Structure and expression of the human gene encoding testicular H1 histone (H1t)

The gene coding for the human H1t histone, a testis-specific H1 subtype, was isolated from a genomic library using a human somatic H1 gene as a hybridization probe. The corresponding mRNA is not polyadenylated and encodes a 206-amino-acid protein. Sequence analysis and S1 nuclease mapping of the human H1t gene reveals that the 5' flanking region contains several consensus promoter elements, as described for somatic, i.e., S-phase-dependent H1 subtype genes. The 3' region includes the stem-and-loop structure necessary for mRNA processing of most histone mRNAs. Northern blot analysis with RNAs from different human tissues and cell lines revealed that only testicular RNA hybridized with this gene probe.     

Isolation and characterization of a mouse fully replication-dependent H1 gene within a genomic cluster of core histone genes

We have used an oligonucleotide complementary to a sequence coding for the conserved central globular domain of H1s to screen a mouse genomic library for H1 genes. We then used a series of universal histone oligonucleotides to identify five different H1 genes which were linked to core histone genes. We characterized one of the H1 genes which was linked to an H2a, an H2b, an H3, and an H4 histone gene. This characterization involved: 1) sequencing of the coding region of the gene and several hundred base pairs of flanking region. 2) Comparison of this sequence to other H1 sequences from other organisms. This sequence analysis clearly showed that the gene coded for an H1 and identified H1 consensus sequences in the 5'- and 3'-flanking region. 3) Mapping of the 5'- and 3'-ends of the mRNA complementary to this gene by S1 nuclease analysis. 4) Identifying this gene and an adjacent H3 gene as being of the fully replication-dependent expression class, by measuring changes in the steady state levels of their mRNAs in the presence of hydroxyurea and during differentiation of murine erythroleukemia cells.     

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.     

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.     

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.     

Nonallelic histone gene clusters of individual sea urchins (Lytechinus pictus): mapping of homologies in coding and spacer DNA

The linear arrangement and lengths of the spacers and coding regions in the two nonallelic histone gene variant clusters of L. pictus are remarkably homologous by R loop analysis and are similar in general topography to the histone gene repeat units of other sea urchins examined to date. No interventing sequences were detected. The coding regions of these two histone gene variants share considerable sequence homology; however, there are areas of nonhomology in every spacer region and the lengths of the nonhomologous spacers between the H2A and H1 genes are not the same for the two repeat unit classes (inter-gene heterogeneity). Combining length measurements obtained with both R loops and heteroduplexes suggests that the DNA sequences of the analogous leader regions for the two H1 mRNAs are nonhomologous. Similar observations were made for the H4 leader sequences, as well as the trailer region on H2B. S. purpuratus spacer DNA segments share little sequence homology with L. pictus; however, the analgous coding (and possibly flanking) regions have conserved their sequences. The various coding and spacer regions within a repeat unit do not share DNA sequences. Thus certain areas in the sea urchin histone gene repeat units have been highly conserved during evolution, while other areas have been allowed to undergo considerable sequence change not only between species but within a species.