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.     

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.     

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.     

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.     

Changes in the histone H2A variant H2A.Z and polyubiquitinated histone species in developing trout testis

The trout histone H2A variant H2A.Z has been identified by its electrophoretic mobility on two-dimensional polyacrylamide gels and its N-terminal amino acid sequence. Similar to bovine H2A.Z and chicken H2A.F (also called H2A.Z and M1), the trout H2A.Z had a two-residue extension when aligned with trout H2A and a 67% sequence homology with the N-terminal portion of trout H2A. The first 29 amino acids of trout H2A.Z were identical with those of chicken H2A.F and differed from those of bovine H2A.Z at only one position. Thus, the N-terminal part of histone H2A.Z appears to be highly conserved. The levels of histone H2A.Z and ubiquitinated species of the histones H2A, H2A.Z, and H2B, which were detected with an anti-ubiquitin antibody, were studied at various stages of trout testis development. At the final stages of spermatogenesis in trout, histones are replaced by protamines. Ubiquitinated and diubiquitinated histone H2A remained at similar levels in early and late stage testis nucleohistone. In the late stage testis chromatin (nucleohistone), ubiquitinated histone H2A.Z was not detected, the level of ubiquitinated histone H2B was reduced, and the amount of diubiquitinated histone H2B increased. There was also a marked reduction in the level of histone H2A.Z. This observation suggests nucleosomes with this histone variant were selectively disassembled during the transition from nucleohistone to nucleoprotamine, indicating that protamine deposition is not a random process in rainbow trout.     

Independent evolutionary origin of histone H3.3-like variants of animals and Tetrahymena.

All three genes encoding histone H3 proteins were cloned and sequenced from Tetrahymena thermophila. Two of these genes encode a major H3 protein identical to that of T. pyriformis and 87% identical to the major H3 of vertebrates. The third gene encodes hv2, a quantitatively minor replication independent (replacement) variant. The sequence of hv2 is only 85% identical to the animal replacement variant H3.3 and is the most divergent H3 replacement variant described. Phylogenetic analysis of 73 H3 protein sequences suggests that hv2, H3.3, and the plant replacement variant H3.III evolved independently, and that H3.3 is not the ancestral H3 gene, as was previously suggested (Wells, D., Bains, W., and Kedes, L. 1986, J. Mol. Evol., 23: 224-241). These results suggest it is the replication independence and not the particular protein sequence that is important in the function of H3 replacement variants.     

H2A.X. a histone isoprotein with a conserved C-terminal sequence, is encoded by a novel mRNA with both DNA replication type and polyA 3'' processing signals.

A full length cDNA clone that directs the in vitro synthesis of human histone H2A isoprotein H2A.X has been isolated and sequenced. H2A.X contains 142 amino acid residues, 13 more than human H2A.1. The sequence of the first 120 residues of H2A.X is almost identical to that of human H2A.1. The sequence of the carboxy-terminal 22 residues of H2A.X is unrelated to any known sequence in vertebrate histone H2A; however, it contains a sequence homologous with those of several lower eukaryotes. This homology centers on the carboxy-terminal tetrapeptide which in H2A.X is SerGlnGluTyr. Homologous sequences are found in H2As of three types of yeasts, in Tetrahymena and Drosophila. Seven of the nine carboxy-terminal amino acids of H2A.X are identical with those of S. cerevisiae H2A.1. It is suggested that this H2A carboxy-terminal motif may be present in all eukaryotes. The H2A.X cDNA is 1585 bases long followed by a polyA tail. There are 73 nucleotides in the 5' UTR, 432 in the coding region, and 1080 in the 3' UTR. Even though H2A.X is considered a basal histone, being synthesized in G1 as well as in S-phase, and its mRNA contains polyA addition motifs and a polyA tail, its mRNA also contains the conserved stem-loop and U7 binding sequences involved in the processing and stability of replication type histone mRNAs. Two forms of H2A.X mRNA, consistent with the two sets of processing signals were found in proliferating cell cultures. One, about 1600 bases long, contains polyA; the other, about 575 bases long, lacks polyA. The short form behaves as a replication type histone mRNA, decreasing in amount when cell cultures are incubated with inhibitors of DNA synthesis, while the longer behaves as a basal type histone mRNA.     

Characterization of a cDNA clone coding for a sea urchin histone H2A variant related to the H2A.F/Z histone protein in vertebrates.

A cDNA clone coding for a sea urchin histone H2A variant has been isolated. The coding region of the clone has been sequenced and the sequence found to be closely related to the H2A.F sequence in chickens. The nucleotide sequence of the sea urchin H2A.F/Z is 74% conserved when compared to chicken H2A.F and 51% conserved compared to sea urchin H2A early and 60% compared to sea urchin H2A late. The nucleotide-derived amino acid comparisons show that H2A.F/Z is 97% homologous with H2A.F in chickens and 57% and 56% homologous when compared to sea urchin H2A early and late respectively. There are between 3-6 copies of the H2A.F/Z sequence in the S. purpuratus genome. The H2A.F/Z gene sequence codes for the previously identified H2A.Z protein. All embryonic stages and adult tissues tested contain mRNA for H2A.F/Z. The mRNA appears in the poly A+ RNA fraction after chromatography over oligo dT cellulose.     

Tetrahymena histone H1. Isolation and amino acid sequence lacking the central hydrophobic domain conserved in other H1 histones

The complete amino acid sequence of a single H1 histone of the protozoan Tetrahymena pyriformis was determined, following previous determinations of the sequences of histones H2B, H2A, H3, and H4. Only a single H1 species was obtained by fractionation of a 0.5 M HClO4-soluble fraction from the whole histone extract and further purification. This starting material for sequencing contained 1.1 mol/mol phosphate and showed a single electrophoretic band after dephosphorylation. The sequence determination was performed by Edman degradation of BrCN fragments, staphylococcal protease peptides, and tryptic peptides, as well as secondary peptides from one BrCN fragment and one staphylococcal protease peptide. Phosphorus analysis of the tryptic peptides, containing serine or threonine, showed that five sites of the sequence were phosphorylated to various extents (5-30%). Thus, the total sequence, consisting of 165 amino acid residues and having a molecular weight of 17,942 in the unmodified form, was completely determined. This unusually small H1 sequence differs substantially from the human spleen H1 sequence of 218 residues, having larger proportions of hydrophilic residues and smaller proportions of hydrophobic residues. Comparison of the distribution pattern of hydrophilic and hydrophobic residues, between the protozoan and human sequences, showed that the protozoan sequence lacks the central hydrophobic domain that is conserved in the known vertebrate and other H1 histones. The implications for the function of H1 are discussed from the evolutionary viewpoint.     

Glycosylation, ADP-ribosylation, and methylation of Tetrahymena histones

We have examined some of the postsynthetic modifications that occur in macronuclear histones from Tetrahymena thermophila. When purified macronuclei are incubated with [32P]NAD+, histones H1, H2A, H2B, and H3 are ADP-ribosylated. Furthermore, histones H1, H2A, H2B, and H3 contain fucose and mannose residues as evidenced by the incorporation of [3H]fucose and by the specific binding to these proteins of gorse seed lectin and concanavalin A. Finally, our studies on incorporation of methyl groups into histones show that histone H2A, together with the related nonhistone protein A24, is methylated in Tetrahymena.     

The amino acid sequence of boar H1t, a testis-specific H1 histone variant

H1t is a testis-specific H1 variant found in spermatocytes and spermatids of mammals. The complete amino acid sequence has been determined for H1t isolated from boar testes. The protein is composed of 211 amino acids with the composition 3 aspartic acids, 6 asparagines, 13 threonines, 21 serines, 7 glutamic acids, 7 glutamines, 15 prolines, 14 glycines, 37 alanines, 11 valines, 1 methionine, 3 isoleucines, 14 leucines, 1 tyrosine, 1 phenylalanine, 42 lysines, 15 arginines and a calculated molecular weight of 22,059 disregarding the post-translational acetylation of the amino-terminal alanine. The protein shows typical H1 domains with basic amino- and carboxyl-terminal regions separated by a conserved, presumably globular, core sequence. The core region is very homologous to the highly conserved core sequence found in somatic mammalian H1 histones but does differ from this sequence in 15 places. Accordingly, it may be appropriate to consider H1t as new variant category. The carboxyl-terminal half of H1t is distinguished from the standard somatic family by being somewhat shorter and by the presence of 10 arginine residues. In contrast to many H1 proteins, the carboxyl-terminal region of H1t does not show an obvious pattern of peptide repeats.