Nucleotide sequence of a member of the chicken H2B histone-encoding gene family

Targeted disruption of H2B-V encoding a particular H2B histone variant causes changes in protein patterns on two-dimensional polyacrylamide gel electrophoresis in the DT40 chicken B cell line

The chicken H2B gene family comprises eight members (H2B-I to H2B-VIII), which are all located in two major histone gene clusters. All of them have been shown to encode four different protein variants (classes I to IV). In the DT40 chicken B cell line, the H2B-V gene, encoding the class III H2B variant, constituted about 10% of the total intracellular mRNA from all the H2B genes. To study the nature of this particular variant in vivo, we generated heterozygous (H2B-V, +/-) and homozygous (H2B-V, -/-) DT40 mutants by targeted integration. The remaining H2B genes were shown to be expressed more in these mutants than in the wild-type cell lines. The growth rate of DT40 cells was unchanged in the absence of the H2B-V gene. Two-dimensional polyacrylamide gel electrophoresis showed that the protein patterns were, on the whole, similar between the wild-type and homozygous cell lines. However, within this constant background, some cellular proteins disappeared or decreased quantitatively in the homozygous mutants, and several other proteins increased or newly appeared. These results suggest that the class III H2B variant participates negatively or positively in regulation of the expression of particular genes that encode the proteins that vary in DT40 cells. This type of regulation is possibly mediated through alterations in nucleosome structure over the restricted regions involving the putative genes of the DT40 genome.

Presence of particular transcription regulatory elements in the 5'-intergenic region shared by the chicken H2A-III and H2B-V pair

The two chicken histone gene families, H2A and H2B, contain nine and eight members, respectively, within two major histone gene clusters. Six genes each from families H2A and H2B have been found to be closely associated in inverted directions as H2A/H2B gene pairs. Two previously sequenced H2A members (H2A-I and H2A-II) encode the same amino acid (aa) sequence (class I), whereas seven sequenced H2B genes encode three different variants (classes I, II and III). In this study, we first sequenced H2A-III, a member of the H2A family, which is located in inverted orientation and 350 bp upstream from H2B-V, encoding the class-III H2B protein. The protein encoded by H2A-III differs from the class-I H2A protein in a single aa (Ala70-->Pro; class II). As a step toward elucidation of the transcriptional regulation of the H2A and H2B families, we fused this 5'-intergenic region to the cat gene in inverted orientations to generate two chimeric plasmids, pH2A-III-350 and pH2B-V-350. Transient CAT assays using these constructs indicated that the promoter of H2B-V is more active than that of H2A-III. CAT assays with 5'-deletion mutants of H2A-III and H2B-V showed that they each possess particular transcriptional motifs which are located relatively close to, or apart from, their own coding regions. These findings, together with those reported previously on the H2A-V/H2B-II pair, suggest distinct manners of transcription regulation of different members of the chicken histone gene families, H2A and H2B.

The chicken histone gene family

1. Most of the chicken 43 core and H1 histone genes belong to two major histone gene clusters. 2. Each of six H1 genes encodes a different H1 protein sequence. 3. The known core histone genes, four H2A, seven H2B, and seven H3 genes, respectively, encode two, three and three different protein variants, whereas the four known H4 genes encode the same amino acid sequence. 4. The core histone genes have particular transcription regulatory elements within the 5'-flanking regions and the regulations of their expressions are distinct, even though they are members of the same core histone gene family. 5. There are some undefined differences in the DNA structures of the particular core histone genes in various chicken tissues and these structural variations probably result in differences in their transcriptional regulation.

Presence of distinct transcriptional regulatory elements in the 5'-flanking region shared by the chicken H3 histone gene homopair

The chicken H3 histone gene family contains nine members belonging to two major histone gene clusters. Six of these genes have been sequenced and shown to encode two different H3 protein variants. Five H3 genes (H3-I, -II, -IV, -V, and -VI) encode the same amino acid sequence (class I) and another H3 gene (H3-III) differs from class I in a single amino acid (IIe113-Met) (class II). H3-II and H3-III have inverted orientations and share a 5' intergenic region of about 900 bp. To understand the regulation of expression of these two genes, we fused the 5'-flanking region to the CAT gene in inverted orientations to generate two chimeric plasmids, pH3-II-900 and pH3-III-900. Transient CAT assays using these constructs indicated that the promoter of H3-III is more active than that of H3-II. CAT assays with deletion mutants showed that H3-II and H3-III each possess a particular transcription regulatory sequence 5' adjacent to their coding sequence. In addition, the functional sequences of H3-II have no effect on expression of H3-III and vice versa. These results suggest that the regulations of expression of the two H3 genes are distinct.

Evidence for possible structural changes of particular H3 and H2B histone genes in different chicken tissues (cells)

The two chicken histone gene families H3 and H2B contain nine and eight members, respectively. To clarify whether the structures of these genes differ in different tissues (and cells), we analyzed DNAs from chicken lung, kidney, oviduct, and sperm. An H3-specific probe (probe 1.3SS) hybridized with a 10 kb EcoRI fragment carrying two H3 genes (H3-II and H3-III) from the lung, kidney, and oviduct with intensities of about one quarter of that of the fragment from the sperm. On the other hand, the intensities of hybridization of the H2B-specific probes (probes H2B-Ia, H2B-IIb, and H2B-III) with a 12 kb EcoRI fragment carrying two H2B genes (H2B-IV and H2B-V) from the oviduct, lung, and sperm were about a quarter of the intensity of hybridization with this fragment from the kidney. These findings, together with those reported previously, suggest that these particular histone genes H3 and H2B possess inherent abilities to form either a tight or loose structure, and that they exist in a loose form in the sperm and kidney but in a tight form in the other tissues tested.

Structural change of a particular H2B histone gene possibly results in differences in its transcriptional regulation in different chicken tissues

The chicken H2B histone gene family consists of eight highly homologous members (H2B-I to H2B-VIII) belonging to two major histone gene clusters. Seven of these genes have been sequenced and shown to encode three different H2B protein variants. Northern analysis with a probe, which mainly consists of the 5'-flanking region containing the sequence for the mRNA leader of H2B-V encoding a particular H2B protein variant, revealed that the mRNA level transcribed from this particular gene was higher in the kidney than in the oviduct and lung. To elucidate whether the structure of the H2B gene differs in the three different tissues, we analyzed DNAs from the oviduct, lung, and kidney. On Southern analysis, various H2B gene-specific probes hybridized with two particular H2B genes (H2B-IV and H2B-V), which are located in close proximity within a 12 kb EcoRI fragment, from the oviduct and lung with an intensity of about one quarter of that from the kidney. These findings suggest that some difference of DNA structure of the H2B-V gene may result in its relatively higher expression in the kidney.

Nucleotide sequences of two members of the chicken H4 histone-encoding gene family

The nucleotide sequences of two genes (H4-III and H4-IV) from the chicken H4 histone-encoding gene family have been determined. The four H4 genes, including the previously sequenced H4-I and H4-II genes, encode the same amino acid sequence and possess several copies of the possible Sp1-binding sequences on the coding and noncoding strands within the 5'-flanking regions.