DNA double-stranded breaks induce histone H2AX phosphorylation on serine 139.

When mammalian cell cultures or mice are exposed to ionizing radiation in survivable or lethal amounts, novel mass components are found in the histone H2A region of two-dimensional gels. Collectively referred to as gamma, these components are formed in vivo by several procedures that introduce double-stranded breaks into DNA. gamma-Components, which appeared to be the only major novel components detected by mass or 32PO4 incorporation on acetic acid-urea-Triton X-100-acetic acid-urea-cetyltrimethylammonium bromide or SDS-acetic acid-urea-cetyltrimethylammonium bromide gels after exposure of cells to ionizing radiation, are shown to be histone H2AX species that have been phosphorylated specifically at serine 139. gamma-H2AX appears rapidly after exposure of cell cultures to ionizing radiation; half-maximal amounts are reached by 1 min and maximal amounts by 10 min. At the maximum, approximately 1% of the H2AX becomes gamma-phosphorylated per gray of ionizing radiation, a finding that indicates that 35 DNA double-stranded breaks, the number introduced by each gray into the 6 x 10(9) base pairs of a mammalian G1 genome, leads to the gamma-phosphorylation of H2AX distributed over 1% of the chromatin. Thus, about 0.03% of the chromatin appears to be involved per DNA double-stranded break. This value, which corresponds to about 2 x 10(6) base pairs of DNA per double-stranded break, indicates that large amounts of chromatin are involved with each DNA double-stranded break. Thus, gamma-H2AX formation is a rapid and sensitive cellular response to the presence of DNA double-stranded breaks, a response that may provide insight into higher order chromatin structures.

Increasing the distance between the snRNA promoter and the 3' box decreases the efficiency of snRNA 3'-end formation.

Chimeric genes which contained the mouse U1b snRNA promoter, portions of the histone H2a or globin coding regions and the U1b 3'-end followed by a histone 3'-end were constructed. The distance between the U1 promoter and the U1 3' box was varied between 146 and 670 nt. The chimeric genes were introduced into CHO cells by stable transfection or into Xenopus oocytes by microinjection. The efficiency of utilization of the U1 3' box, as measured by the relative amounts of transcripts that ended at the U1 3' box and the histone 3'-end, was dependent on the distance between the promoter and 3'-end box. U1 3'-ends were formed with >90% efficiency on transcripts shorter than 200 nt, with 50-70% efficiency on transcripts of 280-400 nt and with only 10-20% efficiency on transcripts >500 nt. Essentially identical results were obtained after stable transfection of CHO cells or after injecting the genes into Xenopus oocytes. The distance between the U1 promoter and the U1 3' box must be <280 nt for efficient transcription termination at the U1 3' box, regardless of the sequence transcribed.

Histone H2A.X gene transcription is regulated differently than transcription of other replication-linked histone genes.

Histone H2A.X is a replication-independent histone H2A isoprotein species that is encoded by a transcript alternatively processed at the 3' end to yield two mRNAs: a 0.6-kb mRNA ending with the stem-loop structure characteristic of the mRNAs for replication-linked histone species, and a second, polyadenylated 1.6-kb mRNA ending about 1 kb further downstream (C. Mannironi, W. M. Bonner, and C. L. Hatch, Nucleic Acids Res. 17:9113-9126, 1989). Of the two, the 0.6-kb H2A.X stem-loop mRNA predominates in many cell lines, indicating that the presence of two types of mRNA may not completely account for the replication independence of H2A.X protein synthesis. The ambiguity is resolved by the finding that the level of the 0.6-kb H2A.X mRNA is only weakly downregulated during the inhibition of DNA replication and only weakly upregulated during the inhibition of protein synthesis, while the levels of other replication-linked mRNAs are strongly down- or upregulated under these two conditions. Analysis of the nuclear transcription rates of specific H2A genes showed that while the rates of transcription of replication-linked H2A genes decreased substantially during the inhibition of DNA synthesis and increased substantially during the inhibition of protein synthesis, the rate of H2A.X gene transcription decreased slightly under both conditions. These differences in transcriptional regulation between the H2A.X gene and other replication-linked histone genes are sufficient to account for the differences in regulation of their respective stem-loop mRNAs.

The histone mRNA 3' end is required for localization of histone mRNA to polyribosomes.

The final step in mRNA biosynthesis is transport of the mRNA from the nucleus to the cytoplasm. Histone genes from which the 3' stem-loop has been deleted are transcribed to give RNAs with heterogeneous 3' ends. These RNAs are localized in the nucleus and are stable. Addition of the histone 3' processing signal either on short (< 250 nts) or long (> 1000 nts) transcripts restores 3' processing and transport of the mRNA to the cytoplasm. In addition chimeric histone-U1 snRNA genes which produced RNAs with either histone or U1 3' ends were analyzed. Transcripts which ended with U1 snRNA 3' ends were not efficiently localized to polyribosomes. However, transcripts containing the same sequences including the snRNA 3' end followed by the histone 3' end were present in the cytoplasm on polyribosomes. Taken together these results suggest that the histone 3' end is required for export of histone mRNA to the cytoplasm and association of the mRNA with polyribosomes.

Expression of histone-U1 snRNA chimeric genes: U1 promoters are compatible with histone 3' end formation.

Chimeric genes which fuse the mouse histone H2a gene and the mouse U1b gene were constructed and introduced into CHO cells by cotransfection. In the UH genes, the U1b gene promoter and the start of the U1b gene were fused to the H2a gene in the 5' untranslated region. In the HU genes, the U1b 3' end was inserted into the 3' untranslated region of the H2a gene replacing the normal histone 3' end. Transcripts from the UH genes initiated at the start of the U1 gene and ended at the normal histone 3' end. Transcripts from the HU chimeric genes did not end at the U1 3' end but extended at least 80 nucleotides further and had heterogeneous 3' ends. Placing both a U1 snRNA promoter and a U1 snRNA 3' end around a histone coding region resulted in transcripts which initiate and terminate at the appropriate U1 ends. These results are consistent with previous reports that formation of the U1 3' ends require U1 promoters, but indicate that the histone 3' end can be formed on transcripts initiating at U1 promoters. The transcripts initiated at the U1 start site and ending at the histone 3' end are present on polyribosomes and show proper posttranscriptional regulation.

U3 snRNPs and nucleolar development during oocyte maturation, fertilization and early embryogenesis in the mouse: U3 snRNA and snRNPs are not regulated coordinate with other snRNAs and snRNPs.

U3 small nuclear ribonucleic acids (snRNA) and U3 small nuclear ribonucleoprotein (snRNP), which are thought to be responsible for ribosomal RNA processing, are quantitated and localized during oocyte maturation, fertilization, and early embryogenesis in the mouse. On the basis of Northern blot and nuclease protection experiments, it is estimated that there are about 5 x 10(4) U3 snRNA molecules in an ovulated oocyte and in a two-cell embryo. This number then increases roughly 50-fold to 2.7 x 10(6) molecules per embryo by the blastocyst stage. At all stages of development U3 snRNP antigens colocalize with nucleoli, as defined by differential interference contrast microscopy and an antibody to a nucleolar epitope. The synthesis and distribution of U3 snRNA and U3 snRNP follow a pattern independent from other major U snRNPs and snRNAs.

The small nuclear RNAs for pre-mRNA splicing are coordinately regulated during oocyte maturation and early embryogenesis in the mouse.

The abundance and localization of snRNAs and snRNPs involved in processing and splicing of pre-mRNA has been studied during early mouse embryogenesis. The amount of U1, U2, U4, U5 and U6 RNA remains relatively constant between the postovulatory oocyte and 2-cell stage but increases three- to ten-fold in quantity between the 2-cell and blastocyst stages. Localization was examined by in situ hybridization with U1, U2 and U6 riboprobes and immunofluorescence microscopy using a monoclonal antibody to snRNP antigens. The snRNAs and snRNPs are primarily localized to the germinal vesicle in the preovulatory oocyte but are released and diluted within the cytoplasm of the oocyte during germinal vesicle breakdown and meiotic maturation. They subsequently relocalize to both pronuclei following fertilization and the nuclei of the 2-cell embryo following the first cleavage division. Since the amount of snRNA is constant during the first cleavage, the small amount of pre-mRNA that is synthesized at the time of transcriptional activation in the 2-cell embryo may be spliced and processed by snRNPs of maternal origin.

Characterization of mouse H3.3-like histone genes.

We designed a strategy to select genomic clones of mouse replication-independent H3.3 histone genes. We obtained three clones which met our selection criteria for being H3.3 genes. Upon sequencing two of these clones we found that they were unlike previously isolated chicken H3.3 clones: they code for several unpredicted amino acid substitutions and contain no introns in the coding regions. We showed by S1 nuclease assays that these genes are protected by mRNAs that have expression characteristics of H3.3 mRNA. The protection data and nucleotide sequence analysis show that the H3.3 transcripts can be processed at one of four cleavage/polyadenylation sites. We show that these genes probably evolved through reverse transcription intermediates, and are processed pseudogenes which are no longer under selective pressure. The 5' and 3' transcribed, nontranslated sequences show extensive homology to those of a human cDNA clone, and we suggest that these sequences may be required for appropriate regulation of expression of H3.3 genes.