A human histone H2B.1 variant gene, located on chromosome 1, utilizes alternative 3' end processing.

A variant human H2B histone gene (GL105), previously shown to encode a 2300 nt replication independent mRNA, has been cloned. We demonstrate this gene expresses alternative mRNAs regulated differentially during the HeLa S3 cell cycle. The H2B-Gl105 gene encodes both a 500 nt cell cycle dependent mRNA and a 2300 nt constitutively expressed mRNA. The 3' end of the cell cycle regulated mRNA terminates immediately following the region of hyphenated dyad symmetry typical of most histone mRNAs, whereas the constitutively expressed mRNA has a 1798 nt non-translated trailer that contains the same region of hyphenated dyad symmetry but is polyadenylated. The cap site for the H2B-GL105 mRNAs is located 42 nt upstream of the protein coding region. The H2B-GL105 histone gene was localized to chromosome region 1q21-1q23 by chromosomal in situ hybridization and by analysis of rodent-human somatic cell hybrids using an H2B-GL105 specific probe. The H2B-GL105 gene is paired with a functional H2A histone gene and this H2A/H2B gene pair is separated by a bidirectionally transcribed intergenic promoter region containing consensus TATA and CCAAT boxes and an OTF-1 element. These results demonstrate that cell cycle regulated and constitutively expressed histone mRNAs can be encoded by the same gene, and indicate that alternative 3' end processing may be an important mechanism for regulation of histone mRNA. Such control further increases the versatility by which cells can modulate the synthesis of replication-dependent as well as variant histone proteins during the cell cycle and at the onset of differentiation.     

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.     

Butyrate induced accumulation of a 2.3 kb polyadenylated H1(0) histone mRNA in HeLa cells.

Sodium butyrate was used to induce the accumulation of human H1(0) mRNA in HeLa cells. The length of this mRNA (2,300 nucleotides) was determined by Northern blot hybridization and S1 nuclease analysis using a human H1(0) gene probe. The mRNA shows long 5' and 3' non coding segments and it is polyadenylated. The signal for this step of mRNA maturation (cleavage and polyadenylation) appears to be the hexanucleotide AAUAAA in analogy to most (other than histone) mRNA species. Thus, the mode of maturation of H1(0) mRNA differs, on one hand, from that of the cell cycle dependent mRNA species, where it is based on a specific stem-and-loop structure. On the other hand, the 3' end of H1(0) mRNA varies from H5 mRNA, which is characterized by two unique dyad symmetry structures at its 3' end.     

The structural organization and DNA sequence of a wheat histone H4 gene.

Some wheat histone H4 genes have been cloned from a Charon 4 wheat genomic DNA library using sea urchin histone H4 DNA as a probe. DNA sequence analysis of a cloned gene showed that the deduced amino acid sequence of wheat histone H4 protein was identical to that of pea. The 5' end of wheat histone H4 mRNA was mapped on the cloned gene by the S1-procedure. Southern blotting analysis of the genomic DNA indicated that histone H4 genes were reiterated 100 to 125 times per hexaploid wheat genome.     

Characterization of the structure and transcriptional patterns of the gene encoding the late histone subtype H1-beta of the sea urchin Strongylocentrotus purpuratus.

We have cloned and characterized the gene encoding the late histone H1-beta subtype from the sea urchin Strongylocentrotus purpuratus. The gene contains all of the upstream sequence homologies previously seen in late H1-gamma genes. The expression of H1-beta mRNA is coordinated with that of H1-gamma mRNA, and like H1-gamma it is expressed in all adult somatic tissues tested.     

Characterization of the histone H1-binding protein, NASP, as a cell cycle-regulated somatic protein

Nuclear autoantigenic sperm protein (NASP), initially described as a highly autoimmunogenic testis and sperm-specific protein, is a histone-binding protein that is a homologue of the N1/N2 gene expressed in oocytes of Xenopus laevis. Here, we report a somatic form of NASP (sNASP) present in all mitotic cells examined, including mouse embryonic cells and several mouse and human tissue culture cell lines. Affinity chromatography and histone isolation demonstrate that NASP from myeloma cells is complexed only with H1, linker histones. Somatic NASP is a shorter version of testicular NASP (tNASP) with two deletions in the coding region arising from alternative splicing and differs from tNASP in its 5' untranslated regions. We examined the relationship between NASP mRNA expression and the cell cycle and report that in cultures of synchronized mouse 3T3 cells and HeLa cells sNASP mRNA levels increase during S-phase and decline in G(2), concomitant with histone mRNA levels. NASP protein levels remain stable in these cells but become undetectable in confluent cultures of nondividing CV-1 cells and in nonmitotic cells in various body tissues. Expression of sNASP mRNA is regulated during the cell cycle and, consistent with a role as a histone transport protein, NASP mRNA expression parallels histone mRNA expression.     

Characterization of the chicken histone H1 gene complement. Generation of a complete set of vertebrate H1 protein sequences

Sequence analysis of four chicken H1 histone genes described here completes the characterization of the full complement of six H1 genes in the chicken genome. Each of the six genes codes for a different H1 protein sequence, and these range in size from 217 to 224 amino acids. The proteins are distinct in sequence from the H1-related chicken H5 protein and appear to be analogous to the standard somatic mammalian H1 subtypes. The protein sequence data deduced from the genes represent the first complete set of vertebrate H1 protein sequences. Comparison of the chicken H1 gene noncoding sequences with each other and with H1 gene sequences from other organisms reveals conservation of an H1 gene-specific element, a G-rich element, and histone gene-specific 3' elements. Additional sequences are conserved between H1 genes of the chicken and other vertebrates. Comparisons also reveal variation in promoter and 3' elements between chicken genes that could play a role in the differential expression of H1 gene protein products.     

Testis-Specific Expression of a Novel Human H3 Histone Gene

We have investigated the expression of a recently described, solitary human H3 histone gene. Using RNase protection assays, the corresponding mRNA could only be detected in RNA preparations from human testis, whereas several human cell lines and somatic tissues did not exhibit expression of this gene.In situhybridization of sections from human testis revealed expression to be confined to primary spermatocytes. In addition to H1t, this novel H3 gene, which is located on chromosome 1, is the second tissue-specific human histone gene that has been found to be expressed solely in the testis.     

H1 subtype expression during cell proliferation and growth arrest

H1 histone subtype genes differ in their expression patterns during the different stages of the cell cycle interphase. While the group of replication-dependent H1 histone subtypes is synthesized during S phase, the replacement histone subtype H1.0 is also expressed replication-independently in non-proliferating cells. The present study is the first report about the analysis of the cell cycle-dependent expression of all five replication-dependent H1 subtypes, the replacement histone H1.0 and the ubiquitously expressed subtype H1x. The expression of these H1 histone subtypes in HeLa cells was analysed on mRNA level by quantitative real-time RT-PCR as well as on protein level by immunoblotting. We found that after arrest of HeLa cells in G1 phase by treatment with sodium butyrate, the mRNA levels of all replication-dependently expressed H1 subtypes decreased, but to very different extent. During S phase the individual replication-dependently expressed H1 subtypes show similar kinetics regarding their mRNA levels. However, the variations in their protein amounts partially differ from the respective RNA levels which especially applies to histone H1.3. In contrast, the mRNA as well as the protein level of H1x remained nearly unchanged in G1 as well as during S phase progression. The results of the present study demonstrate that the cell cycle-dependent mRNA and protein expression of various H1 subtypes is differentially regulated, supporting the hypothesis of a functional heterogeneity.     

Calculated flexibility of histone proteins correlate with mammalian histone H1 subtype.

We have calculated the polypeptide flexibility index for mammalian histone H1 sequences obtained from the National Center for Biotechnology Information Histone Sequence Database. This database contains over 1000 histone protein entries, from various species, compiled from SWISS_PROT, PIR, the Protein Data Bank (PDB), and CDS translations from GenBank. Histone H1 proteins were analyzed because of their critical role in chromatin structure and gene expression. Flexibility calculations revealed that histone subtype H1.0, which accumulates during terminal differentiation, has the highest flexibility index of all mammalian H1 subtypes. Other mammalian H1 subtypes had lower flexibility indices, including the human H1.2 subtype whose mRNA contains both a hairpin loop sequence and a poly(A) addition sequence. Histone mRNAs containing both of these structures have been shown to be expressed prior to and after terminal differentiation, yet these proteins do not necessarily accumulate in the chromatin of terminally differentiated cells. H1.2 and the H1.t have the lowest flexibility index (most ridged) of all human H1 subtypes. All human H1 proteins of the replication dependent subtypes have intermediate values for their flexibility indices.