Chromatin reconstitution on small DNA rings. II. DNA supercoiling on the nucleosome

DNA supercoiling on the nucleosome was investigated by relaxing with topoisomerase I mono- and dinucleosomes reconstituted on small DNA rings. Besides 359 base-pair (bp) rings whose linking differences were integers, two additional series of rings with fractional differences, 341 and 354 bp in size, were used. Mononucleosomes reconstituted on 359 bp rings were found to relax into a single mononucleosome form. In contrast, 341 and 354 bp mononucleosomes relaxed into a mixture of two forms, corresponding to two adjacent topoisomers. The observation that the ratio between these two forms was, within each ring series, virtually independent of the initial linking number of the topoisomer used for the reconstitution suggested that each partition reflected an equilibrium. Comparison with the equilibria observed for the same rings in the absence of histones showed that the formation of a single nucleosome is associated with a linking number change of -1.1(+/-0.1) turn. Dinucleosomes, in contrast, were not relaxed to completion and do not reach equilibria. The corresponding linking number change per nucleosome was, however, estimated to be similar to the above figure, in agreement with previous data from the literature obtained with circular chromatins containing larger numbers of nucleosomes. DNA structure in mononucleosomes was subsequently investigated by means of high-resolution electron microscopy and gel electrophoresis. It was found that the above linking number reduction could be ascribed to a particle with a large open extranucleosomal DNA loop and with no more than 1.5 turns of a superhelix around the histone core. A theoretical model of a nucleosome on a small ring was constructed in which one part of the DNA was wrapped around a cylinder and the other part was free to vary both in torsion and flexion. The linking number reduction predicted was found to be most consistent with experimental data when the twist of the DNA in the superhelix was between 10.5 and 10.65 pb per turn, suggesting that wrapping on the nucleosome does not alter the twist of the DNA significantly. A lower estimate of the linking number reduction associated with a two-turn nucleosome was also derived, based on an analysis of recent data obtained upon treatment of reconstituted minichromosomes with gyrase. The value, 1.6 turns, set a lower limit of 10.44 bp per turn for the twist of nucleosomal DNA, in agreement with the above estimate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Functional role of extranucleosomal DNA and the entry site of the nucleosome in chromatin remodeling by ISW2

A minimal amount of extranucleosomal DNA was required for nucleosome mobilization by ISW2 as shown by using a photochemical histone mapping approach to analyze nucleosome movement on a set of nucleosomes with varied lengths of extranucleosomal DNA. ISW2 was ineffective in repositioning or mobilizing nucleosomes with 相似文献   

The RSC chromatin remodelling enzyme has a unique role in directing the accurate positioning of nucleosomes

Nucleosomes impede access to DNA. Therefore, nucleosome positioning is fundamental to genome regulation. Nevertheless, the molecular nucleosome positioning mechanisms are poorly understood. This is partly because in vitro reconstitution of in vivo-like nucleosome positions from purified components is mostly lacking, barring biochemical studies. Using a yeast extract in vitro reconstitution system that generates in vivo-like nucleosome patterns at S. cerevisiae loci, we find that the RSC chromatin remodelling enzyme is necessary for nucleosome positioning. This was previously suggested by genome-wide in vivo studies and is confirmed here in vivo for individual loci. Beyond the limitations of conditional mutants, we show biochemically that RSC functions directly, can be sufficient, but mostly relies on other factors to properly position nucleosomes. Strikingly, RSC could not be replaced by either the closely related SWI/SNF or the Isw2 remodelling enzyme. Thus, we pinpoint that nucleosome positioning specifically depends on the unique properties of the RSC complex.     

Reconstitution experiments show that sequence-specific histone-DNA interactions are the basis for nucleosome phasing on mouse satellite DNA

The molecular basis underlying the sequence-specific positioning of nucleosomes on DNA was investigated. We previously showed that histone octamers occupy multiple specific positions on mouse satellite DNA in vivo and have now reconstituted the 234 bp mouse satellite repeat unit with pure core histones into mononucleosomes. Histones from mouse liver or chicken erythrocytes bind to the DNA in multiple precisely defined frames in perfect phase with a diverged 9 bp subrepeat of the satellite DNA. This is the first time that nucleosome positions on a DNA in vivo have been compared to those found on the same DNA by in vitro reconstitution. Most of the nucleosomes occupy identical positions in vivo and in vitro. There are, however, some characteristic differences. We conclude that sequence-dependent histone-DNA interactions play a decisive role in the positioning of nucleosomes in vivo, but that the nucleosome locations in native chromatin are subject to additional constraints.     

The in vitro reconstitution of nucleosome and its binding patterns with HMG1／2 and HMG14／17 proteins

Using atomic force microscopy (AFM), the dynamic process of the in vitro nucleosome reconstitution followed by slow dilution from high salt to low salt was visualized. Data showed that the histone octamers were dissociatedfrom DNA at 1M NaC1. When the salt concentration was slowly reduced to 650 mM and 300 mM, the core histones bound to the naked DNA gradually. Once the salt concentration was reduced to 50 mM the classic “beads-on-a-string“ structure was clearly visualized. Furthermore, using the technique of the in vitro reconstitution of nucleosome,the mono- and di- nucleosomes were assembled in vitro with both HS2core (-10681 to -10970 bp) and NCR2 (-372to -194 bp) DNA sequences in the 5‘flanking sequence of human b-globin gene. Data revealed that HMG 1/2 and HMG 14/17 proteins binding to both DNA sequences are changeable following the assembly and disassembly of nucleosomes. We suggest that the changeable binding patterns of HMG 14/17 and HMG1/2 proteins with these regulatory elements may be critical in the process of nucleosome assembly, recruitment of chromatin-modifying activities, and the regulation of human b-globin gene expression.     

Structural features of a regulatory nucleosome

DNA sequences from the long terminal repeat of the mouse mammary tumor virus (MMTV-LTR) position nucleosomes both in vivo and in vitro. Here, were present chromatin reconstitution experiments showing that MMTV-LTR sequences from -236 to +204 accommodate two histone octamers in positions compatible with the in vivo data. This positioning is not influenced by the length of the DNA fragment and occurs in linear as well as in closed circular DNA molecules. MMTV-LTR DNA sequences show an intrinsic bendability that closely resembles its wrapping around the histone octamer. We propose that bendability is responsible for the observed rotational nucleosome positioning. Translational nucleosome positioning seems also to be determined by the DNA sequence. These data, along with the results from reconstitution experiments with insertion mutants, support a modular model of nucleosome phasing on MMTV-LTR, where the actual positioning of the histone octamer results from the additive effect of multiple features of the DNA sequence.     

DNA-histone interactions are sufficient to position a single nucleosome juxtaposing Drosophila Adh adult enhancer and distal promoter.

The alcohol dehydrogenase gene (Adh) of Drosophila melanogaster is transcribed from two tandem promoters in distinct developmental and tissue-specific patterns. Both promoters are regulated by separate upstream enhancer regions. In its wild-type context the adult enhancer specifically stimulates only the distal promoter, approximately 400 bp downstream, and not the proximal promoter, which is approximately 700 bp further downstream. Genomic footprinting and micrococcal nuclease analyses have revealed a specifically positioned nucleosome between the distal promoter and adult enhancer. In vitro reconstitution of this nucleosome demonstrated that DNA-core histone interactions alone are sufficient to position the nucleosome. Based on this observation and sequence periodicities in the underlying DNA, the mechanism of positioning appears to involve specific DNA structural features (ie flexibility or curvature). We have observed this nucleosome positioned early during development, before tissue differentiation, and before non-histone protein-DNA interactions are established at the distal promoter or adult enhancer. This nucleosome positioning element in the Adh regulatory region could be involved in establishing a specific tertiary nucleoprotein structure that facilitates specific cis-element accessibility and/or distal promoter-adult enhancer interactions.     

RSC unravels the nucleosome

RSC and SWI/SNF chromatin-remodeling complexes were previously reported to generate a stably altered nucleosome. We now describe the formation of hybrids between nucleosomes of different sizes, showing that the stably altered structure is a noncovalent dimer. A basis for dimer formation is suggested by an effect of RSC on the supercoiling of closed, circular arrays of nucleosomes. The effect may be explained by the interaction of RSC with DNA at the ends of the nucleosome, which could lead to the release 60--80 bp or more from the ends. DNA released in this way may be trapped in the stable dimer or lead to alternative fates such as histone octamer transfer to another DNA or sliding along the same DNA molecule.     

Modified curved DNA that could allow local DNA underwinding at the nucleosomal pseudodyad fails to position a nucleosome in vivo.

In competitive in vitro reconstitution experiments synthetic DNA composed of tandem repeats of the repetitive sequence (A/T)3NN(G/C)3NN, specifically the 20 bp 'TG sequence' (5'-TCGGTGTTAGAGCCTGTAAC-3'), was reported to associate with the histone octamer with an affinity higher than that of nucleosomally derived DNA. However, at least two groups have independently shown that tandem repeats of the TG sequence do not accommodate a stably positioned nucleosome in vivo. It was suggested that the anisotropic flexibility of the TG sequence, governed by a 10 bp sequence periodicity, is incompatible with the required underwinding of the DNA helix at the nucleosome pseudodyad while maintaining a bending preference that can be accommodated in the remainder of the nucleosome. Here we test this hypothesis directly by studying the in vivo nucleosomal structure of modified TG sequences designed to accommodate underwinding at the pseudodyad. We show that these modifications are not sufficient to allow stable incorporation of the TG sequence repeat into a nucleosome in vivo, but do note invasion from one end of the TG heptamer of a translationally random but rotationally constrained nucleosome. We discuss possible reasons for the absence of nucleosomes from the TG sequence in vivo.     

Chromatin structure at the 3'-boundary of the human beta-globin locus control region hypersensitive site-2

Chromatin structure was examined at the 3′-boundary region of the human β-globin locus control region hypersensitive site-2 (LCR HS-2) using several footprinting agents. Erythroid K562 cells (possessing HS-2) were damaged by the footprinting agents: hedamycin, bleomycin and four nitrogen mustard analogues. Purified DNA and non-erythroid HeLa cells (lacking HS-2) were also damaged as controls for comparison with K562 cells. The comparison between intact cells and purified DNA showed several protected regions in K562 cells. A large erythroid-specific protected region of 135 bp was found at the boundary of HS-2. The length of this protected region (135 bp) was close to that of DNA contained in a nucleosome core (146 bp). Another two protected regions were found upstream of the protected region. A 16-bp erythroid-specific footprint co-localised with a GATA-1 motif—this indicated that the GATA-1 protein could be involved in positioning the nucleosome. Further upstream, a 100-bp footprint coincided with an AT-rich region. Thus our footprinting results suggest that the 3′-boundary of LCR HS-2 is flanked by a positioned nucleosome and that an erythroid-specific protein binds to the sequence adjacent to the nucleosome and acts to position the nucleosome at the boundary of the hypersensitive site.     

Isolation,characterization, and structure of the folded interphase genome of Drosophila melanogaster

The intact interphase genome of Drosophila melanogaster has been isolated by sucrose gradient centrifugation after gentle lysis of tissue culture cells in 0.9 M NaCl-0.4% Nonidet P40. The nonviscous folded DNA sediments as a single broad 5000S peak in a complex with RNA (a fraction of the nuclear nascent RNA) and protein (all of the four intranucleosome histones: H2A, H2B, H3, and H4).The folded DNA is supercoiled and can be relaxed to slower sedimenting forms either by intercalating ethidium or by nicking with DNAase I. Incomplete DNAase treatment gives partially relaxed complexes, indicating that each nick relaxes only a stretch of DNA (defined as a supercoiled DNA loop) without affecting the superhelical content of the rest of the genome. The concentration of superhelices in the Drosophila folded DNA is the same as in the E. coli and SV40 closed circular DNAs—that is, about one negative turn every 200 base pairs (bp) in 0.15 M NaCl at 26°C. The estimated average size of the supercoiled DNA loops, about 85,000 bp, equals the size of the larger Drosophila chromomeres.Ethidium intercalation in 0.9 M NaCl both removes the negative superhelical turns and dissociates the four histones from the DNA. The four histones are dissociated in equimolar concentrations, and the relative proportion of histones displaced from the DNA is a function of ethidium concentration. The histones are completely dissociated from the folded DNA at the ethidium concentration which removes all of the negative superhelices. Thus the data strongly suggest that the rotation of the Watson Crick helix which accompanies ethidium intercalation causes the loss of nucleosomes from the DNA.The results are interpreted in terms of a model for the folded Drosophila genome which has the DNA constrained (by both protein-DNA and RNA-DNA interactions) into independent supercoiled loops containing on the average 400 nucleosomes per loop. Each nucleosome is composed of a histone core with the DNA wound around it in a 360° left-handed toroidal supercoil; each nucleosome toroidal supercoil plus its relaxed internucleosome DNA contains, on the average, 200 bp.     

Interactions between HMG proteins and the core sequence of DNaseI hypersensitive site 2 in the locus control region (LCR) of the human β-like globin gene cluster

HMG proteins are abundant chromosomal non-histone proteins. It has been suggested that the HMG proteins may play an important role in the structure and function of chromatin. In the present study, the binding of HMG proteins (HMG1/2 and HMG14/17) to the core DNA sequence of DNaseI hypersensitive site 2 (HS2core DNA sequence, -10681--10970 bp) in the locus control region (LCR) of the human b-like globin gene cluster has been examined by using both the in vitro nucleosome reconstitution and the gel mobility shift assays. Here we show that HMG1/2 can bind to the naked HS2core DNA sequence, however, HMG14/17 cannot. Using the in vitro nucleosome reconstitution we demonstrate that HMG14/17 can bind to the HS2core DNA sequence which is assembled into nucleosomes with the core histone octamer transferred from chicken erythrocytes. In contrast, HMG1/2 cannot bind to the nucleosomes reconstituted in vitro with the HS2core DNA sequence. These results indicate that the binding patterns between HMG proteins and the HS2core DNA sequence which exists in different states (the naked DNA or the in vitro reconstituted nucleosomal DNA) are quite different. We speculate that HMG proteins might play a critical role in the regulation of the human β-like globin gene's expression.     

Micrococcal nuclease does not substantially bias nucleosome mapping

We have mapped sequence-directed nucleosome positioning on genomic DNA molecules using high-throughput sequencing. Chromatins, prepared by reconstitution with either chicken or frog histones, were separately digested to mononucleosomes using either micrococcal nuclease (MNase) or caspase-activated DNase (CAD). Both enzymes preferentially cleave internucleosomal (linker) DNA, although they do so by markedly different mechanisms. MNase has hitherto been very widely used to map nucleosomes, although concerns have been raised over its potential to introduce bias. Having identified the locations and quantified the strength of both the chicken or frog histone octamer binding sites on each DNA, the results obtained with the two enzymes were compared using a variety of criteria. Both enzymes displayed sequence specificity in their preferred cleavage sites, although the nature of this selectivity was distinct for the two enzymes. In addition, nucleosomes produced by CAD nuclease are 8-10 bp longer than those produced with MNase, with the CAD cleavage sites tending to be 4-5 bp further out from the nucleosomal dyad than the corresponding MNase cleavage sites. Despite these notable differences in cleavage behaviour, the two nucleases identified essentially equivalent patterns of nucleosome positioning sites on each of the DNAs tested, an observation that was independent of the histone type. These results indicate that biases in nucleosome positioning data collected using MNase are, under our conditions, not significant.     

A phase relationship associates tRNA structural gene sequences with nucleosome cores

DNA (760 bp) isolated from nucleosome tetramers of staphylococcal nuclease-digested chicken embryo chromatin was highly enriched for tRNA genes and subsequently cloned in E. coli chi 1776. The location of genes coding for chicken embryo tRNALys, tRNAPhe and tRNAiMet within the cloned nucleosome tetramer DNA was determined using restriction endonucleases for which single cleavage sites could be predicted from the respective tRNA base sequence. All our tRNA genes reside nonrandomly at four locations on nucleosome tetramer DNA. The spacing between the tRNA gene locations is approximately 190 bp, similar to the DNA repeat length of chicken embryo chromatin. The four tRNA gene locations were also defined in noncloned nucleosome tetramer DNA highly enriched for tRNA genes. The majority of genes coding for tRNALys, tRNAPhe and tRNAiMet, respectively, are located in equal proportion 40-45, 230, 420 and 610 bp distant from the 5' end of the tRNA-identical strand. Thus the tRNA structural gene sequences all appear to begin about 20 bp "inside" the nucleosome core. As observed with nucleosomal DNA not enriched for tRNA genes, the phase relationship between tRNA genes and nucleosome location is maintained over a distance of 4-6 subsequent nucleosomes. A cloned molecule of nucleosomal DNA containing both a tRNALys gene and a tRNAiMet gene in the same polarity reveals that a phase adjustment might be necessary for the nucleosomes between these two tRNA genes in chicken embryo chromatin.     

A large "footprint" at the boundary of the human beta-globin locus control region hypersensitive site-2

The 5'-boundary region of the human beta-globin locus control region hypersensitive site-2 (HS-2) was examined for protein-DNA interactions. The HS-2 is an erythroid specific DNase I hypersensitive site that extends for approximately 600 bp. Erythroid K562 cells and non-erythroid HeLa cells were damaged by bleomycin and hedamycin--these agents are able to "footprint" nucleosome cores and proteins bound to DNA. The fragments generated by DNA damage were amplified by the ligation-mediated polymerase chain reaction with primers specific for the 5'-boundary region of HS-2 and examined at base pair resolution on DNA sequencing gels. The intensity of damage in intact cells was compared with that in purified DNA. The comparison between intact cells and purified DNA revealed a protected region of 226 bp with bleomycin and 182 bp with hedamycin in K562 cells. The length of the protected region was consistent with the presence of a nucleosome core. We postulate that an erythroid-specific protein binds next to the positioned nucleosome at the boundary of HS-2 to prevent sliding of the nucleosome into the hypersensitive site--this would also account for the large size of the protected region. HeLa cells (lacking a hypersensitive site in the beta-globin cluster) did not have an area of protection in this region.