The sequence and organization of the core histone H3 and H4 genes in the early branching amitochondriate protistTrichomonas vaginalis

Among the unicellular protists, several of which are parasitic, some of the most divergent eukaryotic species are found. The evolutionary distances between protists are so large that even slowly evolving proteins like histones are strongly divergent. In this study we isolated cDNA and genomic histone H3 and H4 clones fromTrichomonas vaginalis. Two histone H3 and three histone H4 genes were detected on three genomic clones with one complete H3 and two complete H4 sequences. H3 and H4 genes were divergently transcribed with very short intergenic regions of only 194 bp, which containedT. vaginalis-specific as well as histone-specific putative promoter elements. Southern blot analysis showed that there may be several more histone gene pairs. The two complete histone H4 genes were different on the nucleotide level but encoded the same amino acid sequence. Comparison of the amino acid sequences of theT. vaginalis H3 and H4 histones with sequences from animals, fungi, and plants as well as other protists revealed a significant divergence not only from the sequences in multicellular organisms but especially from the sequences in other protists likeEntamoeba histolytica, Trypanosoma cruzi, andLeishmania infantum.     

Common features of analogous replacement histone H3 genes in animals and plants

Phylogenetic analysis of histone H3 protein sequences demonstrates the independent origin of the replacement histone H3 genes in animals and in plants. Multiple introns in the replacement histone H3 genes of animals in a pattern distinct from that in plant replacement H3 genes supports this conclusion. It is suggested that replacement H3 genes arose at the same time that, independently, multicellular forms of animals and of plants evolved. Judged by the degree of invariant and functionally constrained amino acid positions, histones H3 and H4, which form together the tetramer kernel of the nucleosome, have co-evolved with equal rates of sequence divergence. Residues 31 and 87 in histone H3 are the only residues that consistently changed across each gene duplication event that created functional replacement histone H3 variant forms. Once changed, these residues have remained invariant across divergent speciation. This suggests that they are required to allow replacement histone H3 to participate in the assembly of nucleosomes in non–S-phase cells. The abundant occurrence of polypyrimidine sequences in the introns of all replacement H3 genes, and the replacement of an intron by a polypyrimidine motif upstream of the alfalfa replacement H3 gene, suggests a function. It is speculated that they may contribute to the characteristic cell-cycle-independent pattern of replacement histone H3 genes by binding nucleosome-excluding proteins.     

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.     

Sequence, organization and expression of the core histone genes of Aspergillus nidulans

Summary The core histone gene family ofAspergillus nidulans was characterized. The H2A, H2B and H3 genes are unique in theA. nidulans genome. In contrast there are two H4 genes, H4.1 and H4.2. As previously reported for the H2A gene (May and Morris 1987) introns also interrupt the other core histone genes. The H2B gene, like the H2A gene, is interrupted by three introns, the H3 and H4.1 gene are each interrupted by two introns and the H4.2 gene contains one intron. The position of the single intron in H4.2 is the same as that the first intron of the H4.1 gene. The H2A and H2B genes are arranged as a gene pair separated by approximately 600 by and are divergently transcribed. The H3 and H4.1 genes are similarly arranged and are separated by approximately 800 bp. The H4.2 gene is not closely linked to either the H2A-H2B or H3-H4.1 gene pairs. Using pulse field gel electrophoresis an electrophoretic karyotype was established forA. nidulans. This karyotype was used to assign the H3–H4.1 gene pair and the H4.2 gene to linkage group VIII and the H2A–H2B gene pair to either linkage group III or VI. The abundance of each of the histone messenger RNAs was determined to be cell cycle regulated but the abundance of the H4.2 mRNA appears to be regulated differently from the others.     

Evolution of late H2A, H2B, and H4 histone genes of the sea urchin, Strongylocentrotus purpuratus.

Sea urchins possess several distinct sets of histone genes, including "early" genes, maximally active in cleavage and blastula stages, and "late" genes, active from the late blastula stage onwards. We determined the nucleotide sequences of six sea urchin (Strongylocentrotus purpuratus) late histone genes located on four genomic segments. Comparative analysis of these sequences identified several conserved elements in 5' flanking regions, including the sequences ATGPyATANTATA shared by all late genes and GGCGGGAAATTGAAAA shared by two late H4s. Comparisons of protein-coding sequences of late H4 and H2B genes with their early counterparts showed that silent sites have diverged to the theoretical maximum, indicating that early and late histone gene classes diverged at least 200 million years ago. Since extant echinoderms evolved from a common ancestor at about that time, it is likely that early and late histone gene sets are characteristic of all echinoderm groups. Amino acid sequences derived from nucleotide sequences of late H2A and H2B gistone genes differ substantially from amino acid sequences of their late counterparts. Most such differences are in highly mutable positions. A few, however, occur in positions that do not mutate frequently and thus may reflect functional differences between the early and late forms of the H2A and H2B proteins.     

Characterization of two types of histone H2B genes from macronuclei of Tetrahymena thermophila.

Two histone H2B gene clones were isolated from macronuclei of Tetrahymena thermophila. Nucleotide sequences of the two clones were highly homologous within the coding region but not in the noncoding region. Comparison of the deduced amino acid sequences between the two clones showed three differences in a total of 121 amino acids. Each of the two clones contained a TAA triplet within the coding region, which appeared to code for a glutamine residue. To demonstrate the existence of histone mRNA containing UAA triplet, nuclease P1 protection mapping using total cellular RNA and nucleotide sequencing of primer extension products were carried out. The results clearly indicated that two cloned histone H2B genes were transcribed, giving rise to the major histone H2B mRNAs with a UAA triplet sequence in frame. The tentative 5'- and 3'-ends of histone H2B mRNAs were determined.     

Nucleotide sequence of the histone gene cluster in the coral acropora formosa (cnidaria; scleractinia): Features of histone gene structure and organization are common to diploblastic and triploblastic metazoans

We report the nucleotide sequence of the core histone gene cluster from the Cnidarian Acropora formosa. This is the first histone gene cluster to be sequenced from a diploblastic organism and the predicted amino acid sequences most resemble those of sea urchin equivalents. Each of the Cnidarian histone genes has two conserved regions 3 of the coding sequences and these closely resemble those of the metazoan a-class histone genes. In A. formosa the core histone genes are arranged as opposed (H3/H4 and H2A/H2B) pairs, a pattern common to the nondeuterostome metazoa, and tandem repetition is the predominant pattern of organization in the Cnidarian. With the recent identification of several classes of homeobox genes in Cnidarians these features clearly align the Cnidaria with triploblastic metazoans, supporting a monophyletic origin of the metazoa.     

A phylogenetic analysis based on the gene encoding phosphoglycerate kinase

Summary We have determined the nucleotide sequence of both genomic and complementary DNA (cDNA) for the gene encoding the glycolytic enzyme phosphoglycerate kinase from the ciliated protozoan Tetrahymena thermophila. The amino acid sequence for the enzyme has also been derived from the cDNA sequence. The gene contains an open reading frame of 1260 nucleotides encoding 420 amino acids. Coding sequence in genomic DNA is interrupted by two introns at positions corresponding to introns 3 and 4 in mammalian phosphoglycerate kinase genes. The derived amino acid sequence was used to prepare a phylogeny by aligning the Tetrahymena sequence with 25 other phosphoglycerate kinase amino acid sequences. The Tetrahymena sequence is a typical eukaryotic sequence. There is recognizable and clear homology across species that cover nearly the complete range of life forms. The phylogenetic reconstruction of these sequences generally supports the conclusions that have been reached using rRNA sequences.Offprint requests to: R.E. Pearlman     

Intron splice sites of Papilio glaucus PglRh3 corroborate insect opsin phylogeny

Full-length cDNA clones encoding the PglRh3 opsin from the tiger swallowtail butterfly Papilio glaucus were isolated from cDNA synthesized from adult head tissue total RNA. This cDNA consists of 1679 nucleotides and contains a single open reading frame predicted to be 379 amino acids in length. PCR amplification of genomic DNA with primers spanning the coding region yielded a single 2760bp fragment which was sequenced. The PglRh3 gene has nine exons and eight introns, four of which are in unique locations relative to the positions of introns in other known insect opsin sequences. Phylogenetic analyses of amino acid and nucleotide sequence data places PglRh3 within a clade of insect visual pigments thought to be sensitive to long wavelengths of light. The genomic structure of PglRh3 is the first characterized from a member of this opsin clade. Three PglRh3 intron positions are shared with Drosophila Rh1, and one of these is also shared with Drosophila Rh2. By contrast, none of the known intron locations in a clade of anciently diverged ultraviolet- and blue-sensitive visual pigments are shared by P. glaucus PglRh3, Drosophila Rh1 or Rh2. The placement of introns within opsin genes therefore independently supports the clustering of a putatively long-wavelength-sensitive clade with a clade of blue-green-sensitive visual pigments.     

Organization of the histone H3 genes in soybean, barley and wheat

Several variants of the replacement histone H3 genes from soybean, barley and wheat have been cloned and sequenced. Analysis of segregating populations in barley and soybean, as well as analysis of clones isolated from a soybean genomic library, suggested that these genes are dispersed throughout the genome. Several genes contain introns located in similar positions, but of different lengths and sequence. Comparison of mRNA levels in different tissues revealed that the intron-containing and intronless genes have different expression patterns. The distribution of the introns in the histone H3 genes across several plant species suggests that some of the introns might have been lost during the evolution of the gene family. Sequence divergence among introns and gene-flanking sequences in cloned gene variants allowed us to use them as specific probes for localizing individual gene copies and analyzing the genomic distribution of these variants across a range of genotypes.Journal paper No. J-16127 of the Iowa Agriculture and Home Economics Experiment Station, Ames, IowaMention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the United States Department of Agriculture and does not imply its approval to the exclusion of other products that may be suitable     

The vertebrate linker histones H10, H5, and H1M are descendants of invertebrate “orphon” histone H1 genes

We investigated the evolutionary history of the divergent vertebrate linker histones H1⁰, H5, and HIM. We observed that the sequence of the central conserved domain of these vertebrate proteins shares characteristic features with histone H1 proteins of plants and invertebrate animals which otherwise never appear in any vertebrate histone H1 protein. A quantitative analysis of 58 linker histone sequences also reveals that these proteins are more similar to invertebrate and plant histone H1 than to histone H1 of vertebrates. A phylogenetic tree deduced from an alignment of the central domain of all known linker histones places H1⁰, H5, and HIM in close vicinity to invertebrate sperm histone H1 proteins and to invertebrate histone H1 proteins encoded by polyadenylated mRNAs. We therefore conclude that the ancestors of the vertebrate linker histones H1⁰, H5, and HIM diverged from the main group of histone H1 proteins before the vertebrate type of histone H1 was established in evolution. We discuss this observation in the general context of linker histone evolution. Correspondence to: B. and E. Schulze     

Drosophila virilis histone gene clusters lacking H1 coding segments

Summary Approximately 30–40% ofDrosophila virilis DNA complementary to clonedDrosophila histone genes is reduced to 3.4-kilobase-pair (kbp) segments by Bgl I or Bgl II digestion. The core histone genes of a 3.4-kbp Bgl II segment cloned in the plasmid pDv3/3.4 have the same order as theD. melanogaster core histone genes in the plasmid cDm500: . Nonetheless, pDv3/3.4 and cDm500 have different histone gene configurations: In pDv3/3.4, the region between the H2B and H3 genes contains 0.35 kbp and cannot encode histone H1; in cDm500, the region contains 2.0 kbp and encodes histone H1. The lack of an H1 gene between the H2B and H3 genes in 30–40% ofD. virilis histone gene clusters suggests that changes in histone gene arrays have occurred during the evolution ofDrosophila. The ancestors of modernDrosophila may have possessed multiple varieties of histone gene clusters, which were subsequently lost differentially in thevirilis andmelanogaster lineages. Alternatively, they may have possessed a single variety, which was rearranged during evolution. The H1 genes ofD. virilis andD. melanogaster did not cross-hybridize in vitro under conditions that maintain stable duplexes between DNAs that are 75% homologous. Consequently,D. virilis H1 genes could not be visualized by hybridization to an H1-specific probe and thus remain unidentified. Our observations suggest that the coding segments in the H1 genes ofD. virilis andD. melanogaster are >25% divergent. Our estimate of sequence divergence in the H1 genes ofD. virilis andD. melanogaster seems high until one considers that the coding sequences of cloned H1 genes from the closely related speciesD. melanogaster andD. simulans are 5% divergent.     

Analysis of a histone H2A variant from fission yeast: evidence for a role in chromosome stability

We have isolated and characterised the pht1 gene from the fission yeast Schizosaccharomyces pombe. The sequence of the predicted translation product has revealed a striking similarity to the family of H2A.F/Z histone variant proteins, which have been found in a variety of different organisms. Cells deleted for the pht1 gene locus grow slowly, exhibit an altered colony morphology, increased resistance to heat shock and show a significant decrease in the fidelity of segregation of an S. pombe minichromosome. We propose that the histone H2A variant encoded by the pht1 gene is important for chromosomal structure and function, possibly including a role in controlling the fidelity of chromosomal segregation during mitosis.