A mammalian oocyte-specific linker histone gene H1oo: homology with the genes for the oocyte-specific cleavage stage histone (cs-H1) of sea urchin and the B4/H1M histone of the frog

Oocytes and early embryos of multiple (non-mammalian) species lack the somatic form of the linker histone H1. To the best of our knowledge, a mammalian oocyte-specific linker (H1) histone(s) has not, as yet, been reported. We have uncovered the cDNA in question in the course of a differential screening (suppression subtractive hybridization (SSH)) project. Elucidation of the full-length sequence of this novel 1.2 kb cDNA led to the identification of a 912 bp open reading frame. The latter encoded a novel 34 kDa linker histone protein comprised of 304 amino acids, tentatively named H1oo. Amino acid BLAST analysis revealed that H1oo displayed the highest sequence homology to the oocyte-specific B4 histone of the frog, the respective central globular (putative DNA binding) domains displaying 54% identity. Substantial homology to the cs-H1 protein of the sea urchin oocyte was also apparent. While most oocytic mRNAs corresponding to somatic linker histones are not polyadenylated (and remain untranslated), the mRNAs of (non-mammalian) oocyte-specific linker histones and of mammalian H1oo, are polyadenylated, a process driven by the consensus signal sequence, AAUAAA, detected in the 3'-untranslated region of the H1oo cDNA. Our data suggest that the mouse oocyte-specific linker histone H1oo (1) constitutes a novel mammalian homolog of the oocyte-specific linker histone B4 of the frog and of the cs-H1 linker histone of the sea urchin; (2) is expressed as early as the GV (PI) stage oocyte, persisting into the MII stage oocyte, the oocytic polar bodies, and the two-cell embryo, extinction becoming apparent at the four- to eight-cell embryonic stage; and (3) may play a key role in the control of gene expression during oogenesis and early embryogenesis, presumably through the perturbation of chromatin structure.     

A rat histone H4 gene closely associated with the testis-specific H1t gene

A rat histone H4 gene closely associated with the testis-specific H1t gene was isolated by screening the Sargent-Bonner rat genomic library using cloned human histone genes as probes. Both the H4 gene and the H1t gene are located on a 7-kb EcoRI genomic DNA fragment. Although the deduced amino acid sequence of the rat H4 histone is identical to that of the sequence of human histone H4, the nucleotide sequence of the coding region differs significantly from the coding region of the human H4 gene. Moreover, the relative spacing between the 5'-consensus sequence elements is unique for an H4 gene. S1-nuclease protection analyses reveal that both the H4 and H1t mRNA species are present in a fraction of rat testis cells highly enriched in pachytene spermatocytes, while only the H4 mRNA species is present in a rat myeloma cell line (Y3-Ag1.2.3). During a 1-h hydroxyurea treatment of the Y3 cells, which produces a 99% inhibition of DNA synthesis, the level of this H4 mRNA drops by only 50%, indicating that the stability of this mRNA is only partially coupled with DNA synthesis.     

Isolation and characterization of two replication-dependent mouse H1 histone genes.

Mice contain at least seven nonallelic forms of the H1 histones, including the somatic variants H1a-e and less closely related variants H1 degrees and H1t. The mouse H1 degrees and H1c (H1var.1) genes were isolated and characterized previously. We have now isolated, sequenced and studied the expression properties of two additional mouse H1 genes, termed H1var.2 and H1var.3. Extensive amino acid and nucleotide sequence comparisons were made between the two genes and other mammalian H1 histone genes. A high degree of nucleotide sequence identity was seen between the H1var.2, rat H1d and human H1b genes, even well beyond the coding region, indicating that these genes are likely homologues. Unlike the previously characterized mouse H1var.1 gene which produces both nonpolyadenylated and polyadenylated mRNAs, the H1var.2 and H1var.3 genes produce only typical, replication dependent, nonpolyadenylated mRNAs.     

Histone H1

Linker histones of which histone H1 is a representative are a diverse family of architectural proteins within the eukaryotic nucleus. These proteins have a variety of structures, but invariably contain a region enriched in lysine, serine, alanine and profine. All metazoan histone His also include a structured domain that binds to DNA through a helix-turn-helix motif. By binding to the linker DNA flanking the nucleosome core they contribute to the assembly of higher-order chromatin structures. Surprisingly, the use of “knockout” technology to eliminate histone H1 in isolated cells and Xenopus does not prevent the assembly of chromosomes or nuclei, however specific genes are activated or repressed indicative of targeted regulatory functions. A dual role for histone HI in chromatin structure and gene regulation might contribute to epigenetic phenomena in which heritable states of gene activity are maintained through mechanisms independent of gene sequence. This may have important implications for biotechnological and medical research.     

Characterization of the H1.5 gene completes the set of human H1 subtype genes

The H1 histone family in mammals contains at least seven subtypes. In the past we have isolated six of the seven genes encoding these isoforms. To complete the set of the human H1 histone genes, we have designed two PCR primers deduced from a partially published sequence of the remaining histone H1 gene [Carozzi et al. (1984)Science 224, 1115–1118] and from a consensus sequence which we have derived from the conserved region of human histone H1 genes. Using these primers we have amplified a 417-bp DNA fragment from total human DNA. This fragment was used for screening a human phage genomic library. Two overlapping clones were isolated. The region contains a set of 5 genes representing each of the five histone classes. In continuation of our numbering of human H1 genes, we have named this H1 gene H1.5. This gene encodes a protein almost identical to the previously published protein sequence designated H1a [Ohe et al. (1986)J. Biochem. 100, 359–368]; since the changes are in a region of some uncertainty of the peptide sequencing, we conclude that the newly isolated gene codes for the H1a protein. The structures of the flanking regions of the genes except the H2B gene are typical for histone genes. They include: (1) a CCAAT element in the promotor region, (2) a TATA box and (3) a palindromic termination element. The H2B sequence shows no typical regulatory elements and no complete ORF, therefore we consider it as a pseudogene. The expression of the H1.5 gene was examined in several cell lines.     

Self-interaction of heterochromatin protein 1 is required for direct binding to histone methyltransferase,SUV39H1

Heterochromatin protein 1 (HP1) binds to the nucleosome via a methylated lysine residue 9 of histone H3 which is catalyzed by a histone methyltransferase such as SUV39H1. Although co-localization of HP1 and SUV39H1 has been evident in immunostaining and immunoprecipitation experiments, direct protein-protein interactions have remained to be characterized. We examined interactions between mouse HP1 alpha (mHP1 alpha) and SUV39H1 in yeast and in vitro. A yeast two-hybrid and a glutathione S-transferase pull-down study indicated that the chromo shadow domain of mHP1 alpha directly interacts with the N-terminal 39 amino acid stretch of SUV39H1. The IY165/168EE mutation in the chromo shadow domain of mHP1 alpha abrogated a self-interaction and this mutant did not interact with SUV39H1. The 13-mer peptide containing a consensus sequence for binding to the dimer surface formed by the chromo shadow domains inhibited interaction between mHP1 alpha and SUV39H1. It seems that self-interaction through the chromo shadow domain of HP1 is crucial for recruitment of SUV39H1 onto nucleosomes.     

Reconstitution of compact polynucleosomes and comparison of the functions of histones H1 and H5

Polynucleosomes with a definite length (about 4,500 base pairs) were prepared from chicken erythrocyte nuclei without depleting magnesium ions from the medium. The polynucleosomes in the presence of Mg2+ ions as well as monovalent salts were more compact than those with monovalent salts alone. We minimized the occurrence of nicks in the DNA of nucleosome fiber during the preparation. When histones H1 and H5 were completely removed from polynucleosomes, linker histone-depleted polynucleosomes sedimented slower than the original ones. When isolated histone H1 or H5 was reassembled with linker histone-depleted polynucleosomes, no significant difference was observed among the reconstituted polynucleosomes with histone H1, the reconstituted polynucleosomes with histone H5, and the original polynucleosomes. We concluded that histones H1 and H5 are similar in their effects on higher order structure of polynucleosomes, as far as can be judged from such characteristics as sedimentation velocity, linker histone content, and the patterns of nuclease digestion.