Core histone acetylation is regulated by linker histone stoichiometry in vivo.

We investigated the relationship between linker histone stoichiometry and the acetylation of core histones in vivo. Exponentially growing cell lines induced to overproduce either of two H1 variants, H1(0) or H1c, displayed significantly reduced rates of incorporation of [(3)H]acetate into all four core histones. Pulse-chase experiments indicated that the rates of histone deacetylation were similar in all cell lines. These effects were also observed in nuclei isolated from these cells upon labeling with [(3)H]acetyl-CoA. Nuclear extracts prepared from control and H1-overexpressing cell lines displayed similar levels of histone acetylation activity on chromatin templates prepared from control cells. In contrast, extracts prepared from control cells were significantly less active on chromatin templates prepared from H1-overexpressing cells than on templates prepared from control cells. Reduced levels of acetylation in H1-overproducing cell lines do not appear to depend on higher order chromatin structure, because it persists even after digestion of the chromatin with micrococcal nuclease. The results suggest that alterations in chromatin structure, resulting from changes in linker histone stoichiometry may modulate the levels or rates of core histone acetylation in vivo.

Effects of H1 histone variant overexpression on chromatin structure.

The importance of histone H1 heterogeneity and total H1 stoichiometry in chromatin has been enigmatic. Here we report a detailed characterization of the chromatin structure of cells overexpressing either H1(0) or H1c. Nucleosome spacing was found to change during cell cycle progression, and overexpression of either variant in exponentially growing cells results in a 15-base pair increase in nucleosome repeat length. H1 histones can also assemble on chromatin and influence nucleosome spacing in the absence of DNA replication. Overexpression of H1(0) and, to a lesser extent, H1c results in a decreased rate of digestion of chromatin by micrococcal nuclease. Using green fluorescent protein-tagged H1 variants, we show that micrococcal nuclease-resistant chromatin is specifically enriched in the H1(0) variant. Overexpression of H1(0) results in the appearance of a unique mononucleosome species of higher mobility on nucleoprotein gels. Domain switch mutagenesis revealed that either the N-terminal tail or the central globular domain of the H1(0) protein could independently give rise to this unique mononucleosome species. These results in part explain the differential effects of H1(0) and H1c in regulating chromatin structure and function.

Histone H1 reduces the frequency of initiation in Xenopus egg extract by limiting the assembly of prereplication complexes on sperm chromatin.

Somatic histone H1 reduces both the rate and extent of DNA replication in Xenopus egg extract. We show here that H1 inhibits replication directly by reducing the number of replication forks, but not the rate of fork progression, in Xenopus sperm nuclei. Density substitution experiments demonstrate that those forks that are active in H1 nuclei elongate to form large tracts of fully replicated DNA, indicating that inhibition is due to a reduction in the frequency of initiation and not the rate or extent of elongation. The observation that H1 dramatically reduces the number of replication foci in sperm nuclei supports this view. The establishment of replication competent DNA in egg extract requires the assembly of prereplication complexes (pre-RCs) on sperm chromatin. H1 reduces binding of the pre-RC proteins, XOrc2, XCdc6, and XMcm3, to chromatin. Replication competence can be restored in these nuclei, however, only under conditions that promote the loss of H1 from chromatin and licensing of the DNA. Thus, H1 inhibits replication in egg extract by preventing the assembly of pre-RCs on sperm chromatin, thereby reducing the frequency of initiation. These data raise the interesting possibility that H1 plays a role in regulating replication origin use during Xenopus development.

Differential effect of H1 variant overproduction on gene expression is due to differences in the central globular domain.

The in vivo overproduction of two mouse histone H1 variants in homologous mouse fibroblasts has opposite effects on gene expression. Overproduction of H1(0) results in repression of transcript levels of all polymerase II genes tested. In contrast, overproduction of H1c results in elevated levels of transcripts. We created a series of chimeric H1 genes in which the regions encoding the three structural domains common to this family of these proteins were systematically switched. Overexpression of these genes in vivo resulted in the accumulation of large amounts of the chimeric H1 in chromatin. Analysis of the effects of overproduction of these proteins revealed that the differential effect of H1 variant overproduction on gene expression is due to differences in the central globular domain.

Histone H1 modulates DNA replication through multiple pathways in Xenopus egg extract.

We investigated the effects of histone H1s on DNA replication using Xenopus egg extract. Mouse variants H1c and H10 were assembled onto Xenopus sperm chromatin by the extract during the remodeling that accompanies nuclear decondensation. The association of H1 with chromatin was rapid and concentration dependent. H1-associated chromatin displayed a typical nucleosomal repeat pattern indicating that linker histones are properly positioned along the DNA. The presence of H1 on sperm chromatin reduced both the rate and extent of DNA replication in egg extract. This reduction in rate is due, in part, to a delay in initiation of replication within individual nuclei. Initiation in extract is dependent upon nuclear assembly. Analysis of the assembly process revealed that H1 does not inhibit nuclear membrane formation or the import of nuclear protein, however, it does slow the rate of nuclear lamina formation. This H1-induced delay in lamina assembly is responsible for the delay in initiation as pre-assembled H1-containing nuclei initiate replication at the same time as control nuclei. However, H1 inhibits replication even when lamina assembly is complete suggesting that H1 also affects replication directly. These data indicate that H1 modulates DNA replication through multiple pathways in egg extract.

Differential effect of H1 variant overexpression on cell cycle progression and gene expression.

To identify functional differences among non-allelic variants of the mammalian H1 linker histones a system for the overexpression of individual H1 variants in vivo was developed. Mouse 3T3 cells were transformed with an expression vector containing the coding regions for the H1c or H10 variant under the control of an inducible promoter. Stable, single colony transformants, in which the normal stoichiometry of H1 variants was perturbed, displayed normal viability, unaltered morphology and no long-term growth arrest. However, upon release from synchronization at different points in the cell cycle transformants significantly overproducing H10 exhibited transient inhibition of both G1 and S phase progression. Overexpression of H1c to comparable levels had no effect on cell cycle progression. Analysis of transcript levels for several cell cycle-regulated and housekeeping genes indicated that overexpression of H10 resulted in significantly reduced expression of all genes tested. Surprisingly, overexpression of H1c to comparable levels resulted in either a negligible effect or, in some cases, a dramatic increase in transcript levels. These results support the suggestion that functional differences exist among H1 variants.

Isolation and characterization of two replication-dependent mouse H1 histone genes.

Mice contain at least seven nonallelic forms of the H1 histones, including the somatic variants H1a-e and less closely related variants H1 degrees and H1t. The mouse H1 degrees and H1c (H1var.1) genes were isolated and characterized previously. We have now isolated, sequenced and studied the expression properties of two additional mouse H1 genes, termed H1var.2 and H1var.3. Extensive amino acid and nucleotide sequence comparisons were made between the two genes and other mammalian H1 histone genes. A high degree of nucleotide sequence identity was seen between the H1var.2, rat H1d and human H1b genes, even well beyond the coding region, indicating that these genes are likely homologues. Unlike the previously characterized mouse H1var.1 gene which produces both nonpolyadenylated and polyadenylated mRNAs, the H1var.2 and H1var.3 genes produce only typical, replication dependent, nonpolyadenylated mRNAs.

Preferential binding of H1e histone to GC-rich DNA.

We have investigated the binding of a pure H1 histone, the mouse variant H1e, to a 214 bp fragment of DNA from pBR322. Binding was monitored by observing the effects of the protein on melting of the DNA and by a gel-mobility-shift assay. We found, using this highly purified system, that H1e protein binds preferentially and cooperatively to the GC-rich region of the DNA. A chemically synthesized peptide containing 25 residues, corresponding to a region of the carboxyl-terminal domain of H1e, shows the same sequence preference but does not exhibit cooperativity.

Identification through overexpression and tagging of the variant type of the mouse H1e and H1c genes.

Multiple, nonallelic forms of histone H1 are found in most mammalian tissues. Attempts to determine a functional significance to this diversity is hindered by a paucity of primary amino acid sequence data. Although numerous H1 genes have been cloned, the type of variant they encode cannot be determined by sequence analysis alone. We used transformation and overexpression methods to determine that two cloned mouse H1 genes, MH143 and MH175, encode H1c and H1e, respectively. Since these genes have been completely sequenced, these results establish the amino acid sequence of these variants. Assignment was accomplished by mutagenically "tagging" the genes by incorporation of a codon for methionine, which is not found in the major somatic H1 variants. These genes were placed under the control of the mouse metallothionein I promoter and introduced into 3T3 cells. Products of these mutagenized genes were detected by [35S]methionine labeling and identified by high performance liquid chromatography and sodium dodecyl sulfate-acid polyacrylamide gel electrophoresis. We were also able to induce major alterations in the normal stoichiometry of chromatin-associated H1 variants through overproduction of H1c and H1e. This had little effect on the growth properties of these transformants.

Histone gene switching in murine erythroleukemia cells is differentiation specific and occurs without loss of cell cycle regulation.

We investigated the expression characteristics of the fully replication-dependent (FRD) and the partially replication-dependent (PRD) histone gene variants by measuring changes in steady-state mRNA levels during hexamethylene bisacetamide (HMBA)-induced differentiation of murine erythroleukemia (MEL) cells. Between 24 and 60 h after induction, there was a dramatic switch in histone gene expression, such that the ratio of PRD to FRD transcripts increased severalfold over that found in uninduced MEL cells. We demonstrated that this gene switching was not simply a partial or complete uncoupling of PRD gene expression from DNA synthesis. PRD and FRD transcript levels were regulated coordinately upon treatment of uninduced or induced MEL cells with inhibitors of DNA synthesis, protein synthesis, or both. Using several criteria, we were unable to detect any difference in PRD and FRD gene expression under any conditions except in cells undergoing differentiation. MEL cells were arrested at a precommitment stage of differentiation by induction with HMBA in the presence of dexamethasone (DEX). If DEX was subsequently removed, DNA synthesis resumed, the cells underwent commitment, and histone gene switching was observed. In contrast, if both DEX and HMBA were removed, DNA synthesis still resumed, but commitment did not occur and no gene switching was observed. These results imply that histone gene switching is intimately related to the differentiation process.

Isolation and characterization of a mouse fully replication-dependent H1 gene within a genomic cluster of core histone genes.

We have used an oligonucleotide complementary to a sequence coding for the conserved central globular domain of H1s to screen a mouse genomic library for H1 genes. We then used a series of universal histone oligonucleotides to identify five different H1 genes which were linked to core histone genes. We characterized one of the H1 genes which was linked to an H2a, an H2b, an H3, and an H4 histone gene. This characterization involved: 1) sequencing of the coding region of the gene and several hundred base pairs of flanking region. 2) Comparison of this sequence to other H1 sequences from other organisms. This sequence analysis clearly showed that the gene coded for an H1 and identified H1 consensus sequences in the 5'- and 3'-flanking region. 3) Mapping of the 5'- and 3'-ends of the mRNA complementary to this gene by S1 nuclease analysis. 4) Identifying this gene and an adjacent H3 gene as being of the fully replication-dependent expression class, by measuring changes in the steady state levels of their mRNAs in the presence of hydroxyurea and during differentiation of murine erythroleukemia cells.

Characterization of mouse H3.3-like histone genes.

We designed a strategy to select genomic clones of mouse replication-independent H3.3 histone genes. We obtained three clones which met our selection criteria for being H3.3 genes. Upon sequencing two of these clones we found that they were unlike previously isolated chicken H3.3 clones: they code for several unpredicted amino acid substitutions and contain no introns in the coding regions. We showed by S1 nuclease assays that these genes are protected by mRNAs that have expression characteristics of H3.3 mRNA. The protection data and nucleotide sequence analysis show that the H3.3 transcripts can be processed at one of four cleavage/polyadenylation sites. We show that these genes probably evolved through reverse transcription intermediates, and are processed pseudogenes which are no longer under selective pressure. The 5' and 3' transcribed, nontranslated sequences show extensive homology to those of a human cDNA clone, and we suggest that these sequences may be required for appropriate regulation of expression of H3.3 genes.

The expression of a gene for eukaryotic elongation factor Tu in Artemia during development. Translation of poly(A)+ RNA and the use of a synthetic oligonucleotide to detect the presence of eukaryotic elongation factor Tu-specific mRNA.

Total in vivo proteins from Artemia embryos at different developmental stages were examined by two-dimensional gel electrophoresis. A variety of peptides change during development, with one of them, the eukaryotic elongation factor Tu (eEF-Tu), presenting a dramatic increase from dormant embryos to nauplii. When poly(A)+ RNA is translated in vitro, the same relative increase is seen for eEF-Tu during development. Based on the amino acid sequence for Artemia eEF-Tu (Amons, R., Pluijms, W., Roobol, K., and Möller, W. (1983) FEBS Lett. 153, 37-42), a synthetic oligodeoxynucleotide was prepared and used to prime the synthesis of cDNA with poly(A)+ RNA from 12-h developing embryos as template. Direct sequence analysis of the 900-base primary cDNA product shows it to be specific for the 5' end of Artemia eEF-Tu mRNA. Hybridization of a "Northern" blot of denatured (poly(A)+ RNA from different developmental stages with this cDNA reveals a major band migrating at about 1800 bases, which increase in intensity as development proceeds, paralleling the increase in eEF-Tu seen by in vitro translation. When poly(A)+ RNA is separated on a nondenaturing gel, blotted to poly(U) paper, and hybridized with the eEF-Tu cDNA, a single band is observed migrating faster than 18 S. Elution and in vitro translation of this band results in a major product migrating with eEF-Tu in a dodecyl sulfate-polyacrylamide gel and which is precipitable with eEF-Tu-specific antibodies.

Changes in the levels of three different classes of histone mRNA during murine erythroleukemia cell differentiation.

We used a gene-specific S1 nuclease assay to study the changes in steady-state mRNA levels of several core histone variants during the differentiation of murine erythroleukemia cells. These studies allowed us to distinguish three distinct expression classes of histone genes. The expression of the major replication-dependent class of histone genes was tightly linked to DNA synthesis. The concentrations of these transcripts decreased rapidly as cell division slowed during the process of differentiation. In contrast, the replication-independent H3.3 transcript levels were constitutively maintained throughout differentiation and were unaffected by inhibitors of DNA or protein synthesis. We also identified among the cloned histone genes used as probes a third expression class, the partially replication-dependent variants. Expression of these transcripts became transiently uncoupled from the reduced rate of DNA synthesis accompanying the early stages of differentiation. We show that their synthesis is sensitive to the DNA synthesis inhibitor hydroxyurea but that selective uncoupling from DNA synthesis of these histone mRNAs occurs at a specific stage of differentiation. We present several hypotheses to explain how this might be accomplished. The expression characteristics of the mRNAs studied coincided with those of the proteins for which they code, indicating that changes in the relative levels of the different variants is mediated at least in part by changes in mRNA levels.

Structure of a cluster of mouse histone genes.

The four mouse histone genes (2 H3 genes, an H2b gene and an H2a gene) present in a cloned 12.9 kilobase fragment of DNA have been completely sequenced including both 5' and 3' flanking regions. These genes are expressed in cultured mouse cells and the 3' and 5' ends of the mRNA have been determined by S1 nuclease mapping. These genes code for a minor fraction of the histone mRNAs expressed in cultured mouse cells. They comprise at most 5-8% of the total histone mRNA of each type. The two H3 genes code for H3.2 and H3.1 histone proteins, while the H2b gene codes for an H2b.1 protein with a single amino acid change (val-leu) at position 18. Only the 3' portion of the H2a gene is contained in the clone and there is an amino acid change (alanine-proline) at position 126. Comparison of the 5' and 3' flanking sequences reveals a conserved sequence at the 3' end of the mRNA which forms a hairpin loop structure. The codon usage in the genes is non-random and there has been no discrimination against CG doublets in the coding region of the genes.

Histone mRNA concentrations are regulated at the level of transcription and mRNA degradation.

The levels of histone mRNA are rapidly reduced after treatment of cultured cells with hydroxyurea or cytosine arabinonucleoside. The histone mRNA for the replicative histone variants is destroyed rapidly, with a half-life of 10-15 min. The levels of mRNA coding for the replacement histone variant H3.3 were unchanged after treatment with DNA synthesis inhibitors. In addition to the rapid destruction of histone mRNA, there was a reduction to 1/5th in the rate of transcription of the histone genes. Lymphoma cells (S49) arrested in G1 by cyclic AMP produce and contain significant levels of histone mRNA. Hydroxyurea reduces the rate of transcription and the levels of histone mRNA in the G1-arrested cells.

Purification and characterization of the RNA polymerases of the sea urchin, Lytechinus variegatus.

We have identified four forms of sea urchin RNA polymerase (Ia, Ib, II and III). Three of the forms co-elute on DEAE cellulose chromatography but separate on DEAE Sephadex chromatography. The separation of these three enzyme forms by DEAE Sephadex chromatography can be eliminated with non-ionic detergent. We also demonstrate that either form I or form III RNA polymerase loses its resistance to alpha-amanitin after DEAE chromatography. A procedure for the purification of combined form I and III RNA polymerase and the purification of RNA polymerase II is also presented.

Isolation of two clusters of mouse histone genes.

Histone mRNA was partially purified from mouse myeloma cells synchronized in S phase by isoleucine starvation. A cDNA was prepared that contained sequences complementary to all five mouse histone genes. This cDNA was used to screen a library of mouse DNA in lambda phage. The positive clones were screened by hybridization with sea urchin histone gene-specific probes to identify those clones that contained histone genes. Confirmation of this identification was obtained by hybridization with Drosophila histone genes. Two independent clusters of histone genes were isolated. One, MM531, contains regions hybridizing specifically to H3, H4, and H1 and the other, MM221, contains two regions hybridizing specifically to H3 and single regions complementary to H4, H2b, and H2a. They are not part of a simple repeating structure. The nucleotide sequence of the coding region of the H3 gene in MM531 has been determined. This gene could code for a variant H3 protein that has several amino acid substitutions not reported in other H3 proteins.