Nucleosomes are positioned on mouse satellite DNA in multiple highly specific frames that are correlated with a diverged subrepeat of nine base-pairs

Switching between Epigenetic States at Pericentromeric Heterochromatin

Pericentromeric DNA represents a large fraction of the mammalian genome that is usually assembled into heterochromatin. Recent advances have revealed that the composition of pericentromeric heterochromatin is surprisingly dynamic. Indeed, high levels of histone H3 trimethylation on lysine 9 (H3K9me3) and DNA methylation normally characterize the repressive environment of this region. However, in specific tissues and in cancer cells, Polycomb proteins can occupy pericentromeric heterochromatin and act as a molecular sink for transcriptional regulators. Restoring heterochromatin methylation marks could, thus, be an important way to bring back normal gene expression programs in disease. Here, I discuss the potential mechanisms by which Polycomb complexes are recruited to pericentromeric DNA.

Molecular and physical characterization of the complex pericentromeric heterochromatin of the vole species Microtus thomasi

A new repeated DNA from Microtus thomasi, Mth-Alu2.2, was cloned and characterized and is presented here for the first time. Digestion of genomic DNA from M. thomasi with AluI restriction enzyme revealed a 2.2-kb repetitive DNA sequence with a high AT content (69%). This sequence consists of a tandemly repeated nonanucleotide of the consensus sequence CACAATGTA, which constitutes approximately 93-95% of the total unit length. The location of the Mth-Alu2.2 sequence in the karyotype was determined by FISH, demonstrating strong hybridization signals in the pericentromeric regions of all chromosomes and in the heterochromatin blocks of several X chromosome variants. In addition, the distribution of the 4 pericentromeric repeat sequences Msat-160, Mth-Alu900, Mth-Alu2.2, and interstitial telomeric repeats was analyzed by in situ hybridization in M. thomasi, in order to shed light on the complex composition of the chromosomal pericentromeric regions in this species. The order and organization of these sequences in the pericentromeric regions are conserved, with slight variations in both the degree of overlapping and the amount of each repeated DNA in the chromosomes. Specifically, Mth-Alu2.2 is localized in the terminal regions of the chromosomes, with Msat-160 occupying the immediately inner region, partially intermixed with Mth-Alu2.2. The sequence Mth-Alu900 is found in internal positions below Msat-160, and the interstitial telomeric repeats are located close to the long-arm euchromatin of the chromosomes.

Regulation of the nucleosome repeat length in vivo by the DNA sequence, protein concentrations and long-range interactions

The nucleosome repeat length (NRL) is an integral chromatin property important for its biological functions. Recent experiments revealed several conflicting trends of the NRL dependence on the concentrations of histones and other architectural chromatin proteins, both in vitro and in vivo, but a systematic theoretical description of NRL as a function of DNA sequence and epigenetic determinants is currently lacking. To address this problem, we have performed an integrative biophysical and bioinformatics analysis in species ranging from yeast to frog to mouse where NRL was studied as a function of various parameters. We show that in simple eukaryotes such as yeast, a lower limit for the NRL value exists, determined by internucleosome interactions and remodeler action. For higher eukaryotes, also the upper limit exists since NRL is an increasing but saturating function of the linker histone concentration. Counterintuitively, smaller H1 variants or non-histone architectural proteins can initiate larger effects on the NRL due to entropic reasons. Furthermore, we demonstrate that different regimes of the NRL dependence on histone concentrations exist depending on whether DNA sequence-specific effects dominate over boundary effects or vice versa. We consider several classes of genomic regions with apparently different regimes of the NRL variation. As one extreme, our analysis reveals that the period of oscillations of the nucleosome density around bound RNA polymerase coincides with the period of oscillations of positioning sites of the corresponding DNA sequence. At another extreme, we show that although mouse major satellite repeats intrinsically encode well-defined nucleosome preferences, they have no unique nucleosome arrangement and can undergo a switch between two distinct types of nucleosome positioning.

The CentO satellite confers translational and rotational phasing on cenH3 nucleosomes in rice centromeres

Plant and animal centromeres comprise megabases of highly repeated satellite sequences, yet centromere function can be specified epigenetically on single-copy DNA by the presence of nucleosomes containing a centromere-specific variant of histone H3 (cenH3). We determined the positions of cenH3 nucleosomes in rice (Oryza sativa), which has centromeres composed of both the 155-bp CentO satellite repeat and single-copy non-CentO sequences. We find that cenH3 nucleosomes protect 90-100 bp of DNA from micrococcal nuclease digestion, sufficient for only a single wrap of DNA around the cenH3 nucleosome core. cenH3 nucleosomes are translationally phased with 155-bp periodicity on CentO repeats, but not on non-CentO sequences. CentO repeats have an ∼10-bp periodicity in WW dinucleotides and in micrococcal nuclease cleavage, providing evidence for rotational phasing of cenH3 nucleosomes on CentO and suggesting that satellites evolve for translational and rotational stabilization of centromeric nucleosomes.

High-resolution mapping of h1 linker histone variants in embryonic stem cells

H1 linker histones facilitate higher-order chromatin folding and are essential for mammalian development. To achieve high-resolution mapping of H1 variants H1d and H1c in embryonic stem cells (ESCs), we have established a knock-in system and shown that the N-terminally tagged H1 proteins are functionally interchangeable to their endogenous counterparts in vivo. H1d and H1c are depleted from GC- and gene-rich regions and active promoters, inversely correlated with H3K4me3, but positively correlated with H3K9me3 and associated with characteristic sequence features. Surprisingly, both H1d and H1c are significantly enriched at major satellites, which display increased nucleosome spacing compared with bulk chromatin. While also depleted at active promoters and enriched at major satellites, overexpressed H1⁰ displays differential binding patterns in specific repetitive sequences compared with H1d and H1c. Depletion of H1c, H1d, and H1e causes pericentric chromocenter clustering and de-repression of major satellites. These results integrate the localization of an understudied type of chromatin proteins, namely the H1 variants, into the epigenome map of mouse ESCs, and we identify significant changes at pericentric heterochromatin upon depletion of this epigenetic mark.

Embryonic stem cells (ESCs) possess unique chromatin and epigenetic signatures, which are important in defining the identity and genome plasticity of pluripotent stem cells. Although ESC epigenomes have been extensively characterized, the genome localization of histone H1 variants, the chromatin structural proteins facilitating higher-order chromatin folding, remains elusive. Linker histone H1 is essential for mammalian development and regulates the expression of specific genes in ESCs. Here, by using a knock-in system coupled with ChIP–seq, we first achieve the high resolution mapping of two H1 variants on a genome-wide scale in mouse ESCs. Our study reveals the correlations of this underexplored histone family with other epigenetic marks and genome attributes. Surprisingly, we identify a dramatic enrichment of H1d and H1c at major satellite sequences. H1⁰, mapped using an overexpressing ESC line, shows similar features at active promoters but differential binding at repetitive sequences compared with H1d and H1c. Furthermore, using mutant ESCs that are deficient for multiple H1 variants, we demonstrate the role of H1 in chromocenter clustering and transcriptional repression of major satellites. Thus, these results connect this important repressive mark with the well understood ESC epigenome and identify novel functions of H1 in mammalian genome organization.

Proximity of H2A.Z containing nucleosome to the transcription start site influences gene expression levels in the mammalian liver and brain

Nucleosome positioning maps of several organisms have shown that Transcription Start Sites (TSSs) are marked by nucleosome depleted regions flanked by strongly positioned nucleosomes. Using genome-wide nucleosome maps and histone variant occupancy in the mouse liver, we show that the majority of genes were associated with a single prominent H2A.Z containing nucleosome in their promoter region. We classified genes into clusters depending on the proximity of H2A.Z to the TSS. The genes with no detectable H2A.Z showed lowest expression level, whereas H2A.Z was positioned closer to the TSS of genes with higher expression levels. We confirmed this relation between the proximity of H2A.Z and expression level in the brain. The proximity of histone variant H2A.Z, but not H3.3 to the TSS, over seven consecutive nucleosomes, was correlated with expression. Further, a nucleosome was positioned over the TSS of silenced genes while it was displaced to expose the TSS in highly expressed genes. Our results suggest that gene expression levels in vivo are determined by accessibility of the TSS and proximity of H2A.Z.

Nucleosome positioning, nucleosome spacing and the nucleosome code

Nucleosome positioning has been the subject of intense study for many years. The properties of micrococcal nuclease, the enzyme central to these studies, are discussed. The various methods used to determine nucleosome positions in vitro and in vivo are reviewed critically. These include the traditional low resolution method of indirect end-labelling, high resolution methods such as primer extension, monomer extension and nucleosome sequencing, and the high throughput methods for genome-wide analysis (microarray hybridisation and parallel sequencing). It is established that low resolution mapping yields an averaged chromatin structure, whereas high resolution mapping reveals the weighted superposition of all the chromatin states in a cell population. Mapping studies suggest that yeast DNA contains information specifying the positions of nucleosomes and that this code is made use of by the cell. It is proposed that the positioning code facilitates nucleosome spacing by encoding information for multiple alternative overlapping nucleosomal arrays. Such a code might facilitate the shunting of nucleosomes from one array to another by ATP-dependent chromatin remodelling machines.

Repair of UV lesions in nucleosomes--intrinsic properties and remodeling

Nucleotide excision repair and reversal of pyrimidine dimers by photolyase (photoreactivation) are two major pathways to remove UV-lesions from DNA. Here, it is discussed how lesions are recognized and removed when the DNA is condensed into nucleosomes. During the recent years it was shown that nucleosomes inhibit photolyase and excision repair in vitro and slow down repair in vivo. The correlation of DNA-repair rates with nucleosome positions in yeast suggests that intrinsic properties of nucleosomes such as mobility and transient unwrapping of nucleosomal DNA facilitate damage recognition. Moreover, it was shown that nucleosome remodeling activities can act on UV-damaged DNA in vitro and facilitate repair suggesting that random remodeling of chromatin might contribute to damage recognition in vivo. Recent work on nucleosome structure and mobility is included to evaluate how nucleosomes accommodate DNA lesions and how nucleosome mobility and remodeling can take place on damaged DNA.

Characterization of an EcoRI family of satellite DNA from two species of the genus Eptesicus (Vespertilionidae; Chiroptera)

We have cloned and sequenced a 321 bp band of repetitive DNA from Eptesicus fuscus and E. serotinus observed after gel electrophoresis of EcoRI digested genomic DNA in both species. Southern blot analysis of genomic DNA (from both species) digested with the same enzyme showed the existence of a ladder pattern indicating that the repetitive DNA is arrayed in tandem. The repetitive sequences have a monomer unit of 321 bp which is composed of two subunits of 160 bp, suggested by the existence of a 160 bp band in the ladder of E. fuscus and by the presence of some direct repeats found in the analysis of the consensus sequence. Analysis of the methylation status demonstrated that cytosines in CCGG sequences in this satellite DNA are methylated in E. fuscus but not in the E. serotinus. Alignment of the sequenced clones showed that several nucleotide positions are diagnostic species-specific and consequently the phylogenetic analysis grouped the monomer units from both species in two clearly separated groups.

Pericentric satellite DNA sequences in Pipistrellus pipistrellus (Vespertilionidae; Chiroptera)

This paper reports the molecular and cytogenetic characterization of a HindIII family of satellite DNA in the bat species Pipistrellus pipistrellus. This satellite is organized in tandem repeats of 418 bp monomer units, and represents approximately 3% of the whole genome. The consensus sequence from five cloned monomer units has an A-T content of 62.20%. We have found differences in the ladder pattern of bands between two populations of the same species. These differences are probably because of the absence of the target sites for the HindIII enzyme in most monomer units of one population, but not in the other. Fluorescent in situ hybridization (FISH) localized the satellite DNA in the pericentromeric regions of all autosomes and the X chromosome, but it was absent from the Y chromosome. Digestion of genomic DNAs with HpaII and its isoschizomer MspI demonstrated that these repetitive DNA sequences are not methylated. Other bat species were tested for the presence of this repetitive DNA. It was absent in five Vespertilionidae and one Rhinolophidae species, indicating that it could be a species/genus specific, repetitive DNA family.

Aspects of nucleosomal positional flexibility and fluidity

Nucleosomes have been considered until recently to be stable and uniquely localized particles. We focus here on two properties of nucleosomes that are emerging as central attributes of their functions: mobility and multiplicity of localization. The biological relevance of these phenomena is based on the fact that chromatin functions depend on the relative stability of nucleosomes, on their covalent or conformational modifications, their dynamics, their localization, and the density of their distribution. In order to understand these complex behaviors both the structure of the nucleosome core particles and the informational rules governing their interaction with defined DNA sequences are here taken into consideration. The fact that nucleosomes solve the problem of how to locate a specific interaction site on a potentially infinite combination of sequences, with interactions recurring to a controlled level of informational ambiguity and stochasticity, is discussed. Nucleosomes have been shown to slide along DNA. This novel facet of their behavior and its implications in chromatin remodeling are reviewed.

In vivo changes of nucleosome positioning in the pretranscription state

The involvement of chromatin structure and organization in transcriptional regulatory pathways has become evident. One unsolved question concerns the molecular mechanisms of chromatin remodeling during in vivo promoter activation. By using a high resolution in vivo analysis we show that when yeast cells are exposed to a regulatory signal the positions of specific nucleosomes change. The system analyzed consists of the basic elements of the Saccharomyces cerevisiae ADH2 promoter, two nucleosomes of which are shown to change the distribution of their positions by few nucleotides in the direction of transcription when the glucose content of the medium is lowered. Such repositioning does not occur in the absence of the ADH2 transcriptional activator Adr1 or in the presence of its DNA-binding domain alone. A construct consisting of the DNA-binding domain plus a 43-amino acid peptide containing the Adr1 activation domain is sufficient to induce the same effect of the full-length protein. Nucleosome repositioning occurs even when the catalytic activity of the RNA polymerase II is impaired, suggesting that the Adr1 activation domain mediates the recruitment of some factor to correctly preset the relevant sequences for the subsequent transcription steps.

Distinctive higher-order chromatin structure at mammalian centromeres

The structure of the higher-order chromatin fiber has not been defined in detail. We have used a novel approach based on sucrose gradient centrifugation to compare the conformation of centromeric satellite DNA-containing higher-order chromatin fibers with bulk chromatin fibers obtained from the same mouse fibroblast cells. Our data show that chromatin fibers derived from the centromeric domain of a chromosome exist in a more condensed structure than bulk chromatin whereas pericentromeric chromatin fibers have an intermediate conformation. From the standpoint of current models, our data are interpreted to suggest that satellite chromatin adopts a regular helical conformation compatible with the canonical 30-nm chromatin fiber whereas bulk chromatin fibers appear less regularly folded and are perhaps intermittently interrupted by deformations. This distinctive conformation of the higher-order chromatin fiber in the centromeric domain of the mammalian chromosome could play a role in the formation of heterochromatin and in the determination of centromere identity.

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.

Molecular cloning of a widely distributed microsatellite core sequence from the cultivated mushroom Agaricus bisporus

An Agaricus bisporus microsatellite with the tetranucleotide motif TATG tandemly repeated was isolated from an A. bisporus library enriched in repeated sequences. The use of the 16-mer oligonucleotide (TATG)4 indicates that many loci contain nearby copies of the microsatellite in opposite orientations. The wide distribution of the microsatellite in the A. bisporus genome was assessed (i) by polyacrylamide gel electrophoresis of the products generated by directed amplification of microsatellite-region DNA (DAMD) and (ii) by hybridization of these products with A. bisporus chromosomes separated by pulsed-field gel electrophoresis. This is, to our knowledge, the first microsatellite reported in the cultivated edible mushrooms. DAMD-PCR products were generated using DNA of three Pleurotus species (P. pulmonarius, P. sajor-caju, and P. florida), indicating that (TATG)4 repeats are also present in these cultivated species. The variability found within closely related strains indicates that such microsatellites are useful in fingerprinting and studying genetic variability in wild and commercial mushrooms.

In vitro reconstitution of Artemia satellite chromatin

We report the characterization of an in vitro chromatin assembly system derived from Artemia embryos and its application to the study of AluI-113 satellite DNA organization in nucleosomes. The system efficiently reconstitutes chromatin templates by associating DNA, core histones, and H1. The polynucleosomal complexes show physiological spacing of repeat length 190 +/- 5 base pairs, and the internucleosomal distances are modulated by energy-using activities that contribute to the dynamics of chromatin conformation. The assembly extract was used to reconstitute tandemly repeated AluI-113 sequences. The establishment of preferred histone octamer/satellite DNA interactions was observed. In vitro, AluI-113 elements dictated the same nucleosome translational localizations as found in vivo. Specific rotational constraints seem to be the central structural requirement for nucleosome association. Satellite dinucleosomes showed decreased translational mobility compared with mononucleosomes. This could be the consequence of interactions between rotationally positioned nucleosomes separated by linker DNA of uniform length. AluI-113 DNA led to weak cooperativity of nucleosome association in the proximal flanking regions, which decreased with distance. Moreover, the structural properties of satellite chromatin can spread, thus leading to a specific organization of adjacent nucleosomes.

Uncurved-DNA signals are important for translational positioning of nucleosomes

We describe here a possible mechanism for non-random arrangement of nucleosomes along genomic DNA by short stretches of uncurved DNA. Available biochemical data on nucleosome positioning on different DNA sequences were analyzed. A strong correlation between location of nucleosome borders and location of uncurved sequences along DNA was observed. Tested sequences include satellites, 5S RNA genes and 5' regions of different genes.

Chicken MAR-binding protein ARBP is homologous to rat methyl-CpG-binding protein MeCP2

Here, we describe the cloning and further characterization of chicken ARBP, an abundant nuclear protein with a high affinity for MAR/SARs. Surprisingly, ARBP was found to be homologous to the rat protein MeCP2, previously identified as a methyl-CpG-binding protein. A region spanning 125 amino acids in the N-terminal halves is 96.8% identical between chicken ARBP and rat MeCP2. A deletion mutation analysis using Southwestern and band shift assays identified this highly conserved region as the MAR DNA binding domain. Alignment of chicken ARBP with rat and human MeCP2 proteins revealed six trinucleotide amplifications generating up to 34-fold repetitions of a single amino acid. Because MeCP2 was previously localized to pericentromeric heterochromatin in mouse chromosomes, we analyzed the in vitro binding of ARBP to various repetitive sequences. In band shift experiments, ARBP binds to two chicken repetitive sequences as well as to mouse satellite DNA with high affinity similar to that of its binding to chicken lysozyme MAR fragments. In mouse satellite DNA, use of several footprinting techniques characterized two high-affinity binding sites, whose sequences are related to the ARBP binding site consensus in the chicken lysozyme MAR (5'-GGTGT-3'). Band shift experiments indicated that methylation increased in vitro binding of ARBP to mouse satellite DNA two- to fivefold. Our results suggest that ARBP/MeCP2 is a multifunctional protein with roles in loop domain organization of chromatin, the structure of pericentromeric heterochromatin, and DNA methylation.

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

The mouse mammary tumor virus acquires a highly reproducible chromatin structure when integrated into cellular DNA. Previous studies have suggested that the LTR is arranged as a series of six phased nucleosomes, that occupy specific positions on the LTR. On the basis of nucleosome reconstitution studies using DNA from the B region of the LTR, it has been argued that this sequence directs a uniquely positioned nucleosome. Here we demonstrate in vitro that reconstituted B region nucleosomes adopt at least five distinct translational positions in two rotational frames on a 206 bp fragment of DNA. We have resolved an initial reconstitute into its component species using nondenaturing gel electrophoresis, and precisely mapped the positions of each species using a hydroxyl radical footprinting assay. To confirm the nucleosome positions determined with the hydroxyl radical assay, nucleosome boundaries were mapped using exonuclease III. Comparison of the results from the hydroxyl radical footprinting and exonuclease III assays revealed a symmetrical pattern of overdigestion by exonuclease III which made unequivocal determination of nucleosome boundaries dubious. We conclude that the general use of exonuclease III to map the positions of nucleosomes may lead to incorrect assignment of position, and that assignment of position through the determination of the nucleosome pseudo-dyad from hydroxyl radical footprinting data represents a superior method of analysis.

DNA curvature of the tobacco GRS repetitive sequence family and its relation to nucleosome positioning

Recently, a highly repetitive DNA sequence family (GRS) from tobacco was described in our laboratory. These sequences were found to be localized predominantly in the pericentromeric heterochromatin of tobacco chromosomes. To test the hypothesis that these sequences play an important role in the formation of heterochromatin, we investigated the DNA curvature of the GRS sequences and its possible impact to the chromatin structure at these loci. Application of the nearest-neighbour wedge model of intrinsic DNA curvature for the GRS1 family member predicted two loci of curvature: a major bend at the 5' end of the sequence and a minor bend of opposite direction at the centre of the GRS1. The presence of the major and the minor loci of DNA curvature was studied experimentally using permutation analysis and site-directed mutagenesis. The experimental results were consistent with the computer predictions. We gave evidence that the described DNA curvature is also present in the entire GRS family. Genomic statistical sequencing showed the conservation of the major bend sequence determinants in the members of the GRS family. To investigate the chromatin structure at the GRS sequences, we determined the nucleosome positioning in vivo at these sequences using thermal cycle primer extension. A relation between the curvature pattern and the histone octamer position was observed: the major bend is excluded from the nucleosome surface to the linker region, while the minor bend is distributed along the core DNA. The suggestion is made that the sequences in the minor locus of curvature define the rotational setting of the nucleosome, and a possible role of the major bend as a factor, which defines the translational setting, is discussed.

Effects of DNA topology in the interaction with histone octamers and DNA topoisomerase I

Several simple proteins and complex protein systems exist which do not recognize a defined sequence but--rather--a specific DNA conformation. We describe experiments and principles for two of these systems: nucleosomes and eukaryotic DNA topoisomerase I. Evidences are summarized that describe the effects of negative DNA supercoiling on nucleosome formation and the influence of DNA intrinsic curvature on their localization. The function of the DNA rotational information in nucleosome positioning and in the selection of multiple alternative positions on the same helical phase are described. This function suggests a novel genetic regulatory mechanism, based on nucleosome mobility and on the correlation between in vitro and in vivo positions. We observe that the same rules that determine the in vitro localization apply to the in vivo nucleosome positioning, as determined by a technique that relies on the use of nystatin and on the import of active enzymes in living yeast cells. The sensitivity of DNA topoisomerase I to the topological condition of the DNA substrate is reviewed and discussed taking into account recent experiments that describe the effect of the DNA tridimensional context on the reaction. These topics are discussed in the following order: (i) Proteins that look for a consensus DNA conformation; (ii) Nucleosomes; (iii) Negative supercoiling and nucleosomes; (iv) DNA curvature/bending and nucleosomes; (v) Multiple positioning; (vi) Multiple nucleosomes offer a contribution to the solution of the linking number paradox; (vii) Rotational versus translational information; (viii) A regulatory mechanism; (ix) DNA topoisomerase I; (x) DNA topoisomerase I and DNA supercoiling: a regulation by topological feedback; (xi) DNA topoisomerase I and DNA curvature; (xii) The in-and-out problem in the accessibility of DNA information; (xiii) The integrating function of the free energy of supercoiling.

Periodicity of dinucleotides in nucleosomes derived from simian virus 40 chromatin

It is thought that statistical analysis of dinucleotide periodicities can provide insight into the general features of nucleosome forming sequences. The chromatin of simian virus 40 (SV40) provides a model for a unique DNA sequence that is found in association with histones in vivo. I have therefore analyzed the periodicity of dinucleotides in a collection of cloned nucleosomal DNA fragments prepared from SV40 chromatin isolated under relatively mild conditions, in order to learn about the generality of results obtained from the statistical approach and to examine the SV40 data set in the context of models that have been proposed to explain the molecular basis of nucleosome formation. In one study, I assumed a symmetry in the distribution of dinucleotides with respect to the nucleosome dyad position and considered complementary dinucleotides to be equivalent, i.e. AA = TT and GG = CC. The results showed a periodic signal for GG/CC but not for AA/TT, purine-purine, and pyrimidine-pyrimidine dinucleotides. In a second study, the SV40 nucleosomal DNA fragments were aligned and examined with respect to the late strand of the viral genome to determine the distribution of dinucleotides in one direction. Fourier analysis revealed periodic signals for AA/TT (10.26 bp) and GG/CC (10.0 bp) and indicated that AA dominates the occurrences of AA/TT and GG dominates the occurrences of GG/CC. The results of both studies implied that there might be an asymmetry and a directionality in the distribution of certain dinucleotides in nucleosomes.

Dissection of the methyl-CpG binding domain from the chromosomal protein MeCP2

MeCP2 is a chromosomal protein which binds to DNA that is methylated at CpG. In situ immunofluorescence in mouse cells has shown that the protein is most concentrated in pericentromeric heterochromatin, suggesting that MeCP2 may play a role in the formation of inert chromatin. Here we have isolated a minimal methyl-CpG binding domain (MBD) from MeCP2. MBD is 85 amino acids in length, and binds exclusively to DNA that contains one or more symmetrically methylated CpGs. MBD has negligable non-specific affinity for DNA, confirming that non-specific and methyl-CpG specific binding domains of MeCP2 are distinct. In vitro footprinting indicates that MBD binding can protect a 12 nucleotide region surrounding a methyl-CpG pair, with an approximate dissociation constant of 10(-9) M.

Multiple nucleosome positioning with unique rotational setting for the Saccharomyces cerevisiae 5S rRNA gene in vitro and in vivo

A simple no-background assay was developed for high-resolution in vivo analysis of yeast chromatin. When applied to Saccharomyces cerevisiae 5S rRNA genes (5S rDNA), this analysis shows that nucleosomes completely cover this chromosomal region, occupying alternative positions characterized by a unique helical phase. This supports the notion that sequence-intrinsic rotational signals are the major determinant of nucleosome localization. Nucleosomal core particles reconstituted in vitro occupy the same positions and have the same helically phased distribution observed in vivo, as determined by mapping of exonuclease III-resistant borders, mapping by restriction cleavages, and by DNase I and hydroxyl-radical digestion patterns.

W-heterochromatin of chicken; its unusual DNA components, late replication, and chromatin structure

About 65% of DNA in the chicken W chromosome has been shown to consist of XhoI and EcoRI family repetitive sequences. These sequences showed remarkable delay in the electrophoretic mobility at low temperature on a polyacrylamide gel. Three dimensional structures of the 0.7-kb XhoI and the 1.2-kb EcoRI family repeating units were estimated to be irregular solenoids using a computer program based on wedge angles of all the 16 dinucleotide steps. Fluorescence in situ hybridization demonstrated that these two family sequences were localized in a major heterochromatic body in an interphase nucleus. Incorporation of bromodeoxyuridine into the W chromosome in the synchronous culture of MSB-1 cells occurred about 1 h later than the peak of S phase. The chromatin structure formed along XhoI and EcoRI family sequences was suggested to be different from the total chromatin or chromatin containing the beta-actin gene sequence in that the linker DNA lengths of the former were significantly longer. Fractionation of the HaeIII-digested MSB-1 nuclei yielded a chromatin fraction in which XhoI family sequences were partially enriched. Several DNA-binding proteins showing higher affinity for the XhoI family sequence were present in this fraction.

Construction of nucleosome cores from defined sequence DNA of viral origin

The de novo construction of defined nucleosomes from two DNA fragments of simian virus SV40 is described. One fragment spans the region containing the origin of replication of the virus from base -16 to base 161, a region which is nucleosome-free during virus replication. The other fragment, of 142 bp (1352 to 1493), is within the region coding for viral proteins VP2 and VP3, and serves for comparison. Both fragments form nucleosomes with similar efficiency when combined with histone cores as well as when exchanged with existing core particles. The DNase I digestion pattern and exonuclease III analysis both indicate that true nucleosome cores are formed, and that a prolonged tail is not protruding from the constructs. The efficient formation of a nucleosome core particle from the origin region of DNA implies that the absence of nucleosomes from this region during viral infection is not prescribed by the specific base sequence of origin DNA, and is therefore likely to be determined by non-histone nuclear factors associated with the SV40 replication process.

Construction of nucleosome cores from defined DNA sequences of prokaryotic origin

A procedure for the de novo construction of nucleosome core particles from defined DNA sequences of prokaryotic origin is described. Efficient de novo reconstitution without added carrier DNA is demonstrated. DNase I and exonuclease III analysis of a nucleosome core prepared from a 154 base pair fragment extending from base 853 to base 1006 of pBR322 indicates a non-random positioning of the histone core along the DNA. As bacteria have no histones, their DNA cannot be expected to have a histone core positioning signal encoded in it, the efficient formation of a uniquely positioned core particle is not self evident. The possibility that a phosphate end group positions DNA fragments on the histone is considered. The de novo reconstitution of carrier-less defined nucleosome core particles should facilitate the physicochemical study of nucleosomes on the fine structural level.

DNA and protein determinants of nucleosome positioning on sea urchin 5S rRNA gene sequences in vitro

DNA and protein determinants of nucleosome positioning have been examined after in vitro reconstitutions of native or modified histone octamers onto tandem repeats of 207- and 172-base-pair DNA sequences containing the Lytechinus variegatus 5S rRNA gene and onto monomeric sequences derived from these by digestion with various restriction endonucleases. In all cases, a major nucleosome position as well as a number of minor positions have been observed, which indicates that the generation of multiple positions is an inherent property of the 5S rRNA gene sequence. Interestingly, all positions observed differ by multiples of 10 base pairs. Data obtained under different reconstitution conditions demonstrate that the observed distributions of nucleosomes on these DNA templates are equilibrium distributions. This study has also examined the positioning of histone octamers from which histone "tails" had been removed by tryptic digestion. Results indicate that the histone tails are not determinants of nucleosome positioning. Although our results suggest that the mechanical properties of the 5S rDNA are the fundamental factors determining nucleosome positioning, they are insufficient to direct all nucleosomes into a single location.

Correlation between dinucleotide periodicities and nucleosome positioning on mouse satellite DNA

Previous studies demonstrated 16 well-defined nucleosome locations (A-P) on a tandemly repeated prototype 234 base pair (bp) mouse satellite repeat unit. We have aligned the A-P fragments to search for DNA sequence elements that might contribute to nucleosome placement at these positions. Our results demonstrate a strikingly regular, uninterrupted, periodic pattern for the AA dinucleotide occurrences along the entire length of the aligned fragments. The periodicity of the AA occurrences is about 9.7 bp. The pattern exhibits a local minimum at position 74, near the nucleosome dyad axis of symmetry. Other dinucleotides--including AC: GT, CA: TG, and CC: GG--are also placed periodically, but their patterns of occurrence are less regular and less frequent than AA. The calculated spacings between consecutive preferred nucleosome locations on mouse satellite DNA are nearly identical, corresponding to multiples of 9.7 bp. The correlation between the periodicity of dinucleotide occurrences and the average spacing of nucleosome positions suggests that the preferred nucleosome locations recur at intervals that may correspond to the DNA helical repeat in the mouse satellite nucleosomes, and that the histone octamers sample (or slip along) the duplex in steps of 9.7 bp during nucleosome formation on mouse satellite DNA.

Structure of the nucleosome core particle at 8 A resolution

The x-ray crystallographic structure of the nucleosome core particle has been determined using 8 A resolution diffraction data. The particle has a mean diameter of 106 A and a maximum thickness of 65 A in the superhelical axis direction. The longest chord through the histone core measures 85 A and is in a non-axial direction. The 1.87 turn superhelix consists of B-DNA with about 78 base pairs or 7.6 helical repeats per superhelical turn. The mean DNA helical repeat contains 10.2 +/- 0.05 base pairs and spans 35 A, slightly more than standard B-DNA. The superhelix varies several Angstroms in radius and pitch, and has three distinct domains of curvature (with radii of curvature of 60, 45 and 51 A). These regions are separated by localized sharper bends +/- 10 and +/- 40 base pairs from the center of the particle, resulting in an overall radius of curvature about 43 A. Compression of superhelical DNA grooves on the inner surface and expansion on the outer surface can be seen throughout the DNA electron density. This density has been fit with a double helical ribbon model providing groove width estimates of 12 +/- 1 A inside vs. 19 +/- 1 A outside for the major groove, and 8 +/- 1 A inside vs. 13 +/- 1 A outside for the minor groove. The histone core is primarily contained within the bounds defined by the superhelical DNA, contacting the DNA where the phosphate backbone faces in toward the core. Possible extensions of density between the gyres have been located, but these are below the significance level of the electron density map. In cross-section, a tripartite organization of the histone octamer is apparent, with the tetramer occupying the central region and the dimers at the extremes. Several extensions of histone density are present which form contacts between nucleosomes in the crystal, perhaps representing flexible or "tail" histone regions. The radius of gyration of the histone portion of the electron density is calculated to be 30.4 A (in reasonable agreement with solution scattering values), and the histone core volume in the map is 93% of its theoretical volume.

A proposal for a possible role of nucleosome positioning in the evolutionary adjustment of introns

1. Prokaryotes and yeast have mostly intronless genes, whereas the presence of a large number of extended introns are characteristic of the genes of of multicellular eukaryotic organisms which, however, as an exception also have a few intronless genes. 2. According to the current view, the lack of introns in prokaryotic organisms and yeast is due to the selective pressure of a short cell division time. On the other hand, the presence of introns in multicellular eukaryotic organisms is explained by the lack of selective forces against them. 3. In the present hypothesis it is proposed that introns were used as tools in the course of evolution for the organization of eukaryotic genes within the repeating units of nucleosomes, since the distinct DNA conformations of the nucleosome core particle and of the linker region, respectively, represent a constraint for the positioning of genes. 4. Recently it was shown that initiation of transcription is inhibited when the promoter sequence is within a nucleosome. 5. Since the nucleosomal organization of DNA leads to a severely deformed DNA helix and recognition of sequences by regulatory proteins is likely to depend on the conformation of the double helix, it is postulated that for the different sizes of eukaryotic genes which have to be organized within repeating units of nucleosomes, introns provided the flexibility of adjustment for the positioning of regulatory sequences, by drifting in length, sequence and position.

DNA sequence patterns in precisely positioned nucleosomes

Several investigators have recognized the importance of non-periodic DNA sequence information in determining the translational position of precisely positioned nucleosomes. The purpose of this study is to determine the extent of such information, in addition to the character of periodic information present. This is accomplished by examining the half-nucleosome DNA sequences of a considerable number of precisely positioned nucleosomes, and determining the probability of occurrence of each dinucleotide type as a function of position from the nucleosome center to the terminus (positions 0 to 72). By the nature of this procedure, no assumptions of periodicity are made. The results show the importance of several DNA sequence periodicities including 6-7, 10, and 21 base pairs, in addition to significant nonperiodic information. The results demonstrate that each dinucleotide type is unique in terms of its positional preference in precisely positioned nucleosomes (for example AA not equal to TT). The probabilities of occurrence for the dinucleotide types can be used to predict the translational positions of a number of observed nucleosomes.

Structural organization of satellite I chromatin of calf liver

The organization of liver calf satellite DNA I chromatin has been studied. Precisely seven nucleosomes per DNA satellite repeat (1.4 kb) are shown to be present. Several strict positionings of the nucleosomes along the satellite DNA repeat have been described. One of these positionings, the major phase, was shown to be preferentially organized in clustered repeats. Most of the non-methylated CpG restriction sites were shown to be located in the linker DNAs of the satellite I nucleosomes, whilst, accordingly, methylated HpaII sites were found in the core satellite I DNA. The significance of these results is discussed.

Curvature of mouse satellite DNA and condensation of heterochromatin

Cloned, sequenced mouse satellite DNA exhibits properties characteristic of molecules that possess a stable curvature. Circularly permuted fragments containing the region predicted to bend were used to map the curvature relative to DNA sequence. The altered mobility of these fragments in polyacrylamide gels is reversed when gels are run in the presence of distamycin A, a drug that binds preferentially to AT-rich DNA. Treatment of living mouse cells with this drug dramatically reduces the condensation of centromeric heterochromatin, the exclusive location of satellite sequences. In situ hybridization of satellite probes to extended chromosomes at the electron microscope level shows that satellite does not comprise a single block but is distributed throughout the centromere region. Based on these experiments, we hypothesize that the structure of mouse satellite DNA is an important feature of centromeric heterochromatin condensation.

CpG deficiency, dinucleotide distributions and nucleosome positioning

The dinucleotide CpG is deficient in (A + T)-rich regions of vertebrate DNA in both coding and non-coding sequences and there is a corresponding increase above expectation in the occurrence of TpG and CpA. By contrast in (G + C)-rich regions no deficiency of CpG is found. Such (G + C)-rich sequences, containing the expected number of CpG dinucleotides, alternate along the genome with (A + T)-rich sequences which have a lower than expected CpG content. The G + C content of vertebrate DNA can oscillate with a period of 150-200 bp and this may be a factor in positioning nucleosomes. The role of mutagenesis in loss of CpG and increase of A + T, particularly in non-coding regions, is discussed.

Limitations of the poly(glutamic acid) reconstitution method in the reassembly of mono- and dinucleosomes

Reconstitution of mononucleosomes and dinucleosomes at physiological ionic strength by means of poly(glutamic acid) is not efficient at physiological histone octamer:DNA ratios, unlike that with the salt dialysis method. The shorter the DNA is, the less transfer of octamers from poly(glutamic acid) to DNA occurs. By increasing the octamer:DNA ratio it is possible to involve all the DNA in the assembly, but for DNA longer than core particle length, nucleoprotein particles containing extra histones are concomitantly generated. Except for core particle and chromatosome lengths of DNA reassembled at 0.6:1 or 1:1 octamer:DNA ratio (and thus with low yield), reconstituted nucleoprotein particles proved to be different from native nucleosomes by their insolubility upon isolation. In the aggregates, DNA ends seemed to be sufficiently loose to allow exonuclease III digestion up to a certain limit. This resulted in patterns that for some cloned DNA fragments could give the impression, without knowledge of the above, of resulting from a unique octamer position. In view of the small range of length of DNA and the low yield of faithful reconstitution, the assembly method using poly(glutamic acid) is only of limited use in mono- or dinucleosome reconstitution experiments, at least in our hands.

Nucleosomes are phased along the mouse beta-major globin gene in erythroid and nonerythroid cells

We have used the chemical cleavage reagent methidiumpropyl-EDTA-Fe(II) to determine the location of the nucleosomes along the mouse beta-major globin gene in erythroid and nonerythroid cells. In mouse L cells, in which the globin gene is inactive, the nucleosomes are precisely positioned with respect to the underlying DNA sequence from positions -3000 to +1500 relative to the cap site. In uninduced and induced murine erythroleukemia cells, the same phasing persists but is interrupted from positions -200 to +500. This gap in the phased distribution of nucleosomes appears to be protected from MPE-Fe(II) digestion, and is bounded on both sides by hypersensitive sites. These results define at least two structural states for the globin gene: an inactive state in which the gene is covered with a continuous array of phased nucleosomes and an active state in which this array is disrupted over the 5' half of the structural gene.

Reconstitution of mononucleosomes: characterization of distinct particles that differ in the position of the histone core

Reconstitution of mononucleosomes from DNA and core histones was carried out to study the positioning of histone octamers on the DNA. Using random DNA molecules in the 200 to 250 bp size range we found that the reconstitution products consisted of a mixture of three different types of particles that could be separated by low ionic strength gel electrophoresis. In one particle, DNA was complexed with histones along its entire length indicating the binding of more than one histone octamer. The second particle contained only one histone core that was always associated, however, with the terminal 145 bp of the DNA regardless of its sequence which can be ascribed to a DNA end effect. Only the third particle consisted of histone octamers bound at internal positions of the DNA and is therefore the only particle suitable for investigating the influence of the DNA sequence on the positioning of the histone cores. A defined 154 bp pBR 322 restriction fragment that contains three BspRI restriction sites was also reconstituted with core histones. The accessibility of these sites to BspRI was measured in order to delineate the utility of restriction nucleases as probes for the structure of chromatin. Two sites located close to the center of the DNA were less susceptible by at least a factor of 1000 as compared to free DNA while the susceptibility of the third site in the terminal section of the DNA decreased about 50 fold after reconstitution.

Positioning of nucleosomes in satellite I-containing chromatin of rat liver

The location of nucleosomes on rat satellite I DNA has been investigated using a new approach. Nucleosome cores were prepared from rat liver nuclei with micrococcal nuclease, exonuclease III and nucleases S1. From the total population of core DNA fragments the satellite-containing fragments were isolated by molecular cloning and the complete sequence of 50 clones was determined. The location of nucleosomes along the satellite sequence was found to be non-random. Our results show that nucleosomes occupy a number of positions on satellite I DNA. About 35 to 50% of all nucleosomes are positioned in two corresponding major sites, the remainder in about 16 less preferred sites. The major nucleosome positions are apparently strictly defined with the precision of a single base-pair. These results were confirmed by other approaches, including restriction nuclease digestion experiments. There are good indications of a defined long-range organization of the satellite chromatin fiber in two or more oligonucleosomal arrays with distinct nucleosome configurations.