Drosophila virilis histone gene clusters lacking H1 coding segments

Coordinated expression of replication-dependent histone genes from multiple loci promotes histone homeostasis in Drosophila

Production of large amounts of histone proteins during S phase is critical for proper chromatin formation and genome integrity. This process is achieved in part by the presence of multiple copies of replication dependent (RD) histone genes that occur in one or more clusters in metazoan genomes. In addition, RD histone gene clusters are associated with a specialized nuclear body, the histone locus body (HLB), which facilitates efficient transcription and 3' end-processing of RD histone mRNA. How all five RD histone genes within these clusters are coordinately regulated such that neither too few nor too many histones are produced, a process referred to as histone homeostasis, is not fully understood. Here, we explored the mechanisms of coordinate regulation between multiple RD histone loci in Drosophila melanogaster and Drosophila virilis. We provide evidence for functional competition between endogenous and ectopic transgenic histone arrays located at different chromosomal locations in D. melanogaster that helps maintain proper histone mRNA levels. Consistent with this model, in both species we found that individual histone gene arrays can independently assemble an HLB that results in active histone transcription. Our findings suggest a role for HLB assembly in coordinating RD histone gene expression to maintain histone homeostasis.

Preliminary study on a potential antibacterial peptide derived from histone H2A in hemocytes of scallop Chlamys farreri

Histone H2A is reported to participate in host defense response through producing novel antimicrobial peptides (AMPs) from its N-terminus in vertebrates and invertebrates, while the AMPs derived from H2A have not to our knowledge been reported in mollusca. In the present study, gene cloning, mRNA expression of H2A from scallop Chlamys farreri, and the recombinant expression of its N-terminus were conducted to investigate whether a similar mechanism exists in mollusca. The full-length DNA of H2A was identified by the techniques of homology cloning and genomic DNA walking. The full-length DNA of the scallop H2A was 696bp long, including a 5'-terminal untranslated region (UTR) of 90bp, a 3'-terminal UTR of 228bp with a stem-loop structure and a canonical polyadenylation signal sequence AATAAA, and an open reading frame of 375bp encoding a polypeptide of 125 amino acids. The mRNA expression of H2A in the hemocytes of scallop challenged by microbe was measured by semi-quantitative RT-PCR. The expression of H2A was not upregulated after stimulation, suggesting that H2A did not participate in immunity response directly. The DNA fragment of 117bp encoding 39 amino acids corresponding to the N-terminus of scallop H2A, which was homologous to buforin I in vertebrates, was cloned into Pichia pastoris GS115. The transformants (His(+) Mut(+)) containing multi-copy gene insertion were selected with increasing concentration of antibiotic G418. The peptide of 39 amino acids was expressed by induction of 0.5% methanol. The recombinant product exerted antibacterial activity against both Gram-positive (G(+)) and Gram-negative (G(-)) bacteria. The antibacterial activity toward G(+) bacteria was 2.5 times more than that against G(-) bacteria. The results elucidated that N-terminus of H2A was a potential AMP and provided a promising candidate for a new antibiotic screening. However, whether H2A is really involved in scallop immune response mechanisms needs to be further investigated.

Genomic organization, nucleotide sequence analysis of the core histone genes cluster in Chlamys farreri and molecular evolution assessment of the H2A and H2B

This work represents the nucleotide sequence of the core histone gene cluster from scallop Chlamys farreri. The tandemly repeated unit of 5671 bp containing a copy of the four core histone genes H4, H2B, H2A and H3 was amplified and identified by the techniques of homology cloning and genomic DNA walking. All the histone genes in the cluster had the structures in their 3' flanking region which related to the evolution of histone gene expression patterns throughout the cell cycle, including two different termination signals, the hairpin structure and at least one AATAAA polyadenylation signal. In their 5' region, the transcription initiation sites with a conserved sequence of 5'-PyATTCPu-3' known as the CAP site were present in all genes except to H2B, generally 37-45 bp upstream of the start code. Canonical TATA and CAAT boxes were identified only in certain histone genes. In the case of the promoters of H2B and H2A genes, there was a 5'-GATCC-3' element, which had been found to be essential to start transcription at the appropriate site. After this element, in the promoter of H2B, there was another sequence, 5'-GGATCGAAACGTTC-3', which was similar to the consensus sequence of 5'-GGAATAAACGTATTC-3' corresponding to the H2B-specific promoter element. The presence of enhancer sequences (5'-TGATATATG-3') was identified from the H4 and H3 genes, matching perfectly with the consensus sequence defined for histone genes. There were several slightly more complex repetitive DNA in the intergene regions. The presence of the series of conserved sequences and reiterated sequences was consistent with the view that mollusc histone gene cluster arose by duplicating of an ancestral precursor histone gene, the birth-and-death evolution model with strong purifying selection enabled the histone cluster less variation and more conserved function. Meanwhile, the H2A and the H2B were demonstrated to be potential good marks for phylogenetic analysis. All the results will be contributed to the characterization of repeating histone gene families in molluscs.

Molecular characterization and evolution of the repeating units of histone genes in Drosophila americana: coexistence of quartet and quintet units in a genome

Quintet and quartet repeating units of the histone genes in Drosophila americana were cloned and characterized. Nucleotide sequence analysis of the units showed that a 3175 bp unit contained the core histone genes but lacked the H1 gene ('quartet unit') while a 5025 bp unit contained all five histone genes ('quintet unit'). Comparative analysis suggested that these repeating units diverged before the separation of D. americana and D. virilis. Multiple forms of H1 genes, differing by 5.8% of amino acids, were found in D. americana. The genomic organization of the histone gene family in D. americana was found to be very similar to that of D. virilis.

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.

Divergence and heterogeneity of the histone gene repeating units in the Drosophila melanogaster species subgroup

The repeating units of the histone gene cluster containing the H1, H2A, H2B and H4 genes were amplified by PCR from the Drosophila melanogaster species subgroup, i.e., D. yakuba, D. erecta, D. sechellia, D. mauritiana, D. teissieri and D. orena. The PCR products were cloned and their nucleotide sequences of about 4.6-4.8kbp were determined to elucidate the mechanism of molecular evolution of the histone gene family. The heterogeneity among the histone gene repeating units was 0.6% and 0.7% for D. yakuba and D. sechellia, respectively, indicating the same level of heterogeneity as in the H3 gene region of D. melanogaster. Divergence of the genes among species even in the most closely related ones was much greater than the heterogeneity among family members, indicating a concerted mode of evolution for the histone gene repeating units. Among the species in the D. melanogaster species subgroup, the histone gene regions as well as 3rd codon position of the coding region showed nearly the same GC contents. These results suggested that the previous conclusion on analysis of the H3 gene regions, the gene family evolution in a concerted fashion, holds true for the whole histone gene repeating unit.

Evolution of the GC content of the histone 3 gene in seven Drosophila species

The molecular evolution of the histone multigene family was studied by cloning and determining the nucleotide sequences of the histone 3 genes in seven Drosophila species, D. takahashii, D. lutescens, D. ficusphila, D. persimilis, D.pseudoobscura, D. americana and D. immigrans. CT repeats, a TATA box and an AGTG motif in the 5' region, and a hairpin loop and purine-rich motifs (CAA(T/G)GAGA) in the 3' region were conserved even in distantly related species. In D. hydei and D.americana, the GC content at the third codon position in the protein coding region was relatively low (49% and 45%), while in D. takahashii and D. lutescens it was relatively high (64% and 65%). The non- significant correlation between the GC contents in the 3' region and at the third codon position as well as the evidence of less constraint in the 3' region suggested that mutational bias may not be the major mechanism responsible for the biased nucleotide change at the third codon position or for codon usage bias.

Molecular evolutionary analysis of a histone gene repeating unit from Drosophila simulans

A repeating unit of the histone gene cluster from Drosophila simulans containing the H1, H2A, H2B and H4 genes (the H3 gene region has already been analyzed) was cloned and analyzed. A nucleotide sequence of about 4.6 kbp was determined to study the nucleotide divergence and molecular evolution of the histone gene cluster. Comparison of the structure and nucleotide sequence with those of Drosophila melanogaster showed that the four histone genes were located at identical positions and in the same directions. The proportion of different nucleotide sites was 6.3% in total. The amino acid sequence of H1 was divergent, with a 5.1% difference. However, no amino acid change has been observed for the other three histone proteins. Analysis of the GC contents and the base substitution patterns in the two lineages, D. melanogaster and D. simulans, with a common ancestor showed the following. 1) A strong negative correlation was found between the GC content and the nucleotide divergence in the whole repeating unit. 2) The mode of molecular evolution previously found for the H3 gene was also observed for the whole repeating unit of histone genes; the nucleotide substitutions were stationary in the 3' and spacer regions, and there was a directional change of the codon usage to the AT-rich codons. 3) No distinct difference in the mode or pattern of molecular evolution was detected for the histone gene repeating unit in the D. melanogaster and D. simulans lineages. These results suggest that selectional pressure for the coding regions of histones, which eliminate A and T, is less effective in the D. melanogaster and D. simulans lineages than in the other GC-rich species.

Drosophila evolution challenges postulated redundancy in the E(spl) gene complex

The Enhancer of split [E(spl)] gene complex belongs to the class of neurogenic loci, which, in a concerted action, govern neurogenesis in Drosophila. Two genetically distinct functions, vital and neurogenic, reside within the complex defined by lethal mutations in the l(3) gro gene and by the typical neurogenic phenotype of deletions, respectively. Such deletions always affect several of the many embryonically active genes in the region, which cannot be mutated separately to lethality. Seven of these genes are extremely similar at the transcription and sequence level sharing the basic helix-loop-helix (bHLH) motif of transcriptional regulators. While these E(spl) bHLH genes seem to be required collectively for neurogenesis, they are nonessential individually, suggesting functional redundancy of the encoded gene products. No specific functions could yet be ascribed to any of the other genes located within the complex. One might expect these apparently dispensable genes, as well as the supposedly redundant bHLH genes, to be under little evolutionary constraint and, thus, to evolve most rapidly. However, we find the entire E(spl) gene complex highly conserved during Drosophila evolution, indicating that all the genes as well as their organization are of functional importance.

Nucleotide sequence of the Urechis caupo core histone gene tandem repeat

The 4942 bp nucleotide sequence of a repeating unit from the core histone gene tandem repeat of Urechis caupo and the predicted amino acid sequence of the four core histones are presented. Putative promoter elements including the CAP site and TATA box as well as multiple CAAT-like sequences are identified upstream from each gene. Upstream from each core histone gene are 26 or 30 bp sequences that may have a promoter function and appear to be unique to Urechis histone genes. Located 5' to both H2A and H2B is the 26 bp sequence, GGTCATGTGACTCTAATACCGCGCTG. An identical, but inverted, 26 bp sequence is present upstream of H4. Upstream from the H3 gene, two regions of a 30 bp sequence, GGTCTTGTGGCGGGAACAAATACCGCAACG, are very similar to corresponding regions of the 26 bp sequence. Additional 10 bp conserved sequences, CAGCGGGCGC, are present only upstream from the H2A and H2B genes. Conserved sequences containing a region of dyad symmetry followed by a purine-rich sequence that are typical of histone mRNA termination sites are present 27 to 36 bp 3' from the termination codon. Short repetitive DNA sequence elements are present in the spacer sequences between the H2A and H3 genes and the H2B and H4 gene.

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.

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.

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

The arrangement of core histone genes and their transcriptional polarity has been determined for three species of sea stars (Pisaster ochraceus, P. brevispinus, and Dermasterias imbricata) representing two orders which diverged over 500 million years ago. Each species has approximately 500 core histones cluster repeats per haploid genome. The close phylogenetic relationship between the Pisaster species is evident from the correspondence of restriction sites in the repeat element, identical arrangement of core histones, and high degree of sequence homology in both the coding and spacer regions of the H3 gene. The Dermasterias repeat has the same gene order and transcriptional polarity of core histones, but its restriction map is significantly different. Moreover, the Dermasterias H3 gene has the same amino acid sequence, but in comparison to Pisaster nucleotide sequences, shows a high level of silent substitutions. Analyses of the nucleotide sequence of the 5' and 3' regions surrounding the H3 gene from each species demonstrate the presence of appropriately spaced consensus and processing signal segments. The 3' spacer segment of the Dermasterias H4 gene contains an unusual, threefold tandemly repeated, 21-nucleotide, AT-rich sequence. No similar sequence is seen in the P. brevispinus H4 3' region, but these two species show a striking regularity of distribution of five different homologous oligomers in the 3' spacer.