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

MS_HistoneDB, a manually curated resource for proteomic analysis of human and mouse histones

BACKGROUND

Histones and histone variants are essential components of the nuclear chromatin. While mass spectrometry has opened a large window to their characterization and functional studies, their identification from proteomic data remains challenging. Indeed, the current interpretation of mass spectrometry data relies on public databases which are either not exhaustive (Swiss-Prot) or contain many redundant entries (UniProtKB or NCBI). Currently, no protein database is ideally suited for the analysis of histones and the complex array of mammalian histone variants.

RESULTS

We propose two proteomics-oriented manually curated databases for mouse and human histone variants. We manually curated >1700 gene, transcript and protein entries to produce a non-redundant list of 83 mouse and 85 human histones. These entries were annotated in accordance with the current nomenclature and unified with the "HistoneDB2.0 with Variants" database. This resource is provided in a format that can be directly read by programs used for mass spectrometry data interpretation. In addition, it was used to interpret mass spectrometry data acquired on histones extracted from mouse testis. Several histone variants, which had so far only been inferred by homology or detected at the RNA level, were detected by mass spectrometry, confirming the existence of their protein form.

CONCLUSIONS

Mouse and human histone entries were collected from different databases and subsequently curated to produce a non-redundant protein-centric resource, MS_HistoneDB. It is dedicated to the proteomic study of histones in mouse and human and will hopefully facilitate the identification and functional study of histone variants.

Histone H1 and its isoforms: contribution to chromatin structure and function

The lysine-rich H1 histone family in mammals includes eleven different subtypes, and thus it is the most divergent class of histone proteins. The central globular H1 domain asymmetrically interacts with DNA at the exit or entry end of the nucleosomal core DNA, and the C-terminal domain has a major impact on the linker DNA conformation and chromatin condensation. H1 histones are thus involved in the formation of higher order chromatin structures, and they modulate the accessibility of regulatory proteins, chromatin remodeling factors and histone modification enzymes to their target sites. The major posttranslational modification of H1 histones is phosphorylation, which reaches a peak during G2 and mitosis. Phosphorylation is, however, also involved in the control of DNA replication and it contributes to the regulation of gene expression. Disruption of linker histone genes, initially performed in order to delineate subtype-specific functions, revealed that disruption of one or two H1 subtype genes is quantitatively compensated by an increased expression of other subtypes. This suggests a functional redundancy among H1 subtypes. However, the inactivation of three subtypes and the reduction of the H1 moiety in half finally resulted in a phenotypic effect. On the other hand, studies on the role of particular subtypes at specific developmental stages in lower eukaryotes, but also in vertebrates suggest that specific subtypes of H1 participate in particular systems of gene regulation.

Reductions in Linker Histone Levels Are Tolerated in Developing Spermatocytes but Cause Changes in Specific Gene Expression

H1 linker histones are involved in packaging chromatin into 30-nm fibers and higher order structures. Most eukaryotic cells contain nearly one H1 molecule for each nucleosome core particle. Male germ cells in mammals contain large amounts of a germ cell-specific linker histone, HIST1HT, herein denoted H1t, which is particularly abundant in pachytene spermatocytes. Despite its abundance in male germ cells and significant divergence in primary sequence from other H1 subtypes, inactivation of the H1t gene in mice showed that it is not required for spermatogenesis. Analysis of germ cell chromatin from H1t null mice showed that other H1 subtypes, especially the testis-enriched HIST1H1A, herein denoted as the H1a subtype, were able to compensate for the absence of H1t to maintain a normal total H1 to nucleosome core ratio. To disrupt the compensation, we generated H1t and H1a double null mice by two sequential gene-targeting steps in embryonic stem cells. Elimination of both H1t and H1a led to a 25% decrease in the ratio of H1 to nucleosome cores in double null germ cells. Surprisingly, the reduction in H1 did not perturb spermatogenesis or produce detectable defects in meiotic processes. Microarray analysis of gene expression showed that the reduced linker histone levels did not affect global gene expression, but it did cause changes in expression of specific genes. Our results indicate that a partial reduction in linker histone-nucleosome core particle stoichiometry is tolerated in developing male germ cells.

Injury-associated differential regulation of histone expression and modification in the thymus of mice

One of the key events in the regulation of gene expression is chromatin remodeling involving histone regulation. We investigated the effects of burns on the expression of histone that might be associated with altered molecular and pathological profiles in the thymus. A markedly decreased expression of histone variant H2A.1 mRNA was identified in the thymus after burn during a differential display experiment. Subsequently, we examined the histone expression (mRNA and protein) and posttranslational modification in the thymus after burn. Also, changes in proliferating cell nuclear antigen (PCNA), a central molecule in chromatin assembly, was examined. Reverse-transcription polymerase chain reaction analysis revealed a transient decrease in the expression of several histone variants (H2A.1, H1(r1), H3-B, H3-1, and H4-D) mRNAs in the thymus at 1 day after burn. A decrease in histone subtypes H2A, H2B, H3, and H4, but not H1, was demonstrated 1 and 3 days after burn according to the results of Western blot. Furthermore, there were different levels of decreases in acetylated and dimethylated forms of histone H3 1 and 3 days after burn. In addition, decreased levels of PCNA were evident in the thymus 1 day after burn. Changes in the expression of histones and PCNA may reflect mere decrease in proliferating cells and/or a reorganization of the chromatin structure associated with altered transcriptional activities, eventually contributing to the phenotypic changes in the thymus after burn.

H1 linker histones are essential for mouse development and affect nucleosome spacing in vivo

Most eukaryotic cells contain nearly equimolar amounts of nucleosomes and H1 linker histones. Despite their abundance and the potential functional specialization of H1 subtypes in multicellular organisms, gene inactivation studies have failed to reveal essential functions for linker histones in vivo. Moreover, in vitro studies suggest that H1 subtypes may not be absolutely required for assembly of chromosomes or nuclei. By sequentially inactivating the genes for three mouse H1 subtypes (H1c, H1d, and H1e), we showed that linker histones are essential for mammalian development. Embryos lacking the three H1 subtypes die by mid-gestation with a broad range of defects. Triple-H1-null embryos have about 50% of the normal ratio of H1 to nucleosomes. Mice null for five of these six H1 alleles are viable but are underrepresented in litters and are much smaller than their littermates. Marked reductions in H1 content were found in certain tissues of these mice and in another compound H1 mutant. These results demonstrate that the total amount of H1 is crucial for proper embryonic development. Extensive reduction of H1 in certain tissues did not lead to changes in nuclear size, but it did result in global shortening of the spacing between nucleosomes.

Individual somatic H1 subtypes are dispensable for mouse development even in mice lacking the H1(0) replacement subtype

H1 linker histones are involved in facilitating the folding of chromatin into a 30-nm fiber. Mice contain eight H1 subtypes that differ in amino acid sequence and expression during development. Previous work showed that mice lacking H1(0), the most divergent subtype, develop normally. Examination of chromatin in H1(0-/-) mice showed that other H1s, especially H1c, H1d, and H1e, compensate for the loss of H1(0) to maintain a normal H1-to-nucleosome stoichiometry, even in tissues that normally contain abundant amounts of H1(0) (A. M. Sirotkin et al., Proc. Natl. Acad. Sci. USA 92:6434-6438, 1995). To further investigate the in vivo role of individual mammalian H1s in development, we generated mice lacking H1c, H1d, or H1e by homologous recombination in mouse embryonic stem cells. Mice lacking any one of these H1 subtypes grew and reproduced normally and did not exhibit any obvious phenotype. To determine whether one of these H1s, in particular, was responsible for the compensation present in H1(0-/-) mice, each of the three H1 knockout mouse lines was bred with H1(0) knockout mice to generate H1c/H1(0), H1d/H1(0), or H1e/H1(0) double-knockout mice. Each of these doubly H1-deficient mice also was fertile and exhibited no anatomic or histological abnormalities. Chromatin from the three double-knockout strains showed no significant change in the ratio of total H1 to nucleosomes. These results suggest that any individual H1 subtype is dispensable for mouse development and that loss of even two subtypes is tolerated if a normal H1-to-nucleosome stoichiometry is maintained. Multiple compound H1 knockouts will probably be needed to disrupt the compensation within this multigene family.

Spermatogenesis in mice is not affected by histone H1.1 deficiency

The linker histone subtype H1.1 belongs to the group of main-type histones and is synthesized in somatic tissues as well as in germ cells during the S phase of the cell cycle. In adult mice the histone gene H1.1 is expressed mainly in thymus, spleen, and testis. The single-copy gene coding for the H1.1 protein was eliminated by homologous recombination in mouse embryonic stem cells. Mice homozygous for the deficient H1.1 gene developed normally until the adult stage without H1.1 mRNA and H1.1 protein. No anatomic abnormalities could be detected. In addition, mice lacking the H1.1 gene were fertile and they showed normal spermatogenesis and testicular morphology.

Overproduction of histone H1 variants in vivo increases basal and induced activity of the mouse mammary tumor virus promoter

BALB/c 3T3 cell lines containing integrated copies of the MMTV promoter driving a reporter gene were constructed. Expression vectors in which either of two H1 variants, H10 or H1c, were under control of an inducible promoter were introduced into these lines. Surprisingly, overproduction of either variant resulted in a dramatic increase in basal and hormone-induced expression from the MMTV promoter. H1 overproduction also slowed the loss of MMTV promoter activity associated with prolonged hormone treatment. Transiently transfected MMTV reporter genes, which do not adopt a phased nucleosomal arrangement, do not display increased activity upon H1 overproduction. Thus the effects observed for stable constructs most likely represents a direct effect of H1 on a chromatin-mediated process specific to the nucleosomal structure of the integrated constructs. Induction of increased levels of acetylated core histones by treatment with trichostatin A also potentiated MMTV activity and this effect was additive to that caused by H1 overproduction. However, the effects of TSA treatment, in control or H1-overproducing cells, were eliminated by inhibiting protein synthesis. TSA treatment does not necessarily potentiate MMTV promoter activity by increasing core histone acetylation within the MMTV promoter but perhaps by altering the synthesis of an unlinked transcriptional regulator.

Expression of murine H1 histone genes during postnatal development

Murine genes encoding the seven H1 histone isoforms H1.1-H1.5, H1(o) and H1t have been isolated and sequenced. We have established expression patterns of these genes in several tissues during postnatal development. For that analysis, RNase protection assay rather than Northern blot hybridization was used, since the sequences of these genes are highly similar and would cross-hybridize under Northern blot conditions. Expression patterns of H1.1 to H1.5 and H1(o) were determined in tissues of animals at days 5, 9 and 20 after birth and of adult mice. In addition, RNA was analyzed in three mouse cell lines (NIH3T3, P19, TM4). Transcription of the subtype genes H1.2 and H1.4 was found in all tissues and cell lines studied. The most varied expression patterns were obtained with the H1.1 subtype. H1.1 mRNA was found at high concentrations in thymus and spleen throughout development and in testis beginning with a low expression in 5-day-old animals and increasing levels in testis RNA from 9- and 20-day-old and adult mice. H1(o) mRNA was found primarily in highly differentiated tissues with concentrations decreasing from 5-day-old to adult animals.

Drosophila melanogaster histone H2B retropseudogene is inserted into a region rich in transposable elements

We have isolated and characterized the genomic sequence of a Drosophila melanogaster histone H2B pseudogene that is localized outside of the cluster of the replication-dependent histone genes and has all the properties of a retropseudogene. It is highly homologous to the transcribed region of the D. melanogaster histone H2B gene, but not to its flanking regions, and is surrounded by short direct repeats. The pseudogene contains several point mutations that preclude its translation. The sequence of the 3' region of this pseudogene is compatible with the hypothesis that the 3' terminal stem-loop structure of the histone H2B mRNA has served as a primer for the reverse transcription event from which this pseudogene originated. Analysis of the regions flanking the histone H2B pseudogene revealed the presence of three different types of transposable elements, suggesting that this chromosomal locus represents a hotspot for transposition.

The mouse histone H1 genes: gene organization and differential regulation

There are six mouse histone H1 genes present in the histone gene cluster on mouse chromosome 13. These genes encode five histone H1 variants expressed in somatic cells, H1a to H1e, and the testis-specific H1t histone. Two of the genes that have not been assigned previously to the five somatic H1 subtypes have been identified as encoding the H1b and H1d subtypes. Three of the H1 genes, H1a, H1c and H1t, are present on an 80 kb segment of DNA that contains nine core histone genes. Two others, H1d and H1e, are present in a second patch, while the H1b gene is at least 500 kb away in a patch containing 14 core histone genes. The histone H1 genes are differentially expressed. All five genes for the somatic histone H1 proteins are expressed in exponentially growing cells. However, the levels of H1a, H1b and H1d mRNAs are greatly reduced in cells that are terminally differentiated or arrested in G0, while the H1c and H1e mRNAs continue to be expressed. In addition to the major RNA that ends at the stem-loop, the H1c gene expresses a longer, polyadenylated mRNA in differentiated cells, although in varying amounts. None of the other histone H1 genes encodes detectable amounts of polyadenylated mRNAs.

Differential effects of heat shock on translation of normal mRNAs in primary spermatocytes, elongated spermatids, and Sertoli cells in seminiferous tubule culture

Male germ cells in mice develop normally at 32 degrees C and spermatogenesis is severely inhibited by higher temperatures, including abdominal temperature, 37 degrees C. To examine the effects of heat stress on protein synthesis in various testicular cell types, seminiferous tubules were cultured at 32 degrees or 37 degrees C for 70 min or 42.5 degrees or 44 degrees C for 10 min followed by incubation for 60 min at 32 degrees C. Cultures were labeled with [35S]methionine, and the proteins that are soluble in 4% trichloroacetic acid were analyzed by acid-urea polyacrylamide gel electrophoresis. This culture system preserves the cytoarchitecture of the seminiferous epithelium and avoids breaking late haploid cells (elongated spermatids) during tissue dissociation. Incorporation of [35S]methionine into histone H1t, the testis-specific subtype of histone H1, in pachytene primary spermatocytes (meiotic cells) was reduced by about 33-50% following incubation at 37 degrees and 42.5 degrees C and by >/=90% after incubation at 44 degrees C. In contrast, exposure to 37 degrees, 42.5 degrees, and 44 degrees C had minimal effects on incorporation into transition proteins 1 and 2 in elongated spermatids. To determine whether heat stress inhibits translational initiation, the distribution of several mRNAs in cytoplasmic extracts of cultured tubules was analyzed by sucrose gradients and Northern blots. Exposure to 37 degrees and 44 degrees C produces incremental reductions in the size of polysomes translating H1t mRNA in pachytene spermatocytes and the sulfated glycoprotein 2 mRNA in Sertoli cells, the somatic cell type in the germinal epithelium. Neither 37 degrees nor 44 degrees C reduces the size or proportion of polysomal protamine 2 mRNA in elongated spermatids. These results demonstrate that the initiation of translation in pachytene spermatocytes and Sertoli cells is inhibited by exposure to abdominal temperature and that elongated spermatids are much more resistant to thermal stress.

Chromatin modifications during oogenesis in the mouse: removal of somatic subtypes of histone H1 from oocyte chromatin occurs post-natally through a post-transcriptional mechanism

We examined the distribution of the somatic subtypes of histone H1 and the variant subtype, H1(0), and their encoding mRNAs during oogenesis and early embryogenesis in the mouse. As detected using immunocytochemistry, somatic H1 was present in the nuclei of oocytes of 18-day embryos. Following birth, however, somatic H1 became less abundant in both growing and non-growing oocytes, beginning as early as 4 days of age in the growing oocytes, and was scarcely detectable by 19 days. Together with previous results, this defines a period of time when somatic H1 is depleted in oocytes, namely, from shortly after birth when the oocytes are at prophase I until the 4-cell stage following fertilization. At the stages when somatic H1 was undetectable, oocyte nuclei could be stained using an antibody raised against histone H1(0), which suggests that this may be a major linker histone in these cells. In contrast to the post-natal loss of somatic H1 protein, mRNAs encoding four (H1a, H1b, H1d, H1e) of the five somatic subtypes were present, as detected using RT-PCR in growing oocytes of 9-day pups, and all five subtypes including H1c were present in fully grown oocytes of adults. All five subtypes were also present in embryos, both before and after activation of the embryonic genome. mRNA encoding H1(0) was also detected in oocytes and early embryos. Whole-mount in situ hybridization using cloned H1c and H1e cDNAs revealed that the mRNAs were present in the cytoplasm of oocytes and 1-cell embryos, in contrast to the sea urchin early embryo where they are sequestered in the cell nucleus. We suggest that, as in many somatic cell types, the chromatin of mouse oocytes becomes depleted of somatic H1 and relatively enriched in histone H1(0) postnatally, and that somatic H1 is reassembled onto chromatin in cleavage-stage embryos. The post-natal loss of somatic H1 appears to be regulated post-transcriptionally by a mechanism not involving nuclear localization.

Carboxyl-terminal peptides from histone H1 variants: DNA binding characteristics and solution conformation

The carboxyl-terminal domains of the histone H1 proteins bind to DNA and are important in condensation of DNA. Little is known about the details of the interactions between H1 histones and DNA, and in particular, there is little known about differences among variant H1 histones in their interactions with DNA. Questions concerning H1 histone-DNA affinity and H1 conformation were investigated using peptide fragments from the carboxyl terminal domains of four nonallelic histone H1 variant proteins (mouse H1-1, H1-4 and H1(0), and rat H1t). Three of the four peptides showed a slight preference for binding to a GC-rich region of a 214-base-pair DNA fragment, rather than to an AT-rich region. The fourth peptide, H1t, appeared to bind preferentially to the AT-rich region of the 214-base-pair fragment. The results show that these small peptides bind preferentially to a subset of DNA sequences: such sequence preference might be exhibited by the intact H1 histones themselves. CD spectra of the peptides, which are from regions of the proteins that are not compactly folded, showed that the alpha-helical content of the peptides was minimal if the peptides were in 10 mM phosphate buffer, but increased if the peptides were in 1M NaClO4 and 50% trifluoroethanol, conditions that are postulated to approximate certain aspects of binding to DNA. H1-4 peptide, which was predicted to be 70% alpha-helix, but was not alpha-helical in 10 mM phosphate buffer, appeared from difference CD spectra to be more alpha-helical when it was bound to DNA. The regions of the proteins from which these peptides are derived, which are extended in solution, may fold, forming alpha-helices, upon binding to DNA.

Cloning of the cDNA encoding a novel subtype of histone H1

The H1 class of histones is implicated in organizing a higher order of chromatin structure and in involvement with transcriptional repression. They compromise multiple subtypes that presumably have a specific function. We report here the isolation and characterization of a human cDNA encoding a novel subtype of histone H1. It is the most distantly related subtype of mammalian H1 reported to date. However, it still shares the characteristic features of H1: the tripartite structure, conservation in the globular domain, the profile of hydropathy and the basic isoelectric point. The expression of this H1 subtype was ubiquitously observed in all tissues examined. Our findings suggest that novel subtypes of H1 may remain unidentified in mammals.

Characterization of the mouse histone gene cluster on chromosome 13: 45 histone genes in three patches spread over 1Mb

The histone gene cluster on mouse chromosome 13 has been isolated and characterized. Using overlapping YAC clones containing histone genes from chromosome 13, a contig of approximately 2 Mb has been defined. It contains 45 histone genes, organized in three patches containing tightly clustered genes. An 80-kb patch (patch III) containing 12 histone genes is near one end of the contig, and a similar-sized patch (patch I) containing 15 histone genes is near the other end of the contig, located at least 500 kb from the central patch (patch II) of histone genes. The entire cluster contains six histone H1 genes, including the testis-specific histone H1t gene that maps to the middle of the cluster. All nine histone H3 genes in this cluster have been sequenced, and their level of expression determined. Each histone H3 gene is distinct, with five genes encoding the H3.2 protein subtype and four genes encoding the H3.1 protein. They are all expressed, with each histone H3 gene accounting for a small proportion of the total histone H3 mRNA.

Structure of a cluster of mouse histone genes

The structure of a 25 kilobase region of mouse DNA containing 6 functional histone genes and an H2a pseudogene has been determined. The sequences and levels of expression of the H3 and H2b gene as well as the sequence of the H2a pseudogene have been determined.

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 of two murine H1 histone genes and chromosomal mapping of the H1 gene complement

The mammalian H1 histone gene complement consists of at least seven H1 protein isoforms. These include five S-phase-dependent H1 protein subtypes and two more distantly related proteins, which are expressed upon terminal differentiation (H1o) or during the pachytene stage of spermatogenesis (H1t). In the past, three replication-dependent murine H1 genes plus the H1o and H1t genes have been isolated and characterized. In this report, we describe the sequences of two more H1 genes, and we show that all five murine replication-dependent H1 genes and the H1t gene map to the region A2-3 on Chromosome (Chr) 13. This is in agreement with our previous finding that the human H1 histone gene complement maps to 6p21.3, which corresponds to the A2-3 region on the murine Chr 13. Previous reports have shown that the replication-independent H1o genes map to syntenic regions on Chrs 22 (human H1o) and 15 (murine H1o).

Mice develop normally without the H1(0) linker histone

H1 histones bind to the linker DNA between nucleosome core particles and facilitate the folding of chromatin into a 30-nm fiber. Mice contain at least seven nonallelic subtypes of H1, including the somatic variants H1a through H1e, the testis-specific variant H1t, and the replacement linker histone H1(0). H1(0) accumulates in terminally differentiating cells from many lineages, at about the time when the cells cease dividing. To investigate the role of H1(0) in development, we have disrupted the single-copy H1(0) gene by homologous recombination in mouse embryonic stem cells. Mice homozygous for the mutation and completely lacking H1(0) mRNA and protein grew and reproduced normally and exhibited no anatomic or histologic abnormalities. Examination of tissues in which H1(0) is normally present at high levels also failed to reveal any abnormality in cell division patterns. Chromatin from H1(0)-deficient animals showed no significant change in the relative proportions of the other H1 subtypes or in the stoichiometry between linker histones and nucleosomes, suggesting that the other H1 histones can compensate for the deficiency in H1(0) by occupying sites that normally contain H1(0). Our results indicate that despite the unique properties and expression pattern of H1(0), its function is dispensable for normal mouse development.

An upstream control region required for inducible transcription of the mouse H1(zero) histone gene during terminal differentiation

The replacement linker histone H1 (zero) is associated with terminal differentiation in many mammalian cell types, and its accumulation in chromatin may contribute to transcriptional repression occurring during terminal differentiation. H1 (zero) also accumulates in a variety of cell culture lines undergoing terminal differentiation. During in vitro mouse erythroleukemia cell differentiation, H1 (zero) gene expression is induced very rapidly, prior to the time when the cells actually commit to terminal differentiation. We have used a combination of transfection assays and in vitro DNA-protein interaction studies to identify nuclear protein binding sites in the H1 (zero) promoter that control expression and induction of the H1(zero) gene in mouse erythroleukemia cells. The results indicate that transcription of the H1 (zero) gene is controlled by three elements present in the upstream region of the promoter between positions -305 and -470. Site-directed mutagenesis of each of these elements showed that one of them controls inducibility of the gene in differentiating cells. The other two elements in the upstream control region affect primarily the level of transcription of the gene in undifferentiated and differentiating cells. These two elements share a DNA sequence motif consisting of a (dG)6 tract contained in an eight-base consensus, (A/C)GGGGGG(A/C). Additional copies of this motif are present elsewhere in the H1 (zero) promoter.