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 has a conserved function that is distinct from that of the major H2A sequence variants.

Saccharomyces cerevisiae contains three genes that encode members of the histone H2A gene family. The last of these to be discovered, HTZ1 (also known as HTA3), encodes a member of the highly conserved H2A.Z class of histones. Little is known about how its in vivo function compares with that of the better studied genes (HTA1 and HTA2) encoding the two major H2As. We show here that, while the HTZ1 gene encoding H2A.Z is not essential in budding yeast, its disruption results in slow growth and formamide sensitivity. Using plasmid shuffle experiments, we show that the major H2A genes cannot provide the function of HTZ1 and the HTZ1 gene cannot provide the essential function of the genes encoding the major H2As. We also demonstrate for the first time that H2A.Z genes are functionally conserved by showing that the gene encoding the H2A.Z variant of the ciliated protozoan TETRAHYMENA: thermophila is able to rescue the phenotypes associated with disruption of the yeast HTZ1 gene. Thus, the functions of H2A.Z are distinct from those of the major H2As and are highly conserved.

Phosphorylation of linker histone H1 regulates gene expression in vivo by creating a charge patch.

In Tetrahymena, histone H1 phosphorylation can regulate transcription and mimics loss of H1 from chromatin. We investigated the mechanism by which H1 phosphorylation affects transcription. Tetrahymena strains were created containing mutations in H1 that mimicked the charge of the phosphorylated region without mimicking the structure or increased hydrophilicity of the phosphorylated residues. Whenever the charge resembled that of the phosphorylated state, the induced expression of the CyP1 gene was greatly inhibited. Whenever the charge was similar to that of the dephosphorylated state, the CyP1 gene was induced normally. These results argue strongly that phosphorylation of H1 acts by changing the overall charge of a small domain, not by phosphate recognition or by creating a site-specific charge.

Polyglycylation of tubulin is essential and affects cell motility and division in Tetrahymena thermophila.

We analyzed the role of tubulin polyglycylation in Tetrahymena thermophila using in vivo mutagenesis and immunochemical analysis with modification-specific antibodies. Three and five polyglycylation sites were identified at glutamic acids near the COOH termini of alpha- and beta-tubulin, respectively. Mutants lacking all polyglycylation sites on alpha-tubulin have normal phenotype, whereas similar sites on beta-tubulin are essential. A viable mutant with three mutated sites in beta-tubulin showed reduced tubulin glycylation, slow growth and motility, and defects in cytokinesis. Cells in which all five polyglycylation sites on beta-tubulin were mutated were viable if they were cotransformed with an alpha-tubulin gene whose COOH terminus was replaced by the wild-type COOH terminus of beta-tubulin. In this double mutant, beta-tubulin lacked detectable polyglycylation, while the alpha-beta tubulin chimera was hyperglycylated compared with alpha-tubulin in wild-type cells. Thus, the essential function of polyglycylation of the COOH terminus of beta-tubulin can be transferred to alpha-tubulin, indicating it is the total amount of polyglycylation on both alpha- and beta-tubulin that is essential for survival.

A novel chromodomain protein, pdd3p, associates with internal eliminated sequences during macronuclear development in Tetrahymena thermophila.

Conversion of the germ line micronuclear genome into the genome of a somatic macronucleus in Tetrahymena thermophila requires several DNA rearrangement processes. These include (i) excision and subsequent elimination of several thousand internal eliminated sequences (IESs) scattered throughout the micronuclear genome and (ii) breakage of the micronuclear chromosomes into hundreds of DNA fragments, followed by de novo telomere addition to their ends. Chromosome breakage sequences (Cbs) that determine the sites of breakage and short regions of DNA adjacent to them are also eliminated. Both processes occur concomitantly in the developing macronucleus. Two stage-specific protein factors involved in germ line DNA elimination have been described previously. Pdd1p and Pdd2p (for programmed DNA degradation) physically associate with internal eliminated sequences in transient electron-dense structures in the developing macronucleus. Here, we report the purification, sequence analysis, and characterization of Pdd3p, a novel developmentally regulated, chromodomain-containing polypeptide. Pdd3p colocalizes with Pdd1p in the peripheral regions of DNA elimination structures, but is also found more internally. DNA cross-linked and immunoprecipitated with Pdd1p- or Pdd3p-specific antibodies is enriched in IESs, but not Cbs, suggesting that different protein factors are involved in elimination of these two groups of sequences.

Excision of micronuclear-specific DNA requires parental expression of pdd2p and occurs independently from DNA replication in Tetrahymena thermophila.

Elimination of germ-line DNA segments is an essential step in the somatic development of many organisms and in the terminal differentiation of several specialized cell types. In binuclear ciliates, including Tetrahymena thermophila, DNA elimination occurs during the conversion of the germ-line micronuclear genome into the somatic genome of the new macronucleus. Little is known about molecular determinants and regulatory mechanisms involved in this process. Pdd2p is one of a small set of Tetrahymena polypeptides whose time of synthesis, nuclear localization, and physical association with sequences destined for elimination suggest an involvement in the DNA elimination process. In this study, we report that loss of parental expression of Pdd2p leads to the perturbation of several DNA rearrangement processes in developing zygotic macronuclei, including excision of internal eliminated sequences, excision of chromosome breakage sequences, and endoreplication of the new macronuclear genome and eventually results in lethality of the progeny. We demonstrate that excision and elimination of micronuclear-specific DNA occurs independently of endoreplication of the new macronuclear genome that takes place during the same period of time. Thus, our data indicate that parental expression of Pdd2p is required for successful DNA elimination and development of somatic nuclei.

Phosphorylation of linker histone H1 regulates gene expression in vivo by mimicking H1 removal.

Two Tetrahymena strains were created by gene replacement. One contained H1 with all phosphorylation sites mutated to alanine, preventing phosphorylation. The other had these sites changed to glutamic acid, mimicking the fully phosphorylated state. Global gene expression was not detectably changed in either strain. Instead, H1 phosphorylation activated or repressed specific genes in a manner that was remarkably similar to the effects of knocking out the gene encoding H1. These studies demonstrate a role for H1 phosphorylation in the regulation of transcription in vivo and suggest that it acts by mimicking the partial removal of H1.

Identification and mutation of phosphorylation sites in a linker histone. Phosphorylation of macronuclear H1 is not essential for viability in tetrahymena.

Linker histone phosphorylation has been suggested to play roles in both chromosome condensation and transcriptional regulation. In the ciliated protozoan Tetrahymena, in contrast to many eukaryotes, histone H1 of macronuclei is highly phosphorylated during interphase. Macronuclei divide amitotically without overt chromosome condensation in this organism, suggesting that requirements for phosphorylation of macronuclear H1 may be limited to transcriptional regulation. Here we report the major sites of phosphorylation of macronuclear H1 in Tetrahymena thermophila. Five phosphorylation sites, present in a single cluster, were identified by sequencing 32P-labeled peptides isolated from tryptic peptide maps. Phosphothreonine was detected within two TPVK motifs and one TPTK motif that resemble established p34(cdc2) kinase consensus sequences. Phosphoserine was detected at two non-proline-directed sites that do not resemble known kinase consensus sequences. Phosphorylation at the two noncanonical sites appears to be hierarchical because it was observed only when a nearby p34(cdc2) site was also phosphorylated. Cells expressing macronuclear H1 containing alanine substitutions at all five of these phosphorylation sites were viable even though macronuclear H1 phosphorylation was abolished. These data suggest that the five sites identified comprise the entire collection of sites utilized by Tetrahymena and demonstrate that phosphorylation of macronuclear H1, like the protein itself, is not essential for viability in Tetrahymena.

Phosphorylation of histone H3 is required for proper chromosome condensation and segregation.

Phosphorylation of histone H3 at serine 10 occurs during mitosis in diverse eukaryotes and correlates closely with mitotic and meiotic chromosome condensation. To better understand the function of H3 phosphorylation in vivo, we created strains of Tetrahymena in which a mutant H3 gene (S10A) was the only gene encoding the major H3 protein. Although both micronuclei and macronuclei contain H3 in typical nucleosomal structures, defects in nuclear divisions were restricted to mitotically dividing micronuclei; macronuclei, which are amitotic, showed no defects. Strains lacking phosphorylated H3 showed abnormal chromosome segregation, resulting in extensive chromosome loss during mitosis. During meiosis, micronuclei underwent abnormal chromosome condensation and failed to faithfully transmit chromosomes. These results demonstrate that H3 serine 10 phosphorylation is causally linked to chromosome condensation and segregation in vivo and is required for proper chromosome dynamics.

Phosphorylation of histone H3 at serine 10 is correlated with chromosome condensation during mitosis and meiosis in Tetrahymena.

H3 phosphorylation has been correlated with mitosis temporally in mammalian cells and spatially in ciliated protozoa. In logarithmically growing Tetrahymena thermophila cells, for example, H3 phosphorylation can be detected in germline micronuclei that divide mitotically but not in somatic macronuclei that divide amitotically. Here, we demonstrate that micronuclear H3 phosphorylation occurs at a single site (Ser-10) in the amino-terminal domain of histone H3, the same site phosphorylated during mitosis in mammalian cells. Using an antibody specific for Ser-10 phosphorylated H3, we show that, in Tetrahymena, this modification is correlated with mitotic and meiotic divisions of micronuclei in a fashion that closely coincides with chromosome condensation. Our data suggest that H3 phosphorylation at Ser-10 is a highly conserved event among eukaryotes and is likely involved in both mitotic and meiotic chromosome condensation.

A developmentally eliminated sequence in the flanking region of the histone H1 gene in Tetrahymena thermophila contains short repeats.

In Tetrahymena, as in other ciliated protozoans, a transcriptionally active, 'somatic' macronucleus develops from a transcriptionally inactive 'germline' micronucleus after conjugation. The process of development involves elimination of germline DNA segments at thousands of locations in the genome. The characterization of one of these segments in Tetrahymena thermophila is described here. This micronucleus-specific DNA has been identified by comparing the sequence of the corresponding micronuclear and macronuclear regions. The micronucleus-specific DNA is over 1 kb long, is AT-rich and has TTT direct repeats at its termini. At one end of the micronuclear sequence there is a 130 bp duplication, and at the other end there are several related repeats of a 13-mer. Short G-rich sections are found in the middle of the eliminated DNA, as well as on one side of the rearrangement junction. Short G-rich segments are also detectable in three previously described micronucleus-specific sequences. The micronuclear sequence described here is a member of a repeat family. Cross-hybridizing sequences are also detectable in some other Tetrahymena species. The distribution of cross-hybridizing sequences among related species is not consistent with the phylogenetic tree.

Constitutive expression, not a particular primary sequence, is the important feature of the H3 replacement variant hv2 in Tetrahymena thermophila.

Although quantitatively minor replication-independent (replacement) histone variants have been found in a wide variety of organisms, their functions remain unknown. Like the H3.3 replacement variants of vertebrates, hv2, an H3 variant in the ciliated protozoan Tetrahymena thermophila, is synthesized and deposited in nuclei of nongrowing cells. Although hv2 is clearly an H3.3-like replacement variant by its expression, sequence analysis indicates that it evolved independently of the H3.3 variants of multicellular eukaryotes. This suggested that it is the constitutive synthesis, not the particular protein sequence, of these variants that is important in the function of H3 replacement variants. Here, we demonstrate that the gene (HHT3) encoding hv2 or either gene (HHT1 or HHT2) encoding the abundant major H3 can be completely knocked out in Tetrahymena. Surprisingly, when cells lacking hv2 are starved, a major histone H3 mRNA transcribed by the HHT2 gene, which is synthesized little, if at all, in wild-type nongrowing cells, is easily detectable. Both HHT2 and HHT3 knockout strains show no obvious defect during vegetative growth. In addition, a mutant with the double knockout of HHT1 and HHT3 is viable while the HHT2 HHT3 double-knockout mutant is not. These results argue strongly that cells require a constitutively expressed H3 gene but that the particular sequence being expressed is not critical.

Germline and somatic transformation of mating Tetrahymena thermophila by particle bombardment.

Mating Tetrahymena thermophila were bombarded with ribosomal DNA-coated particles at various times in development. Both macronuclear and micronuclear transformants were recovered. Optimal developmental stages for transformation occurred during meiosis for the micronucleus and during anlagen formation for the macronucleus. Evidence is given for transient retention of the introduced plasmid. Genetic and molecular tests confirmed that sexually heritable transformation was associated with integration at the homologous site in the recipient micronuclear chromosome.

Germ-line knockout heterokaryons of an essential alpha-tubulin gene enable high-frequency gene replacement and a test of gene transfer from somatic to germ-line nuclei in Tetrahymena thermophila.

The haploid Tetrahymena thermophila genome contains a single alpha-tubulin (ATU) gene. Using biolistic transformation, we disrupted one of the two copies of the ATU gene in the diploid germ-line micronucleus. The heterozygous germ-line transformants were made homozygous in the micronucleus by mating to a star strain containing a defective micronucleus. This mating, known as round 1 genomic exclusion, resulted in two heterokaryon clones of different mating types which have both copies of the ATU gene knocked out in the micronucleus but only wild-type genes in the polycopy somatic macronucleus. When these heterokaryons were mated, the exconjugant progeny cells did not grow because the new somatic macronuclei do not have any alpha-tubulin genes. However, when these conjugants were transformed with a functional marked ATU gene, viable transformants were obtained that contained the transforming ATU gene at the homologous locus in the new macronucleus. The exconjugant progeny could be rescued at a high efficiency (900 transformants per microg of DNA) with a wild-type ATU gene. Unlike previous macronuclear transformation protocols, this strategy should allow introduction of highly disadvantageous (but viable) mutations into Tetrahymena, providing a powerful tool for molecular and functional studies of essential genes. These knockout heterokaryons were used to demonstrate that gene transfer from somatic macronuclei to germ-line micronuclei occurs rarely if at all.

An abundant nucleolar phosphoprotein is associated with ribosomal DNA in Tetrahymena macronuclei.

An abundant 52-kDa phosphoprotein was identified and characterized from macronuclei of the ciliated protozoan Tetrahymena thermophila. Immunoblot analyses combined with light and electron microscopic immunocytochemistry demonstrate that this polypeptide, termed Nopp52, is enriched in the nucleoli of transcriptionally active macronuclei and missing altogether from transcriptionally inert micronuclei. The cDNA sequence encoding Nopp52 predicts a polypeptide whose amino-terminal half consists of multiple acidic/serine-rich regions alternating with basic/proline-rich regions. Multiple serines located in these acidic stretches lie within casein kinase II consensus motifs, and Nopp52 is an excellent substrate for casein kinase II in vitro. The carboxyl-terminal half of Nopp52 contains two RNA recognition motifs and an extreme carboxyl-terminal domain rich in glycine, arginine, and phenylalanine, motifs common in many RNA processing proteins. A similar combination and order of motifs is found in vertebrate nucleolin and yeast NSR1, suggesting that Nopp52 is a member of a family of related nucleolar proteins. NSR1 and nucleolin have been implicated in transcriptional regulation of rDNA and rRNA processing. Consistent with a role in ribosomal gene metabolism, rDNA and Nopp52 colocalize in situ, as well as by cross-linking and immunoprecipitation experiments, demonstrating an association between Nopp52 and rDNA in vivo.

Cloning and characterization of the major histone H2A genes completes the cloning and sequencing of known histone genes of Tetrahymena thermophila.

A truncated cDNA clone encoding Tetrahymena thermophila histone H2A2 was isolated using synthetic degenerate oligonucleotide probes derived from H2A protein sequences of Tetrahymena pyriformis. The cDNA clone was used as a homologous probe to isolate a truncated genomic clone encoding H2A1. The remaining regions of the genes for H2A1 (HTA1) and H2A2 (HTA2) were then isolated using inverse PCR on circularized genomic DNA fragments. These partial clones were assembled into intact HTA1 and HTA2 clones. Nucleotide sequences of the two genes were highly homologous within the coding region but not in the noncoding regions. Comparison of the deduced amino acid sequences with protein sequences of T. pyriformis H2As showed only two and three differences respectively, in a total of 137 amino acids for H2A1, and 132 amino acids for H2A2, indicating the two genes arose before the divergence of these two species. The HTA2 gene contains a TAA triplet within the coding region, encoding a glutamine residue. In contrast with the T. thermophila HHO and HTA3 genes, no introns were identified within the two genes. The 5'- and 3'-ends of the histone H2A mRNAs; were determined by RNase protection and by PCR mapping using RACE and RLM-RACE methods. Both genes encode polyadenylated mRNAs and are highly expressed in vegetatively growing cells but only weakly expressed in starved cultures. With the inclusion of these two genes, T. thermophila is the first organism whose entire complement of known core and linker histones, including replication-dependent and basal variants, has been cloned and sequenced.

Linker histone H1 regulates specific gene expression but not global transcription in vivo.

In a linker histone H1 knockout strain (delta H1) of Tetrahymena thermophila, the number of mature RNAs produced by genes transcribed by pol I and pol III and of most genes transcribed by pol II remains unchanged. However, H1 is required for the normal basal repression of a gene (ngoA) in growing cells but is not required for its activated expression in starved cells. Surprisingly, H1 is required for the activated expression of another gene (CyP) in starved cells but not for its repression in growing cells. Thus, H1 does not have a major effect on global transcription but can act as either a positive or negative gene-specific regulator of transcription in vivo.