Drosophila has a single copy of the gene encoding a highly conserved histone H2A variant of the H2A.F/Z type

Genetic analysis of chromosomal region 97D2-9 of Drosophila melanogaster

The rough homeobox gene of D. melanogaster is required for the correct patterning of the developing eye. The locus maps to cytological location 97D2-5, a region which has not been extensively characterised. As part of our genetic and molecular characterization of rough we carried out an EMS mutagenesis to generate mutants that map to the surrounding region, 97D2-9 which is deleted in Df(3R)ro-XB3. We have generated 1 visible and 13 lethal mutations which, together with the previously described Toll and ms(3)K10 loci, and other unpublished lethals, define nine complementation groups--four lethal, three semi-lethal, one visible and one male-sterile. In addition to rough, one other locus within this region, 1(3)97De, was shown to be required for formation of the normal pattern of photoreceptor cells in the compound eye.

Drosophila melanogaster male germ line-specific transcripts with autosomal and Y-linked genes

We have identified of set of related transcripts expressed in the germ line of male Drosophila melanogaster. Surprisingly, while one of the corresponding genes is autosomal the remainder are located on the Y chromosome. The autosomal locus, at 77F on chromosome arm 3L, corresponds to the previously described transcription unit 18c, located in the first intron of the gene for an RI subunit of cAMP-dependent protein kinase. The Y chromosome copies have been mapped to region h18-h19 on the cytogenetic map of the Y outside of any of the regions required for male fertility. In contrast to D. melanogaster, where Y-linked copies were found in nine different wild-type strains, no Y-linked copies were found in sibling species. Several apparently Y-derived cDNA clones and one Y-linked genomic clone have been sequenced. The Y-derived genomic DNA shares the same intron/exon structure as the autosomal copy as well as related flanking sequences suggesting that it transposed to the Y from the autosomal locus. However, this particular Y-linked copy cannot encode a functional polypeptide due to a stop codon at amino acid position 72. Divergence among five different cDNA clones ranges from 1.5 to 6% and includes a large number of third position substitutions. We have not yet obtained a full-length cDNA from a Y-linked gene and therefore cannot conclude that the D. melanogaster Y chromosome contains functional protein-coding genes. The autosomal gene encodes a predicted polypeptide with 45% similarity to histones of the H5 class and more limited similarity to cysteine-rich protamines. This protein may be a distant relative of the histone H1 family perhaps involved in sperm chromatin condensation.

cDNA sequence and expression of an intron-containing histone H2A gene from Norway spruce, Picea abies

We have isolated a cDNA clone corresponding to a histone H2A gene from Norway spruce, Picea abies (L.) Karst. The clone was isolated on the basis of the preferential expression of the corresponding gene during germination. The identification of the clone was based on the high degree of nucleotide sequence identity (60-65%) to a range of eukaryotic histone H2A genes and the presence of a 9 amino acids long sequence identical to the conserved 'H2A box' in the deduced amino acid sequence. Like other plant histone genes, the spruce histone H2A gene encodes a polyadenylated transcript. Further, the spruce gene contains an intervening sequence of 891 bp in the coding region. The presence of introns is typical of a distinct class of replication-independent histone genes in other eukaryotes. However, the sequence of the spruce gene and its high expression in mitotically active tissues such as the apical meristem, strongly suggests that it belongs to the class of replication-dependent histone genes. This is the first documentation of an intervening sequence in this class of histone genes and the finding implies that introns were present in the ancestral histone H2A gene before the divergence of the two classes of histone genes.

A histone variant, H2AvD, is essential in Drosophila melanogaster

H2AvD, a Drosophila melanogaster histone variant of the H2A.Z class, is encoded by a single copy gene in the 97CD region of the polytene chromosomes. Northern analysis shows that the transcript is expressed in adult females and is abundant throughout the first 12 h of embryogenesis but then decreases. The H2AvD protein is present at essentially constant levels in all developmental stages. Using D. melanogaster stocks with deletions in the 97CD region, we have localized the H2AvD gene to the 97D1-9 interval. A lethal mutation in this interval, l(3)810, exhibits a 311-base pair deletion in the H2AvD gene, which removes the second exon. P-element mediated transformation using a 4.1-kilobase fragment containing the H2AvD gene rescues the lethal phenotype. H2AvD is therefore both essential and continuously present, suggesting a requirement for its utilization, either to provide an alternative capability for nucleosome assembly or to generate an alternative nucleosome structure.

The organization, localization and nucleotide sequence of the histone genes of the midge Chironomus thummi

Several histone gene repeating units containing the genes for histones H1, H2A, H2B, H3 and H4 were isolated by screening a genomic DNA library from the midge Chironomus thummi ssp. thummi. The nucleotide sequence of one complete histone gene repeating unit was determined. This repeating unit contains one copy of each of the five histone genes in the order and orientation mean value of H3 H4 mean value of H2A H2B H1 mean value of. The overall length is 6262 bp. The orientation, nucleotide sequence and inferred amino acid sequence as well as the chromosomal arrangement and localization are different from those reported for Drosophila melanogaster. The codon usage also shows marked differences between Chironomus and Drosophila. Thus the histone gene structure reported for Drosophila is not typical of all insects.

Conservation of intron position indicates separation of major and variant H2As is an early event in the evolution of eukaryotes

Genomic clones of Drosophila and Tetrahymena histone H2A variants were isolated using the corresponding cDNA clones (van Daal et al. 1988; White et al. 1988). The site corresponding to the initiation of transcription was defined by primer extension for both Drosophila and Tetrahymena genomic sequences. The sequences of the genomic clones revealed the presence of introns in each of the genes. The Drosophila gene has three introns: one immediately following the initiation codon, one between amino acids 26 and 27 (gln and phe), and one between amino acids 64 and 65 (glu and val). The Tetrahymena gene has two introns, the positions of which are identical to the first two introns of the Drosophila gene. The chicken H2A.F variant gene has been recently sequenced and it contains four introns (Dalton et al. 1989). The first three of these are in the same positions as the introns in the Drosophila gene. The fourth intron interrupts amino acid 108 (gly). In all cases the sizes and the sequences of the introns are divergent. However, the fact that they are in conserved positions suggests that at least two of the introns were present in the ancestral gene. A phylogenetic tree constructed from the sequences of the variant and major cell cycle-regulated histone H2A proteins from several species indicates that the H2A variant proteins are evolutionarily separate and distinct from the major cell cycle-regulated histone H2A proteins. The ancestral H2A gene must have duplicated and diverged before fungi and ciliates diverged from the rest of the eukaryote lineage. In addition, it appears that the variant histone H2A proteins analyzed here are more conserved than the major histone H2A proteins.

On the origins of tandemly repeated genes: does histone gene copy number in Drosophila reflect chromosomal location?

Widely regarded beliefs about Drosophila histone gene copy numbers and developmental requirements have been generalized from fairly limited data since studies on histone gene arrangements and copy numbers have been largely confined to a single species, D. melanogaster. Histone gene copy numbers and chromosomal locations were examined in three species: D. melangaster, D. hydei and D. hawaiiensis. Quantitative whole genome blot analysis of DNA from diploid tissues revealed a tenfold variability in histone gene copy numbers for these three species. In situ hybridization to polytene chromosomes showed that the histone DNA (hDNA) chromosomal location is different in all three species. These observations lead us to propose a relationship between histone gene reiteration and chromosomal position.

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.

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.

Expression of a mouse replacement histone H3.3 gene with a highly conserved 3' noncoding region during SV40- and polyoma-induced Go to S-phase transition

We have isolated and sequenced a mouse replacement variant histone H3.3 cDNA. It corresponds to the most abundant mRNA expressed from a unique gene by the use of one out of three polyadenylation sites. The 3' non coding region of H3.3 is very long (approximately 1100 nt) and highly conserved throughout evolution since it is about 95% homologous to the 3' non coding region of the chicken H3.3B gene. We studied the expression of the H3.3 gene during SV40- and polyoma-induced mitotic host reaction in confluent, Go-arrested primary mouse kidney cell cultures. H3.3 replacement variant mRNA steady state levels increased during the Go to S-phase transition, apparently as the result of two mechanisms: one related to cell growth, whereas the other was linked to cellular DNA synthesis. The latter mechanism was however far less pronounced than with replication histone variant mRNAs. The biological implications of these results are discussed.

Transcription from the intron-containing chicken histone H2A.F gene is not S-phase regulated

The nucleotide sequence of an 8.2 kb BamHI fragment containing the entire chicken histone H2AF gene has been determined. Unlike the majority of histone genes, the coding region is interrupted by four intervening sequences. While sequencing the 8.2 kb BamHI fragment it was found that the promoter and first exon of an unidentified non-histone gene lies immediately downstream of the H2AF gene. Studies of H2AF gene transcription show that, unlike the major core and H1 histone genes, it is not coupled to DNA synthesis.