hv1 is an evolutionarily conserved H2A variant that is preferentially associated with active genes

A phylogenetic and proteomic reconstruction of eukaryotic chromatin evolution

Histones and associated chromatin proteins have essential functions in eukaryotic genome organization and regulation. Despite this fundamental role in eukaryotic cell biology, we lack a phylogenetically-comprehensive understanding of chromatin evolution. Here, we combine comparative proteomics and genomics analysis of chromatin in eukaryotes and archaea. Proteomics uncovers the existence of histone post-translational modifications in Archaea. However, archaeal histone modifications are scarce, in contrast with the highly conserved and abundant marks we identify across eukaryotes. Phylogenetic analysis reveals that chromatin-associated catalytic functions (e.g., methyltransferases) have pre-eukaryotic origins, whereas histone mark readers and chaperones are eukaryotic innovations. We show that further chromatin evolution is characterized by expansion of readers, including capture by transposable elements and viruses. Overall, our study infers detailed evolutionary history of eukaryotic chromatin: from its archaeal roots, through the emergence of nucleosome-based regulation in the eukaryotic ancestor, to the diversification of chromatin regulators and their hijacking by genomic parasites.

The H2A.Z-nuclesome code in mammals: emerging functions

H2A.Z is a histone variant that provides specific structural and docking-side properties to the nucleosome, resulting in diverse and specialised molecular and cellular functions. In this review, we discuss the latest studies uncovering new functional aspects of mammalian H2A.Z in gene transcription, including pausing and elongation of RNA polymerase II (RNAPII) and enhancer activity; DNA repair; DNA replication; and 3D chromatin structure. We also review the recently described role of H2A.Z in embryonic development, cell differentiation, neurodevelopment, and brain function. In conclusion, our cumulative knowledge of H2A.Z over the past 40 years, in combination with the implementation of novel molecular technologies, is unravelling an unexpected and complex role of histone variants in gene regulation and disease.

Three-dimensional chromatin in infectious disease-A role for gene regulation and pathogenicity?

The recent Coronavirus Disease 2019 pandemic has once again reminded us the importance of understanding infectious diseases. One important but understudied area in infectious disease research is the role of nuclear architecture or the physical arrangement of the genome in the nucleus in controlling gene regulation and pathogenicity. Recent advances in research methods, such as Genome-wide chromosome conformation capture using high-throughput sequencing (Hi-C), have allowed for easier analysis of nuclear architecture and chromosomal reorganization in both the infectious disease agents themselves as well as in their host cells. This review will discuss broadly on what is known about nuclear architecture in infectious disease, with an emphasis on chromosomal reorganization, and briefly discuss what steps are required next in the field.

Exploring the Histone Acetylation Cycle in the Protozoan Model Tetrahymena thermophila

The eukaryotic histone acetylation cycle is composed of three classes of proteins, histone acetyltransferases (HATs) that add acetyl groups to lysine amino acids, bromodomain (BRD) containing proteins that are one of the most characterized of several protein domains that recognize acetyl-lysine (Kac) and effect downstream function, and histone deacetylases (HDACs) that catalyze the reverse reaction. Dysfunction of selected proteins of these three classes is associated with human disease such as cancer. Additionally, the HATs, BRDs, and HDACs of fungi and parasitic protozoa present potential drug targets. Despite their importance, the function and mechanisms of HATs, BRDs, and HDACs and how they relate to chromatin remodeling (CR) remain incompletely understood. Tetrahymena thermophila (Tt) provides a highly tractable single-celled free-living protozoan model for studying histone acetylation, featuring a massively acetylated somatic genome, a property that was exploited in the identification of the first nuclear/type A HAT Gcn5 in the 1990s. Since then, Tetrahymena remains an under-explored model for the molecular analysis of HATs, BRDs, and HDACs. Studies of HATs, BRDs, and HDACs in Tetrahymena have the potential to reveal the function of HATs and BRDs relevant to both fundamental eukaryotic biology and to the study of disease mechanisms in parasitic protozoa.

The histone variant H2A.Z in gene regulation

The histone variant H2A.Z is involved in several processes such as transcriptional control, DNA repair, regulation of centromeric heterochromatin and, not surprisingly, is implicated in diseases such as cancer. Here, we review the recent developments on H2A.Z focusing on its role in transcriptional activation and repression. H2A.Z, as a replication-independent histone, has been studied in several model organisms and inducible mammalian model systems. Its loading machinery and several modifying enzymes have been recently identified, and some of the long-standing discrepancies in transcriptional activation and/or repression are about to be resolved. The buffering functions of H2A.Z, as supported by genome-wide localization and analyzed in several dynamic systems, are an excellent example of transcriptional control. Posttranslational modifications such as acetylation and ubiquitination of H2A.Z, as well as its specific binding partners, are in our view central players in the control of gene expression. Understanding the key-mechanisms in either turnover or stabilization of H2A.Z-containing nucleosomes as well as defining the H2A.Z interactome will pave the way for therapeutic applications in the future.

The bromodomain-containing protein Ibd1 links multiple chromatin-related protein complexes to highly expressed genes in Tetrahymena thermophila

Background

The chromatin remodelers of the SWI/SNF family are critical transcriptional regulators. Recognition of lysine acetylation through a bromodomain (BRD) component is key to SWI/SNF function; in most eukaryotes, this function is attributed to SNF2/Brg1.

Results

Using affinity purification coupled to mass spectrometry (AP–MS) we identified members of a SWI/SNF complex (SWI/SNF^Tt) in Tetrahymena thermophila. SWI/SNF^Tt is composed of 11 proteins, Snf5^Tt, Swi1^Tt, Swi3^Tt, Snf12^Tt, Brg1^Tt, two proteins with potential chromatin-interacting domains and four proteins without orthologs to SWI/SNF proteins in yeast or mammals. SWI/SNF^Tt subunits localize exclusively to the transcriptionally active macronucleus during growth and development, consistent with a role in transcription. While Tetrahymena Brg1 does not contain a BRD, our AP–MS results identified a BRD-containing SWI/SNF^Tt component, Ibd1 that associates with SWI/SNF^Tt during growth but not development. AP–MS analysis of epitope-tagged Ibd1 revealed it to be a subunit of several additional protein complexes, including putative SWR^Tt, and SAGA^Tt complexes as well as a putative H3K4-specific histone methyl transferase complex. Recombinant Ibd1 recognizes acetyl-lysine marks on histones correlated with active transcription. Consistent with our AP–MS and histone array data suggesting a role in regulation of gene expression, ChIP-Seq analysis of Ibd1 indicated that it primarily binds near promoters and within gene bodies of highly expressed genes during growth.

Conclusions

Our results suggest that through recognizing specific histones marks, Ibd1 targets active chromatin regions of highly expressed genes in Tetrahymena where it subsequently might coordinate the recruitment of several chromatin-remodeling complexes to regulate the transcriptional landscape of vegetatively growing Tetrahymena cells.

Electronic supplementary material

The online version of this article (10.1186/s13072-018-0180-6) contains supplementary material, which is available to authorized users.

Transcriptional regulation mediated by H2A.Z via ANP32e-dependent inhibition of protein phosphatase 2A

The mechanisms that regulate H2A.Z and its requirement for transcription in differentiated mammalian cells remains ambiguous. In this study, we identified the interaction between the C-terminus of ANP32e and N-terminus of H2A.Z in a yeast two-hybrid screen. Knockdown of ANP32e resulted in proteasomal degradation and nuclear depletion of H2A.Z or of a chimeric green florescence protein fused to its N-terminus. This effect was reversed by inhibition of protein phosphatase 2A (PP2A) and, conversely, reproduced by overexpression of its catalytic subunit. Accordingly, knockdown of ANP32e inhibited phosphorylation of H2A.Z, whereas a mutation of serine-9 proved its requirement for both the protein's stability and nuclear localization, as did knockdown of the nuclear mitogen and stress-induced kinase 1. Moreover, ANP32e's knockdown also revealed its differential requirement for cell signaling and gene expression, whereas, genome-wide binding analysis confirmed its co-localization with H2A.Z at transcription start sites, as well as, gene bodies of inducible and tissue-specific genes. The data also suggest that H2A.Z restricts transcription, which is moderated by ANP32e at the promoter and gene bodies of expressed genes. Thus, ANP32e, through inhibition of PP2A, is required for nucleosomal inclusion of H2A.Z and the regulation of gene expression.

Evolution of epigenetic chromatin states

The central dogma of gene expression entails the flow of genetic information from DNA to RNA, then to protein. Decades of studies on epigenetics have characterized an additional layer of information, where epigenetic states help to shape differential utilization of genetic information. Orchestrating conditional gene expressions to elicit a defined phenotype and function, epigenetics states distinguish different cell types or maintain a long-lived memory of past signals. Packaging the genetic information in the nucleus of the eukaryotic cell, chromatin provides a large regulatory repertoire that capacitates the genome to give rise to many distinct epigenomes. We will discuss how reversible, heritable functional annotation mechanisms in chromatin may have evolved from basic chemical diversification of the underlying molecules.

Precise deposition of histone H2A.Z in chromatin for genome expression and maintenance

Histone variant H2A.Z is essential in higher eukaryotes and has different functions in the cell. Several studies indicate that H2A.Z is found at specific loci in the genome such as regulatory-gene regions, where it poises genes for transcription. Itsdeposition creates chromatin regions with particular structural characteristics which could favor rapid transcription activation. This review focuses on the highly regulated mechanism of H2A.Z deposition in chromatin which is essential for genome integrity. Chaperones escort H2A.Z to large ATP-dependent chromatin remodeling enzymes which are responsible for its deposition/eviction. Over the last ten years, biochemical, genetic and genomic studies helped us understand the precise role of these complexes in this process. It hasbeen suggested that a cooperation occurs between histone acetyltransferase and chromatin remodeling activities to incorporate H2A.Z in chromatin. Its regulated deposition near centromeres and telomeres also shows its implication in chromosomal structure integrity and parallels a role in DNA damage response. Thedynamics of H2A.Z deposition/eviction at specific loci was shown to be critical for genome expression andmaintenance, thus cell fate. Altogether, recent findings reassert the importance of the regulated depositionof this histone variant. This article is part of a Special Issue entitled: Histone chaperones and Chromatin assembly.

Histone variants: emerging players in cancer biology

Histone variants are key players in shaping chromatin structure, and, thus, in regulating fundamental cellular processes such as chromosome segregation and gene expression. Emerging evidence points towards a role for histone variants in contributing to tumor progression, and, recently, the first cancer-associated mutation in a histone variant-encoding gene was reported. In addition, genetic alterations of the histone chaperones that specifically regulate chromatin incorporation of histone variants are rapidly being uncovered in numerous cancers. Collectively, these findings implicate histone variants as potential drivers of cancer initiation and/or progression, and, therefore, targeting histone deposition or the chromatin remodeling machinery may be of therapeutic value. Here, we review the mammalian histone variants of the H2A and H3 families in their respective cellular functions, and their involvement in tumor biology.

Analysis of active chromatin modifications in early mammalian embryos reveals uncoupling of H2A.Z acetylation and H3K36 trimethylation from embryonic genome activation

Early embryonic development is characterized by dramatic changes in cell potency and chromatin organization. The role of histone variants in the context of chromatin remodeling during embryogenesis remains under investigated. In particular, the nuclear distribution of the histone variant H2A.Z and its modifications have not been examined. Here we investigated the dynamics of acetylation of H2A.Z and two other active chromatin marks, H3K9ac and H3K36me3, throughout murine and bovine pre-implantation development. We show that H2A.Z distribution is dynamic during the earliest stages of mouse development, with protein levels significantly varying across stages and lowest at the 2-cell stage. When present, H2A.Z localizes preferentially to euchromatin at all stages analyzed. H2A.Z is acetylated in pre-implantation blastomeres and is preferentially localized to euchromatin, in line with the known role of H2A.Zac in transcriptional activation. Interestingly, however, H2A.Zac is undetectable in mouse embryos at the 2-cell stage, the time of major embryonic genome activation (EGA). Similarly, H3K36me3 is present exclusively in the maternal chromatin immediately after fertilization but becomes undetectable in interphase nuclei at the 2-cell stage, suggesting uncoupling of these active marks with global embryonic transcription activation. In bovine embryos, which undergo EGA at the 8-cell stage, H2A.Zac can be detected in zygotes, 4-, 8- and 16-cell stage embryos as well as in blastocysts, indicating that the dynamics of H2A.Zac is not conserved in mammals. In contrast, H3K36me3 displays mostly undetectable and heterogeneous localization pattern throughout bovine pre-implantation development. Thus, our results suggest that 'canonical' active chromatin marks exhibit a dynamic behavior in embryonic nuclei, which is both stage- and species-specific. We hypothesize that chromatin of early embryonic nuclei is subject to fine-tuning through differential acquisition of histone marks, allowing for proper chromatin remodeling and developmental progression in a species-specific fashion.

Histone H2A.Z acid patch residues required for deposition and function

The incorporation of histone variants is one mechanism used by the eukaryotic cell to alter the generally repressive chromatin template. However, the exact molecular mechanisms that direct this incorporation are not well understood. The SWR1 chromatin remodeling complex that binds to and directs incorporation of histone variant H2A.Z into chromatin has been characterized, but significantly less information is available concerning the requirements on the H2A.Z target molecule. We performed an unbiased mutagenic screen designed to elucidate the function of H2A.Z in Saccharomyces cerevisiae. The screen identified residues within the conserved acidic patch of H2A.Z as being important for the function of the variant. We characterized single point mutations in the patch that are phenotypically sensitive to a variety of growth conditions and are expressed at lower protein levels, but are functionally defective (htz1-D99A, htz1-D99K, and htz1-E101K). The mutants were significantly less detectable by chromatin immunoprecipitation at PHO5, a gene previously described to be enriched for H2A.Z. These results identify acidic patch residues of H2A.Z that are critical for mediating deposition and function in chromatin, and represent potential candidates for the interaction of H2A.Z with its deposition and/or targeting machinery.

Restricting dosage compensation complex binding to the X chromosomes by H2A.Z/HTZ-1

Dosage compensation ensures similar levels of X-linked gene products in males (XY or XO) and females (XX), despite their different numbers of X chromosomes. In mammals, flies, and worms, dosage compensation is mediated by a specialized machinery that localizes to one or both of the X chromosomes in one sex resulting in a change in gene expression from the affected X chromosome(s). In mammals and flies, dosage compensation is associated with specific histone posttranslational modifications and replacement with variant histones. Until now, no specific histone modifications or histone variants have been implicated in Caenorhabditis elegans dosage compensation. Taking a candidate approach, we have looked at specific histone modifications and variants on the C. elegans dosage compensated X chromosomes. Using RNAi-based assays, we show that reducing levels of the histone H2A variant, H2A.Z (HTZ-1 in C. elegans), leads to partial disruption of dosage compensation. By immunofluorescence, we have observed that HTZ-1 is under-represented on the dosage compensated X chromosomes, but not on the non-dosage compensated male X chromosome. We find that reduction of HTZ-1 levels by RNA interference (RNAi) and mutation results in only a very modest change in dosage compensation complex protein levels. However, in these animals, the X chromosome-specific localization of the complex is partially disrupted, with some nuclei displaying DCC localization beyond the X chromosome territory. We propose a model in which HTZ-1, directly or indirectly, serves to restrict the dosage compensation complex to the X chromosome by acting as or regulating the activity of an autosomal repellant.

Global histone analysis by mass spectrometry reveals a high content of acetylated lysine residues in the malaria parasite Plasmodium falciparum

Post-translational modifications (PTMs) of histone tails play a key role in epigenetic regulation of gene expression in a range of organisms from yeast to human; however, little is known about histone proteins from the parasite that causes malaria in humans, Plasmodium falciparum. We characterized P. falciparum histone PTMs using advanced mass spectrometry driven proteomics. Acid-extracted proteins were resolved in SDS-PAGE, in-gel trypsin digested, and analyzed by reversed-phase LC-MS/MS. Through the combination of Q-TOF and LTQ-FT mass spectrometry we obtained high mass accuracy of both precursor and fragment ions, which is a prerequisite for high-confidence identifications of multisite peptide modifications. We utilize MS/MS fragment marker ions to validate the identification of histone modifications and report the m/z 143 ion as a novel MS/MS marker ion for monomethylated lysine. We identified all known P. falciparum histones and mapped 44 different modifications, providing a comprehensive view of epigenetic marks in the parasite. Interestingly, the parasite exhibits a histone modification pattern that is distinct from its human host. A general preponderance for modifications associated with a transcriptionally permissive state was observed. Additionally, a novel differentiation in the modification pattern of the two histone H2B variants (H2B and H2Bv) was observed, suggesting divergent functions of the two H2B variants in the parasite. Taken together, our results provide a first comprehensive map of histone modifications in P. falciparum and highlight the utility of tandem MS for detailed analysis of peptides containing multiple PTMs.

The genomic distribution and function of histone variant HTZ-1 during C. elegans embryogenesis

In all eukaryotes, histone variants are incorporated into a subset of nucleosomes to create functionally specialized regions of chromatin. One such variant, H2A.Z, replaces histone H2A and is required for development and viability in all animals tested to date. However, the function of H2A.Z in development remains unclear. Here, we use ChIP-chip, genetic mutation, RNAi, and immunofluorescence microscopy to interrogate the function of H2A.Z (HTZ-1) during embryogenesis in Caenorhabditis elegans, a key model of metazoan development. We find that HTZ-1 is expressed in every cell of the developing embryo and is essential for normal development. The sites of HTZ-1 incorporation during embryogenesis reveal a genome wrought by developmental processes. HTZ-1 is incorporated upstream of 23% of C. elegans genes. While these genes tend to be required for development and occupied by RNA polymerase II, HTZ-1 incorporation does not specify a stereotypic transcription program. The data also provide evidence for unexpectedly widespread independent regulation of genes within operons during development; in 37% of operons, HTZ-1 is incorporated upstream of internally encoded genes. Fewer sites of HTZ-1 incorporation occur on the X chromosome relative to autosomes, which our data suggest is due to a paucity of developmentally important genes on X, rather than a direct function for HTZ-1 in dosage compensation. Our experiments indicate that HTZ-1 functions in establishing or maintaining an essential chromatin state at promoters regulated dynamically during C. elegans embryogenesis.

To fit within a cell's nucleus, DNA is wrapped around protein spools composed of the histones H3, H4, H2A, and H2B. One spool and the DNA wrapped around it are called a nucleosome, and all of the packaged DNA in a cell's nucleus is collectively called “chromatin.” Chromatin is important because it modulates access to information encoded in the underlying DNA. Spools with specialized functions can be created by replacing a typical histone component with a variant version of the histone protein. Here, we examine the distribution and function of the C. elegans histone H2A variant H2A.Z (called HTZ-1) during development. We demonstrate that HTZ-1 is required for proper development, and that embryos are dependent on a contribution of HTZ-1 from their mothers for survival. We mapped the location of HTZ-1 incorporation genome-wide and found that HTZ-1 binds upstream of 23% of genes, which tend to be genes that are essential for development and occupied by RNA polymerase. Fewer sites of HTZ-1 incorporation were found on the X chromosome, probably due to an under-representation of essential genes on X rather than a direct role for HTZ-1 in X-chromosome dosage compensation. Our study reveals how the genome is remodeled by HTZ-1 to allow the proper regulation of genes critical for development.

Dynamic nuclear reorganization during genome remodeling of Tetrahymena

The single-celled ciliate Tetrahymena thermophila possesses two versions of its genome, one germline, one somatic, contained within functionally distinct nuclei (called the micronucleus and macronucleus, respectively). These two genomes differentiate from identical zygotic copies. The development of the somatic nucleus involves large-scale DNA rearrangements that eliminate 15 to 20 Mbp of their germline-derived DNA. The genomic regions excised are dispersed throughout the genome and are largely composed of repetitive sequences. These germline-limited sequences are targeted for removal from the genome by a RNA interference (RNAi)-related machinery that directs histone H3 lysine 9 and 27 methylation to their associated chromatin. The targeting small RNAs are generated in the micronucleus during meiosis and then compared against the parental macronucleus to further enrich for germline-limited sequences and ensure that only non-genic DNA segments are eliminated. Once the small RNAs direct these chromatin modifications, the DNA rearrangement machinery, including the chromodomain proteins Pdd1p and Pdd3p, assembles on these dispersed chromosomal sequences, which are then partitioned into nuclear foci where the excision events occur. This DNA rearrangement mechanism is Tetrahymena's equivalent to the silencing of repetitive sequences by the formation of heterochromatin. The dynamic nuclear reorganization that occurs offers an intriguing glimpse into mechanisms that shape nuclear architecture during eukaryotic development.

New Insights into the Macronuclear Development in Ciliates

During macronuclear differentiation in ciliated protozoa, most amazing "DNA gymnastics" takes place, which includes DNA excision, DNA elimination, DNA reorganization, and DNA-specific amplification. Although the morphological events occurring during macronuclear development are well described, a detailed knowledge of the molecular mechanisms and the regulation of this differentiation process is still missing. However, recently several models have been proposed for the molecular regulation of macronuclear differentiation, but these models have yet to be verified experimentally. The scope of this review is to summarize recent discoveries in different ciliate species and to compare and discuss the different models proposed. Results obtained in these studies are not only relevant for our understanding of nuclear differentiation in ciliates, but also for cellular differentiation in eukaryotic organisms in general as well as for other disciplines such as bioinformatics and computational biology.

Temporal regulation of foregut development by HTZ-1/H2A.Z and PHA-4/FoxA

The histone variant H2A.Z is evolutionarily conserved and plays an essential role in mice, Drosophila, and Tetrahymena. The essential function of H2A.Z is unknown, with some studies suggesting a role in transcriptional repression and others in activation. Here we show that Caenorhabditis elegans HTZ-1/H2A.Z and the remodeling complex MYS-1/ESA1–SSL-1/SWR1 synergize with the FoxA transcription factor PHA-4 to coordinate temporal gene expression during foregut development. We observe dramatic genetic interactions between pha-4 and htz-1, mys-1, and ssl-1. A survey of transcription factors reveals that this interaction is specific, and thus pha-4 is acutely sensitive to reductions in these three proteins. Using a nuclear spot assay to visualize HTZ-1 in living embryos as organogenesis proceeds, we show that HTZ-1 is recruited to foregut promoters at the time of transcriptional onset, and this recruitment requires PHA-4. Loss of htz-1 by RNAi is lethal and leads to delayed expression of a subset of foregut genes. Thus, the effects of PHA-4 on temporal regulation can be explained in part by recruitment of HTZ-1 to target promoters. We suggest PHA-4 and HTZ-1 coordinate temporal gene expression by modulating the chromatin environment.

During development, a single fertilized egg gives rise to the different cell types within an embryo. These different cell types are characterized by the different genes that they express. A critical question in biology is how embryonic cells activate genes at the appropriate time and place to generate the different cell types. In this paper, the authors explore temporal regulation of gene expression during formation of an organ, namely the Caenorhabditis elegans foregut. They have discovered that foregut genes require a variant of the canonical H2A histone for the onset of transcription. This variant, called H2A.Z, or htz-1 in C. elegans, promotes transcription by modifying how DNA is packaged within cells. Their data suggest that a key regulator of foregut development, the transcription factor PHA-4, recruits HTZ-1 to pharyngeal promoters, and this association contributes to their timely activation.

Patterning chromatin: form and function for H2A.Z variant nucleosomes

Although many histone variants are specific to higher eukaryotes, the H2A variant H2A.Z has been conserved during eukaryotic evolution. Genetic studies have demonstrated roles for H2A.Z in antagonizing gene-silencing, chromosome stability and gene activation. Biochemical work has identified a conserved chromatin-remodeling complex responsible for H2A.Z deposition. Recent studies have shown that two H2A.Z nucleosomes flank a nucleosome-free region containing the transcription initiation site in promoters of both active and inactive genes in Saccharomyces cerevisiae. This chromatin pattern is generated through the action of a DNA deposition signal and a specific pattern of histone tail acetylation.

Histone variants meet their match

A fascinating aspect of how chromatin structure impacts on gene expression and cellular identity is the transmission of information from mother to daughter cells, independently of the primary DNA sequence. This epigenetic information seems to be contained within the covalent modifications of histone polypeptides and the distinctive characteristics of variant histone subspecies. There are specific deposition pathways for some histone variants, which provide invaluable mechanistic insights into processes whereby the major histones are exchanged for their more specialized counterparts.

Histone variants: deviants?

Histones are a major component of chromatin, the protein-DNA complex fundamental to genome packaging, function, and regulation. A fraction of histones are nonallelic variants that have specific expression, localization, and species-distribution patterns. Here we discuss recent progress in understanding how histone variants lead to changes in chromatin structure and dynamics to carry out specific functions. In addition, we review histone variant assembly into chromatin, the structure of the variant chromatin, and post-translational modifications that occur on the variants.

A Dicer-like protein in Tetrahymena has distinct functions in genome rearrangement, chromosome segregation, and meiotic prophase

Previous studies indicated that genome rearrangement involving DNA sequence elimination that occurs at late stages of conjugation in Tetrahymena is epigenetically controlled by siRNA-like scan (scn) RNAs produced from nongenic, heterogeneous, bidirectional, micronuclear transcripts synthesized at early stages of conjugation. Here, we show that Dcl1p, one of three Tetrahymena Dicer-like enzymes, is required for processing the micronuclear transcripts to scnRNAs. DCL1 is also required for methylation of histone H3 at Lys 9, which, in wild-type cells, specifically occurs on the sequences (IESs) being eliminated. These results argue that Dcl1p processes nongenic micronuclear transcripts to scnRNAs and is required for IES elimination. This is the first evidence linking nongenic micronuclear transcripts, scnRNAs, and genome rearrangement. Dcl1p also is required for proper mitotic and meiotic segregation of micronuclear chromosomes and for normal chromosome alignment in meiotic prophase, suggesting that DCL1 has multiple functions in regulating chromosome dynamics.

[Nucleosome differentiation: role of histone H2A variants]

The histones H2A, H2B, H3 and H4 are very conserved basic proteins that wrap almost two turns of DNA to form the nucleosome core. Conventional histones can be replaced with histone variants that are found in all eukaryotic organisms. Together with other nucleosome modification pathways, histone variants participate in the functional specialization of chromatin. In this review, we focus on three major H2A histone variants: H2A.X, H2A.Z and macroH2A. Recent discoveries highlight their involvement in crucial events such as DNA repair and transcriptional regulation.

Phylogenomics of the nucleosome

Histones are best known as the architectural proteins that package the DNA of eukaryotic organisms, forming octameric nucleosome cores that the double helix wraps tightly around. Although histones have traditionally been viewed as slowly evolving scaffold proteins that lack diversification beyond their abundant tail modifications, recent studies have revealed that variant histones have evolved for diverse functions. H2A and H3 variants have diversified to assume roles in epigenetic silencing, gene expression and centromere function. Such diversification of histone variants and 'deviants' contradicts the perception of histones as monotonous members of multigene families that indiscriminately package and compact the genome. How these diverse functions have evolved from ancestral forms can be addressed by applying phylogenetic tools to increasingly abundant sequence data.

The nonessential H2A N-terminal tail can function as an essential charge patch on the H2A.Z variant N-terminal tail

Tetrahymena thermophila cells contain three forms of H2A: major H2A.1 and H2A.2, which make up approximately 80% of total H2A, and a conserved variant, H2A.Z. We showed previously that acetylation of H2A.Z was essential (Q. Ren and M. A. Gorovsky, Mol. Cell 7:1329-1335, 2001). Here we used in vitro mutagenesis of lysine residues, coupled with gene replacement, to identify the sites of acetylation of the N-terminal tail of the major H2A and to analyze its function in vivo. Tetrahymena cells survived with all five acetylatable lysines replaced by arginines plus a mutation that abolished acetylation of the N-terminal serine normally found in the wild-type protein. Thus, neither posttranslational nor cotranslational acetylation of major H2A is essential. Surprisingly, the nonacetylatable N-terminal tail of the major H2A was able to replace the essential function of the acetylation of the H2A.Z N-terminal tail. Tail-swapping experiments between H2A.1 and H2A.Z revealed that the nonessential acetylation of the major H2A N-terminal tail can be made to function as an essential charge patch in place of the H2A.Z N-terminal tail and that while the pattern of acetylation of an H2A N-terminal tail is determined by the tail sequence, the effects of acetylation on viability are determined by properties of the H2A core and not those of the N-terminal tail itself.

Histone H2A.Z acetylation modulates an essential charge patch

Histone H2A.Z is structurally and functionally distinct from the major H2As. To understand the function of H2A.Z acetylation, we performed a mutagenic analysis of the six acetylated lysines in the N-terminal tail of Tetrahymena H2A.Z. Tetrahymena cannot survive with arginines at all six sites. Retention of one acetylatable lysine is sufficient to provide the essential function of H2A.Z acetylation. This essential function can be mimicked by deleting the region encompassing all six sites, or by mutations that reduce the positive charge of the N terminus at the acetylation sites themselves, or at other sites in the tail. These properties argue that the essential function of H2A.Z acetylation is to modify a "charge patch" by reducing the charge of the tail.

Histone H2A.Z regulats transcription and is partially redundant with nucleosome remodeling complexes

Nucleosomes impose a block to transcription that can be overcome in vivo by remodeling complexes such as SNF/SWI and histone modification complexes such as SAGA. Mutations in the major core histones relieve transcriptional repression and bypass the requirement for SNF/SWI and SAGA. We have found that the variant histone H2A.Z regulates gene transcription, and deletion of the gene encoding H2A.Z strongly increases the requirement for SNF/SWI and SAGA. This synthetic genetic interaction is seen at the level of single genes and acts downstream of promoter nucleosome reorganization. H2A.Z is preferentially crosslinked in vivo to intergenic DNA at the PH05 and GAL1 loci, and this association changes with transcriptional activation. These results describe a novel pathway for regulating transcription using variant histones to modulate chromatin structure.

Pdd1p, a novel chromodomain-containing protein, links heterochromatin assembly and DNA elimination in Tetrahymena

During Tetrahymena conjugation, programmed DNA degradation occurs in two separate nuclei. Thousands of germline-specific deletion elements are removed from the genome of the developing somatic macronucleus, and the old parental macronucleus is degraded by an apoptotic mechanism. An abundant polypeptide, Pdd1p (formerly p65), localizes to both of these nuclei at the time of DNA degradation. Here we report that, in developing macronuclei, Pdd1p localizes to electron-dense, heterochromatic structures that contain germline-specific deletion elements. Pdd1p also associates with parental macronuclei during terminal stages of apoptosis. Sequencing of the PDD1 gene reveals it to be a member of the chromodomain family, suggesting a molecular link between heterochromatin assembly and programmed DNA degradation.

Characterization of the proximal promoter of the human histone H2A.Z gene

Histone H2A.Z is a distinct and evolutionarily conserved member of the histone H2A family whose synthesis, in contrast to that of most other histone species, is not dependent on DNA replication. The gene for H2A.Z lacks the signals involved in the 3' processing of replication-linked histone mRNA species and contains introns as well as polyadenylation signals. The H2A.Z gene proximal promoter, a 200-bp region upstream of the transcription start site that provides maximal activity in CAT reporter studies, contains three CCAAT and two GGGCGG elements as well as a consensus TATA element. In vitro DNase I footprint analysis of this region indicated that the central CCAAT and the distal GGGCGG elements were protected by factors present in HeLa nuclear extract. Site-directed mutations of selected promoter elements were generated in the H2A.Z gene promoter region of a CAT reporter construct by a novel one-step PCR procedure. Of the elements examined, the central CCAAT element was found to be the most important determinant of promoter activity; its disruption decreased CAT reporter activity by 65%. Disruption of the proximal CCAAT or the distal GGGCGG elements led to decreases in activity of 40%, while disruption of any of the other examined led to smaller decreases. Gel-mobility shift analysis showed that the three CCAAT elements had overlapping but not identical binding specificities for nuclear factors. The two GGGCGG elements both were found to bind transcription factor Sp1, but the distal element bound Sp1 with higher affinity. The findings show that the central and proximal CCAAT elements and the distal GGGCGG element appear to be the major determinants of the transcriptional activity of the H2A.Z gene.

Proteolytic removal of core histone amino termini and dephosphorylation of histone H1 correlate with the formation of condensed chromatin and transcriptional silencing during Tetrahymena macronuclear development

During the sexual cycle in Tetrahymena, the germ-line micronucleus gives rise to new macro- and micronuclei, whereas the former somatic macronucleus ceases transcription, becomes highly condensed, and is eventually eliminated from the cell. With polyclonal antibodies specific for acetylated forms of histone H4, immunofluorescent analyses have demonstrated that transcriptionally active macronuclei stain positively at all stages of the life cycle except during conjugation, when parental macronuclei become inactive and are eliminated from the cell. In this report using affinity-purified antibodies to either the acetylated or unacetylated amino-terminal domain of H4, immunofluorescent analyses suggest that the acetylated amino-terminal tails of H4 are proteolytically removed in "old" macronuclei during this period. This suggestion was further confirmed by biochemical analysis of purified old macronuclei that revealed several polypeptides with molecular mass 1-2 kD less than that of intact core histones. These species, which are unique to old macronuclei, are not newly synthesized and fail to stain with either acetylated or unacetylated H4 antibodies. Microsequence analysis clearly shows that these polypeptides are proteolytically processed forms of core histones whose amino-terminal "tails" (varying from 13 to 21 residues) have been removed. During the same developmental period, histone H1 is dephosphorylated rapidly and completely in old macronuclei. These results strongly suggest that the developmentally regulated proteolysis of core histones and dephosphorylation of histone H1 participate in a novel pathway leading to the formation of highly condensed chromatin and transcriptional silencing during Tetrahymena macronuclear development.

Normal transitions in synthesis of replacement histones H2A.Z and H3.3 during differentiation of dystrophic myotube cells. A brief note

We previously reported that differentiating G0 myotube cells cultured from normal chicken embryos exhibit a histone synthesis pattern that is highlighted by transitions in the expression of the minor replacement variants H3.3 and perhaps H2A.Z (Wunsch and Lough, Dev. Biol. 119 (1987) 94-99). Because these proteins may be synthesized to maintain chromatin structure during the differentiation and maturation of the skeletal muscle fiber, it was of interest to determine whether they are made at normal levels during the differentiation of dystrophic muscle. To this end, the synthesis of histone proteins in cultured myoblasts and myotubes from normal and dystrophic avian embryos has been characterized by two-dimensional polyacrylamide gel electrophoresis and fluorography. Proliferating myoblasts (day 1) as well as two stages of differentiating myotubes (days 3, 4) exhibited histone synthesis patterns that were indistinguishable when comparing normal and dystrophic cells. It is noteworthy that this study also revealed that, in both cell types, the change in H2A.Z synthesis during the myoblast/myotube transition was remarkable, increasing from approximately 20% of the non-ubiquitinated H2As in myoblasts to 80% in myotubes. Also, gel staining patterns and immunoblotting detected no differences in the degree of histone ubiquitination between normal and dystrophic cells. These findings indicate that, up to this point in dystrophic differentiation, neither the synthesis nor ubiquitination of histones are perturbed.

Conservation of intron position indicates separation of major and variant H2As is an early event in the evolution of eukaryotes

Genomic clones of Drosophila and Tetrahymena histone H2A variants were isolated using the corresponding cDNA clones (van Daal et al. 1988; White et al. 1988). The site corresponding to the initiation of transcription was defined by primer extension for both Drosophila and Tetrahymena genomic sequences. The sequences of the genomic clones revealed the presence of introns in each of the genes. The Drosophila gene has three introns: one immediately following the initiation codon, one between amino acids 26 and 27 (gln and phe), and one between amino acids 64 and 65 (glu and val). The Tetrahymena gene has two introns, the positions of which are identical to the first two introns of the Drosophila gene. The chicken H2A.F variant gene has been recently sequenced and it contains four introns (Dalton et al. 1989). The first three of these are in the same positions as the introns in the Drosophila gene. The fourth intron interrupts amino acid 108 (gly). In all cases the sizes and the sequences of the introns are divergent. However, the fact that they are in conserved positions suggests that at least two of the introns were present in the ancestral gene. A phylogenetic tree constructed from the sequences of the variant and major cell cycle-regulated histone H2A proteins from several species indicates that the H2A variant proteins are evolutionarily separate and distinct from the major cell cycle-regulated histone H2A proteins. The ancestral H2A gene must have duplicated and diverged before fungi and ciliates diverged from the rest of the eukaryote lineage. In addition, it appears that the variant histone H2A proteins analyzed here are more conserved than the major histone H2A proteins.

Chromosomal proteins of Arabidopsis thaliana

In plants with large genomes, each of the classes of the histones (H1, H2A, H2B, H3 and H4) are not unique polypeptides, but rather families of closely related proteins that are called histone variants. The small genome and preponderance of single-copy DNA in Arabidopsis thaliana has led us to ask if this plant has such families of histone variants. We have thus isolated histones from Arabidopsis and analyzed them on four polyacrylamide gel electrophoretic systems: an SDS system; an acetic acid-urea system; a Triton transverse gradient system; and a two-dimensional system combining SDS and Triton-acetic acid-urea systems. This approach has allowed us to identify all four of the nucleosomal core histones in Arabidopsis and to establish the existence of a set of H2A and H2B variants. Arabidopsis has at least four H2A variants and three H2B variants of distinct molecular weights as assessed by electrophoretic mobility on SDS-polyacrylamide gels. Thus, Arabidopsis displays a diversity in these histones similar to the diversity displayed by plants with larger genomes such as wheat.The high mobility group (HMG) non-histone chromatin proteins have attracted considerable attention because of the evidence implicating them as structural proteins of transcriptionally active chromatin. We have isolated a group of non-histone chromatin proteins from Arabidopsis that meet the operational criteria to be classed as HMG proteins and that cross-react with antisera to HMG proteins of wheat.

Synthesis of nucleosomal histone variants during wheat grain development

The synthesis and distribution of histone subfractions (variants) were investigated during early grain development and in mature tissues of wheat (Tritium aestivum L.). Histones were extracted from purified chromatin and separated by two-dimensional polyacrylamide gel electrophoresis. There were no detectable differences in the patterns of histone variants from immature grain (3-16 days after fertilization), from mature embryos, from coleoptiles and roots of 4-day-old, etiolated seedlings and from leaves of 10-day-old, light-grown seedlings. Wheat H2 histones are composed of families of closely related variants. H2A consists of three major variants, and H2B consists of two major and four minor variants. The synthesis of these variants during early grain formation was determined by calculating the specific activities of the [3H]lysine-labeled proteins synthesized between 3 and 10 days after fertilization. The rate of synthesis of the nucleosomal histones closely parallels the declining rate of cell division in developing grains. Our results indicate that all the recognized wheat histone variants are present in developing wheat grains from the earliest time investigated (3 days after fertilization) and persist with no detectable changes in relative quantities throughout grain development and in several mature tissues.