Selective unfolding of erythroid chromatin in the region of the active beta-globin gene

How does chromatin package DNA within nucleus and regulate gene expression?

The human body is made up of 60 trillion cells, each cell containing 2 millions of genomic DNA in its nucleus. How is this genomic deoxyribonucleic acid [DNA] organised into nuclei? Around 1880, W. Flemming discovered a nuclear substance that was clearly visible on staining under primitive light microscopes and named it 'chromatin'; this is now thought to be the basic unit of genomic DNA organization. Since long before DNA was known to carry genetic information, chromatin has fascinated biologists. DNA has a negatively charged phosphate backbone that produces electrostatic repulsion between adjacent DNA regions, making it difficult for DNA to fold upon itself. In this article, we will try to shed light on how does chromatin package DNA within nucleus and regulate gene expression?

Functional interplay between histone H1 and HMG proteins in chromatin

The dynamic interaction of nucleosome binding proteins with their chromatin targets is an important element in regulating the structure and function of chromatin. Histone H1 variants and High Mobility Group (HMG) proteins are ubiquitously expressed in all vertebrate cells, bind dynamically to chromatin, and are known to affect chromatin condensation and the ability of regulatory factors to access their genomic binding sites. Here, we review the studies that focus on the interactions between H1 and HMGs and highlight the functional consequences of the interplay between these architectural chromatin binding proteins. H1 and HMG proteins are mobile molecules that bind to nucleosomes as members of a dynamic protein network. All HMGs compete with H1 for chromatin binding sites, in a dose dependent fashion, but each HMG family has specific effects on the interaction of H1 with chromatin. The interplay between H1 and HMGs affects chromatin organization and plays a role in epigenetic regulation.

Coming to terms with chromatin structure

Chromatin, once thought to serve only as a means to package DNA, is now recognized as a major regulator of gene activity. As a result of the wide range of methods used to describe the numerous levels of chromatin organization, the terminology that has emerged to describe these organizational states is often imprecise and sometimes misleading. In this review, we discuss our current understanding of chromatin architecture and propose terms to describe the various biochemical and structural states of chromatin.

A new fractionation assay, based on the size of formaldehyde-crosslinked, mildly sheared chromatin, delineates the chromatin structure at promoter regions

To explore the higher order structure of transcribable chromatin in vivo, its local configuration was assessed through the accessibility of the chromatin to crosslinking with formaldehyde. The application of crosslinked and mildly sheared chromatin to sedimentation velocity centrifugation followed by size-fractionation of the DNA enabled us to biochemically distinguish between chromatin with heavily versus sparsely crosslinkable structures. The separated fractions showed a good correlation with gene expression profiles. Genes with poor crosslinking around the promoter region were actively transcribed, while transcripts were hardly detected from genes with extensive crosslinking in their promoter regions. For the inducible gene, Il2, the distribution of the promoter shifted in the gradient following T-cell receptor stimulation, consistent with a change in structure at this locus during activation. The kinetics of this switch preceded the chromatin change observed in a DNase I accessibility assay. Thus, this new chromatin fractionation technique has revealed a change in chromatin structure that has not been previously characterized.

Chromatin structure and DNA methylation of the IL-4 gene in human T(H)2 cells

Human T(H)2 cell differentiation results in the selective demethylation of several specific CpG dinucleotides in the IL-4 and IL-13 genes, which are expressed in activated T(H)2, but not T(H)1, cells. This demethylation is accompanied by the appearance of six DNase I hypersensitive sites within 1.4 kb at the 5'-end of the IL-4 gene. Micrococcal nuclease (MNase) digestion revealed that in both T(H)1 and T(H)2 cells nine nucleosomes with a repeat length of 201 bp are identically positioned around the 5'-end of the IL-4 gene. However, only in T(H)2 cells are six out of the eight intervening linkers exposed to DNase I. This suggests that a major perturbation of the higher-order chromatin structure occurs above the level of the nucleosome in vivo. It is observed in cells that are poised for expression but which are not actively expressing the gene (i.e. resting T(H)2 cells). Notably, all the demethylated CpGs in T(H)2 cells are found in DNA that is accessible to DNase I. This may suggest that the opening of the chromatin structure allows binding of specific trans-acting factors that prevent de novo methylation.

The chromatin of active genes is not in a permanently open conformation

Quantitative measurements of local chromatin accessibility to DNase I in 15-day chicken embryo erythrocyte nuclei have been performed using a range of nuclease concentrations and real-time TaqMan PCR to monitor the loss of short ( approximately 80 bp) amplicons. At the beta-globin locus, well-established DNase I hypersensitive sites stand out against a background in which actively transcribed gene sequences (e.g., beta-adult and beta-hatching) are no more sensitive than the nearby constitutive heterochromatin that has previously been shown to form the 30-nm fibre structure. Similar observations were made at the lysozyme locus containing the active Gas41 gene and also at the GAPDH locus. We conclude that active genes are not continuously held in an open 'beads-on-a-string' configuration, but adopt a 30-nm-type structure most of the time. This implies that the compact nucleosomal supercoil re-forms in the wake of the polymerase complex.

Hydrodynamic studies on defined heterochromatin fragments support a 30-nm fiber having six nucleosomes per turn

We have compared the physical properties of a 15.51-kb constitutive heterochromatin segment and a 16.17-kb facultative heterochromatin segment that form part of the chicken beta-globin locus. These segments were excised from an avian erythroleukemia cell line by restriction enzyme digestion and released from the nucleus, thus allowing measurement of the sedimentation coefficients by use of calibrated sucrose gradients. A determination of the buoyant density of the cross-linked particle in CsCl led to the total mass of the particles and their frictional coefficients, f. Despite the slight differences in nucleosome density, the measured value of f for both fragments was consistent with a rodlike particle having a diameter of 33-45 nm and a length corresponding to approximately six to seven nucleosomes per 11-nm turn. At higher ionic strengths we found no evidence of any abrupt conformational change, demonstrating that these chromatin fragments released from the nucleus did not assume the more compact conformations recently described for some reconstituted structures.

Long-range histone acetylation: biological significance, structural implications, and mechanismsThis paper is one of a selection of papers published in this Special Issue, entitled 27th International West Coast Chromatin and Chromosome Conference, and has undergone the Journal's usual peer review process

Genomic characterization of various euchromatic regions in higher eukaryotes has revealed that domain-wide hyperacetylation (over several kb) occurs at a range of loci, including individual genes, gene family clusters, compound clusters, and more general clusters of unrelated genes. Patterns of long-range histone hyperacetylation are strictly conserved within each unique cellular system studied and they reflect biological variability in gene regulation. Domain-wide histone acetylation consists generally of nonuniform peaks of enriched hyperacetylation of specific core histones, histone isoforms, and (or) histone variants against a backdrop of nonspecific acetylation across the domain in question. Here we review the characteristics of long-range histone acetylation in some higher eukaryotes and draw special attention to recent literature on the multiple effects that histone hyperacetylation has on chromatin’s structural integrity and how they affect transcription. These include the thermal, ionic, cumulative, and isoform-specific (H4 K16) consequences of acetylation that result in a more dynamic core complex and chromatin fiber.

Systems biology in the cell nucleus

The mammalian nucleus is arguably the most complex cellular organelle. It houses the vast majority of an organism's genetic material and is the site of all major genome regulatory processes. Reductionist approaches have been spectacularly successful at dissecting at the molecular level many of the key processes that occur within the nucleus, particularly gene expression. At the same time, the limitations of analyzing single nuclear processes in spatial and temporal isolation and the validity of generalizing observations of single gene loci are becoming evident. The next level of understanding of genome function is to integrate our knowledge of their sequences and the molecular mechanisms involved in nuclear processes with our insights into the spatial and temporal organization of the nucleus and to elucidate the interplay between protein and gene networks in regulatory circuits. To do so, catalogues of genomes and proteomes as well as a precise understanding of the behavior of molecules in living cells are required. Converging technological developments in genomics, proteomics, dynamics and computation are now leading towards such an integrated biological understanding of genome biology and nuclear function.

Chromatin architecture of the human genome: gene-rich domains are enriched in open chromatin fibers

We present an analysis of chromatin fiber structure across the human genome. Compact and open chromatin fiber structures were separated by sucrose sedimentation and their distributions analyzed by hybridization to metaphase chromosomes and genomic microarrays. We show that compact chromatin fibers originate from some sites of heterochromatin (C-bands), and G-bands (euchromatin). Open chromatin fibers correlate with regions of highest gene density, but not with gene expression since inactive genes can be in domains of open chromatin, and active genes in regions of low gene density can be embedded in compact chromatin fibers. Moreover, we show that chromatin fiber structure impacts on further levels of chromatin condensation. Regions of open chromatin fibers are cytologically decondensed and have a distinctive nuclear organization. We suggest that domains of open chromatin may create an environment that facilitates transcriptional activation and could provide an evolutionary constraint to maintain clusters of genes together along chromosomes.

Physical properties of a genomic condensed chromatin fragment

We have studied the physical properties of a segment of condensed chromatin that lies upstream of the chicken beta-globin locus. This segment can be excised from an avian erythroleukemia cell line by restriction enzyme digestion and released from the nucleus as an essentially homogeneous fragment about 15.5 kbp long. Because of this homogeneity we could measure its sedimentation coefficient quite accurately by a combination of sucrose gradient and analytical ultracentrifugation. By measuring additionally the buoyant density of the cross-linked particle in CsCl we could deduce the total mass of the particle, hence its frictional coefficient, f, directly related to its shape. The measured value of f is consistent with a rod-like particle of the approximate length and diameter proposed earlier for the 30 nm chromatin fiber. The method is generally applicable to homogeneous particles of unique sequence at genomic abundance.

Tn5406, a new staphylococcal transposon conferring resistance to streptogramin a and related compounds including dalfopristin

We characterized a new transposon, Tn5406 (5,467 bp), in a clinical isolate of Staphylococcus aureus (BM3327). It carries a variant of vgaA, which encodes a putative ABC protein conferring resistance to streptogramin A but not to mixtures of streptogramins A and B. It also carries three putative genes, the products of which exhibit significant similarities (61 to 73% amino acid identity) to the three transposases of the staphylococcal transposon Tn554. Like Tn554, Tn5406 failed to generate target repeats. In BM3327, the single copy of Tn5406 was inserted into the chromosomal att554 site, which is the preferential insertion site of Tn554. In three other independent S. aureus clinical isolates, Tn5406 was either present as a single plasmid copy (BM3318), as two chromosomal copies (BM3252), or both in the chromosome and on a plasmid (BM3385). The Tn5406-carrying plasmids also contain two other genes, vgaB and vatB. The insertion sites of Tn5406 in BM3252 were studied: one copy was in att554, and one copy was in the additional SCCmec element. Amplification experiments revealed circular forms of Tn5406, indicating that this transposon might be active. To our knowledge, a transposon conferring resistance to streptogramin A and related compounds has not been previously described.

Junk DNA and sectorial gene repression

Transcriptional repression in eukaryotes often involves tens or hundreds of kilobase pairs, two to three orders of magnitude more than the bacterial operator/repressor model does. Classical repression, represented by this model, was maintained over the whole span of evolution under different guises, and consists of repressor factors interacting primarily with promoters and, in later evolution, also with enhancers. The use of much larger amounts of DNA in the other mode of repression, here called the sectorial mode ('superrepression'), results in the conceptual transfer of so-called junk DNA to the domain of functional DNA. This contribution to the solution of the c-value paradox involves perhaps 15% of genomic 'junk,' and encompasses the bulk of the introns, thought to fill a stabilizing role in sectorially repressed chromatin structures. In the case of developmental genes, such structures appear to be heterochromatoid in character. However, solid clues regarding general structural features of superrepressed terminal differentiation genes remain elusive. The competition among superrepressible DNA sectors for sectorially binding factors offers, in principle, a molecular mechanism for developmental switches. Position effect variegation may be considered an abnormal manifestation of normal processes that underly development and involve heterochromatoid sectorial repression, which is apparently required for local elimination or modulation of morphological features (morpholysis). Sectorial repression of genes participating either in development or in terminal differentiation is considered instrumental in establishing stable cell types, and provides a basis for the distinction between determination and cell type specification. The gamut of possible stable cell types may have been broadened by the appearance in evolution of heavy isochores. Additional types of relatively frequent GC-rich cis-acting DNA motifs may offer reiterated binding sites to factors endowed with a selective (though not individually strong) affinity for these motifs. The majority of sequence motifs thought to be used in superrepression need not be individually maintained by natural selection. It is re-emphasized that the dispensability of sequences is not an indicator of their nonfunctionality and that in many cases, along noncoding sequences, nucleotides tend to fill functions collectively, rather than individually.

Alleviation of histone H1-mediated transcriptional repression and chromatin compaction by the acidic activation region in chromosomal protein HMG-14

Histone H1 promotes the generation of a condensed, transcriptionally inactive, higher-order chromatin structure. Consequently, histone H1 activity must be antagonized in order to convert chromatin to a transcriptionally competent, more extended structure. Using simian virus 40 minichromosomes as a model system, we now demonstrate that the nonhistone chromosomal protein HMG-14, which is known to preferentially associate with active chromatin, completely alleviates histone H1-mediated inhibition of transcription by RNA polymerase II. HMG-14 also partially disrupts histone H1-dependent compaction of chromatin. Both the transcriptional enhancement and chromatin-unfolding activities of HMG-14 are mediated through its acidic, C-terminal region. Strikingly, transcriptional and structural activities of HMG-14 are maintained upon replacement of the C-terminal fragment by acidic regions from either GAL4 or HMG-2. These data support the model that the acidic C terminus of HMG-14 is involved in unfolding higher-order chromatin structure to facilitate transcriptional activation of mammalian genes.

Structure of active chromatin: higher-order folding of transcriptionally active chromatin in control and hypothyroid rat liver

Investigation have been carried out into the salt-induced higher-order folding in the transcriptionally active chromatin region of rat liver nuclei by nuclease digestion, sedimentation and CD. The sensitivity of active chromatin in nuclei to micrococcal nuclease was suppressed by raising the ionic strength from 25 to 90 mM, indicating the occurrence of salt-induced condensation. The rate of sedimentation of fractionated inactive chromatin fragments of both moderate (approximately 3.5 kbp) and large (approximately 8.8 kbp) size increased maximally to the same extent, while that of active chromatin fragments was dependent on their size. The rate of sedimentation of moderately sized active chromatin fragments (approximately 5.5 kbp) showed a maximal 15% increase at 90 mM ionic strength. In contrast, a large increase (at least 60%) in the sedimentation rate of large active chromatin fragments (approximately 21 kbp) was observed at 65 mM ionic strength. A reasonable degree of higher-order folding was observed in large active chromatin fragment even at 25 mM ionic strength. On considering the percentage increase in sedimentation rate as a measure of the higher-order folding of chromatin, a different type of higher-order folding was observed in active chromatin fragments. Although the percentage increase in sedimentation decreased from 40 to 24% with an increase in the size of active chromatin from approximately 3 to approximately 9 kbp, a further increase in size up to 16 kbp brought the percentage increase back to 40%. CD studies agreed with the conclusions drawn from sedimentation studies. Active chromatin from hypothyroid rats showed similar folding behaviour, but the order of folding was slightly lower than for control active chromatin, at all sizes.

Diversity among the gram-positive acetyltransferases inactivating streptogramin A and structurally related compounds and characterization of a new staphylococcal determinant, vatB

A gene encoding an acetyltransferase inactivating streptogramin A (SgA) and structurally similar compounds was isolated from a staphylococcal plasmid and sequenced. This gene, designated vatB, potentially encodes a 212-amino-acid protein, VatB, of 23,320 Da with 47.4 and 58.4% amino acid identities with two other enzymes with the same activity, Vat and SatA, respectively, which are encoded by a staphylococcal plasmid and an enterococcal plasmid, respectively. The C-terminal parts of these three enzymes share significant homology with the C-terminal parts of 10 other acetyltransferases modifying various substrates. A pair of degenerate primers representing the conserved motifs shared by VatB, Vat, and SatA was designed to detect the three genes encoding these SgA acetyltransferases. Five of 12 clinical SgAr Staphylococcus aureus isolates tested carried neither these genes nor the gene vga, which confers resistance to SgA by a different mechanism, suggesting that another gene(s) and possibly another mechanism of resistance to SgA in staphylococci remains to be characterized.

Repair of transcriptionally active and inactive genes during S and G2 phases of the cell cycle

To study the effect of ultraviolet irradiation on S and G2 phases of the cell cycle, BB88 mouse cells synchronized by a double thymidine block were exposed to ultraviolet light, and rates of DNA synthesis and mitotic indexes were determined at regular intervals. It was found that with increasing ultraviolet dose, semiconservative DNA synthesis decreased and the sharp mitotic wave observed in the unirradiated cells gradually degenerated. To study repair, semiconservative DNA replication was inhibited with hydroxyurea at different time intervals after releasing cells from the block and the DNA synthesized as a result of repair of the ultraviolet damage was labeled with 5'-bromodeoxyuridine (BrdU). The newly repaired DNA was separated from bulk DNA by immunoprecipitation with monoclonal anti-BrdU antibody, labeled with 32P and hybridized to nine different gene and oncogene probes dot-blotted in excess on nylon membranes to determine their abundance in the repaired DNA. The results showed that: (a) the most actively repaired segment was a 211-bp sequence adjacent to the promotor region of the beta-actin gene; (b) all transcriptionally active genes were repaired at similar and constant rates throughout S and G2 phases; (c) the nontranscribed genes were repaired at much lower rates in early S phase, but later in S phase and especially in G2 phase, their repair rates increased and approached those of the transcribed genes.

Chromatin as an essential part of the transcriptional mechanism

The increasingly detailed biochemical definition of the protein complexes that regulate gene transcription has led to the re-emergence of questions about the role of histones. Much recent evidence suggests that transcriptional activation requires that transcription factors successfully compete with histones for binding to promoters, and that there may be more than one mechanism by which this is achieved.

Loosened nucleosome linker folding in transcriptionally active chromatin of chicken embryo erythrocyte nuclei

We have investigated the mechanism of the electrophoresis-driven chromatin aggregation which had been described by Weintraub (1984, Cell 38, 17-27) as a putative mean for propagation of genetic repression in eukaryotes. We show that the oligonucleosome aggregates are assembled de novo at the starting zone of DNP electrophoresis. A new system of native two-dimensional DNP electrophoresis has been worked out to separate the oligonucleosome aggregates ('A' particles) and the freely-migrating oligonucleosomes ('B' particles). The 'B' particle fraction which is derived from transcriptionally-active chromatin regions undergoes an extensive nuclease degradation of its DNA termini during the nuclease digestion. This fraction is partially depleted of histones H1 and H5 and is enriched in HMG nonhistone proteins. 'A' particles comprise the repressed chromatin DNA fragments which are about 60 b.p. longer than the corresponding DNA oligomers of 'B' particles. An oligonucleosome preparation containing the elongated DNA oligomers has been also isolated by means of sucrose gradient ultracentrifugation. Exonuclease III mapping reveals that the two chromatin fractions differ by an extent of terminal linker DNA trimming during the Micrococcal nuclease digestion rather than by the nucleosome repeat length. The complex character of nuclease digestion is not observed when the chromatin is digested in solution after the nuclear lysis. We argue that the protection of terminal oligonucleosome linkers is due to selective condensation of inactive chromatin in chicken erythrocyte nuclei and that the terminal DNA tails together with linker histones bound to them mediate the aggregation of repressed chromatin fragments.

Chromatin structure of the developmentally regulated early histone genes of the sea urchin Strongylocentrotus purpuratus

Chromatin organization of the early histone gene repeat was studied at the early embryonic stages of the sea urchin S. purpuratus. Micrococcal nuclease digestion showed a highly irregular packaging of the whole repeat at the period of transcriptional activity, which was progressively replaced by more regular nucleosomal arrays upon developmentally programmed inactivation. No evidence for unique positioning of the nucleosomes was found. Regions upstream of each of the genes were hypersensitive to DNAase I digestion in the active state. These regions contained one (H2A and H2B), or two (H3 and H4) well-defined DNAase I cutting sites, or two poorly-defined sites (H1). They mapped within DNA sequences shown previously to be required for proper expression of the genes. Hypersensitivity continued in the hatching blastula, which have a conventional nucleosomal structure and a much reduced transcriptional activity. Hypersensitivity of these regions during morula and early blastula was not dependent on the torsional strain in chromatin, as it was not influenced by extensive gamma ray-induced nicking of the DNA in nuclei. By late blastula no hypersensitive regions were present.

Presence of histone H1 on an active Balbiani ring gene

We have investigated whether histone H1 is present on active Balbiani ring genes in the salivary glands of Chironomus tentans using immunoelectron microscopy. The genes were studied in two activity states: maximally activated genes with a fully extended template and repressed genes in a 30 nm fiber conformation. Histone H1 was recorded on the gene in both conformations; the immunosignal was considerably stronger in the transcriptionally active state, probably reflecting the increased accessibility of histone H1 to the antibody in unfolded versus compacted chromatin. We conclude that during transcription the DNA template is extended and the nucleosomes are disrupted at the RNA polymerases, but histone H1, and most likely also the core histones, remains bound to the template.

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.

Heparin binds to intact mononucleosomes and induces a novel unfolded structure

It has been previously shown that heparin can bind to chromatin and enhance transcriptional activity. To characterize this phenomenon further, we have studied the interaction of heparin with isolated core mononucleosomes from avian reticulocytes. The results of these studies suggest that heparin bound reversibly to intact core mononucleosomes to induce a new structure, identified by decreased electrophoretic mobility and altered circular dichroism spectra. This altered nucleosome conformation exhibits 3-5-fold increased sensitivity to digestion by the nuclease, DNase I, and allows more efficient passage of RNA polymerase. At higher concentrations of heparin, core histones were completely removed from DNA. The finding of a reversible nucleosome-heparin complex in which core DNA is readily accessible to both RNA polymerase and the nuclease DNase I is discussed in the context of transcriptionally active chromatin.

Characterization of phosphorylation sites in histone H1 in the amitotic macronucleus of Tetrahymena during different physiological states

Histone H1 is highly phosphorylated in transcriptionally active, amitotic macronuclei of Tetrahymena during vegetative growth. However, the level of H1 phosphorylation changes dramatically in response to different physiological conditions. H1 is hyperphosphorylated in response to heat shock and during prezygotic stages of conjugation. Conversely, H1 is largely dephosphorylated during prolonged starvation and during elimination of parental macronuclei during conjugation. Mapping of phosphorylation sites within H1 indicates that phosphorylation occurs at multiple sites in the amino-terminal portion of the molecule, predominantly at threonine residues. Two of these sites have been identified by compositional analyses and microsequencing of tryptic peptides. Interestingly, two major sites contain the sequence Thr-Pro-Val-Lys similar to that contained in the sites recognized by growth-associated histone kinase in other organisms. No new sites are detected during the hyperphosphorylation of H1 which occurs during heat shock or in early stages of conjugation, and no sites are preferentially dephosphorylated during starvation or later stages of conjugation. Therefore, changes in the overall level of H1 phosphorylation, as opposed to phosphorylation or dephosphorylation at particular sites, appear to be important in the regulation of chromatin structure under these physiological conditions. Further, since no cell division or DNA replication occurs under these conditions, changes in the level of H1 phosphorylation are best correlated to changes in gene expression during heat shock, starvation, and conjugation. We suggest that, at least in Tetrahymena, H1 hyperphosphorylation is used as a rapid and transient mechanism for the cessation of transcription under conditions of cellular stress.

Microheterogeneity in H1 histones and its consequences

The extent of microheterogeneity of H1 histones in individual higher organisms, without considering post-translational modifications, is such that five to eight molecular species can be recognized. The H1 variants differ among themselves in their ability to condense DNA and chromatin fragments, and they are non-uniformly distributed in chromatin. This review assembles data that support the notion that the differences in chromatin condensation (heterochromatization) observed through the microscope are maintained by the non-uniform distribution of H1 variants, and that this pattern of chromatin condensation may determine the dynamics of chromatin during replication and may represent the commitment aspect of differentiation. The differential response of the multiple H1 variants with regard to their synthesis and turnover is consistent with this notion.

Differential stability of the higher order structure of chromatin associated with genes having different transcriptional activity

We have investigated the stability of the higher order structure of chromatin associated to genes which display a different transcriptional activity in adult rat live. Nuclei were digested with micrococcal nuclease and chromatin was fractionated by sedimentation in sucrose gradients. Specific DNA sequences were revealed by dot-blotting. In conditions of physiological ionic strength the distribution of the inactive gamma-casein gene sequences is similar than the bulk of chromatin. In the same conditions the relative content of the albumin gene, highly expressed in adult rat liver, revealed an enhanced instability of the chromatin superstructure. The distribution of the potentially active but silent alpha-fetoprotein sequences in adult liver showed an intermediate unfolding of its chromatin superstructure. These distinct behavior was not observed in non-physiological ionic strength conditions. Our results suggest that distinct folding of the local higher order structure of chromatin actually occurs in the region of active, potentially active and inactive genes.

Perturbation of chromatin structure in the region of the adult beta-globin gene in chicken erythrocyte chromatin

An EcoRI chromatin fragment containing the adult beta-globin gene and flanking sequences, isolated from chicken erythrocyte nuclei, sediments at a reduced rate relative to bulk chromatin fragments of the same size. We show that the specific retardation cannot be reversed by adding extra linker histones to native chromatin. When the chromatin fragments are unfolded either by removing linker histones or lowering the ionic strength, the difference between globin and bulk chromatin fragments is no longer seen. The refolded chromatin obtained by restoring the linker histones to the depleted chromatin, however, exhibits the original sedimentation difference. This difference is therefore due to a special property of the histone octamers on the active gene that determines the extent of its folding into higher-order structure. That it is not due to the differential binding of linker histones in vitro is shown by measurements of the protein to DNA ratios using CsCl density-gradients. Both before and after selective removal of the linker histones, the globin gene fragment and bulk chromatin fragments exhibit only a marginal difference in buoyant density. In addition, we show that cleavage of the EcoRI fragment by digestion at the 5' and 3' nuclease hypersensitive sites flanking the globin gene liberates a fragment from between these sites that sediments normally. We conclude that the hypersensitive sites per se are responsible for the reduction in sedimentation rate. The non-nucleosomal DNA segments appear to be too long to be incorporated into the chromatin solenoid and thus create spacers between separate solenoidal elements in the chromatin, which can account for its hydrodynamic behaviour.

Structure of transcriptionally active chromatin

Transcriptionally active or potentially active genes can be distinguished by several criteria from inactive sequences. Active genes show both an increased general sensitivity to endonucleases like DNase I or micrococcal nuclease and the presence of nuclease hypersensitive sites. Frequently, the nuclease hypersensitive sites are present just upstream of the transcription initiation site covering sequences that are crucial for the promoter function. Viral or cellular transcription enhancer elements are also associated with DNase I hypersensitive sites. At least for the SV40 enhancer, it was shown by electronmicroscopic studies that the DNase I hypersensitive DNA segment is excluded from nucleosomes. It is highly plausible that the binding of regulatory proteins to enhancer or promoter sequences is responsible for the exclusion of these DNA segments from nucleosomes and for the formation of nuclease hypersensitive sites. We speculate that the binding of such proteins may switch on a change in the conformation and/or the protein composition of a chromatin segment or domain containing one to several genes. Biochemical analysis of fractionated nucleosome particles or of active and inactive chromatin fractions have revealed differences in the composition as well as in the degree of modification of histones in these two subfractions of the chromosome. However, until present it is impossible to define unambiguously what are the crucial structural elements that distinguish between particles present on active and inactive chromatin.

Efficient solubilization and partial purification of sea urchin histone genes as chromatin

Soluble chromatin fragments are rapidly and efficiently produced when nuclei are digested with restriction endonucleases in buffers containing very low concentrations of magnesium. Under these conditions, the sequence specificity of the restriction endonucleases is maintained, resulting in release of specific genes as fragments with discrete molecular weights that can be fractionated by size on glycerol gradients. Gradient fractions can be chosen to be significantly enriched in specific genes and their associated proteins. For instance, we can achieve a 16-fold enrichment of the chromatin containing the early histone genes of sea urchin. The enrichments produced by these methods are useful as a first step in techniques to purify specific genes as chromatin. Glycerol gradient analyses can also be used to test whether putative gene-specific proteins are actually bound to the same sequences in vivo.

The effect of salt extraction on the structure of transcriptionally active genes; evidence for a DNAseI-sensitive structure which could be dependent on chromatin structure at levels higher than the 30 nm fibre

The procedure developed by Lawson and Cole (Biochemistry, 1979, 18 2161-2166) for removing lysine-rich histones from nuclei at low pH also quantitatively extracts proteins HMG14 and 17. The effect of this low pH extraction on the DNAseI-sensitive structures of active genes in avian red blood cells has been investigated. No major perturbation of a developmentally regulated DNAseI hypersensitive site in the beta-globin domain and at the 5' end of the alpha D gene was seen. The overall DNAseI-sensitive conformation of the beta A-globin gene (relative to the ovalbumin gene) is minimally affected by pH3 salt extraction, but there is some loss of sensitivity of the alpha D gene. Removal of HMG proteins at neutral pH had no effect on the sensitivity of active genes in erythroid or fibroblast nuclei. These results, together with those carried out on DNAseI sensitivity and HMG binding to monomer nucleosomes, indicate that there is a major structural feature of active genes responsible for DNAseI-sensitivity which is independent of HMG proteins or nucleosome core particle structure but may be dependent on higher order chromatin structures.

Mapping of DNase I-hypersensitive sites in the 5' and 3' long terminal repeats of integrated moloney murine leukemia virus proviral DNA

The chromatin state of integrated Moloney murine leukemia virus (M-MuLV) proviral DNA was investigated. Nuclei from M-MuLV-infected mouse NIH 3T3 cells were digested with limited amounts of DNase I, and hypersensitive (HS) sites were mapped by the indirect end labeling technique. Particular emphasis was placed on the 5' long terminal repeat (LTR), since viral transcription initiates there. M-MuLV proviral DNA showed two strong DNase I-HS sites in the 5' LTR, one coincident with the transcription initiation (cap) site and the other with the transcriptional enhancers. Two weaker DNase I-HS sites were also detected in internal proviral DNA. The 3' LTR also showed a strong HS site in the region of the enhancers, but an HS site at the cap site of the 3' LTR was not detected. Thus, the chromatin configurations of the 5' and 3' LTRs of integrated M-MuLV proviruses appear to be different. The chromatin configuration of M-MuLV proviruses which contain LTR insertions of polyomavirus enhancer sequences was also studied. The 5' LTR of M-MuLV proviruses containing polyoma enhancer sequences substituted for the M-MuLV enhancers showed two strong HS sites, one in the polyoma sequences and one at the cap site. The 5' LTR of M-MuLV proviruses containing polyoma enhancer sequences inserted into the wild-type M-MuLV LTR between the cap site and the M-MuLV enhancers showed three HS sites. Two HS sites corresponded to those of the wild-type M-MuLV LTR, whereas the third mapped to the inserted polyoma sequences. The HS site associated with the inserted polyoma sequences was considerably stronger than the M-MuLV-associated HS sites.

Analysis of gene expression during hematopoiesis: present and future applications

Recombinant DNA technology now provides the strategies required to identify genes whose expression controls the development of normal and pathologic blood cells. Characterization of the gene families responsible for synthesis of hemoglobins, immunoglobulins, histocompatibility antigens, and cellular enzymes have already, or are about to, provide major insights into the mechanisms producing normal erythroid cells, immunocytes, and immune surface features. Hemoglobinopathies, leukemias, and autoimmune diseases of the bone marrow can now be examined to a degree of detail previously inaccessible to investigators. Oncogene translocation analysis is shedding new light on the pathogenesis of leukemias and lymphomas. Recent basic advances now permit direct cloning and identification of genes in host organisms which express their protein products, thus allowing isolation of genes coding for the hematopoietic surface markers and growth factors which characterize and regulate blood cell progenitors. This review summarizes the molecular genetic approach to analysis of normal and pathologic hematopoiesis, surveys major findings which have resulted, and examines the potential use of refined gene cloning strategies for improved understanding of blood cell development.

Molecular analysis of erythropoiesis. A current appraisal

This article considers recent evidence concerning the molecular mechanisms involved in the coordinate regulation of gene expression during red blood cell (RBC) differentiation. Contrary to popular belief, recent evidence shows that only a few of the characteristic RBC proteins are restricted to the erythroid lineage: apart from the globins, an RBC lipoxygenase and (possibly) glycophorin are the only examples for which there is reasonably good evidence. In contrast, the proteins forming the RBC cytoskeleton (spectrin, ankyrin, band 4.1, actin and possibly the major anion exchange transmembrane protein by which the cytoskeleton is attached to the plasma membrane) have closely-related variants in other cell types. Yet two beta-spectrin variants are found exclusively in certain terminally differentiated cells, often only in certain specific regions of the cell membrane. Certain RBC isozymes (e.g. for pyruvate kinase and carbonic anhydrase) and an RBC 19 kD protein (ep19) are also expressed only in a subset of other cell types. This illustrates the importance of gene families which are differentially regulated in certain subsets of cell types during differentiation and development. The expression of the globin genes seems to be regulated mainly at the transcriptional level, although transport of these transcripts to the cytoplasm may be controlled by interactions with other RNAs: stabilisation of globin mRNAs by ribonucleoprotein complexes in the cytoplasm may also be important. In fact, the expression of the globin genes involves two distinct phases: first, structural changes occur in the chromatin surrounding the genes (as determined by sensitivity to digestion by nucleases) and these can be maintained independently of any subsequent transcription. In many cases, these nuclease-sensitive sites in the chromatin correspond to low-level transcription initiation sites and to DNA sequences with regulatory functions when the isolated genes are assayed for transcription in vivo after transfection into cells. How the unlinked alpha- and beta-globin genes are coordinately regulated is not yet understood. Indeed, the alpha- and beta-gene promoters have quite different properties as judged by their responses to DNA replication and to factors known to affect viral gene function (e.g. the cis-acting SV40 enhancer elements and the trans-acting adenovirus regulatory protein, Ela). Other evidence shows that a nuclear protein present only in erythroid cells is able to bind to the beta-globin gene precisely in the region that is hypersensitive to nuclease digestion in chromatin from erythroid cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Control of RNA polymerase binding to chromatin by variations in linker histone composition

We have measured the frequency of initiation sites in chromatin for RNA polymerase in vitro as a function of the composition of linker histones (H1 and its analogues). In linker histone-depleted chromatin, RNA chain initiation appears to be restricted to the exposed linker DNA. On titration with purified linker histones, initiation is further restricted to an extent determined by the amount and type of linker histone, and the source of depleted chromatin. The extent of repression is correlated with the capacity of linker histones to induce the formation of higher-order structure in the complex. The results suggest that the effects of linker histones are mediated through the higher-order structure of chromatin, which prevents access of polymerase to the linker DNA. Accordingly, we find that structures imposed by the linker histones after polymerase binding are not inhibitory. Microscopy reveals that the higher-order structure in partially condensed chromatin is discontinuous, with solenoidal units spaced by sections of unravelled nucleosomes. Since salt stimulation of linker histone exchange does not result in derepression of linkers in our assay, we conclude that the distribution of higher-order units in chromatin is static and that the linker histones exchange between high-affinity sites in established units. We have previously shown that the globin gene is selectively unfolded in tissues that express the gene. The present results suggest that the transcriptional activity of specific genes is maintained by differential linker histone binding within chromatin.

Transcriptionally active chromatin

Eukaryotic chromatin has a dynamic, complex hierarchical structure. Active gene transcription takes place on only a small proportion of it at a time. While many workers have tried to characterize active chromatin, we are still far from understanding all the biochemical, morphological and compositional features that distinguish it from inactive nuclear material. Active genes are apparently packaged in an altered nucleosome structure and are associated with domains of chromatin that are less condensed or more open than inactive domains. Active genes are more sensitive to nuclease digestions and probably contain specific nonhistone proteins which may establish and/or maintain the active state. Variant or modified histones as well as altered configurations or modifications of the DNA itself may likewise be involved. Practically nothing is known about the mechanisms that control these nuclear characteristics. However, controlled accessibility to regions of chromatin and specific sequences of DNA may be one of the primary regulatory mechanisms by which higher cells establish potentially active chromatin domains. Another control mechanism may be compartmentalization of active chromatin to certain regions within the nucleus, perhaps to the nuclear matrix. Topological constraints and DNA supercoiling may influence the active regions of chromatin and be involved in eukaryotic genomic functions. Further, the chromatin structure of various DNA regulatory sequences, such as promoters, terminators and enhancers, appears to partially regulate transcriptional activity.