A model chromatin assembly system. Factors affecting nucleosome spacing

Binding Dynamics of Disordered Linker Histone H1 with a Nucleosomal Particle

Linker histone H1 is an essential regulatory protein for many critical biological processes, such as eukaryotic chromatin packaging and gene expression. Mis-regulation of H1s is commonly observed in tumor cells, where the balance between different H1 subtypes has been shown to alter the cancer phenotype. Consisting of a rigid globular domain and two highly charged terminal domains, H1 can bind to multiple sites on a nucleosomal particle to alter chromatin hierarchical condensation levels. In particular, the disordered H1 amino- and carboxyl-terminal domains (NTD/CTD) are believed to enhance this binding affinity, but their detailed dynamics and functions remain unclear. In this work, we used a coarse-grained computational model, AWSEM-DNA, to simulate the H1.0b-nucleosome complex, namely chromatosome. Our results demonstrate that H1 disordered domains restrict the dynamics and conformation of both globular H1 and linker DNA arms, resulting in a more compact and rigid chromatosome particle. Furthermore, we identified regions of H1 disordered domains that are tightly tethered to DNA near the entry-exit site. Overall, our study elucidates at near-atomic resolution the way the disordered linker histone H1 modulates nucleosome's structural preferences and conformational dynamics.

Aspects of large-scale chromatin structures in mouse liver nuclei can be predicted from the DNA sequence

The large amount of non-coding DNA present in mammalian genomes suggests that some of it may play a structural or functional role. We provide evidence that it is possible to predict computationally, from the DNA sequence, loci in mouse liver nuclei that possess distinctive nucleosome arrays. We tested the hypothesis that a 100 kb region of DNA possessing a strong, in-phase, dinucleosome period oscillation in the motif period-10 non-T, A/T, G, should generate a nucleosome array with a nucleosome repeat that is one-half of the dinucleosome oscillation period value, as computed by Fourier analysis of the sequence. Ten loci with short repeats, that would be readily distinguishable from the pervasive bulk repeat, were predicted computationally and then tested experimentally. We estimated experimentally that less than 20% of the chromatin in mouse liver nuclei has a nucleosome repeat length that is 15 bp, or more, shorter than the bulk repeat value of 195 +/- bp. All 10 computational predictions were confirmed experimentally with high statistical significance. Nucleosome repeats as short as 172 +/- 5 bp were observed for the first time in mouse liver chromatin. These findings may be useful for identifying distinctive chromatin structures computationally from the DNA sequence.

Role of linker histone in chromatin structure and function: H1 stoichiometry and nucleosome repeat length

Despite a great deal of attention over many years, the structural and functional roles of the linker histone H1 remain enigmatic. The earlier concepts of H1 as a general transcriptional inhibitor have had to be reconsidered in the light of experiments demonstrating a minor effect of H1 deletion in unicellular organisms. More recent work analysing the results of depleting H1 in mammals through genetic knockouts of selected H1 subtypes in the mouse has shown that cells and tissues can tolerate a surprisingly low H1 content. One common feature of H1-depleted nuclei is a reduction in nucleosome repeat length (NRL). Moreover, there is a robust linear relationship between H1 stoichiometry and NRL, suggesting an inherent homeostatic mechanism that maintains intranuclear electrostatic balance. It is also clear that the 1 H1 per nucleosome paradigm for higher eukaryotes is the exception rather than the rule. This, together with the high mobility of H1 within the nucleus, prompts a reappraisal of the role of linker histone as an obligatory chromatin architectural protein.

Long-range oscillation in a periodic DNA sequence motif may influence nucleosome array formation

We have experimentally examined the characteristics of nucleosome array formation in different regions of mouse liver chromatin, and have computationally analyzed the corresponding genomic DNA sequences. We have shown that the mouse adenosine deaminase (MADA) gene locus is packaged into an exceptionally regular nucleosome array with a shortened repeat, consistent with our computational prediction based on the DNA sequence. A survey of the mouse genome indicates that <10% of 70 kb windows possess a nucleosome-ordering signal, consisting of regular long-range oscillations in the period-10 triplet motif non-T, A/T, G (VWG), which is as strong as the signal in the MADA locus. A strong signal in the center of this locus, confirmed by in vitro chromatin assembly experiments, appears to cooperate with weaker, in-phase signals throughout the locus. In contrast, the mouse odorant receptor (MOR) locus, which lacks locus-wide signals, was representative of ∼40% of the mouse genomic DNA surveyed. Within this locus, nucleosome arrays were similar to those of bulk chromatin. Genomic DNA sequences which were computationally similar to MADA or MOR resulted in MADA- or MOR-like nucleosome ladders experimentally. Overall, we provide evidence that computationally predictable information in the DNA sequence may affect nucleosome array formation in animal tissue.

Distinct activities of CHD1 and ACF in ATP-dependent chromatin assembly

CHD1 is a chromodomain-containing protein in the SNF2-like family of ATPases. Here we show that CHD1 exists predominantly as a monomer and functions as an ATP-utilizing chromatin assembly factor. This reaction involves purified CHD1, NAP1 chaperone, core histones and relaxed DNA. CHD1 catalyzes the ATP-dependent transfer of histones from the NAP1 chaperone to the DNA by a processive mechanism that yields regularly spaced nucleosomes. The comparative analysis of CHD1 and ACF revealed that CHD1 assembles chromatin with a shorter nucleosome repeat length than ACF. In addition, ACF, but not CHD1, can assemble chromatin containing histone H1, which is involved in the formation of higher-order chromatin structure and transcriptional repression. These results suggest a role for CHD1 in the assembly of active chromatin and a function of ACF in the assembly of repressive chromatin.

DNA sequence alterations affect nucleosome array formation of the chicken ovalbumin gene

The role of the large amount (more than half of the genome) of noncoding DNA in higher organisms is not well understood. DNA evolved to function in the context of chromatin, and the possibility exists that some of the noncoding DNA serves to influence chromatin structure and function. In this age of genomics and bioinformatics, genomic DNA sequences are being searched for informational content beyond the known genetic code. The discovery that period-10 non-T, A/T, G (VWG) triplets are among the most abundant motifs in human genomic DNA suggests that they may serve some function in higher organisms. In this paper, we provide direct evidence that the regular oscillation of period-10 VWG that occurs in the chicken ovalbumin gene sequence with a dinucleosome-like period facilitates nucleosome array formation. Using a linker histone-dependent in vitro chromatin assembly system that spontaneously aligns nucleosomes into a physiological array, we show that nucleosomes tend to avoid DNA regions with low period-10 VWG counts. This avoidance leads to the formation of an array with a nucleosome repeat equal to half the period value of the oscillation in period-10 VWG, as determined by Fourier analysis. Two different half-period deletions in the wild-type DNA sequence altered the nucleosome array, as predicted computationally. In contrast, a full-period deletion had an insignificant effect on the nucleosome array formed, also consistent with the prediction. An inversion mutation, with no DNA sequences deleted, again altered the nucleosome array formed, as predicted computationally. Hence, a VWG dinucleosome signal is plausible.

Nucleosomal arrays can be salt-reconstituted on a single-copy MMTV promoter DNA template: their properties differ in several ways from those of comparable 5S concatameric arrays

Subsaturated nucleosomal arrays were reconstituted on a single-copy MMTV promoter DNA fragment by salt dialysis procedures and studied by atomic force microscopy. Up to an occupation level of approximately eight nucleosomes on this 1900 bp template, salt reconstitution produces nucleosomal arrays which look very similar to comparably loaded 5S rDNA nucleosomal arrays; i.e., nucleosomes are dispersed on the DNA template. Thus, at these occupation levels, the single-copy MMTV template forms arrays suitable for biophysical analyses. A quantitative comparison of the population features of subsaturated MMTV and 5S arrays detects differences between the two: a requirement for higher histone levels to achieve a given level of nucleosome occupation on MMTV templates, indicating that nucleosome loading is thermodynamically less favorable on this template; a preference for pairwise nucleosome occupation of the MMTV (but not the 5S) template at midrange occupation levels; and an enhanced salt stability for nucleosomes on MMTV versus 5S arrays, particularly in the midrange of array occupation. When average occupation levels exceed approximately eight nucleosomes per template, MMTV arrays show a significant level of mainly intramolecular compaction; 5S arrays do not. Taken together, these results show clearly that the nature of the underlying DNA template can affect the physical properties of nucleosomal arrays. DNA sequence-directed differences in the physical properties of chromatin may have important consequences for functional processes such as gene regulation.

Circle ligation of in vitro assembled chromatin indicates a highly flexible structure

Evidence is provided that some condensed linker histone-containing chromatin structures are highly flexible in solutions containing 2 mM Mg2+. Chromatin assembled in vitro +/- histone H5 on a 6.3 kb linear DNA fragment in 90 mM NaCl using the polyglutamic acid method sedimented fairly homogeneously. The H5-containing sample had s(20, w) values that were 58-69% greater than the sample lacking H5. Chromatin assembled on linear pUC19 plasmid DNA was treated with T4 DNA ligase in solutions containing 2 mM Mg2+ over a range of DNA concentrations. It was found that the intramolecular DNA ends of the chromatin could be joined together more efficiently than the intramolecular ends of the naked DNA at the higher DNA concentrations. This result could not be attributed to the effective reduction in DNA length by nucleosome formation. The chromatin structures formed did not have naked DNA tails extending from the ends as assessed by exonuclease III digestion. Chromatin assembled on DNA shortened by up to 420 bp gave very similar results, suggesting that the structure was a flexible one, rather than a rigid one having DNA ends that were fortuitously juxtaposed.

A signal encoded in vertebrate DNA that influences nucleosome positioning and alignment

Evidence is provided that the nucleotide triplet con-sensus non-T(A/T)G (abbreviated to VWG) influences nucleosome positioning and nucleosome alignment into regular arrays. This triplet consensus has been recently found to exhibit a fairly strong 10 bp periodicity in human DNA, implicating it in anisotropic DNA bendability. It is demonstrated that the experimentally determined preferences for nucleosome positioning in native SV40 chromatin can, to a large extent, be pre-dicted simply by counting the occurrences of the period-10 VWG consensus. Nucleosomes tend to form in regions of the SV40 genome that contain high counts of period-10 VWG and/or avoid regions with low counts. In contrast, periodic occurrences of the dinucleotides AA/TT, implicated in the rotational positioning of DNA in nucleosomes, did not correlate with the preferred nucleosome locations in SV40 chromatin. Periodic occurrences of AA did correlate with preferred nucleosome locations in a region of SV40 DNA where VWG occurrences are low. Regular oscillations in period-10 VWG counts with a dinucleosome period were found in vertebrate DNA regions that aligned nucleosomes into regular arrays in vitro in the presence of linker histone. Escherichia coli and plasmid DNA, which fail to align nucleosomes in vitro, lacked these regular VWG oscillations.

DNA sequence encodes information for nucleosome array formation

We have examined the effects of base sequence on nucleosome array formation using randomly selected chicken genomic DNA sequences. DNA clones were assembled into chromatin under identical conditions using a defined in vitro system capable of generating physiologically spaced nucleosomes on some sequences. The nucleosome arrangements in native chromatin on the selected sequences were also examined in liver nuclei. Variations in nucleosome ladders were found among the different sequences that were similar in vitro and in nuclei. Differences in both the degree of regularity of nucleosome arrays and in the value of the nucleosome repeat length were observed. Analysis of an approximately 100 kilobase-pair contiguous region using cosmid clones suggested that well-ordered regions of chromatin, generally less than two kilobase-pairs in extent, alternate with less-ordered regions. This mosaic arrangement for chromatin organization appears to be largely a consequence of information encoded in the DNA base sequence. Nucleosome ordering with a 210 base-pair periodicity in a highly ordered ten-nucleosome array appeared to result from linker histone-dependent alignment with respect to each of two positioned nucleosomes, approximately 1000 base-pairs apart.

The AT-rich flanks of the oocyte-type 5S RNA gene of Xenopus laevis act as a strong local signal for histone H1-mediated chromatin reorganization in vitro

In vivo, histone H1 plays an active role in establishing the transcriptionally repressed chromatin state of the oocyte-type 5S RNA genes in the early stages of Xenopus development. By using fully defined in vitro system of chromatin assembly on plasmids with cloned oocyte- or somatic-type 5S gene repeats we found that the oocyte repeat which comprises a 120 bp oocyte-type 5S RNA gene placed within the few hundred bp long native AT-rich flanks, but not the somatic repeat (a similar 120 bp somatic-type 5S RNA gene placed within native GC-rich flanks) enables histone H1 to realign the nucleosomal core particles densely packed on plasmid DNA. The realignment results in creation of the repeat unit of approximately 240 bp and is achieved through complete removal of several core histone complexes from plasmid template with the oocyte-type repeat. This effect of H1 is independent on the plasmid sequences and seems to be solely due to the presence in the oocyte-repeat of the AT-rich flanks. The effects of H1 are completely suppressed by distamycin A, a drug that specifically recognizes and binds oligo(dA).oligo(dT) runs in DNA. The binding of H1 results in increased protection of DNA sites within the AT-rich oocyte-type 5S repeat. In an in vitro transcription assay performed with reconstituted chromatin templates containing plasmids with the oocyte- or somatic-type repeats only the transcription of the oocyte-type 5S RNA gene was repressed in the presence of physiological concentration of histone H1. These results support the view that the AT-rich flanks of the oocyte-type 5S RNA gene are involved in histone H1-mediated chromatin reorganization that results in the transcriptional repression observed in vivo.

Dissociation of protamine-DNA complexes by Xenopus nucleoplasmin and minichromosome assembly in vitro

Nucleoplasmin, an acidic thermostable protein abundant in the nucleus of Xenopus laevis oocytes, has been found to dissociate complexes of pUC19 DNA and protein phi 1, an intermediate protamine present in ripe sperm from the mollusc Mytilus edulis. Cruder preparations of nucleoplasmin, such as the amphibian oocyte S150 extract and its thermostable fraction, also dissociate the heterologous DNA-phi 1 complexes and, in addition, promote the assembly of plasmid DNA into a minichromosome displaying regular nucleosomal periodicity, as revealed by micrococcal nuclease digestion. In contrast, purified nucleoplasmin complemented with rat hepatocyte core histone octamers in the presence of DNA topoisomerase I, although capable of inducing nucleoprotein formation onto the complexed DNA, fails to position nucleosomes at the native spacings seen in chromatin in vivo. These data favour the existence of a general mechanism to bring about, in a concerted manner, removal of sperm-specific nuclear proteins and reconstitution of somatic chromatin following fertilization.

Conserved nucleoprotein structure at the ends of vertebrate and invertebrate chromosomes

Eukaryotic chromosomes terminate with telomeres, nucleoprotein structures that are essential for chromosome stability. Vertebrate telomeres consist of terminal DNA tracts of sequence (TTAGGG)n, which in rat are predominantly organized into nucleosomes regularly spaced by 157 bp. To test the hypothesis that telomeres of other animals have nucleosomes, we compared telomeres from eight vertebrate tissues and cell cultures, as well as two tissues from an invertebrate. All telomeres have substantial tracts of (TTAGGG)n comprising 0.01-0.2% of the genome. All telomeres are long (20-100 kb), except for those of sea urchin, human, and some chicken chromosomes, which are 3-10 kb in length. All of the animal telomeres contained nucleosome arrays, consistent with the original hypothesis. The telomere repeat lengths vary from 151 to 205 bp, seemingly uncorrelated with telomere size, regularity of nucleosome spacing, species, or state of differentiation but surprisingly correlated with the repeat of bulk chromatin within the same cells. The telomere nucleosomes were consistently approximately 40 bp smaller than bulk nucleosomes. Thus, animal telomeres have highly conserved sequences and unusually short nucleosomes with cell-specific structure.

Signals in chicken beta-globin DNA influence chromatin assembly in vitro

We have confirmed the result that chicken beta-globin gene chromatin, which possesses the characteristics of active chromatin in erythroid cells, has shortened internucleosome spacings compared with bulk chromatin or that of the ovalbumin gene, which is inactive. To understand how the short (approximately 180-bp) nucleosome repeat arises specifically on beta-globin DNA, we have studied chromatin assembly of cloned chicken beta-globin DNA in a defined in vitro system. With chicken erythrocyte core histones and linker histone H5 as the only cellular components, a cloned 6.2-kb chicken beta-globin DNA fragment assembled into chromatin possessing a regular 180 +/- 5-bp repeat, very similar to what is observed in erythroid cells. A 2-kb DNA subfragment containing the beta A gene and promoter region, but lacking the downstream intergenic region between the beta A and epsilon genes, failed to generate a regular nucleosome array in vitro, suggesting that the intergenic region facilitates linker histone-induced nucleosome alignment. When the beta A gene was placed on a plasmid that contained a known chromatin-organizing signal, nucleosome alignment with a 180-bp periodicity was restored, whereas nucleosomes on flanking plasmid sequences possessed a 210-bp spacing periodicity. Our results suggest that the shortened 180-bp nucleosome spacing periodicity observed in erythroid cells is encoded in the beta-globin DNA sequence and that nucleosome alignment by linker histones is facilitated by sequences in the beta A-epsilon intergenic region.

Dynamics of interaction of RNA polymerase II with nucleosomes. I. Effect of salts

Mononucleosomes were labeled with the sulfhydryl-specific fluorescence probe 1,5-IAEDANS (5-(2-((iodoacetyl)amino)ethyl)amino-naphthalene-1-sulfonic acid) by attaching the dye to the single cysteine of H3 through a covalent linkage. The enzyme RNA polymerase II (pol II) utilized the native and the reconstituted fluorescent nucleosomes as templates with greatest efficiency when 0.2 M potassium acetate (AcOK) was used as the supporting salt; 0.2 M NaCl was found to be very much inhibitory. Measurement of polarity of the microenvironment of the dye at its binding site in the nucleosome showed the conformation to be more open in the presence of AcOK, compared to that in 0.1 or 0.2 M NaCl. The binding of pol II to the nucleosome resulted in a relatively more compact structure when measured in terms of the polarity of the microenvironment of the dye in various salt-dependent conformations of the nucleosomes. Time-resolved fluorescence spectroscopy showed that the probe molecule at its binding site undergoes certain excited-state processes, and the presence/absence or rate of these excited-state processes depends on the conformation of nucleosomes, which in turn depends on the type and concentration of the ion present in the medium. Time-resolved emission spectra showed that binding of nucleosomes by pol II established some new contacts that resulted in inaccessibility of the dye to the bulk solvent, reflecting a more hydrophobic environment for the dye in the steady-state spectra. Thus, binding or transcription of nucleosomes by pol II did not break open their structure. Rather, some transient internal adjustments within the histone octamer may take place to accommodate the bulky pol II molecule.

Signals in chicken beta-globin DNA influence chromatin assembly in vitro

We have confirmed the result that chicken beta-globin gene chromatin, which possesses the characteristics of active chromatin in erythroid cells, has shortened internucleosome spacings compared with bulk chromatin or that of the ovalbumin gene, which is inactive. To understand how the short (approximately 180-bp) nucleosome repeat arises specifically on beta-globin DNA, we have studied chromatin assembly of cloned chicken beta-globin DNA in a defined in vitro system. With chicken erythrocyte core histones and linker histone H5 as the only cellular components, a cloned 6.2-kb chicken beta-globin DNA fragment assembled into chromatin possessing a regular 180 +/- 5-bp repeat, very similar to what is observed in erythroid cells. A 2-kb DNA subfragment containing the beta A gene and promoter region, but lacking the downstream intergenic region between the beta A and epsilon genes, failed to generate a regular nucleosome array in vitro, suggesting that the intergenic region facilitates linker histone-induced nucleosome alignment. When the beta A gene was placed on a plasmid that contained a known chromatin-organizing signal, nucleosome alignment with a 180-bp periodicity was restored, whereas nucleosomes on flanking plasmid sequences possessed a 210-bp spacing periodicity. Our results suggest that the shortened 180-bp nucleosome spacing periodicity observed in erythroid cells is encoded in the beta-globin DNA sequence and that nucleosome alignment by linker histones is facilitated by sequences in the beta A-epsilon intergenic region.

Trypanosoma brucei brucei: differences in the nuclear chromatin of bloodstream forms and procyclic culture forms

Nucleosome filaments of two stages of the life-cycle of Trypanosoma brucei brucei, namely bloodstream forms and procyclic culture forms, were investigated by electron microscopy. Chromatin of bloodstream forms showed a salt-dependent condensation. The level of condensation was higher than that shown by chromatin from procyclic culture forms, but 30 nm fibres as formed in rat liver chromatin preparations were not found. Analysis of histones provided new evidence for the existence of H1-like proteins, which comigrated in the region of the core histones in SDS-PAGE and in front of the core histones in Triton acid urea gels. Differences were found between the H1-like proteins of the two trypanosome stages as well as between the core histones in their amount, number of bands and banding pattern. It can be concluded that T. b. brucei contains a full set of histones, including H1-like proteins, and that the poor condensation of its chromatin is not due to the absence of H1, but most probably due to histone-DNA interaction being weak. It is obvious that structural and functional differences of the chromatin exist not only between T. b. brucei and higher eukaryotes, but also between various stages of the life-cycle of the parasite. It is therefore not adequate to investigate the chromatin only of the procyclic culture forms as a model for all stages of the life-cycle of T. b. brucei.

Effects of plasmid length and positioned nucleosomes on chromatin assembly in vitro

Histone H5 induces extensive nucleosome alignment in vitro, with a 210 +/- 5 base pair (bp) average unit repeat, on some of the constructs derived from plasmid pBR327. Plasmid pBR327 itself aligns nucleosomes poorly, even though it possesses a chromatin organizing region which nucleates the alignment reaction [Jeong et al. (1991) J. Mol. Biol. 222, 1131-1147]. Examination of various regions of pBR327 chromatin by Southern hybridization revealed no substantial regional differences, suggesting an essentially all-or-none alignment mechanism. Twenty-four pBR327 deletion constructs, with the chromatin organizing region intact, were analyzed for nucleosome alignment in vitro, in addition to the six previously described. Although nucleosome alignment on plasmids of size greater than 5 kb was not affected by small length changes, circular plasmids with total lengths between 2400 and 3600 bp generally permitted alignment only when their lengths were close to integer multiples of 210 +/- 3 bp. The measured repeat lengths for the large plasmids and the smaller ones that aligned nucleosomes were all 210 bp, within experimental precision. The failure of two approximately 3.2-kb plasmids to align nucleosomes, even though their lengths were close to 15 x 210 bp, could be attributed to the effects of four strongly positioned nucleosomes that form on pBR327 sequences. Evidence is provided that nucleosome arrays can be quasicrystalline and are capable of transmitting information over a distance of more than 2 kb.

Biochemical and functional characterization of histone H1-like proteins in procyclic Trypanosoma brucei brucei

Four variants and/or posttranslational modifications of histone H1-like proteins of Trypanosoma brucei brucei procyclic culture forms were extracted with 0.25 N HCl from isolated nuclei and analyzed by two-dimensional gel electrophoresis. The amino acid composition of these proteins, their ability to space nucleosomes regularly and to induce salt-dependent condensation of the chromatin indicated their histone H1 nature. On the other hand, the histone H1-like proteins clearly differed from their higher-eukaryote counterparts by their weak interaction with DNA under low-salt conditions. As a consequence, intact nucleosome filaments were prepared according to a new preparation protocol especially adapted to the unstable chromatin of T. b. brucei. Our results indicate that the biochemical properties of the histone H1-like proteins contribute to the structural and functional differences between the chromatin of procyclic T. b. brucei and that of higher eukaryotes.

Nucleosome spacing is compressed in active chromatin domains of chick erythroid cells

We have cleaved the chromatin of embryonic and adult chicken erythroid cells using a novel nuclease that is capable of resolving clearly the nucleosomes of active chromatin. We found that in active chromatin, nucleosomes are spaced up to 40 base pairs closer together than in inactive chromatin. This was true for both "housekeeping" and "luxury" genes and was observed whether the digestion was carried out on isolated nuclei in vitro or by activating the endogenous nuclease in vivo. The close spacing extended several kilobases into flanking chromatin, indicating that this is a domain property of active chromatin, not just a characteristic of regions disrupted by transcription. A simple interpretation of our results is that the nucleosomes of active chromatin are mobile in vivo and, not being constrained by linker histones, freely move closer together.

Chromatin assembly on plasmid DNA in vitro. Apparent spreading of nucleosome alignment from one region of pBR327 by histone H5

We have found that histone H5 (or H1) induces physiological nucleosome spacings and extensive ordering on some plasmid constructions, but not on others, in a fully defined in vitro system. Plasmid pBR327 containing DNA insertions with lengths close to 300 base-pairs permitted histone H5 to induce a remarkable degree of nucleosome alignment. Seventeen multiples of a unit 210(+/- 4) base-pair repeat, covering the entire plasmid, were detected. Plasmid pBR327, not containing a DNA insert, permitted continuous alignment of only a few nucleosomes. These observations suggest that a necessary requirement in this system for histone H5 (or H1)-induced nucleosome alignment on small (less than 4 kb; 1 kb = 10(3) bases or base-pairs) circular plasmids may be that the total DNA length must be close to an integer multiple of the nucleosome repeat length generated, a type of boundary effect. Consistent with this hypothesis, five deletion constructs of pBR327 (not containing inserts), that spanned 64% of the plasmid, and possessed DNA lengths close to integer multiples of 210 base-pairs, permitted nucleosome alignment by histone H5. We have also found that plasmid length adjustment is not a sufficient condition for nucleosome alignment. For example, plasmids pBR322 and pUC18 did not permit nucleosome alignment when adjusted to near-integer multiples of 210 base-pairs. Also, for pBR327 that contained a length-adjusted deletion in one particular region, appreciable nucleosome alignment no longer occurred. These data suggest that a contiguous approximately 800 base-pair region of pBR327, interrupted in pBR322 and not present in pUC18, can nucleate histone H5-induced nucleosome alignment, which can then spread to adjacent chromatin. Supporting this idea, a positioned five-nucleosome array appears to originate in the required region. Additionally, on a larger (6.9 kb) plasmid construction, the "chromatin organizing region" of pBR327 and adjacent DNA on one side of it exhibited preferred H5-induced nucleosome alignment.

ATP dependent histone phosphorylation and nucleosome assembly in a human cell free extract

Physiologically spaced nucleosome formation in HeLa cell extracts is ATP dependent. ATP hydrolysis is required for chromatin assembly on both linear and covalently closed circular DNA. The link between the phosphorylation state of histones and nucleosome formation has been examined and we demonstrate that in the absence of histone phosphorylation no stable and regularly spaced nucleosomes are formed. Phosphorylated H3 stabilizes the nucleosome core; while phosphorylation of histone H2a is necessary to increase the linker length between nucleosomes from 0 to approximately 45 bp. Histone H1 alone, whether phosphorylated or unphosphorylated, does not increase the nucleosome repeat length in the absence of core histone phosphorylation. Phosphorylations of H1 and H3 correlate with condensation of chromatin. Maximum ATP hydrolysis which is necessary to increase the periodicity of nucleosomes from approximately 150 to approximately 185 bp, not only inhibits H1 and H3 phosphorylation but facilitates their dephosphorylation.

Role of nucleosomal cores and histone H1 in regulation of transcription by RNA polymerase II

The relation between chromatin structure and transcriptional activity was examined by in vitro transcription analysis of chromatin reconstituted in the absence or presence of histone H1. To maintain well-defined template DNA, purified components were used in the reconstitution of chromatin. Reconstitution of nucleosomal cores to an average density of 1 nucleosome per 200 base pairs of DNA resulted in a mild reduction of basal RNA polymerase II transcription to 25 to 50 percent of that obtained with naked DNA templates. This nucleosome-mediated repression was due to nucleosomal cores located at the RNA start site and could not be counteracted by the sequence-specific transcription activators Sp1 and GAL4-VP16. When H1 was incorporated into the chromatin at 0.5 to 1.0 molecule per nucleosome (200 base pairs of DNA), RNA synthesis was reduced to 1 to 4 percent of that observed with chromatin containing only nucleosomal cores, and this H1-mediated repression could be counteracted by the addition of Sp1 or GAL4-VP16 (antirepression). With naked DNA templates, transcription was increased by a factor of 3 and 8 by Sp1 and GAL4-VP-16, respectively (true activation). With H1-repressed chromatin templates, however, the magnitude of transcriptional activation mediated by Sp1 and GAL4-VP16 was 90 and more than 200 times higher, respectively, because of the combined effects of true activation and antirepression. The data provide direct biochemical evidence that support and clarify previously proposed models in which there is depletion or reconfiguration of nucleosomal cores and histone H1 at the promoter regions of active genes.

Effects of DNA sequence and histone-histone interactions on nucleosome placement

Using competitive reconstitution, we have refined the parameters for the binding of histone octamers to artificial nucleosome-positioning sequences of the form: (A/T3nn(G/C)3nn. We find that the optimal period between flexible segments is approximately 10.1 base-pairs, supporting the view that the DNA on the nucleosome surface is overwound. The strongest requirement for flexible DNA is near the protein dyad. However, we see no indication of changes in DNA helical repeat in this region. Using a series of repetitive sequences, we confirm that neither all A/T-rich nor all G/C-rich regions are identical in promoting nucleosome formation. Surprisingly, A/T-rich segments containing the TpA step, subject to purine-purine clash in the minor groove, favor nucleosome formation over sequences lacking this step. Short tracts of adenine residues are found to position on the histone surface like other A/T-rich regions, in the manner predicted by the direction of their sequence-directed bends as determined by electrophoretic methods. Tracts containing five adenine residues are extremely aniostropic in their flexibility and are strongly detrimental to nucleosome formation when positioned for major groove compression. Longer adenine tracts are found to position near the ends of the nucleosomal DNA. However, other positions may be occupied by an A12 tract, with only a minor penalty in the free energy of nucleosome formation. Overall, reconstituted nucleosome positions are translationally degenerate, suggesting a weak dependence on DNA flexibility for nucleosome positioning. Dinucleosomal reconstitutions on tandem dimers of the 5 S RNA gene of Lytechinus variegatus demonstrate a weak phasing dependence for the interaction between nucleosomes. This interaction is maximal for the 202 base-pair repeat and suggests a co-operative mechanism for the formation of ordered nucleosomal arrays based on a combination of DNA flexibility and nucleosome-nucleosome interactions.

Location of nucleosomes in simian virus 40 chromatin

Over the past decade, the results of numerous indirect mappings analyses have not clarified whether or not nucleosomes occupy preferred positions in simian virus 40 (SV40) chromatin. To address this question more directly, we followed a shotgun cloning approach and determined the nucleotide sequences of over 400 cloned nucleosomal DNA fragments obtained from digestion of SV40 chromatin with micrococcal nuclease. Our results demonstrate and establish that nucleosomes do not occupy unique positions in SV40 minichromosomes and thus indicate the existence of at least several types of chromatin molecules having different nucleosome organization patterns. We developed two types of statistical analysis in order to examine the cloning data in greater detail. One type, overlap analysis, revealed the distribution of the cloned fragments with respect to SV40 DNA. The distribution exhibits an oscillating pattern, dividing the genome into regions of weak or strong nucleosome density. The other analysis determined the distribution of the midpoints of the cloned fragments and revealed potential strong and weak nucleosome location sites, and an early versus late distinction in organization of nucleosomes in SV40 chromatin. The late region appears to contain more strong nucleosome location sites (8) than the early region (4). The strongest nucleosome abuts the late side of the nuclease-hypersensitive region and includes the major transcription initiation site of the late genes. Another strong site precedes this nucleosome and includes sequences implicated in controlling the expression of the SV40 early and late genes. A strong or weak nucleosome location site is not apparent near the early side of the nucleosome-hypersensitive region. Only weak and overlapping nucleosome location sites are found in the region where replication terminates in the SV40 minichromosomes.

Chromatin reconstitution on small DNA rings. III. Histone H5 dependence of DNA supercoiling in the nucleosome

Mononucleosomes were reconstituted on small DNA rings in the presence of histone H5 and relaxed to an equilibrium using calf thymus topoisomerase I. DNA products, when compared to the equilibria observed with the same minicircles in the absence of histones, showed that a linking number reduction of 1.6 to 1.7 was associated with this reconstitution, in contrast with the 1.1 to 1.2 figure reported in our recent study of the H5-free nucleosome. Gel electrophoretic properties and electron microscopic visualization of the nucleosomes suggest a correlation between this increase and a further wrapping of the DNA around the histone core from less than 1.5 turns of the superhelix in the absence of H5, to close to two turns in its presence. Implications for DNA topology in chromatin are discussed.

Nucleosome assembly of simian virus 40 DNA in a mammalian cell extract

We report here a mammalian cell-free system that can support chromatin assembly. Effective nucleosome assembly in HeLa cell extracts occurred at 125 to 200 mM KCl or potassium glutamate. At this physiological K+ ion concentration, two types of chromatin assembly were observed. The first was interfered with by Mg2+. Other cations such as Mn2+, Ca2+, Fe3+, and spermidine also inhibited this type of nucleosome assembly. The second type of assembly occurred in the presence of Mg2+ and at least equimolar ATP. However, even in the presence of ATP, excess Mg2+ inhibited assembly and promoted catenation of DNA; these effects could be circumvented by excess ATP, GTP, EDTA, or polyglutamic acid. The critical DNA concentration for optimum assembly in both pathways suggested a stoichiometric association of histones with DNA. The spacing of nucleosomes formed by both types of assembly on linear and circular DNA was reasonably regular, but chromatin assembled in the presence of ATP and Mg2+ was more stable.

Nucleosome assembly of simian virus 40 DNA in a mammalian cell extract

We report here a mammalian cell-free system that can support chromatin assembly. Effective nucleosome assembly in HeLa cell extracts occurred at 125 to 200 mM KCl or potassium glutamate. At this physiological K+ ion concentration, two types of chromatin assembly were observed. The first was interfered with by Mg2+. Other cations such as Mn2+, Ca2+, Fe3+, and spermidine also inhibited this type of nucleosome assembly. The second type of assembly occurred in the presence of Mg2+ and at least equimolar ATP. However, even in the presence of ATP, excess Mg2+ inhibited assembly and promoted catenation of DNA; these effects could be circumvented by excess ATP, GTP, EDTA, or polyglutamic acid. The critical DNA concentration for optimum assembly in both pathways suggested a stoichiometric association of histones with DNA. The spacing of nucleosomes formed by both types of assembly on linear and circular DNA was reasonably regular, but chromatin assembled in the presence of ATP and Mg2+ was more stable.

Sequence-specific chemical modification of chromatin DNA with reactive derivatives of oligonucleotides

Chemical modification of the chromatin DNA with alkylating derivatives of oligothymidylate (pT)16 and oligoadenylate (pA)16 bearing 4-(N-2-chloroethyl-N-methylamino)benzylphosphamide group at the 5'-phosphate has been investigated. It was found that the derivatives do react with DNA in chromatin. The reactions occur presumably at the complementary sequences of the DNA since the reaction of the oligothymidylate derivative is inhibited by oligonucleotide (pT)16 taken in excess and is not influenced by hexadecanucleotide of a random structure. Isolated DNA does not react with the oligothymidylate derivative. It is concluded that in chromatin, DNA is partially unwound or possesses some sites which can be opened easily in the presence of complementary oligonucleotides.

Histone H1 represses transcription from minichromosomes assembled in vitro

We have previously shown that transcription from a Xenopus 5S rRNA gene assembled into chromatin in vitro can be repressed in the absence of histone H1 at high nucleosome densities (one nucleosome per 160 base pairs of DNA) (A. Shimamura, D. Tremethick, and A. Worcel, Mol. Cell. Biol. 8:4257-4269, 1988). We report here that transcriptional repression may also be achieved at lower nucleosome densities (one nucleosome per 215 base pairs of DNA) when histone H1 is present. Removal of histone H1 from the minichromosomes with Biorex under conditions in which no nucleosome disruption was observed led to transcriptional activation. Transcriptional repression could be restored by adding histone H1 back to the H1-depleted minichromosomes. The levels of histone H1 that repressed the H1-depleted minichromosomes failed to repress transcription from free DNA templates present in trans. The assembly of transcription complexes onto the H1-depleted minichromosomes protected the 5S RNA gene from inactivation by histone H1.

Histone H1 represses transcription from minichromosomes assembled in vitro

We have previously shown that transcription from a Xenopus 5S rRNA gene assembled into chromatin in vitro can be repressed in the absence of histone H1 at high nucleosome densities (one nucleosome per 160 base pairs of DNA) (A. Shimamura, D. Tremethick, and A. Worcel, Mol. Cell. Biol. 8:4257-4269, 1988). We report here that transcriptional repression may also be achieved at lower nucleosome densities (one nucleosome per 215 base pairs of DNA) when histone H1 is present. Removal of histone H1 from the minichromosomes with Biorex under conditions in which no nucleosome disruption was observed led to transcriptional activation. Transcriptional repression could be restored by adding histone H1 back to the H1-depleted minichromosomes. The levels of histone H1 that repressed the H1-depleted minichromosomes failed to repress transcription from free DNA templates present in trans. The assembly of transcription complexes onto the H1-depleted minichromosomes protected the 5S RNA gene from inactivation by histone H1.

Assembly and properties of chromatin containing histone H1

The Xenopus oocyte supernatant (oocyte S-150) forms chromatin in a reaction that is affected by temperature and by the concentration of ATP and Mg. Under optimal conditions at 27 degrees C, relaxed DNA plasmids are efficiently assembled into supercoiled minichromosomes with the endogenous histones H3, H4, H2A and H2B. This assembly reaction is a gradual process that takes four to six hours for completion. Micrococcal nuclease digestions of the chromatin assembled under these conditions generate an extended series of DNA fragments that are, on average, multiples of 180 base-pairs. We have examined the effect of histone H1 in this system. Exogenous histone H1, when added at a molar ratio of H1 to nucleosome of 1:1 to 5:1, causes an increase in the micrococcal nuclease resistance of the chromatin without causing chromatin aggregation under these experimental conditions. Furthermore, the periodically arranged nucleosomes display longer internucleosome distances, and the average length of the nucleosome repeat is a function of the amount of histone H1 added, when this histone is present at the onset of the assembly process. In contrast, no major change in the length of the nucleosome repeat is observed when histone H1 is added at the end of the chromatin assembly process. Protein analyses of the purified minichromosomes show that histone H1 is incorporated in the chromatin that is assembled in the S-150 supplemented with histone H1. The amount of histone H1 bound to chromatin is a function of the total amount of histone H1 added. We define here the parameters that generate histone H1-containing chromatin with native nucleosome repeats from 160 to 220 base-pairs, and we discuss the implications of these studies.

Self-attraction and natural curvature in null DNA

Forces of self-attraction inherent in DNA are unmasked when its ionic charge is neutralized. On the global level, self-attraction operates between segments to condense null (charge-neutralized) DNA into a segment-rich particle. Locally, self-attraction tends to contract an individual segment along its axis. If certain conditions are satisfied, the compressed segment buckles outward from the original line of the axis. Its most stable shape is then curved, or, as an extreme case, even completely folded. Buckling conditions are derived and shown to be met by DNA, thus explaining the high degree of ordered curvature and folding in the observed morphologies of condensed null DNA. The central concept employed is the buckling persistence length. It is evaluated for null DNA (40-50 bp) and agrees with experimental data (less than 60 bp). It helps in understanding the observed cooperative unit in the condensation/decondensation equilibrium (about 60 bp) and the observed size of digestion fragments unstable in the condensed phase (about 80 bp). The root-mean-square thermal compression/extension fluctuation in DNA is estimated at about 0.1 A/bp.

Reconstitution of nucleosomes in vitro with a plasmid carrying the long terminal repeat of Moloney murine leukemia virus

The potential of nucleosome assembly along the sequence of a plasmid carrying the long terminal repeat (LTR) and its flanking region of Moloney murine leukemia virus was analyzed by in vitro reconstitution experiments with histones from chicken erythrocytes. The results of electrophoretic mobility-shift and micrococcal nuclease-digestion assays indicated that the plasmid DNA contained four preferred sites for nucleosome formation. However, all of these sites were mapped on the vector moiety but not on the LTR moiety. Computer analysis of the sequences in the four preferred sites, each spanning about 150 bp, indicated that short runs of (dA,dT) containing two kinds of triplets, AAA/TTT and AAT/ATT, occurred frequently. Furthermore, many of these triplets tended to occur in the same side of the DNA helix, suggesting that DNA curvature was involved in the preferred sites for nucleosome assembly. Consistent was the observation that DNA fragments carrying these preferred sites showed anomalous electrophoretic mobilities at a low temperature.

Characterization of the repressed 5S DNA minichromosomes assembled in vitro with a high-speed supernatant of Xenopus laevis oocytes

We describe an in vitro system, based on the Xenopus laevis oocyte supernatant of Glikin et al. (G. Glikin, I. Ruberti, and A. Worcel, Cell 37:33-41, 1984), that packages DNA into minichromosomes with regularly spaced nucleosomes containing histones H3, H4, H2A, and H2B but no histone H1. The same supernatant also assembles the 5S RNA transcription complex; however, under the conditions that favor chromatin assembly, transcription is inhibited and a phased nucleosome forms over the 5S RNA gene. The minichromosomes that are fully loaded with nucleosomes remain refractory to transcriptional activation by 5S RNA transcription factors. Our data suggest that this repression is caused by a nucleosome covering the 5S RNA gene and that histone H1 is not required for regular nucleosome spacing or for gene repression in this system.

Differences in the binding of H1 variants to DNA. Cooperativity and linker-length related distribution

A study of the complexes formed between short linear DNA and three H1 variants, a typical somatic H1, and the extreme variants H5, from chicken erythrocytes, and spH1 from sea urchin sperm, has revealed differences between H1, H5 and spH1 that have implications for chromatin structure and folding. 1. All three histones bind cooperatively to DNA in 35 mM NaCl forming similar, but not identical, rod-like complexes. With sufficiently long DNA the complexes may be circular, circles forming more easily with H5 and spH1 than with H1. 2. The binding of H5 and spH1 to DNA is cooperative even in 5 mM NaCl, resulting in well-defined thin filaments that appear to contain two DNA molecules bridged by histone molecules. In contrast, H1 binds distributively over all the DNA molecules in 5 mM NaCl, but forms short stretches similar in appearance to the thin filaments formed with H5 and spH1. Rods appear to arise from the intertwining of regular thin filaments containing cooperatively bound histone molecules on raising the NaCl concentration to 35 mM. 3. The compositions of the rods correspond to one histone molecule for about every 47 bp (H1), 81 bp (H5) and 112 bp (spH1), suggesting average spacings of 24 bp (H1), 41 bp (H5) and 56 bp (spH1) in the component thin (double) filaments. Strikingly, these values are proportional to the linker lengths of the chromatins in which the particular H1 variant is the main or sole H1.

Generation of different nucleosome spacing periodicities in vitro. Possible origin of cell type specificity

We have been able to generate ordered nucleosome arrays that span the physiological range of spacing periodicities, using an in vitro system. Our system (a refinement of the procedure previously developed) uses the synthetic polynucleotide poly[d(A-T)], poly[d(A-T)], core histones, purified H1, and polyglutamic acid, a factor that increases nucleohistone solubility and greatly promotes the formation of ordered nucleosome arrays. This system has three useful features, not found in other chromatin assembly systems. First, it allowed us to examine histones from three different cell types/species (sea urchin sperm, chicken erythrocyte, and HeLa) as homologous or heterologous combinations of core and H1 histones. Second, it allowed us to control the average packing density (core histone to polynucleotide weight ratio) of nucleosomes on the polynucleotide; histone H1 is added in a second distinct step in the procedure to induce nucleosome alignment. Third, it permitted us to study nucleosome array formation in the absence of DNA base sequence effects. We show that the value of the spacing periodicity is controlled by the value of the initial average nucleosome packing density. The full range of physiological periodicities appears to be accessible to arrays generated using chicken erythrocyte (or HeLa) core histones in combination with chicken H5. However, chromatin-like structures cannot be assembled for some nucleosome packing densities in reactions involving some histone types, thus limiting the range of periodicities that can be achieved. For example, H1 histone types differ significantly in their ability to recruit disordered nucleosomes into ordered arrays at low packing densities. Sea urchin sperm H1 is more efficient than chicken H5, which is more efficient than H1 from HeLa or chicken erythrocyte. Sea urchin sperm core histones are more efficient in this respect than the other core histone types used. These findings suggest how different repeat lengths arise in different cell types and species, and provide new insights into the problems of nucleosome linker heterogeneity and how different types of chromatin structures could be generated in the same cell.

Characterization of the repressed 5S DNA minichromosomes assembled in vitro with a high-speed supernatant of Xenopus laevis oocytes

We describe an in vitro system, based on the Xenopus laevis oocyte supernatant of Glikin et al. (G. Glikin, I. Ruberti, and A. Worcel, Cell 37:33-41, 1984), that packages DNA into minichromosomes with regularly spaced nucleosomes containing histones H3, H4, H2A, and H2B but no histone H1. The same supernatant also assembles the 5S RNA transcription complex; however, under the conditions that favor chromatin assembly, transcription is inhibited and a phased nucleosome forms over the 5S RNA gene. The minichromosomes that are fully loaded with nucleosomes remain refractory to transcriptional activation by 5S RNA transcription factors. Our data suggest that this repression is caused by a nucleosome covering the 5S RNA gene and that histone H1 is not required for regular nucleosome spacing or for gene repression in this system.

Spectroscopic studies on histone-DNA interactions. I. The interaction of histone (H2A, H2B) dimer with DNA: DNA sequence dependence

Binding of the histone (H2A, H2B) dimer with chicken erythrocyte DNA has been studied by salt-titration spectroscopy in equilibrium conditions. The circular dichroism of DNA near 275 nm is depressed by the interaction with (H2A, H2B) at low concentrations of salt. The depression increases with increasing amounts of (H2A, H2B), and reaches a plateau at an (H2A, H2B) to DNA ratio of 1.5 (w/w), at which one (H2A, H2B) dimer occupies 28 base-pairs of DNA. The fluorescence emission intensity of the tyrosine residues in (H2A, H2B) is depressed by the H2A, H2B)-DNA interaction. When the DNA-(H2A, H2B) complex is titrated with NaCl, these two signals show transitions with increasing ionic strength of the buffer, whose normalized transition curves agree well. The midpoint of the transition is about 0.42 M-NaCl for a sample with a DNA concentration of 0.05 mg/ml and an (H2A, H2B) to DNA ratio of 0.4 (w/w). The fluorescence titration curves have been analyzed to obtain the binding constant for the (H2A, H2B) dimer with DNA. The sample concentration dependence of the titration profiles is consistent with the model of non-cooperative binding of (H2A, H2B) dimer to DNA. The titration profiles are reversible. The obtained binding constant for the (H2A, H2B) dimer with chicken erythrocyte DNA at 20 degrees C (pH 7.6), as a function of the ionic strength, I, is as follows: log10K = -14.9 log10(I)-1.2. The change of enthalpy delta H accompanied by the binding of the (H2A, H2B) dimer is nearly equal to zero, within an error of +/- 1.4 kcal/mol (1 cal = 4.184 J). DNA sequence dependence of the stability of DNA-(H2A, H2B) interactions is observed using reconstituted materials of synthetic DNAs. A decreasing stability of the interaction is observed following the order: the duplex of poly[(dA)-(dT)] greater than chicken erythrocyte DNA or the copolymer duplex of poly(dA).poly(dT) greater than the duplex of poly[(dG)-(dC)]. The difference in free energy of the association of the (H2A,H2B) dimer between the two copolymers is 0.8 kcal/mol.

Spectroscopic studies on histone-DNA interactions. II. Three transitions in nucleosomes resolved by salt-titration

The multiple-step transitions in DNA-histone interactions in chicken erythrocyte nucleosomes with increasing ionic strength are resolved by salt-titration spectroscopy. Both the circular dichroism of the DNA and the fluorescence of the histones in nucleosomes change during the titration process with concentrations of NaCl from 0.1 M to 2.5 M. By differentiating the titration curves, three distinct peaks corresponding to three structural transitions are observed. The two peaks near 0.95 M and 1.45 M-NaCl are common to the circular dichroism and fluorescence curves. The circular dichroism curve has another peak near 0.55 M-NaCl. Because the derivative of the fluorescence titration curve for the DNA-(H3, H4) complex has only one peak near 1.45 M-NaCl, that peak is attributed to the dissociation of the histone dimer (H3, H4). The peak near 0.95 M-NaCl corresponds to the dissociation of the dimer (H2A, H2B) from the DNA-(H3, H4) complex, as shown by binding experiments of (H2A, H2B) to the DNA-(H3, H4) complex at the salt concentration near this peak. The peak near 0.55 M-NaCl reflects some inner-core structural change. As the change of the circular dichroism signal is reversible, salt-titration spectroscopy is applicable to equilibrium studies of the physical chemical properties of DNA-histone interactions. By the assumption of a non-co-operative model, the binding constant for the chicken erythrocyte (H2A, H2B) dimer to the DNA-(H3, H4) complex is calculated as 2.8 X 10(6) M-1 at 1.0 M-NaCl (20 degrees C, pH 7.6). The DNA sequence dependence of the stability of the DNA-(H3, H4) interaction is observed in the salt-titration profiles of reconstituted material. Decreasing stability of the interaction of (H3, H4) is observed following the order: poly[(dG)-(dC)] much greater than chicken erythrocyte DNA greater than poly[(dA)-(dT)]. It is concluded that histones (H3, H4) have a different DNA sequence dependence from histones (H2A, H2B).