A conserved histone variant enriched in nucleoli of mammalian cells

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.

Micronucleus formation during chromatin condensation and under apoptotic conditions

In early S phase the newly replicated DNA is folded back to increasingly compact structures. The process of chromatin condensation inside the nucleus starts with the formation of a micronucleus observed in five established cell lines (K562, CHO, Indian muntjac, murine preB and SCC). Supercoiling of chromatin generates a polarized end-plate region extruded from the nucleus. The extruded chromatin is turned around itself forming the head portion (micronucleus) visible by fluorescence microscopy until the middle of S phase when chromatin structures are succeeded by distinguishable early forms of chromosomes. The generation of micronuclei upon apoptotic treatment was achieved by the methotrexate (MTX) treatment of cells. A close correlation was found between the frequency of micronucleus and MTX concentration, with low frequency at low (0.1 µM) and increasingly higher frequency between 1 and 100 µM concentrations. Characteristic deformation and shrinkage of nuclei indicated apoptosis. High MTX concentration (100 µM) caused the enlargement and necrotic disruption of nuclei. Inhibition of DNA synthesis during replicative DNA synthesis by biotinylated nucleotide prevented the formation of metaphase chromosomes and elevated the frequency of early intermediates of chromosome condensation including micronucleus formation. Based on these observations the micronucleus is regarded as: (a) a regularly occuring element of early chromatin condensation and (b) a typical sign of nuclear membrane damage under toxic conditions. Explanation is given why the micronucleus is hidden in nuclei under normal chromatin condensation and why chromatin motifs including micronuclei become visible upon cellular damage.

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.

Preferential expression of scores of functionally and evolutionarily diverse DNA and RNA-binding proteins during Oxytricha trifallax macronuclear development

During its sexual reproduction, the stichotrichous ciliate Oxytricha trifallax orchestrates a remarkable transformation of one of the newly formed germline micronuclear genomes. Hundreds of thousands of gene pieces are stitched together, excised from chromosomes, and replicated dozens of times to yield a functional somatic macronuclear genome composed of ~16,000 distinct DNA molecules that typically encode a single gene. Little is known about the proteins that carry out this process. We profiled mRNA expression as a function of macronuclear development and identified hundreds of mRNAs preferentially expressed at specific times during the program. We find that a disproportionate number of these mRNAs encode proteins that are involved in DNA and RNA functions. Many mRNAs preferentially expressed during macronuclear development have paralogs that are either expressed constitutively or are expressed at different times during macronuclear development, including many components of the RNA polymerase II machinery and homologous recombination complexes. Hundreds of macronuclear development-specific genes encode proteins that are well-conserved among multicellular eukaryotes, including many with links to germline functions or development. Our work implicates dozens of DNA and RNA-binding proteins with diverse evolutionary trajectories in macronuclear development in O. trifallax. It suggests functional connections between the process of macronuclear development in unicellular ciliates and germline specialization and differentiation in multicellular organisms, and argues that gene duplication is a key source of evolutionary innovation in this process.

Nuclear dualism

Nuclear dualism is a characteristic feature of the ciliated protozoa. Tetrahymena have two different nuclei in each cell. The larger, polyploid, somatic macronucleus (MAC) is the site of transcriptional activity in the vegetatively growing cell. The smaller, diploid micronucleus (MIC) is transcriptionally inactive in vegetative cells, but is transcriptionally active in mating cells and responsible for the genetic continuity during sexual reproduction. Although the MICs and MACs develop from mitotic products of a common progenitor and reside in a common cytoplasm, they are different from one another in almost every respect.

SUV39h-independent association of HP1 beta with fibrillarin-positive nucleolar regions

Heterochromatin protein 1 (HP1), which binds to sites of histone H3 lysine 9 (H3K9) methylation, is primarily responsible for gene silencing and the formation of heterochromatin. We observed that HP1 beta is located in both the chromocenters and fibrillarin-positive nucleoli interiors. However, HP1 alpha and HP1 gamma occupied fibrillarin-positive compartments to a lesser extent, corresponding to the distinct levels of HP1 subtypes at the promoter of rDNA genes. Deficiency of histone methyltransferases SUV39h and/or inhibition of histone deacetylases (HDACi) decreased HP1 beta and H3K9 trimethylation at chromocenters, but not in fibrillarin-positive regions that co-localized with RNA polymerase I. Similarly, SUV39h- and HDACi-dependent nucleolar rearrangement and inhibition of rDNA transcription did not affect the association between HP1 beta and fibrillarin. Moreover, the presence of HP1 beta in nucleoli is likely connected with transcription of ribosomal genes and with the role of fibrillarin in nucleolar processes.

Chromatin: linking structure and function in the nucleolus

The nucleolus is an informative model structure for studying how chromatin-regulated transcription relates to nuclear organisation. In this review, we describe how chromatin controls nucleolar structure through both the modulation of rDNA activity by convergently-evolved remodelling complexes and by direct effects upon rDNA packaging. This packaging not only regulates transcription but may also be important for suppressing internal recombination between tandem rDNA repeats. The identification of nucleolar histone chaperones and novel chromatin proteins by mass spectrometry suggests that structure-specific chromatin components remain to be characterised and may regulate the nucleolus in novel ways. However, it also suggests that there is considerable overlap between nucleolar and non-nucleolar-chromatin components. We conclude that a fuller understanding of nucleolar chromatin will be essential for understanding how gene organisation is linked with nuclear architecture.

Unique Residues on the H2A.Z Containing Nucleosome Surface Are Important for Xenopus laevis Development

Critical to vertebrate development is a complex program of events that establishes specialized tissues and organs from a single fertilized cell. Transitions in chromatin architecture, through alterations in its composition and modification markings, characterize early development. A variant of the H2A core histone, H2A.Z, is essential for development of both Drosophila and mice. We recently showed that H2A.Z is required for proper chromosome segregation. Whether H2A.Z has additional specific functions during early development remains unknown. Here we demonstrate that depletion of H2A.Z by RNA interference perturbs Xenopus laevis development at gastrulation leading to embryos with malformed, shortened trunks. Consistent with this result, whole embryo in situ hybridization indicates that endogenous expression of H2A.Z is highly enriched in the notochord. H2A.Z modifies the surface of a canonical nucleosome by creating an extended acidic patch and a metal ion-binding site stabilized by two histidine residues. To examine the significance of these specific surface regions in vivo, we investigated the consequences of overexpressing H2A.Z and mutant proteins during X. laevis development. Overexpression of H2A.Z slowed development following gastrulation. Altering the extended acidic patch of H2A.Z reversed this effect. Remarkably, modification of a single stabilizing histidine residue located on the exposed surface of an H2A.Z containing nucleosome was sufficient to disrupt normal trunk formation mimicking the effect observed by RNA interference. Taken together, these results argue that key determinants located on the surface of an H2A.Z nucleosome play an important specific role during embryonic patterning and provide a link between a chromatin structural modification and normal vertebrate development.

Characterization of the stability and folding of H2A.Z chromatin particles: implications for transcriptional activation

H2A.Z and H2A.1 nucleosome core particles and oligonucleosome arrays were obtained using recombinant versions of these histones and a native histone H2B/H3/H4 complement reconstituted onto appropriate DNA templates. Analysis of the reconstituted nucleosome core particles using native polyacrylamide gel electrophoresis and DNase I footprinting showed that H2A.Z nucleosome core particles were almost structurally indistinguishable from its H2A.1 or native chicken erythrocyte counterparts. While this result is in good agreement with the recently published crystallographic structure of the H2A.Z nucleosome core particle (Suto, R. K., Clarkson, M J., Tremethick, D. J., and Luger, K. (2000) Nat. Struct. Biol. 7, 1121-1124), the ionic strength dependence of the sedimentation coefficient of these particles exhibits a substantial destabilization, which is most likely the result of the histone H2A.Z-H2B dimer binding less tightly to the nucleosome. Analytical ultracentrifuge analysis of the H2A.Z 208-12, a DNA template consisting of 12 tandem repeats of a 208-base pair sequence derived from the sea urchin Lytechinus variegatus 5 S rRNA gene, reconstituted oligonucleosome complexes in the absence of histone H1 shows that their NaCl-dependent folding ability is significantly reduced. These results support the notion that the histone H2A.Z variant may play a chromatin-destabilizing role, which may be important for transcriptional activation.

Expression-site-associated gene 8 (ESAG8) of Trypanosoma brucei is apparently essential and accumulates in the nucleolus

Trypanosoma brucei variant surface glycoprotein expression sites are interesting examples of genomic loci under complex epigenetic control. In the infectious bloodstream stage, only one of about 20 expression sites is actively transcribed. In the Tsetse midgut (procyclic) stage, chromatin remodeling silences all expression sites. We have begun to explore the function of one of the expression-site-associated genes, ESAG8. Gene knockout experiments implied that ESAG8 is essential. ESAG8 is present at a very low level and apparently accumulates in the nucleolus. A 32-amino-acid domain, which contains a putative bipartite nuclear localization signal (NLS), is both necessary and sufficient to target fusions of ESAG8, with Aequorea victoria green fluorescent protein, to the trypanosome nucleolus. This same sequence functioned only as an NLS in mammalian cells, supporting the idea that nucleolar accumulation requires specific interactions. These results have implications for models of ESAG8 function.

A histone variant, Htz1p, and a Sir1p-like protein, Esc2p, mediate silencing at HMR

Silencing at HMR requires silencers, and one of the roles of the silencer is to recruit Sir proteins. This work focuses on the function of Sir1p once it is recruited to the silencer. We have generated mutants of Sir1p that are recruited to the silencer but are unable to silence, and we have utilized these mutants to identify four proteins, Sir3p, Sir4p, Esc2p, and Htz1p, that when overexpressed, restored silencing. The isolation of Sir3p and Sir4p validated this screen. Molecular analysis suggested that Esc2p contributed to silencing in a manner similar to Sir1p and probably helped recruit or stabilize the other Sir proteins, while Htz1p present at HMR assembled a specialized chromatin structure necessary for silencing.

Heme initiates changes in the expression of a wide array of genes during the early erythroid differentiation stage

Heme is central to oxygen sensing and utilization in all living organisms. It directly regulates numerous molecular and cellular processes for systems that sense or use oxygen. In mammals, heme plays an indispensable role in erythroid cell differentiation. To investigate heme regulatory functions, we identified, by differential display, and confirmed, by quantitative RT-PCR and Northern blotting analysis, the genes whose expression is altered by heme during the early stage of K562 cell differentiation. These include genes encoding a GAP-associated p62 protein, histone H2A.Z, a subunit of the small nuclear ribonucleoprotein complex, and the chaperonin Tcp20, and a cellular immediate-early-response gene. The results suggest that heme initiates changes in key factors that control a wide array of processes ranging from cell cycle and Ras signaling to chromatin structure, splicing and protein folding. These key factors might act together to mediate heme action, which is critical for erythroid cell differentiation.

An unusual histone H3 specific for early macronuclear development in Euplotes crassus

Characterization of the histone H3 genes of the ciliated protozoan Euplotes crassus indicates that one gene functions only during the sexual phase of the life cycle. Maximum expression of this gene, as judged by transcript accumulation, correlates with DNA replications leading to polytenization of the micronuclear chromosomes before massive DNA elimination, which produces a transcriptionally active macronucleus. Transcripts of the other gene accumulate primarily during vegetative growth and in the sexual phase of the life cycle during replication phases not related to polytenization. Although both histone H3 genes encode proteins that are fairly divergent in sequence at the amino terminus, the meiotic/polytene-specific histone H3 contains two insertions in the amino terminus that increase the size of the protein by 15 amino acids. Analysis of micrococcal nuclease digests of chromatin using hybridization probes specific for micronuclear vs. macronuclear sequences indicates that a change in nucleosomal spacing correlates with the maximal expression of the meiotic/polytene-specific histone H3 gene. Thus, we surmise that this unusual histone H3 may play a key role in targeting DNA sequences for either transcriptional activation and retention in the macronucleus or heterochromatization and elimination.

H2A.ZI, a new variant histone expressed during Xenopus early development exhibits several distinct features from the core histone H2A

We have isolated from a subtractive cDNA library of Xenopus laevis a novel transcript, H2A.ZI, which belongs to the H2A.Z variant gene family. Characterization of its expression during oogenesis and development shows significant differences from the expression of the core histone H2A. First, H2A.ZI mRNA is mainly detected only during oogenesis and after the midblastula transition, whereas H2A is constitutively expressed, at much higher levels, throughout embryonic growth. Second, in contrast with H2A, the variant H2A.ZI is polyadenylated during development. Third, expression of H2A.ZI is uncoupled from the S phase after gastrula, whereas synthesis of the core histone H2A mRNA is tightly controlled to DNA replication. Interestingly, H2A.ZI is less charged in the N-terminal tail which is crucial for chromatin-mediated repression. The characteristics of H2A.ZI suggest that its incorporation into nucleosomes would lead to a chromatin structure more competent for gene expression during development.

Essential and nonessential histone H2A variants in Tetrahymena thermophila

Although variants have been identified for every class of histone, their functions remain unknown. We have been studying the histone H2A variant hv1 in the ciliated protozoan Tetrahymena thermophila. Sequence analysis indicates that hv1 belongs to the H2A.F/Z type of histone variants. On the basis of the high degree of evolutionary conservation of this class of histones, they are proposed to have one or more distinct and essential functions that cannot be performed by their major H2A counterparts. Considerable evidence supports the hypothesis that the hv1 protein in T. thermophila and hv1-like proteins in other eukaryotes are associated with active chromatin. In T. thermophila, simple mass transformation and gene replacement techniques have recently become available. In this report, we demonstrate that either the HTA1 gene or the HTA2 gene, encoding the major H2As, can be completely replaced by disrupted genes in the polyploid, transcriptionally active macronucleus, indicating that neither of the two genes is essential. However, only some of the HTA3 genes encoding hv1 can be replaced by disrupted genes, indicating that the H2A.F/Z type variants have an essential function that cannot be performed by the major H2A genes. Thus, an essential gene in T. thermophila can be defined by the fact that it can be partially, but not completely, eliminated from the polyploid macronucleus. To our knowledge, this study represents the first use of gene disruption technology to study core histone gene function in any organism other than yeast and the first demonstration of an essential gene in T. thermophila using these methods. When a rescuing plasmid carrying a wild-type HTA3 gene was introduced into the T. thermophila cells, the endogenous chromosomal HTA3 could be completely replaced, defining a gene replacement strategy that can be used to analyze the function of essential genes.

Either of the major H2A genes but not an evolutionarily conserved H2A.F/Z variant of Tetrahymena thermophila can function as the sole H2A gene in the yeast Saccharomyces cerevisiae

H2A.F/Z histones are conserved variants that diverged from major H2A proteins early in evolution, suggesting they perform an important function distinct from major H2A proteins. Antisera specific for hv1, the H2A.F/Z variant of the ciliated protozoan Tetrahymena thermophila, cross-react with proteins from Saccharomyces cerevisiae. However, no H2A.F/Z variant has been reported in this budding yeast species. We sought to distinguish among three explanations for these observations: (i) that S. cerevisiae has an undiscovered H2A.F/Z variant, (ii) that the major S. cerevisiae H2A proteins are functionally equivalent to H2A.F/Z variants, or (iii) that the conserved epitope is found on a non-H2A molecule. Repeated attempts to clone an S. cerevisiae hv1 homolog only resulted in the cloning of the known H2A genes yHTA1 and yHTA2. To test for functional relatedness, we attempted to rescue strains lacking the yeast H2A genes with either the Tetrahymena major H2A genes (tHTA1 or tHTA2) or the gene (tHTA3) encoding hv1. Although they differ considerably in sequence from the yeast H2A genes, the major Tetrahymena H2A genes can provide the essential functions of H2A in yeast cells, the first such case of trans-species complementation of histone function. The Tetrahymena H2A genes confer a cold-sensitive phenotype. Although expressed at high levels and transported to the nucleus, hv1 cannot replace yeast H2A proteins. Proteins from S. cerevisiae strains lacking yeast H2A genes fail to cross-react with anti-hv1 antibodies. These studies make it likely that S. cerevisiae differs from most other eukaryotes in that it does not have an H2A.F/Z homolog. A hypothesis is presented relating the absence of H2A.F/Z in S. cerevisiae to its function in other organisms.

Novel electrophoretic protocol for collection of mutations in the lambda light chain immunoglobulin gene in a human B-lymphoblastoid cell strain

Spontaneous and chemically induced mutation was examined in the lambda light chain immunoglobulin gene in a human B-lymphoblastoid cell strain (T5-1). The hemizygous lambda gene is a unique mutational target gene which codes for a protein that is both expressed on the cell membrane and secreted. Mutations in the lambda gene were detected by analysis of western blots of isoelectric focusing gel electrophoresis of T5-1 cell conditioned culture medium. None of 5,841 individual clones established from vehicle-exposed populations had detectable variations in the isoelectric banding pattern of the constitutively secreted lambda immunoglobulin protein. In contrast, 113 of 6,128 clonal populations established from N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-exposed populations exhibited stable variations in expression of the lambda immunoglobulin: isoelectric variants (n = 3) and non-secretors (n = 110). MNNG-induced mutations in the lambda gene, which resulted in lambda immunoglobulin proteins with altered isoelectric points (pIs), occurred at a frequency of no less than 4.9 x 10(-4) mutations/cell, indicating the mature rearranged lambda immunoglobulin gene is comparably sensitive to carcinogen induced mutation as other human autosomal target genes. Approximately one-half of the MNNG-induced non-secretor mutant clones lacked lambda mRNA while one-half maintained constitutive transcription and expression of the lambda immunoglobulin on the cell surface, demonstrating that carcinogen damage interdicted gene function at multiple points.

An abundant high-mobility-group-like protein is targeted to micronuclei in a cell cycle-dependent and developmentally regulated fashion in Tetrahymena thermophila

In this report, we have demonstrated for the first time that an abundant high-mobility-group (HMG)-like protein, HMG B, previously thought to be specific to macronuclei in Tetrahymena thermophila, is also present in micronuclei. Biochemical data document the fact that HMG B is extremely labile in micronuclei. Unless extreme precautions are taken during the isolation of nuclei (addition of 1% formaldehyde to the nucleus isolation buffer), HMG B is not detected in micronuclei. Using polyclonal antibodies highly selective for HMG B, immunoblotting and immunofluorescence analyses show that the presence of HMG B in micronuclei is dynamic, correlating well with known periods of micronuclear DNA replication. This is the case not only during the vegetative cell cycle but also during early stages of the sexual cycle, conjugation, when the presence of HMG B in micronuclei is also closely correlated with meiotic DNA recombination and repair. Since micronuclei are transcriptionally inactive during vegetative growth, our data lend support to the idea that HMG B does not function exclusively in the establishment of transcriptionally competent chromatin. However, micronuclei are transcriptionally active during early stages of conjugation. Evidence that HMG B is strongly synthesized and deposited into micronuclei during this stage is presented. Therefore, it is tempting to suggest that HMG B may play an important role in remodeling micronuclear chromatin into an "active," more open configuration. We favor a model wherein HMG B, like other abundant, low-specificity HMG box-containing proteins, functions to wrap DNA, presumably modulating higher-order chromatin structure for a broad range of biological processes, including transcription and replication.

An abundant high-mobility-group-like protein is targeted to micronuclei in a cell cycle-dependent and developmentally regulated fashion in Tetrahymena thermophila

In this report, we have demonstrated for the first time that an abundant high-mobility-group (HMG)-like protein, HMG B, previously thought to be specific to macronuclei in Tetrahymena thermophila, is also present in micronuclei. Biochemical data document the fact that HMG B is extremely labile in micronuclei. Unless extreme precautions are taken during the isolation of nuclei (addition of 1% formaldehyde to the nucleus isolation buffer), HMG B is not detected in micronuclei. Using polyclonal antibodies highly selective for HMG B, immunoblotting and immunofluorescence analyses show that the presence of HMG B in micronuclei is dynamic, correlating well with known periods of micronuclear DNA replication. This is the case not only during the vegetative cell cycle but also during early stages of the sexual cycle, conjugation, when the presence of HMG B in micronuclei is also closely correlated with meiotic DNA recombination and repair. Since micronuclei are transcriptionally inactive during vegetative growth, our data lend support to the idea that HMG B does not function exclusively in the establishment of transcriptionally competent chromatin. However, micronuclei are transcriptionally active during early stages of conjugation. Evidence that HMG B is strongly synthesized and deposited into micronuclei during this stage is presented. Therefore, it is tempting to suggest that HMG B may play an important role in remodeling micronuclear chromatin into an "active," more open configuration. We favor a model wherein HMG B, like other abundant, low-specificity HMG box-containing proteins, functions to wrap DNA, presumably modulating higher-order chromatin structure for a broad range of biological processes, including transcription and replication.

MacroH2A, a core histone containing a large nonhistone region

A histone, macroH2A, nearly three times the size of conventional H2A histone, was found in rat liver nucleosomes. Its N-terminal third is 64 percent identical to a full-length mouse H2A. However, it also contains a large nonhistone region. This region has a segment that resembles a leucine zipper, a structure known to be involved in dimerization of some transcription factors. Nucleosomes containing macroH2A may have novel functions, possibly involving interactions with other nuclear proteins.

A simplified formaldehyde fixation and immunoprecipitation technique for studying protein-DNA interactions

Using the single cell eukaryote Tetrahymena thermophila, a simple method was developed for studying protein-DNA associations by cross-linking proteins to DNA with formaldehyde and immunoprecipitating the solubilized chromatin fragments with a specific antiserum. The protocol uses crude antiserum and involves only three steps: cross-linking, shearing to solubilize the chromatin, and immunoprecipitation. Methods for optimizing certain critical parameters, such as fixation time and NaCl concentration, are described. The method is likely to be generally useful for a variety of nuclear antigens.

Localization and expression of mRNA for a macronuclear-specific histone H2A variant (hv1) during the cell cycle and conjugation of Tetrahymena thermophila

hv1 is a histone H2A variant found in the transcriptionally active Tetrahymena macronucleus but not in the transcriptionally inert micronucleus. This, along with a number of other lines of evidence, suggests that hv1 is associated with active genes. We have used a cDNA clone as a probe to study hv1 mRNA accumulation throughout the cell cycle and during conjugation. In situ hybridization to glutaraldehyde-fixed growing cells, whose position in the cell cycle was determined by size and morphology, showed that hv1 message is present throughout the cell cycle. The message was uniformly distributed in these vegetative cells. Compared with four other Tetrahymena histone genes studied to date (S. -M. Yu, S. Horowitz, and M. A. Gorovsky, Genes Dev., 1:683, 1987; M. Wu, C. D. Allis, and M. A. Gorovsky, Proc. Natl. Acad. Sci. USA 85:2205, 1988), hv1 mRNA is the only one that does not show a pattern of accumulation during the cell cycle that could explain the nuclear localization of its encoded protein. Thus, either hv1 or some molecule with which it associates contains a macronuclear-specific targeting sequence or there exists a cell cycle-regulated event that restricts its translation to the macronuclear S phase. In situ hybridization to conjugating cells revealed that hv1 message amounts increase just prior to macronuclear development and decline precipitously after the cells separate. The hv1 message showed no marked subcellular localization and is, therefore, unlikely to play a role in the cytoplasmic determination known to occur during macronuclear development.

Codon usage in Tetrahymena and other ciliates

Codon usage in ciliates was examined by analyzing the coding regions of 22 ciliate genes corresponding to a total of 26,142 nucleotides (8,714 codons). It was found that Tetrahymena, Paramecium and the hypotrichs (Oxytricha and Stylonychia) differed in which synonymous codons were used most frequently by their genes. In fact, the codon choices in highly expressed Tetrahymena genes were more similar to those of yeast genes than those of Paramecium genes. The ciliates do not appear to have unusually strong biases in codon usage frequency when compared to other protists such as yeast. The analysis of the Tetrahymena genes indicated that genes which are highly expressed during normal cell growth have a stronger bias towards using the "preferred" codons than those expressed at lower levels during growth or for brief periods during processes such as conjugation. This conforms to what is found in other protists.

Localization and expression of mRNA for a macronuclear-specific histone H2A variant (hv1) during the cell cycle and conjugation of Tetrahymena thermophila

hv1 is a histone H2A variant found in the transcriptionally active Tetrahymena macronucleus but not in the transcriptionally inert micronucleus. This, along with a number of other lines of evidence, suggests that hv1 is associated with active genes. We have used a cDNA clone as a probe to study hv1 mRNA accumulation throughout the cell cycle and during conjugation. In situ hybridization to glutaraldehyde-fixed growing cells, whose position in the cell cycle was determined by size and morphology, showed that hv1 message is present throughout the cell cycle. The message was uniformly distributed in these vegetative cells. Compared with four other Tetrahymena histone genes studied to date (S. -M. Yu, S. Horowitz, and M. A. Gorovsky, Genes Dev., 1:683, 1987; M. Wu, C. D. Allis, and M. A. Gorovsky, Proc. Natl. Acad. Sci. USA 85:2205, 1988), hv1 mRNA is the only one that does not show a pattern of accumulation during the cell cycle that could explain the nuclear localization of its encoded protein. Thus, either hv1 or some molecule with which it associates contains a macronuclear-specific targeting sequence or there exists a cell cycle-regulated event that restricts its translation to the macronuclear S phase. In situ hybridization to conjugating cells revealed that hv1 message amounts increase just prior to macronuclear development and decline precipitously after the cells separate. The hv1 message showed no marked subcellular localization and is, therefore, unlikely to play a role in the cytoplasmic determination known to occur during macronuclear development.

Sequence and properties of the message encoding Tetrahymena hv1, a highly evolutionarily conserved histone H2A variant that is associated with active genes

hv1 is a histone H2A variant found in the transcriptionally active Tetrahymena macronucleus, but not in the transcriptionally inert micronucleus. hv1 also contains antigenic determinants conserved in the histone complements of representatives of all four eukaryotic kingdoms. A cDNA clone encoding hv1 has been isolated and sequenced. Comparison of the derived protein sequence of hv1 with that of the chicken variant H2A.F and the sea urchin variant H2A.F/Z reveals remarkable homology in all but the extreme amino- and carboxy-termini and a small region in the conserved core. Putative regions of conserved antigenicity are discussed. Evidence is presented that suggests that hv1 is a single-copy, intron-containing gene that encodes a polyadenylated message. Unusual features in the 3' flanking sequence and in codon usage are also described. Evidence is also presented showing that hv1 message amounts are ten-fold greater in growing cells than in starved cells.

A constitutive nucleolar protein identified as a member of the nucleoplasmin family

Using monoclonal antibodies we have localized a polypeptide, appearing on gel electrophoresis with a Mr of approximately 38,000 and a pI of approximately 5.6, to the granular component of the nucleoli of Xenopus laevis oocytes and a broad range of cells from various species. The protein (NO38) also occurs in certain distinct nucleoplasmic particles but is not detected in ribosomes and other cytoplasmic components. During mitosis NO38-containing material dissociates from the nucleolar organizer region and distributes over the chromosomal surfaces and the perichromosomal cytoplasm; in telophase it re-populates the forming nucleoli. With these antibodies we have isolated from a X. laevis ovary lambda gt11 expression library a cDNA clone encoding a polypeptide which, on one- and two-dimensional gel electrophoresis, co-migrates with authentic NO38. The amino acid sequence deduced from this clone defines a polypeptide of 299 amino acids of mol. wt 33,531 which is characterized by the presence of two domains exceptionally rich in aspartic and glutamic acid, one of them flanked by two putative karyophilic signal heptapeptides. Comparison with other protein sequences shows that NO38 is closely related to the histone-binding, karyophilic protein nucleoplasmin: the first 124 amino acids have 58 amino acid positions in common. Protein NO38 also shows striking homologies to the phosphopeptide region of rat nucleolar protein B23 and the carboxyterminal region of human B23. We propose that protein NO38, which forms distinct homo-oligomers of approximately 7S and Mr of approximately 230,000, is a member of a family of karyophilic proteins, the 'nucleoplasmin family'. It is characterized by its specific association with the nucleolus and might be involved in nuclear accumulation, nucleolar storage and pre-rRNA assembly of ribosomal proteins in a manner similar to that discussed for the role of nucleoplasmin in histone storage and chromatin assembly.

Histones and their modifications

Histones constitute the protein core around which DNA is coiled to form the basic structural unit of the chromosome known as the nucleosome. Because of the large amount of new histone needed during chromosome replication, the synthesis of histone and DNA is regulated in a complex manner. During RNA transcription and DNA replication, the basic nucleosomal structure as well as interactions between nucleosomes must be greatly altered to allow access to the appropriate enzymes and factors. The presence of extensive and varied post-translational modifications to the otherwise highly conserved histone primary sequences provides obvious opportunities for such structural alterations, but despite concentrated and sustained effort, causal connections between histone modifications and nucleosomal functions are not yet elucidated.

Modulation of linker histones during development in Tetrahymena: selective elimination of linker histone during the differentiation of new macronuclei

Macronuclei of Tetrahymena thermophila contain a typical H1 which has been shown to be missing from micronuclei. Instead, micronuclei contain three unique polypeptides, alpha, beta, and gamma, which are associated with linker regions of micronuclear chromatin. In this report polyclonal antibodies raised against macronuclear H1 are shown to react with alpha, beta, and gamma by immunoblotting analyses. This result suggests that these polypeptides share some common structural feature(s). Also consistent with this result is the finding that both macro- and micronuclei in growing and mating cells stain positively with H1 antibodies by in situ indirect immunofluorescence. However, these analyses demonstrate that the level of linker histone is greatly reduced in the micronucleus of starved cells and in young macronuclear anlagen. These results are in agreement with earlier biochemical studies and together provide strong evidence that dramatic changes in linker histone accompany nuclear differentiation (and dedifferentiation) in Tetrahymena.

Structure of the two distinct types of minichromosomes that are assembled on DNA injected in Xenopus oocytes

DNA injected into germinal vesicles of Xenopus oocytes is assembled into two distinct types of minichromosomes. One type is soluble and behaves like conventional nucleosomal chromatin. The other type is insoluble, is sensitive to DNAase I and to micrococcal nuclease, lacks a canonical nucleosome repeat, and generates a half-nucleosome size limit digest with micrococcal nuclease. We suggest that these peculiar minichromosomes may be the ones that display the unconstrained, "dynamic" DNA supercoils in the living oocyte.

Changes in chromatin structure accompany modulation of the rate of transcription of 5S ribosomal genes in Tetrahymena

The chromatin structure of a single cluster of six tandemly repeated 5S ribosomal RNA genes (5S genes) in Tetrahymena thermophila has been characterized. Indirect end labeling experiments indicate that the actively transcribed 5S genes in macronuclei are rapidly cut by DNAse I near the putative internal promotor and just 5' to the transcribed region. When cells are starved to reduce 5S gene transcription rates, the DNAse I sensitivity of the intragenic site is reduced relative to the 5' site. In the nontranscribed 5S genes in micronuclei, neither of these sites is hypersensitive to DNAse I. Thus structural alterations accompany both the activation of transcription during macronuclear development and physiological changes in the rate of transcription of the 5S genes. These DNAse I data together with studies using Staphylococcal nuclease suggest that rapidly transcribed 5S genes may not be associated with histones as nucleosomes. In contrast, the genes in starved cell macronuclei appear to be associated with one nucleosome per 280 base pair tandem repeat.

Proteolytic processing of h1-like histones in chromatin: a physiologically and developmentally regulated event in Tetrahymena micronuclei

Micronuclei isolated from growing cells of Tetrahymena thermophila contain three H1-like polypeptides alpha, beta, and gamma. Micronuclei isolated from young conjugating cells (3-7 h) also contain a larger molecular weight polypeptide, X, which is being actively synthesized and deposited into these nuclei (Allis, C. D., and J. C. Wiggins, 1984, Dev. Biol., 101:282-294). Pulse-chase experiments (with growing and conjugating cells) suggested that X is a precursor to alpha and that alpha is further processed to gamma and a previously undescribed and relatively minor species, delta. These precursor-product relationships were supported by cross-reactivity with polyclonal antibodies raised against alpha and peptide mapping. While beta consistently became labeled under chase conditions (both in growing and mating cells), it was not clear whether it is part of the vivo processing event(s) which interrelates X, alpha, gamma, and delta. Beta was not recognized by alpha antibodies. Despite this uncertainty, these results suggest that proteolytic processing serves to generate significant changes in the complement of H1-like histones present in this nucleus.

Regulation of nucleosomal core histone variant levels in differentiating murine erythroleukemia cells

During hexamethylenebis(acetamide)-induced terminal differentiation of murine erythroleukemia (MEL) cells in vitro, the histone variant proportions undergo changes similar to those observed in vivo in terminally differentiating cells of the young mouse. Thus, there is a rapid increase in the relative amounts of the variants H2A.1 and H2B.2 in parallel with the increase in the number of hemoglobin-producing cells and the sharp decrease in the growth rate. We show that the changes in variant proportions are not associated with slower growth per se but are most likely due to differential changes in the rates of variant synthesis as a result of commitment to terminal differentiation. In addition, we observed an inducer-specific increase in the rate of synthesis and the relative amount of the minor H2A variant 4, well before hemoglobin accumulation. We also present evidence that H2A and H2B histones are synthesized and incorporated into chromatin at a significant rate even when DNA synthesis is inhibited, suggesting turnover of these histones. H2A and H2B turnover can be detected directly even in exponentially growing cells. H2A.1 and H2B.2 have higher turnover rates than H2A.2 and H2B.1, respectively, in exponentially growing cells, a difference which is even more pronounced in induced cells. The magnitude of the differential turnover is not sufficient to account for the changes in the histone variant proportions in the short life of induced MEL cells but could explain the slow accumulation of H2A.2, H2B.1, and H3.3 in nondividing adult tissues of the mouse.

Anticentromere antibodies bind to trout testis histone 1 and a low molecular weight protein from rabbit thymus

Antibodies directed against centromeric chromatin characteristically occur in the sera of patients with the CREST variant of scleroderma. We have studied the in situ enzymatic sensitivity and solubility of the centromeric antigen and have isolated an antigenic moiety that reacts with anticentromere antibodies. The centromeric antigen in the human epithelial cell line, HEp-2, was sensitive to DNAase I and micrococcal nuclease but not affected by RNAase A, trypsin or amylase. It was insoluble in 0.15-4 M NaCl but was extracted from the HEp-2 cells by 4 M urea/2 M NaCl. Antigenic activity in a 4 M urea/2 M NaCl extract of rabbit thymus was demonstrated by immunoabsorption. Indirect immunofluorescence of the extract separated by polyacrylamide gel electrophoresis revealed a fluorescent band with a mol. wt of 33,000. Calf thymus and trout testis histone preparations were fractionated by gel electrophoresis and transferred by blotting techniques to diazobenzyloxymethyl cellulose paper for autoradiography. Anticentromere antibodies bound to and were absorbed by trout testis histone 1. We propose that the centromeric antigen may be a variant of histone 1 that is associated with condensed chromatin.

Timing of the appearance of macronuclear-specific histone variant hv1 and gene expression in developing new macronuclei of Tetrahymena thermophila

Vegetative cells of the ciliated protozoan Tetrahymena thermophila contain a transcriptionally active macronucleus and a transcriptionally inactive micronucleus. Earlier studies ( Allis , C. D., C. V. C. Glover , J. K. Bowen, and M. A. Gorovsky , 1980, Cell, 20:609-617; and Allis , C. D., Y. S. Ziegler , M. A. Gorovsky , and J. B. Olmsted, 1982, Cell, 31:131-136) demonstrated the existence of a macronuclear-specific histone variant, hv1 , which is enriched in small punctate regions in nucleoli of several mammalian cell lines. These observations suggest that this histone variant is highly conserved in evolution and may be associated with actively transcribed sequences. Despite large differences in structure and function during vegetative growth, macro- and micronuclei are related. During conjugation, the sexual phase of the life cycle in Tetrahymena, postzygotic division products of micronuclei give rise to new micro- and macronuclei, while the old macronucleus moves to the posterior of each cell and is eliminated. In this study using antiserum specific for hv1 , we determined by indirect immunofluorescence the time during conjugation at which hv1 first appears in the developing new macronuclei. In growing, starved, and young mating cells (2-5 h after mixing opposite mating types), only macronuclei are detected with affinity-purified antibodies against hv1 . Newly formed macronuclei are either not stained or only weakly stained in cells in which the old macronucleus is located in the center of the cell. However, new macronuclei are clearly observed in cells in which the old macronucleus has moved to the posterior of the cell (approximately 8 h). During later stages of conjugation (10-16 h), the intensity of hv1 staining in new macronuclei increases with time corresponding to the increasing DNA content of these nuclei. Disappearance of detectable hv1 from old macronuclei begins nearly 1 h after these nuclei reach the posterior cytoplasm (approximately 9-10 h) and is sometimes complete before these nuclei are eliminated from the cells. Autoradiography of cells labeled for brief periods with [3H]uridine shows that new macronuclei begin to synthesize RNA very soon after the second postzygotic division (approximately 8 h). During stages when hv1 is clearly detected in new macronuclei, anlagen are active in RNA synthesis. RNA synthesis in old macronuclei ceases very close to the time when RNA synthesis begins in new macronuclei. Thus, the addition of hv1 coincides closely with the transformation of a transcriptionally inactive germinal nucleus into that of a transcriptionally active somatic nucleus. We suspect that addition of hv1 plays a fundamental role in

Chromatin assembly in Xenopus oocytes: in vivo studies

We have followed the time course of chromatin assembly, DNA supercoiling, and transcription on a Xenopus 5S RNA gene clone injected into germinal vesicles of Xenopus oocytes. During the first 2 hr after DNA injection, there is a gradual enhancement in transcription that correlates with the increase in superhelical density of the DNA template; on the other hand, nucleosome assembly is already completed by 10-30 min after DNA injection. To probe further the DNA structure in the assembled minichromosomes, we injected enzymes and chemicals into the germinal vesicle. DNAase I and topoisomerase I injections reveal that the circular DNA has been assembled into two discrete and equally abundant types of chromatin: one type, which we call "dynamic" chromatin, is torsionally strained and is thus fully relaxed by those two enzymes. The other type, which we call "static" chromatin, still yields supercoiled DNA molecules after deproteinization. The dynamic chromatin is also relaxed by injection of novobiocin, and simultaneously, 5S RNA transcription is turned off. The results of our in vivo experiments suggest that the dynamic chromatin is the one that is transcriptionally active. We discuss the biological relevance of these findings.

Electron microscopic immunolocalization of a karyoskeletal protein of molecular weight 145 000 in nucleoli and perinucleolar bodies of Xenopus laevis

Amplified nucleoli of Xenopus laevis oocytes contain a major karyoskeletal protein of Mr 145 000 insoluble in low- and high-salt buffer as well as in non-denaturing detergents. Electron microscopic localization on native and high-salt extracted nucleoli using specific murine antibodies against this polypeptide and gold-coupled antibodies for visualization reveals that the Mr 145 000 protein is located in coils of filaments of ca 4 nm diameter. In addition, this protein occurs in the medusoid filament bodies (MFBs) present in the nucleolar cortex and free in the nucleoplasm. In somatic cells of tissues and in A6 kidney epithelial cells grown in vitro the Mr 145 000 polypeptide or an immunologically related protein is also organized in coiled aggregates of filaments 4-12 nm in diameter present both in the periphery of nucleoli and free in the nucleoplasm. We discuss a possible role of this protein as a karyoskeletal support involved in the storage and transport of preribosomal particles.

Histone rearrangements accompany nuclear differentiation and dedifferentiation in Tetrahymena

Histone synthesis and deposition into specific classes of nuclei has been investigated in starved and conjugating Tetrahymena. During starvation and early stages of conjugation (between 0 and 5 hr after opposite mating types are mixed), micronuclei selectively lose preexisting micronuclear-specific histones alpha, beta, gamma, and H3F. Of these histones, only alpha appears to accumulate in micronuclear chromatin through active synthesis and deposition during the mating process. Curiously, alpha is not observed (by stain or label) in young macronuclear anlagen (4C, 10 hr of conjugation). Thus, young macronuclear anlagen are missing all of the histones which are known to be specific to micronuclei of vegetative cells. By 14-16 hr of conjugation, we observe active synthesis and deposition of macronuclear-specific histones, hv1, hv2, and H1, into new macronuclear anlagen (8C). Thus macronuclear differentiation seems well underway by this time of conjugation. It is also in this time period (14-16 hr) that we first detect significant amounts of micronuclear-specific H1-like polypeptides beta and gamma in micronuclear extracts. These polypeptides do not seem to be synthesized during this period, which suggests that beta and gamma are derived from a precursor molecule(s). Since these micronuclear-specific histones do not appear in micronuclear chromatin until after other micronuclei have been selected to differentiate as macronuclei, we suspect that micronuclear differentiation is also an important process which occurs in 10-16 hr mating cells. Our results also suggest that proteolytic processing of micronuclear H3S into H3F (which occurs in a cell cycle dependent fashion during vegetative growth) is not operative during most if not all of conjugation. Thus micronuclei of mating cells contain only H3S which also seems consistent with the fact that some micronuclei differentiate into new macronuclei (micronuclear H3S is indistinguishable from macronuclear H3). Interestingly, the only H3 synthesized and deposited into the former macronucleus of mating cells is the relatively minor macronuclear-specific H3-like variant, hv2. These results demonstrate that significant histone rearrangements occur during conjugation in Tetrahymena in a manner consistent with the fact that during conjugation some micronuclei eventually differentiate into new macronuclei. Our results suggest that selective synthesis and deposition of specific histones (and histone variants) plays an important role in the nuclear differentiation process in Tetrahymena.