Nucleosomes reconstituted in vitro on mouse mammary tumor virus B region DNA occupy multiple translational and rotational frames

Chromatin potentiation of the hsp70 promoter is linked to GAGA-factor recruitment

The events leading to transcription initiation of the Drosophila melanogaster heat-shock protein (hsp)70 gene have been demonstrated to be directly connected with nucleosome remodeling factor and GAGA-dependent chromatin remodeling on its promoter region. To investigate the relative importance of the multiple GAGA-factor binding sites in the process of chromatin remodeling and their effect on DNA conformation, the position of nucleosomes over the proximal region of the promoter was mapped. No real-positioned nucleosome was detected. By matching the relative position of the GAGA-factor binding sites with the distribution of nucleosomes over the hsp70 promoter, the GAGA site 2 appeared to be the most accessible, i.e., located close to a nucleosomal edge or within the linker DNA. This result, combined with previous observations, suggest a link between increased GAGA-factor accessibility and efficiency of transcription initiation. The effect of GAGA-binding-site mutations, both individually and in combination, on DNA structure and nucleosome remodeling was assessed using free DNA and fly embryo extract chromatin templates assembled in vitro. Results indicated that both the number of functional sites and their positions within the chromatin were important determinants for nucleosome-remodeling efficiency. Ultimately, the degree of accessibility of the GAGA factor to its cognate binding site(s) appears to be proportional to chromatin-remodeling competency of the hsp70 promoter.

Chromatin structure at the flanking regions of the human beta-globin locus control region DNase I hypersensitive site-2: proposed nucleosome positioning by DNA-binding proteins including GATA-1

The human beta-globin locus control region DNase I hypersensitive site-2 (LCR HS-2) is erythroid-specific and is located 10.9 kb upstream of the epsilon-globin gene. Most studies have only examined the core region of HS-2. However, previous studies in this laboratory indicate that positioned nucleosomes are present at the 5'- and 3'-flanking regions of HS-2. In addition, footprints were observed that indicated the involvement of DNA-binding proteins in positioning the nucleosome cores. A consensus GATA-1 site exists in the region of the 3'-footprint. In this study, using an electrophoretic mobility shift assay (EMSA) and DNase I footprinting, we confirmed that GATA-1 binds in vitro at the 3'-end of HS-2. An additional GATA-1 site was found to bind GATA-1 in vitro at a site positioned 40 bp upstream. At the 5'-end of HS-2, DNase I footprinting revealed a series of footprints showing a marked correlation with the in vivo footprints. EMSA indicated the presence of several erythroid-specific complexes in this region including GATA-1 binding. Sequence alignment for 12 mammalian species in HS-2 confirmed that the highest conservation to be in the HS-2 core. However, a second level of conservation extends from the core to the sites of the proposed positioning proteins at the HS-2 flanking regions, before declining rapidly. This indicates the importance of the HS-2 flanking regions and supports the proposal of nucleosome positioning proteins in these regions.

Subnuclear trafficking and gene targeting by steroid receptors

Through the use of novel imaging techniques, we have observed direct steroid receptor binding to a tandem array of a hormone-responsive promoter in living cells. We found that the glucocorticoid receptor (GR) exchanges rapidly with regulatory elements in the continued presence of ligand. We have also reconstituted a GR-dependent nucleoprotein transition with chromatin assembled on promoter DNA, and we discovered that GR is actively displaced from the chromatin template during the chromatin remodeling process. Using high-intensity UV laser crosslinking, we have observed highly periodic interactions of GR with promoter chromatin. These periodic binding events are dependent on GR-directed hSWI/SNF remodeling of the template and require the presence of ATP. Both the in vitro and in vivo results are consistent with a dynamic model ("hit-and-run") in which GR first binds to chromatin after ligand activation, recruits a remodeling activity, and is simultaneously lost from the template. We also find that receptor mobility in the nucleoplasm is strongly enhanced by molecular chaperones. These observations indicate that multiple mechanisms are involved in transient receptor interactions with nucleoplasmic targets.

Spatial contacts and nucleosome step movements induced by the NURF chromatin remodeling complex

The nucleosome remodeling factor NURF is a four-subunit, ISWI-containing chromatin remodeling complex that catalyzes nucleosome sliding in an ATP-dependent fashion, thereby modulating the accessibility of the DNA. To elucidate the mechanism of nucleosome sliding, we have investigated by hydroxyl radical footprinting how NURF makes initial contact with a nucleosome positioned at one end of a DNA fragment. NURF binds to two separate locations on the nucleosome: a continuous stretch of linker DNA up to the nucleosome entry site and a region asymmetrically surrounding the nucleosome dyad within the minor grooves, close to residues of the histone H4 tail that have been implicated in the activation of ISWI activity. Kinetic analysis reveals that nucleosome sliding occurs in apparent increments or steps of 10 bp. Furthermore, single nucleoside gaps as well as nicks about two helical turns before the dyad interfere with sliding, indicating that structural stress at this region assists the relative movement of DNA. These findings support a sliding model in which the position-specific tethering of NURF forces a translocating ISWI ATPase to pump a DNA distortion over the histone octamer, thereby changing the translational position of the nucleosome.

Anatomy of a hypersensitive site

The 600-bp accessible region at the activated PHO5 promoter in S. cerevisiae has become a paradigm for hypersensitive sites. In this review, we summarize the various experimental strategies used to characterize chromatin at the active promoter and point out their virtues and their limitations. We describe the properties of chromatin at the active PHO5 promoter and what we currently know about the transition from the inactive to the active state. The implications for generating a hypersensitive region in chromatin are discussed.

Linker Histone H1 Modulates Nucleosome Remodeling by Human SWI/SNF

Chromatin, a combination of nucleosomes and linker histones, inhibits transcription by blocking polymerase movement and access of factors to DNA. ATP-dependent remodeling complexes such as SWI/SNF and RSC alter chromatin structure to increase or decrease this repression. To further our understanding of how human SWI/SNF (hSWI/SNF) "remodels" chromatin we examined the octamer location, nature, and template specificity of hSWI/SNF-remodeled mononucleosomes when free or bound by linker histone H1. We find that, in the absence of H1, hSWI/SNF consistently moves nucleosomes to DNA ends, regardless of template sequence. On some sequences the repositioned histone octamer appears to be moved approximately 45 bp off the DNA edge, whereas on others it appears to be normal, suggesting that the nature of the remodeled nucleosome can be influenced by DNA sequence. By contrast, in the presence of histone H1, hSWI/SNF slides octamers to more central positions and does not promote nucleosome movement off the ends of the DNA. Our results indicate that the nature and position of hSWI/SNF products may be influenced both by DNA sequence and linker histone, and shed light on the roles of H1 and hSWI/SNF in modulating chromatin structure.

DNA sequence plays a major role in determining nucleosome positions in yeast CUP1 chromatin

The role of DNA sequence in determining nucleosome positions in vivo was investigated by comparing the positions adopted by nucleosomes reconstituted on a yeast plasmid in vitro using purified core histones with those in native chromatin containing the same DNA, described previously. Nucleosomes were reconstituted on a 2.5 kilobase pair DNA sequence containing the yeast TRP1ARS1 plasmid with CUP1 as an insert (TAC-DNA). Multiple, alternative, overlapping nucleosome positions were mapped on TAC-DNA. For the 58 positioned nucleosomes identified, the relative positioning strengths and the stabilities to salt and temperature were determined. These positions were, with a few exceptions, identical to those observed in native, remodeled TAC chromatin containing an activated CUP1 gene. Only some of these positions are utilized in native, unremodeled chromatin. These observations suggest that DNA sequence is likely to play a very important role in positioning nucleosomes in vivo. We suggest that events occurring in yeast CUP1 chromatin determine which positions are occupied in vivo and when they are occupied.

Hormone-induced nucleosome positioning in the MMTV promoter is reversible

The mouse mammary tumor virus (MMTV) promoter is induced by glucocorticoid hormone via the glucocorticoid receptor (GR). The hormone-triggered effects on MMTV transcription and chromatin structure were studied in Xenopus oocytes. We previously showed that the nucleosomes organizing the MMTV promoter became translationally positioned upon hormone induction. A single GR-binding site was necessary and sufficient for the chromatin events to occur, while transcription and basal promoter elements were dispensable. Here we show that addition of the hormone antagonists RU486 or RU43044 to the previously hormone-induced MMTV promoter results in cessation of transcription and loss of chromatin remodeling and nucleosome positioning. In vivo footprinting demonstrated agonist- and RU486-induced GR binding to its DNA response element (GRE), while the other antagonist, RU43044, did not promote GR-GRE interaction. These results demonstrate that induction and maintenance of nucleosome positioning is an active process that requires constant 'pressure' of agonist-GR-recruited chromatin-modifying factor(s) rather than GR-DNA binding itself.

Understanding nuclear receptor function: from DNA to chromatin to the interphase nucleus

The regulation of gene expression by steroid receptors is the fundamental mechanism by which these important bioregulatory molecules exert their action. As such, mechanisms utilized by receptors in the modulation of genetic expression have been intensively studied since the first identification of hormone-binding proteins. Although these mechanisms include both posttranscriptional (1) and posttranslational (2) components, the primary level of control involves direct modulation of the rate of transcription, and it is this process that has been the major focus of research in the field.

Use of digitonin-permeabilized cells in studies of steroid receptor subnuclear trafficking

The application of a cell permeabilization technique to the analysis of nuclear import has led to many major breakthroughs in our understanding of this trafficking pathway. Digitonin permeabilization maintains the nucleus in a state competent for faithful, signal-dependent translocation through the nuclear pore complex. This system has also been used to probe the mechanism of hormone-regulated nuclear import through the use of glucocorticoid receptors (GR) as a model substrate. In this report we provide detailed descriptions of the digitonin-permeabilized cell system for use in studies of GR nuclear import. In addition, we present several novel applications that expand the utility of this system to probe for mechanisms of nuclear protein export and subnuclear trafficking.

Nucleoprotein gel assays for nucleosome positioning and mobility

Recent recognition of the sensitivity of polyacrylamide gel electrophoresis to macromolecular conformation has provided a source of new applications. In chromatin research, nucleoprotein gel electrophoresis can yield a direct and visual estimate of the number and relative abundance of different positions adopted by the core histone octamer on DNA, as well as their locations relative to the middle of the DNA fragment. It is the only technique available for the fractionation of such nucleosome positioning isomers and leaves them intact. Thus this simple method constitutes a powerful tool to analyze and manipulate populations of variously positioned nucleosomes in their native state. Complementing conventional invasive enzymatic procedures that rely on the analysis of cutting patterns on nucleosomal DNA, these procedures are now revealing that histone octamers can reconstitute to a number of discrete, often overlapping, locations on most DNA sequences. Further capitalizing on these advantages of nucleoprotein gel analysis, the development of the technique into a two-dimensional assay has permitted a rare view at the dynamics of nucleosome positioning. Nucleosomes can redistribute between possible positions on DNA, with the distribution patterns of nucleosomes along the DNA being in dynamic equilibrium at 37 degrees in relatively low ionic strength conditions. This mobility of nucleosomes on DNA means that possible positions of nucleosomes can be defined precisely but that the actual locations of the nucleosomes are dynamic. It provides a compelling argument that a nucleosome position should be regarded as a probability rather than a static factor type of binding. This supports a more dynamic view of the nucleosomal organization, which seems more in accordance with the dynamic nature of gene expression. In providing the flexibility for adaptation, multiple positioning and nucleosome mobility could constitute essential ingredients of the mechanisms by which chromatin participates in gene regulation.

Functional interaction between the estrogen receptor and CTF1: analysis of the vitellogenin gene B1 promoter in yeast

Eukaryotic gene expression depends on a complex interplay between the transcriptional apparatus and chromatin structure. We report here a yeast model system for investigating the functional interaction between the human estrogen receptor (hER) and CTF1, a member of the CTF/NFI transcription factor family. We show that a CTF1-fusion protein and the hER transactivate a synthetic promoter in yeast in a synergistic manner. This interaction requires the proline-rich transactivation domain of CTF1. When the natural estrogen-dependent vitellogenin B1 promoter is tested in yeast, CTF1 and CTF1-fusion proteins are unable to activate transcription, and no synergy is observed between hER, which activates the B1 promoter, and these factors. Chromatin structure analysis on this promoter reveals positioned nucleosomes at -430 to -270 (+/-20 bp) and at -270 to - 100 (+/-20 bp) relative to the start site of transcription. The positions of the nucleosomes remain unchanged upon hormone-dependent transcriptional activation of the promoter, and the more proximal nucleosome appears to mask the CTF/NFI site located at - 101 to -114. We conclude that a functional interaction of hER with the estrogen response element located upstream of a basal promoter occurs in yeast despite the nucleosomal organization of this promoter, whereas the interaction of CTF1 with its target site is apparently precluded by a nucleosome.

Assembly of MMTV promoter minichromosomes with positioned nucleosomes precludes NF1 access but not restriction enzyme cleavage

To generate long arrays of nucleosomes within a topologically defined chromatin domain we have assembled minichromosomes on negatively supercoiled plasmid DNA with extracts from Drosophila preblastoderm embryos. These minichromosomes are dynamic substrates for energy-dependent nucleosome remodeling machines that facilitate the binding of various transcription factors but do not exhibit nucleosome positioning. In contrast, if such minichromosomes include the mouse mammary tumour virus (MMTV) promoter we find it wrapped around a nucleosome with similar translational and rotational position as in vivo . This structure precluded binding of NF1 to its cognate site at -75/-65 at salt concentrations between 60 and 120 mM, even in the presence of ATP, which rendered the NF1 site accessible to the restriction enzyme Hin fI. However, insertion of 30 bp just upstream of the NF1 site, which moves the site to the linker DNA, allowed ATP-dependent binding of NF1 to a fraction of the minichromosomes, even in the presence ofstoichiometric amounts of histone H1. The minichromosomes assembled in the Drosophila embryo extract reproduce important features of the native MMTV promoter chromatin and reveal differences in the ability of transcription factors and restriction enzymes to access their binding sites in positioned nucleosomes.

Structure, dynamics, and function of chromatin in vitro

The substrates for the essential biological processes of transcription, replication, recombination, DNA repair, and cell division are not naked DNA; rather, they are protein-DNA complexes known as chromatin, in one or another stage of a hierarchical series of compactions. These are exciting times for students of chromatin. New studies provide incontrovertible evidence linking chromatin structure to function. Exceptional progress has been made in studies of the structure of chromatin subunits. Surprising new dynamic properties have been discovered. And, much progress has been made in dissecting the functional roles of specific chromatin proteins and domains. This review focuses on in vitro studies of chromatin structure, dynamics, and function.

Unique translational positioning of nucleosomes on synthetic DNAs

A computational study was previously carried out to analyze DNA sequences that are known to position histone octamers at single translational sites. A conserved pattern of intrinsic DNA curvature was uncovered that was proposed to direct the formation of nucleosomes to unique positions. The pattern consists of two regions of curved DNA separated by preferred lengths of non-curved DNA. In the present study, 11 synthetic DNAs were constructed which contain two regions of curved DNA of the form [(A5.T5)(G/C)5]4 separated by non-curved regions of variable length. Translational mapping experiments of in vitro reconstituted mononucleosomes using exonuclease III, micrococcal nuclease and restriction enzymes demonstrated that two of the fragments positioned nucleosomes at a single site while the remaining fragments positioned octamers at multiple sites spaced at 10 base intervals. The synthetic molecules that positioned nucleosomes at a single site contain non-curved central regions of the same lengths that were seen in natural nucleosome positioning sequences. Hydroxyl radical and DNase I digests of the synthetic DNAs in reconstituted nucleosomes showed that the synthetic curved element on one side of the nucleosomal dyad assumed a rotational orientation where narrow minor grooves of the A-tracts faced the histone surface with all molecules. In contrast, the curved element on the other side of the nucleosome displayed variable rotational orientations between molecules which appeared to be related to the positioning effect. These results suggest that asymmetry between the two halves of nucleosomal DNA may facilitate translational positioning.

The mouse mammary tumour virus promoter positioned on a tetramer of histones H3 and H4 binds nuclear factor 1 and OTF1

Modulation of eukaryotic gene expression is influenced by the organization of regulatory DNA-elements in chromatin. The mouse mammary tumor virus (MMTV) promoter exhibits regularly positioned nucleosomes that reduce the accessibility of the binding sites for sequence-specific transcription factors, in particular nuclear factor (NF1). Hormonal induction of the MMTV promoter is accompanied by remodeling of the nucleosomal structure, but the biochemical nature of these structural changes is unknown. Using recombinant histones, we have now assembled the MMTV promoter in particles containing either an octamer of the histones H3, H4, H2A and H2B or a tetramer of histones H3 and H4, and have compared the two particles in terms of structure, positioning, and exclusion of transcription factors. Using site-directed hydroxy radicals to map histone locations, two main nucleosome positions are found with dyads at position -107 and at -127. The same two main positions are found for particles containing only the H3/H4 tetramer, showing that the absence of H2A/H2B dimers does not alter positioning. The rotational orientation of the DNA double helix in both types of particles is essentially identical. However, the ends of the nucleosomal DNA as well as its central region are more accessible to cleavage reagents in the tetramer particle than in the octamer particle. In agreement with these structural features, the transcription factors NF1 and OTF1 were able to bind to their cognate sites on the tetramer particle, while they could not gain access to the same sites on the surface of the octamer particle. The DNase I digestion pattern of octamers treated with partially purified SWI/SNF complex from HeLa cells in the presence of ATP is indistinguishable from that of tetramer particles, suggesting that the SWI/SNF complex promotes ATP-dependent remodeling of the octamer particle but not of tetramer particles. These results are compatible with a hormone-induced removal of histone H2A/H2B during MMTV induction.

(1,4,7-trimethyl-1,4,7-triazacyclononane)iron (III)-mediated cleavage of DNA: detection of selected protein-DNA interactions

A new reagent for the oxidative cleavage of DNA, (1,4,7-trimethyl-1, 4,7-triazacyclononane)iron(III) chloride was recently introduced. We have determined the utility of this reagent for detecting protein-DNA interactions within two types of complexes. Interestingly, we find that the rates of DNA cleavage by this reagent are differentially affected by the two classes of protein-DNA interactons studied. We find that the rate of DNA cleavage by this reagent is relatively unaffected by the non-sequence-specific histone-DNA interactions within a nucleosome complex. Conversely, a clear footprint pattern is obtained with two different DNA sequence-specific protein-DNA complexes. The results suggest that (1,4,7-trimethyl-1,4,7-triazacyclononane)iron(III) chloride will be a useful reagent to probe trans -acting-factor-DNA interactions within a chromatin environment. Differences between these two types of protein-DNA interactions, which might account for this observation, are discussed.

Positioning and stability of nucleosomes on MMTV 3'LTR sequences

Uniquely positioned nucleosomes were mapped in vitro on mouse mammary tumor 3' long terminal repeat (MMTV 3'LTR) DNA at base-pair resolution. Nucleosome A assembly was strongly favored over nucleosome B, and heating of each as a mononucleosome caused migration to the ends of the DNA fragment at a unique rate. Taken together with DNA sequence analysis, this suggests why MMTV 3'LTV nucleosome positions reported upstream of vector-derived sequences conflict and also how flanking genomic sequences could modulate the promoter in in vivo situations. Importantly, nucleosomes are shown to migrate for significant distances along DNA under physiologically relevant conditions, and the actual rates have been measured directly in solution. Exact positioning and shifting over greater than 60 bp has important consequences for transcription factor access to this MMTV promoter and for the role of nucleosomes in general.

Nucleosome positioning and transcription-associated chromatin alterations on the human estrogen-responsive pS2 promoter

The positioning of nucleosomes on a promoter is a significant determinant in its responsiveness to inducing signals. We have mapped the chromatin structure of the human, estrogen-responsive pS2 promoter at nucleotide level resolution within the context of its normal genomic location in human mammary epithelial cells. In vivo digestion by nucleases followed by ligation-mediated polymerase chain reaction analysis revealed two rotationally phased and translationally positioned nucleosomes within the promoter between nucleotide positions -450 and +7. The estrogen response elements at -400 and TATAA box at -35 are each located at the edge of a nucleosome. The two precisely positioned nucleosomes exist in both transformed and nontransformed human mammary epithelial cells, regardless of estrogen receptor status or transcriptional activity of the gene. However, two structural alterations correlate with the transcriptional potential of the promoter. In MCF-7 cells, in which the pS2 promoter is inducible, the chromatin exhibits an increased sensitivity to DNase I in a region of DNA adjacent to the TATAA box and an additional micrococcal nuclease-hypersensitive site in the linker DNA between the two positioned nucleosomes. We were also able to demonstrate that nucleotides -1100 to +10 of the pS2 promoter are sufficient to determine the positioning of these two nucleosomes. Our results establish the structural features of the chromatin covering the pS2 promoter as well as transcriptionally associated alterations, suggesting how the nucleosomal template influences transcriptional regulation by estrogen receptor.

Chromatin remodeling regulated by steroid and nuclear receptors

Coactivators and corepressors regulate transcription by controlling interactions between sequence-specific transcription factors, the basal transcriptional machinery and the chromatin environment. This review consider the access of nuclear and steroid receptors to chromatin, their use of corepressors and coactivators to modify chromatin structure and the implications for transcriptional control. The assembly of specific nucleoprotein architectures and targeted histone modification emerge as central controlling elements for gene expression.

Structural and functional features of a specific nucleosome containing a recognition element for the thyroid hormone receptor

The Xenopus thyroid hormone receptor betaA (TRbetaA) gene contains an important thyroid hormone response element (TRE) that is assembled into a positioned nucleosome. We determine the translational position of the nucleosome containing the TRE and the rotational positioning of the double helix with respect to the histone surface. Histone H1 is incorporated into the nucleosome leading to an asymmetric protection to micrococcal nuclease cleavage of linker DNA relative to the nucleosome core. Histone H1 association is without significant consequence for the binding of the heterodimer of thyroid hormone receptor and 9-cis retinoic acid receptor (TR/RXR) to nucleosomal DNA in vitro, or for the regulation of TRbetaA gene transcription following microinjection into the oocyte nucleus. Small alterations of 3 and 6 bp in the translational positioning of the TRE in chromatin are also without effect on the transcriptional activity of the TRbetaA gene, whereas a small change in the rotational position of the TRE (3 bp) relative to the histone surface significantly reduces the binding of TR/RXR to the nucleosome and decreases transcriptional activation directed by TR/RXR. Our results indicate that the specific architecture of the nucleosome containing the TRE may have regulatory significance for expression of the TRbetaA gene.

Binding of NF1 to the MMTV promoter in nucleosomes: influence of rotational phasing, translational positioning and histone H1

To analyse the role of rotational orientation and translational positioning of nucleosomal DNA on transcription factor binding we have generated a series of mutant MMTV promoters containing insertions of various lengths between the hormone-responsive region and the binding site for NF1. These various MMTV promoter fragments were assembled in mononucleosomes and used for structural studies and binding experiments. We show that the insertions change the rotational phase and translational positioning of the NF1 site as predicted if the sequences upstream of the insertion site were the main determinants of nucleosome phasing. In band shift experiments with recombinant NF1 we cannot detect binding of the protein to NF1 sites included within the limits of a nucleosome, independent of their rotational orientation. Moving the NF1 site closer to the nucleosome border also did not permit NF1 binding. This behaviour probably reflects the way NF1 binds DNA, namely it almost completely surrounds the circumference of the double helix establishing a large number of contacts with the bases and the backbone. In contrast to the wild-type and short insertion mutants, NF1 bound readily to nucleosomes containing 30 or 50 bp insertions which placed the NF1 site at the nucleosome edge or within linker DNA. NF1 binding to the linker DNA was unaffected by incorporation of histone H1 into the nucleosome particle. These findings are discussed in relation to chromatin remodelling initiated by steroid hormones during induction of the MMTV promoter.

The matrix attachment region-binding protein SATB1 participates in negative regulation of tissue-specific gene expression

The nuclear matrix has been implicated in several cellular processes, including DNA replication, transcription, and RNA processing. In particular, transcriptional regulation is believed to be accomplished by binding of chromatin loops to the nuclear matrix and by the concentration of specific transcription factors near these matrix attachment regions (MARs). A number of MAR-binding proteins have been identified, but few have been directly linked to tissue-specific transcription. Recently, we have identified two cellular protein complexes (NBP and UBP) that bind to a region of the mouse mammary tumor virus (MMTV) long terminal repeat (LTR) previously shown to contain at least two negative regulatory elements (NREs) termed the promoter-proximal and promoter-distal NREs. These NREs are absent from MMTV strains that cause T-cell lymphomas instead of mammary carcinomas. We show here that NBP binds to a 22-bp sequence containing an imperfect inverted repeat in the promoter-proximal NRE. Previous data showed that a mutation (p924) within the inverted repeat elevated basal transcription from the MMTV promoter and destabilized the binding of NBP, but not UBP, to the proximal NRE. By using conventional and affinity methods to purify NBP from rat thymic nuclear extracts, we obtained a single major protein of 115 kDa that was identified by protease digestion and partial sequencing analysis as the nuclear matrix-binding protein special AT-rich sequence-binding protein 1 (SATB1). Antibody ablation, distamycin inhibition of binding, renaturation and competition experiments, and tissue distribution data all confirmed that the NBP complex contained SATB1. Similar types of experiments were used to show that the UBP complex contained the homeodomain protein Cux/CDP that binds the MAR of the intronic heavy-chain immunoglobulin enhancer. By using the p924 mutation within the MMTV LTR upstream of the chloramphenicol acetyltransferase gene, we generated two strains of transgenic mice that had a dramatic elevation of reporter gene expression in lymphoid tissues compared with reporter gene expression in mice expressing wild-type LTR constructs. Thus, the 924 mutation in the SATB1-binding site dramatically elevated MMTV transcription in lymphoid tissues. These results and the ability of the proximal NRE in the MMTV LTR to bind to the nuclear matrix clearly demonstrate the role of MAR-binding proteins in tissue-specific gene regulation and in MMTV-induced oncogenesis.

In vitro reconstitution and analysis of mononucleosomes containing defined DNAs and proteins

Increasingly, biochemical analyses of processes that occur within eukaryotic nuclei such as transcription and replication require the construction of specific chromatin substrates. Nucleosome complexes reconstituted in vitro have been key elements in a variety of recent studies of polymerase progression and trans-acting factor binding activities. Reconstituted complexes can be easily constructed from purified components in quantities suitable for biochemical and biophysical studies. In addition, reconstituted mononucleosome complexes exhibit native biochemical and biophysical properties but necessarily contain much less heterogeneity with regard to both protein and DNA components than bulk complexes isolated from natural sources. This review details the protocols for reconstitution of model mononucleosome complexes that contain unique DNA sequences and specifically tailored core histone proteins and describes common pitfalls associated with these procedures.

How hormone receptor-DNA binding affects nucleosomal DNA: the role of symmetry

Molecular dynamics simulations have been employed to determine the optimal conformation of an estrogen receptor DNA binding domain dimer bound to a consensus response element, ds(AGGTCACAGTGACCT), and to a nonconsensus response element, ds(AGAACACAGTGACCT). The structures simulated were derived from a crystallographic structure and solvated by a sphere (45-A radius) of explicit water and counterions. Long-range electrostatic interactions were accounted for during 100-ps simulations by means of a fast multipole expansion algorithm combined with a multiple time-step scheme in the molecular dynamics package NAMD. The simulations demonstrate that the dimer induces a bent and underwound (10.7 bp/turn) conformation in the DNA. The bending reflects the dyad symmetry of the receptor dimer and can be described as an S-shaped curve in the helical axis of DNA when projected onto a plane. A similar bent and underwound conformation is observed for nucleosomal DNA near the nucleosome's dyad axis that reflects the symmetry of the histone octamer. We propose that when a receptor dimer binds to a nucleosome, the most favorable dimer-DNA and histone-DNA interactions are achieved if the respective symmetry axes are aligned. Such positioning of a receptor dimer over the dyad of nucleosome B in the mouse mammary tumor virus promoter is in agreement with experiment.

Nucleoprotein gel electrophoresis for the analysis of nucleosomes and their positioning and mobility on DNA

Nucleoprotein gel electrophoresis, as well as its use in chromatin research, is reviewed from its early application in the characterization of native nucleosome composition to current uses in analyzing transcription factor-nucleosome complexes and in visualizing multiple nucleosome positioning. Despite our incomplete understanding of the principles behind the separation of particles in native polyacrylamide, gels, powerful new applications of the method have emerged in recent years. This offers the potential for novel experimental strategies, such as those that have led to the discovery of nucleosome mobility.

Nucleosome-mediated synergism between transcription factors on the mouse mammary tumor virus promoter

In unstimulated mammalian cells and in Saccharomyces cerevisiae, the mouse mammary tumor virus (MMTV) promoter is silent and organized into positioned nucleosomes, one of which encompasses the binding sites for glucocorticoid receptor (GR) and nuclear factor I (NFI). Glucocorticoid induction in vivo involves a functional synergism between GR and NFI and simultaneous occupancy of the promoter sites for both proteins that cannot be reproduced on naked DNA. The role of chromatin in the process of induction was investigated by manipulating the nucleosome density in yeast strains carrying a regulated histone H4 gene. Following depletion of nucleosomes, independent transactivation by NFI or by GR, as well as binding of the individual proteins to the MMTV promoter, were enhanced, in agreement with a repressive function of nucleosomes. In contrast, NFI-dependent hormone induction of the promoter and the simultaneous binding of receptor and NFI were compromised by nucleosome depletion. This effect could be partly mediated by a cryptic binding site for the receptor that is functional only in the nucleosomal context. Thus, positioned nucleosomes do not only account for constitutive repression of the MMTV promoter, but also participate in induction by mediating cooperative binding and functional synergism between GR and NFI.

DNA damage can alter the stability of nucleosomes: effects are dependent on damage type

We have investigated the effects of DNA damage by (+/-)-anti-benzo[a]pyrene diol epoxide (BPDE) and UV light on the formation of a positioned nucleosome in the Xenopus borealis 5S rRNA gene. Gel-shift analysis of the reconstituted products indicates that BPDE damage facilitates the formation of a nucleosome onto this sequence. Competitive reconstitution experiments show that average levels of 0.5, 0.9, and 2.1 BPDE adducts/146 bp of 5S DNA (i.e., the size of DNA associated with a nucleosome core particle) yield changes of -220, -290, and -540 cal/mol, respectively, in the free energy (delta G) of nucleosome formation. These values yield increases of core histone binding to 5S DNA (K(a)) of 1.4-, 1.6-, and 2.5-fold, compared with undamaged DNA. Conversely, irradiation with UV light decreases nucleosome formation. Irradiation at either 500 or 2500 J/m2 of UV light [0.6 and 0.8 cyclobutane pyrimidine dimer/146 bp (on average), respectively] results in respective changes of +130 and +250 cal/mol. This translates to decreases in core histone binding to irradiated 5S DNA (K(a)) of 1.2- and 1.5-fold compared with undamaged DNA. These results indicate that nucleosome stability can be markedly affected by the formation of certain DNA lesions. Such changes could have major effects on the kinetics of DNA processing events.

Regulation of gene expression by nucleosomes

During the past year, the characterization of mechanisms and factors capable of disrupting nucleosomes during transcriptional activation has been a recurrent theme in studies which address the contribution of nucleosome structure to gene regulation. In vivo studies using yeast and Drosophila together with biochemical purification schemes using nucleosome perturbation assays have provided evidence for the existence of multiprotein complexes that are able to alleviate nucleosome repression. At the same time, new insights into the mechanism of heterochromatin formation have been gained, which have direct links to nucleosome structure.

Transcriptional regulation by steroid hormones

Steroid hormones influence the transcription of a large number of genes by virtue of their interaction with intracellular receptors, which are modular proteins composed of a ligand binding domain, a DNA binding domain, and several transactivation functions distributed along the molecule. The DNA binding domain is organized around two zinc ions and allows the receptors to bind as homodimers to palindromic DNA sequences, the hormones responsive elements (HRE), is such a way that each homodimer contacts one half of the palindrome. Since the two halves are separated by three base pairs, the two homodimers contact the same face of the double helix. Before hormone binding, the receptors are part of a complex with multiple chaperones which maintain the receptor in its steroid binding conformation. Following hormone binding, the complex dissociates and the receptors bind to HREs in chromatin. Regulation of gene expression by hormones involves an interaction of the DNA-bound receptors with other sequence-specific transcription factors and with the general transcription factors, which is partly mediated by co-activators and co-repressors. The specific array of cis regulatory elements in a particular promoter/enhancer region, as well as the organization of the DNA sequences in nucleosomes, specifies the network of receptor interactions. Depending on the nature of these interactions, the final outcome can be induction or repression of transcription. The various levels at which these interactions are modulated are discussed using as an example the promoter of the Mouse Mammary Tumor Virus and its organization in chromatin.