Histone genes in three sea star species: cluster arrangement, transcriptional polarity, and analyses of the flanking regions of H3 and H4 genes

An Ancient Repeat Sequence in the ATP Synthase β-Subunit Gene of Forcipulate Sea Stars

A novel repeat sequence with a conserved secondary structure is described from two nonadjacent introns of the ATP synthase beta-subunit gene in sea stars of the order Forcipulatida (Echinodermata: Asteroidea). The repeat is present in both introns of all forcipulate sea stars examined, which suggests that it is an ancient feature of this gene (with an approximate age of 200 Mya). Both stem and loop regions show high levels of sequence constraint when compared to flanking nonrepetitive intronic regions. The repeat was also detected in (1) the family Pterasteridae, order Velatida and (2) the family Korethrasteridae, order Velatida. The repeat was not detected in (1) the family Echinasteridae, order Spinulosida, (2) the family Astropectinidae, order Paxillosida, (3) the family Solasteridae, order Velatida, or (4) the family Goniasteridae, order Valvatida. The repeat lacks similarity to published sequences in unrestricted GenBank searches, and there are no significant open reading frames in the repeat or in the flanking intron sequences. Comparison via parametric bootstrapping to a published phylogeny based on 4.2 kb of nuclear and mitochondrial sequence for a subset of these species allowed the null hypothesis of a congruent phylogeny to be rejected for each repeat, when compared separately to the published phylogeny. In contrast, the flanking nonrepetitive sequences in each intron yielded separate phylogenies that were each congruent with the published phylogeny. In four species, the repeat in one or both introns has apparently experienced gene conversion. The two introns also show a correlated pattern of nucleotide substitutions, even after excluding the putative cases of gene conversion.

Molecular evolutionary characterization of the mussel Mytilus histone multigene family: first record of a tandemly repeated unit of five histone genes containing an H1 subtype with "orphon" features

The present work represents the first characterization of a clustered histone repetitive unit containing an H1 gene in a bivalve mollusk. To complete the knowledge on the evolutionary history of the histone multigene family in invertebrates, we undertake its characterization in five mussel Mytilus species, as an extension of our previous work on the H1 gene family. We report the quintet H4-H2B-H2A-H3-H1 as the major organization unit in the genome of Mytilus galloprovincialis with two 5S rRNA genes with interspersed nontranscribed spacer segments linked to the unit, which is not justified by their cotranscription with histone genes. Surprisingly, 3' UTR regions of histone genes show two different mRNA termination signals, a stem-loop and a polyadenylation signal, both related to the evolution of histone gene expression patterns throughout the cell cycle. The clustered H1 histones characterized share essential features with "orphon" H1 genes, suggesting a common evolutionary origin for both histone subtypes which is supported by the reconstructed phylogeny for H1 genes. The characterization of histone genes in four additional Mytilus species revealed the presence of strong purifying selection acting among the members of the family. The chromosomal location of most of the core histone genes studied was identified by FISH close to telomeric regions in M. galloprovincialis. Further analysis on nucleotide variation would be necessary to assess if H1 proteins evolve according to the birth-and-death model of evolution and if the effect of the strong purifying selection maintaining protein homogeneity could account for the homologies detected between clustered and "orphon" variants.

Structure of histone H2B and H4 genes of the sea cucumber Holothuria tubulosa

A genomic library of the sea cucumber Holothuria tubulosa was screened with human and murine histone gene hybridization probes. A recombinant phage carrying an H4 gene was isolated and sequenced. Hybridization analysis of the entire 20 kb phage insert with probes for H1, H2A, H2B and H3 histones was negative except for H2B. This solitary arrangement of the two neighbouring histone H4 and H2B genes is in contrast to the organization of 'cleavage stage' histone genes, which are arranged in tandem quintets of genes encoding the 5 histone classes. Gene organization and sequence features indicate that the two Holothuria genes are the equivalents of a known pair of late H2B and H4 genes which have been described in the genome of sea urchins. This result shows that the simultaneous occurrence of tandem repeats of histone gene quintets and smaller groups of structurally distinct histone gene subtypes is not unique for sea urchins, but also applies to other echinodermata, such as the sea cucumber Holothuria tubulosa.

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 alpha-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.

Analysis of the core histone gene cluster of the annelid Platynereis dumerilii

The arrangement of the polychaete annelid Platynereis dumerilii core histone gene cluster and nucleotide sequence has been reported (D. Sellos, S. A. Krawetz and G. H. Dixon, 1990). The H2B and H3 mRNAs are transcribed from one DNA strand, while the H2A and H4 histone mRNAs are transcribed from the other. The H1 gene is not contained as a member of this cluster. Computer assisted sequence analysis of this region was undertaken to define the organization and representation of the various sequence motifs embedded within this region. The analysis revealed that two large regions on opposite strands of the cluster were similar to one another. This organization is reminiscent of an ancient gene duplication event from which the various members independently evolved.

Variability and inheritance of histone genes H3 and H4 in Vicia faba

We have compared copy numbers and blothybridization patterns of histone genes (H3 plus H4) between and within individuals of broad bean (Vicia faba). Copy number differences among individuals in the population of 200 individuals were as great as 27 fold, and as much as 3.2 fold among separate leaves of the same plant. Among F2 progeny from genetic crosses, up to a 5.4-fold range was seen (mean=3.5 fold), and among F1 progeny of self-pollinated plants, up to a 5.9-fold range was observed (mean=2.3 fold). Histone gene blot-hybridization patterns for EcoRI and HindIII were also variable among individuals and indicated that the genes are probably clustered in only a few chromosomal loci. The degree of variation in histone gene copy number per haploid genome (2-55 copies, or 27 fold) was similar to that found previously for ribosomal RNA genes (230-22000, or 95 fold) of V. faba. However, the two gene families change independently, since individuals with a high or low copy number for one gene can have either a high or low copy number for the other. The mechanisms(s) for rapid gene copy number change may be similar for these gene families.

Organization and complete nucleotide sequence of the core-histone-gene cluster of the annelid Platynereis dumerilii

The arrangement of the core-histone genes, their transcriptional polarity and their nucleotide sequences have been determined for the polychaete annelid Platynereis dumerili. A clone containing the core-histone genes was isolated from a annelid genomic library constructed in the EMBL-4 phage vector, using a trout H3 genomic probe. This clone was found to contain two and a half repeats of a 6-kbp EcoRV fragment that contained one copy of each of the core-histone genes. The clusters are tandemly arrayed in the genome and the gene order within the core-histone cluster does not vary. Absolutely no differences were found in the nucleotide sequences comprising the same part of two adjacent clusters (bases -225 to 2776 and bases 5821 to 8825). The number of copies of the cluster appeared to be high: approximately 660 copies/diploid cell, as also observed in sea urchins and amphibians. There are also some additional subtypes of histone gene organization: multimers of tandemly arrayed genes and isolated genes; these are present at a much lower copy number (an average of 40-50 copies/diploid genome). Two mRNAs (for H2B and H3) are transcribed from one DNA strand and the two other histone mRNAs (for H2A and H4) from the other strand as is the case for some insects and certain vertebrates. No H1-coding sequence has been found in the completely sequenced four-membered cluster. The organization of histone genes in P. dumerilii is similar to the clustering found in Caenorhabditis elegans but in this nematode worm several different types of organization are observed with a low copy number for each.

Isolation and characterization of a Drosophila hydei histone DNA repeat unit

Histone genes in D. hydei are organized in tandemly repeated clusters., accomodating in total 120-140 repeat units. We cloned one of the repeat units and analysed the nucleotide sequence. The repeat unit has a size of 5.1 x 10(3) base-pairs and contains one copy of each of the genes coding for the core histones and one copy coding for the histone H1. In the promoter regions of the genes we identified the presumptive cap sites and TATA boxes. Two additional sequence elements are shared by all five Drosophila hydei histone genes in the cluster. The sequence CCCTCT/G1 is found in the region upstream of the presumptive CAP sites. The sequence element AGTGAA occurs downstream of the presumptive cap sites and is, in contrast to the promoter element, also seen in the histone genes of Drosophila melanogaster. Cell-cycle dependent regulation of transcription of the Drosophila histone genes may be different from that in other eukaryotes since sequence elements involved in the regulation of cell-cycle dependent transcription are absent. Also other regulatory elements for transcription differ from those of other genes. The highly conserved H1-specific promoter sequence AAACACA and the H2B specific promoter sequence ATTTGCAT, which are involved in the cell-cycle dependent transcription of those histone genes in eukaryotes, are missing in the Drosophila genes. However at the 3' end of the genes the palindrome and the purine-rich region, both conserved sequence elements in histone genes of eukaryotes, are present. The spacer regions show a simple sequence organization. The silent site substitution rate between the coding regions of the D. hydei and D. melanogaster histone genes is at least 1.5 times higher for Drosophila than for sea urchin histone genes.

The genomic nucleotide sequences of two differentially expressed actin-coding genes from the sea star Pisaster ochraceus

The genomic sequences of two differentially expressed actin genes from the sea star Pisaster ochraceus are reported. The cytoplasmic actin gene (Cy) is expressed in eggs and early development. The muscle actin gene (M) is expressed in tube feet and testes. Both genes contain an 1125-nucleotide coding region interrupted by three introns at codons 41, 121 and 204. Gene M contains two additional introns at codons 150 and 267. The intron position at codon 150, although present in higher vertebrate actins, has not been reported in actin genes from invertebrates. The M gene coding region has 89.5% nucleotide homology to the Cy gene, and differs from the Cy actin gene in 13 of 375 amino acids (aa), 11 of which are found in the C-terminal half of the gene. The C-terminal half of the M gene contains a significant number of muscle isotype codons. Even though there is only 1 aa change in the first 150 codons, there have been limited substitutions at many four-fold degenerate sites which may indicate selection pressure upon the secondary structure of the mRNA and/or a biased codon usage. Variant CCAAT, TATA, and poly(A)-addition signals have been identified in the 5' and 3' flanking regions. The presence of 5' and 3' splice junction sequences in the 5' flanking region of the Cy gene suggests the potential for an intron there.