes of ATP-dependent chromatin remodeling complexes, which modulate the structure of chromatin to regulate a variety of cellular processes. The budding yeast, Saccharomyces cerevisiae, encodes two ATPases of the ISWI class, Isw1p and Isw2p. Previously Isw1p was shown to copurify with three other proteins. Here we identify these associated proteins and show that Isw1p forms two separable complexes in vivo (designated Isw1a and Isw1b). Biochemical assays revealed that while both have equivalent nucleosome-stimulated ATPase activities, Isw1a and Isw1b differ in their abilities to bind to DNA and nucleosomal substrates, which possibly accounts for differences in specific activities in nucleosomal spacing and sliding. In vivo, the two Isw1 complexes have overlapping functions in transcriptional regulation of some genes yet distinct functions at others. In addition, these complexes show different contributions to cell growth at elevated temperatures.

The DNA chaperone HMGB1 facilitates ACF/CHRAC-dependent nucleosome sliding

Nucleosome remodelling complexes CHRAC and ACF contribute to chromatin dynamics by converting chemical energy into sliding of histone octamers on DNA. Their shared ATPase subunit ISWI binds DNA at the sites of entry into the nucleosome. A prevalent model assumes that DNA distortions catalysed by ISWI are converted into relocation of DNA relative to a histone octamer. HMGB1, one of the most abundant nuclear non-histone proteins, binds with preference to distorted DNA. We have now found that transient interaction of HMGB1 with nucleosomal linker DNA overlapping ISWI-binding sites enhances the ability of ACF to bind nucleosomal DNA and accelerates the sliding activity of limiting concentrations of remodelling factor. By contrast, an HMGB1 mutant with increased binding affinity was inhibitory. These observations are consistent with a role for HMGB1 as a DNA chaperone facilitating the rate-limiting DNA distortion during nucleosome remodelling.

ATP-dependent nucleosome remodeling

It has been a long-standing challenge to decipher the principles that enable cells to both organize their genomes into compact chromatin and ensure that the genetic information remains accessible to regulatory factors and enzymes within the confines of the nucleus. The discovery of nucleosome remodeling activities that utilize the energy of ATP to render nucleosomal DNA accessible has been a great leap forward. In vitro, these enzymes weaken the tight wrapping of DNA around the histone octamers, thereby facilitating the sliding of histone octamers to neighboring DNA segments, their displacement to unlinked DNA, and the accumulation of patches of accessible DNA on the surface of nucleosomes. It is presumed that the collective action of these enzymes endows chromatin with dynamic properties that govern all nuclear functions dealing with chromatin as a substrate. The diverse set of ATPases that qualify as the molecular motors of the nucleosome remodeling process have a common history and are part of a superfamily. The physiological context of their remodeling action builds on the association with a wide range of other proteins to form distinct complexes for nucleosome remodeling. This review summarizes the recent progress in our understanding of the mechanisms underlying the nucleosome remodeling reaction, the targeting of remodeling machines to selected sites in chromatin, and their integration into complex regulatory schemes.

Strand pairing by Rad54 and Rad51 is enhanced by chromatin

We investigated the role of chromatin in the catalysis of homologous strand pairing by Rad54 and Rad51. Rad54 is related to the ATPase subunits of chromatin-remodeling factors, whereas Rad51 is related to bacterial RecA. In the absence of superhelical tension, we found that the efficiency of strand pairing with chromatin is >100-fold higher than that with naked DNA. In addition, we observed that Rad54 and Rad51 function cooperatively in the ATP-dependent remodeling of chromatin. These findings indicate that Rad54 and Rad51 have evolved to function with chromatin, the natural substrate, rather than with naked DNA.

The nucleolar remodeling complex NoRC mediates heterochromatin formation and silencing of ribosomal gene transcription

Epigenetic control mechanisms silence about half of the ribosomal RNA (rRNA) genes in metabolically active cells. In exploring the mechanism by which the active or silent state of rRNA genes is inherited, we found that NoRC, a nucleolar remodeling complex containing Snf2h (also called Smarca5, SWI/SNF-related matrix-associated actin-dependent regulator of chromatin, subfamily a, member 5), represses rDNA transcription. NoRC mediates rDNA silencing by recruiting DNA methyltransferase and histone deacetylase activity to the rDNA promoter, thus establishing structural characteristics of heterochromatin such as DNA methylation, histone hypoacetylation and methylation of the Lys9 residue of histone H3. These results indicate that active and inactive rRNA genes can be demarcated by their associated proteins, and link chromatin remodeling to DNA methylation and specific histone modifications.

"Stemness": transcriptional profiling of embryonic and adult stem cells

The transcriptional profiles of mouse embryonic, neural, and hematopoietic stem cells were compared to define a genetic program for stem cells. A total of 216 genes are enriched in all three types of stem cells, and several of these genes are clustered in the genome. When compared to differentiated cell types, stem cells express a significantly higher number of genes (represented by expressed sequence tags) whose functions are unknown. Embryonic and neural stem cells have many similarities at the transcriptional level. These results provide a foundation for a more detailed understanding of stem cell biology.

CTD phosphatase: role in RNA polymerase II cycling and the regulation of transcript elongation

The repetitive C-terminal domain (CTD) of the largest RNA polymerase II subunit plays a critical role in the regulation of gene expression. The activity of the CTD is dependent on its state of phosphorylation. A variety of CTD kinases act on RNA polymerase II at specific steps in the transcription cycle and preferentially phosphorylate distinct positions within the CTD consensus repeat. A single CTD phosphatase has been identified and characterized that in concert with CTD kinases establishes the level of CTD phosphorylation. The involvement of CTD phosphatase in controlling the progression of RNAP II around the transcription cycle, the mobilization of stored RNAP IIO, and the regulation of transcript elongation and RNA processing is discussed.

Binding of Acf1 to DNA involves a WAC motif and is important for ACF-mediated chromatin assembly

ACF is a chromatin-remodeling complex that catalyzes the ATP-dependent assembly of periodic nucleosome arrays. This reaction utilizes the energy of ATP hydrolysis by ISWI, the smaller of the two subunits of ACF. Acf1, the large subunit of ACF, is essential for the full activity of the complex. We performed a systematic mutational analysis of Acf1 to elucidate the functions of specific subregions of the protein. These studies revealed DNA- and ISWI-binding regions that are important for the chromatin assembly and ATPase activities of ACF. The DNA-binding region of Acf1 includes a WAC motif, which is necessary for the efficient binding of ACF complex to DNA. The interaction of Acf1 with ISWI requires a DDT domain, which has been found in a variety of transcription and chromatin-remodeling factors. Chromatin assembly by ACF is also impaired upon mutation of an acidic region in Acf1, which may interact with histones during the deposition process. Lastly, we observed modest chromatin assembly defects on mutation of other conserved sequence motifs. Thus, Acf1 facilitates chromatin assembly via an N-terminal DNA-binding region with a WAC motif, a central ISWI-binding segment with a DDT domain, and a C-terminal region with an acidic stretch, a WAKZ motif, PHD fingers, and bromodomain.

A chromatin remodelling complex that loads cohesin onto human chromosomes

Nucleosomal DNA is arranged in a higher-order structure that presents a barrier to most cellular processes involving protein DNA interactions. The cellular machinery involved in sister chromatid cohesion, the cohesin complex, also requires access to the nucleosomal DNA to perform its function in chromosome segregation. The machineries that provide this accessibility are termed chromatin remodelling factors. Here, we report the isolation of a human ISWI (SNF2h)-containing chromatin remodelling complex that encompasses components of the cohesin and NuRD complexes. We show that the hRAD21 subunit of the cohesin complex directly interacts with the ATPase subunit SNF2h. Mapping of hRAD21, SNF2h and Mi2 binding sites by chromatin immunoprecipitation experiments reveals the specific association of these three proteins with human DNA elements containing Alu sequences. We find a correlation between modification of histone tails and association of the SNF2h/cohesin complex with chromatin. Moreover, we show that the association of the cohesin complex with chromatin can be regulated by the state of DNA methylation. Finally, we present evidence pointing to a role for the ATPase activity of SNF2h in the loading of hRAD21 on chromatin.

Dynamics of ATP-dependent chromatin assembly by ACF

The assembly of DNA into chromatin is a critical step in the replication and repair of the eukaryotic genome. It has been known for nearly 20 years that chromatin assembly is an ATP-dependent process. ATP-dependent chromatin-assembly factor (ACF) uses the energy of ATP hydrolysis for the deposition of histones into periodic nucleosome arrays, and the ISWI subunit of ACF is an ATPase that is related to helicases. Here we show that ACF becomes committed to the DNA template upon initiation of chromatin assembly. We also observed that ACF assembles nucleosomes in localized arrays, rather than randomly distributing them. By using a purified ACF-dependent system for chromatin assembly, we found that ACF hydrolyses about 2#150;4 molecules of ATP per base pair in the assembly of nucleosomes. This level of ATP hydrolysis is similar to that used by DNA helicases for the unwinding of DNA. These results suggest that a tracking mechanism exists in which ACF assembles chromatin as an ATP-driven DNA-translocating motor. Moreover, this proposed mechanism for ACF may be relevant to the function of other chromatin-remodelling factors that contain ISWI subunits.

Chromatin structure and transcriptional regulation of the beta-globin locus

Chromatin structure plays a critical role in eukaryotic gene transcriptional regulation. The beta-globin locus provides an ideal system within which to study the interplay between chromatin structure and transcriptional regulation. The process of beta-globin locus activation is remarkably intricate and involves at least two distinct events: chromatin opening and gene activation. Great progress has been made in recent years in understanding how locus control regions confer high-level expression to linked genes. Current interest focuses on some special events, including formation of locus control region hypersensitivity sites, ATP-dependent chromatin remodeling, localized H3 hyperacetylation, and intergenic transcription, which link chromatin and beta-globin locus regulation. These events, and their possible molecular bases, are summarized together with speculations concerning their connections.

A crucial role for the putative Arabidopsis topoisomerase VI in plant growth and development

Plant steroid hormones, brassinosteroids (BRs), play important roles throughout plant growth and development. Plants defective in BR biosynthesis or perception display cell elongation defects and severe dwarfism. Two dwarf mutants named bin3 and bin5 with identical phenotypes to each other display some characteristics of BR mutants and are partially insensitive to exogenously applied BRs. In the dark, bin3 or bin5 seedlings are de-etiolated with short hypocotyls and open cotyledons. Light-grown mutant plants are dwarfs with short petioles, epinastic leaves, short inflorescence stems, and reduced apical dominance. We cloned BIN3 and BIN5 and show that BIN5 is one of three putative Arabidopsis SPO11 homologs (AtSPO11-3) that also shares significant homology to archaebacterial topoisomerase VI (TOP6) subunit A, whereas BIN3 represents a putative eukaryotic homolog of TOP6B. The pleiotropic dwarf phenotypes of bin5 establish that, unlike all of the other SPO11 homologs that are involved in meiosis, BIN5/AtSPO11-3 plays a major role during somatic development. Furthermore, microarray analysis of the expression of about 5500 genes in bin3 or bin5 mutants indicates that about 321 genes are down-regulated in both of the mutants, including 18 of 30 BR-induced genes. These results suggest that BIN3 and BIN5 may constitute an Arabidopsis topoisomerase VI that modulates expression of many genes, including those regulated by BRs.

Designed transcription factors as structural, functional and therapeutic probes of chromatin in vivo. Fourth in review series on chromatin dynamics

Despite its central importance in gene regulation, chromatin in mammalian cells remains relatively poorly understood-a predicament due to the paucity of robust genetic tools in mammals, the complexity of the chromatin remodeling machinery, and the dynamic properties of chromatin in vivo. Here we review recent developments in understanding endogenous mammalian gene regulation via the use of designed transcription factors (TFs). These include mutated forms of naturally occurring TFs that exhibit dominant-negative activity, and designed proteins with novel, predetermined DNA-binding specificities. Systematic targeting of designed TFs to particular promoters is helping to illuminate the complex rules that chromatin imposes on TF access and action in vivo. We evaluate the potential applications of these proteins as probes of mammalian chromatin-based regulatory pathways and their potential for the therapy of human disease, highlighting leukemia in particular.

Spontaneous and double-strand break-induced recombination, and gene conversion tract lengths, are differentially affected by overexpression of wild-type or ATPase-defective yeast Rad54

Rad54 plays key roles in homologous recombination (HR) and double-strand break (DSB) repair in yeast, along with Rad51, Rad52, Rad55 and Rad57. Rad54 belongs to the Swi2/Snf2 family of DNA-stimulated ATPases. Rad51 nucleoprotein filaments catalyze DNA strand exchange and Rad54 augments this activity of Rad51. Mutations in the Rad54 ATPase domain (ATPase(-)) impair Rad54 function in vitro, sensitize yeast to killing by methylmethane sulfonate and reduce spontaneous gene conversion. We found that overexpression of ATPase(-) Rad54 reduced spontaneous direct repeat gene conversion and increased both spontaneous direct repeat deletion and spontaneous allelic conversion. Overexpression of ATPase(-) Rad54 decreased DSB-induced allelic conversion, but increased chromosome loss and DSB-dependent lethality. Thus, ATP hydrolysis by Rad54 contributes to genome stability by promoting high-fidelity DSB repair and suppressing spontaneous deletions. Overexpression of wild-type Rad54 did not alter DSB-induced HR levels, but conversion tract lengths were reduced. Interestingly, ATPase(-) Rad54 decreased overall HR levels and increased tract lengths. These tract length changes provide new in vivo evidence that Rad54 functions in the post-synaptic phase during recombinational repair of DSBs.

Myb-binding protein 1a augments AhR-dependent gene expression

We have studied the mechanism by which an acidic domain (amino acids 515-583) of the aromatic hydrocarbon receptor (AhR) transactivates a target gene. Studies with glutathione S-transferase fusion proteins demonstrate that the wild-type acidic domain associates in vitro with Myb-binding protein 1a, whereas a mutant domain (F542A, I569A) does not. AhR-defective cells reconstituted with an AhR containing the wild-type acidic domain exhibit normal AhR function; however, cells reconstituted with an AhR containing the mutant acidic domain do not function normally. Transient transfection of Myb-binding protein 1a into mouse hepatoma cells is associated with augmentation of AhR-dependent gene expression. Such augmentation does not occur when Myb-binding protein 1a is transfected into AhR-defective cells that have been reconstituted with an AhR that lacks the acidic domain. We infer that 1) Myb-binding protein 1a associates with AhR, thereby enhancing transactivation, and 2) the presence of AhR's acidic domain is both necessary and sufficient for Myb-binding protein 1a to increase AhR-dependent gene expression.

Obligatory role of cyclic adenosine monophosphate response element in cyclooxygenase-2 promoter induction and feedback regulation by inflammatory mediators

BACKGROUND

Cyclooxygenase-2 (COX-2) plays a key role in human inflammatory disorders such as vascular inflammation. COX-2 promoter activity is induced by proinflammatory mediators, but the role of cyclic adenosine monophosphate response element (CRE) in promoter stimulation remains unclear.

METHODS AND RESULTS

Transient transfection of a 0.9-kb COX-2 promoter fragment bearing CRE mutation abrogated COX-2 promoter activity induced by proinflammatory mediators in human endothelial cells and fibroblasts. Dual mutations of CRE and an upstream CCAAT/enhancer binding protein (C/EBP) site did not have an additional effect. Binding of CREB-2, ATF-2, USF-2, and c-Jun transactivators to a wild-type and CRE-mutated oligonucleotide was analyzed by a novel DNA-binding assay. CREB-2 and ATF-2 in nuclear extracts of unstimulated endothelial cells bound to CRE, whereas USF-2 and c-Jun or c-Fos bound to non-CRE sites. CREB-2 and c-Fos binding was increased by phorbol 12-myristate 13-acetate but not tumor necrosis factor-alpha. The binding assay and chromatin immunoprecipitation revealed binding of P300 coactivator to the COX-2 promoter region.

CONCLUSIONS

CRE plays an obligatory role in COX-2 promoter activation by diverse stimuli. CREB-2 and ATF-2 bound to CRE serve as an anchor for P300 interaction with upstream transactivators and downstream transcription machinery.

Chromatin assembly. Cooperation between histone chaperones and ATP-dependent nucleosome remodeling machines

Chromatin is a highly dynamic structure that plays an essential role in regulating all nuclear processes that utilize the DNA template including DNA repair, replication, transcription and recombination. Thus, the mechanisms by which chromatin structures are assembled and modified are questions of broad interest. This minireview will focus on two groups of proteins: (a) histone chaperones and (b) ATP-dependent chromatin remodeling machines, that co-operate to assemble DNA and histone proteins into chromatin. The current understanding of how histone chaperones and ATP-dependent remodeling machines coordinately assemble chromatin in vitro will be discussed, together with the growing body of genetic evidence that supports the role of histone chaperones in the cell.

Regulation of histone acetylation and transcription by nuclear protein pp32, a subunit of the INHAT complex

Histone acetylation by p300/CBP and PCAF coactivators is considered to be a key mechanism of chromatin modification and transcriptional regulation. A multiprotein cellular complex, INHAT (inhibitor of acetyltransferases), containing the Set/TAF-Ibeta oncoprotein and pp32 strongly inhibits the HAT activity of p300/CBP and PCAF by histone masking. Here we report that the INHAT complex and its subunits have overlapping but distinct HAT inhibitory and histone binding characteristics. We provide evidence suggesting that the histone binding and INHAT activity of pp32 can be regulated by its physical association with other INHAT subunits. In vivo colocalization and transfection studies show that pp32 INHAT domains are responsible for histone binding, HAT inhibitory activity, and repression of transcription. We propose that INHAT and its subunits may function by modulating histone acetyltransferases through a histone-masking mechanism and may play important regulatory roles in the establishment and maintenance of the newly proposed "histone code" of chromatin.