Kazunori Shiraishi scite author profile

One difficulty in analyzing the damage response is that the effect of damage itself and that of cellular response are hard to distinguish in irradiated cells. In mouse zygotes, damage can be introduced by irradiated sperm, while damage response can be studied in the unirradiated maternal pronucleus. We have analyzed the p53-dependent damage responses in irradiated-sperm mouse zygotes and found that a p53-responsive reporter was efficiently activated in the female pronucleus. [ 3 H]thymidine labeling experiments indicated that irradiated-sperm zygotes were devoid of G 1 /S arrest, but pronuclear DNA synthesis was suppressed equally in male and female pronuclei. p53 ؊/؊ zygotes lacked this suppression, which was corrected by microinjection of glutathione S-transferase-p53 fusion protein. In contrast, p21؊/؊ zygotes exhibited the same level of suppression upon fertilization by irradiated sperm. About a half of the 6-Gy-irradiated-sperm zygotes managed to synthesize a full DNA content by prolonging S phase, while the other half failed to do so. Regardless of the DNA content, all the zygotes cleaved to become two-cell-stage embryos. These results revealed the presence of p53-dependent pronuclear cross talk and a novel function of p53 in the S-phase DNA damage checkpoint of mouse zygotes.

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p21 provides stage specific DNA damage control to preimplantation embryos

Adiga

Toyoshima

Shiraishi

et al. 2007

Oncogene

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A Cyclized Helix‐Loop‐Helix Peptide as a Molecular Scaffold for the Design of Inhibitors of Intracellular Protein–Protein Interactions by Epitope and Arginine Grafting

et al. 2016

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The design of inhibitors of intracellular protein-protein interactions (PPIs) remains a challenge in chemical biology and drug discovery. We propose a cyclized helix-loop-helix (cHLH) peptide as a scaffold for generating cell-permeable PPI inhibitors through bifunctional grafting: epitope grafting to provide binding activity, and arginine grafting to endow cell-permeability. To inhibit p53-HDM2 interactions, the p53 epitope was grafted onto the C-terminal helix and six Arg residues were grafted onto another helix. The designed peptide cHLHp53-R showed high inhibitory activity for this interaction, and computational analysis suggested a binding mode for HDM2. Confocal microscopy of cells treated with fluorescently labeled cHLHp53-R revealed cell membrane penetration and cytosolic localization. The peptide inhibited the growth of HCT116 and LnCap cancer cells. This strategy of bifunctional grafting onto a well-structured peptide scaffold could facilitate the generation of inhibitors for intracellular PPIs.

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Growth Retardation of Paramecium and Mouse Cells by Shielding Them from Background Radiation

Kawanishi

Okuyama

Shiraishi

et al. 2012

JRR

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In the 1970s and 1980s, Planel et al. reported that the growth of paramecia was decreased by shielding them from background radiation. In the 1990s, Takizawa et al. found that mouse cells displayed a decreased growth rate under shielded conditions. The purpose of the present study was to confirm that growth is impaired in organisms that have been shielded from background radiation. Radioprotection was produced with a shielding chamber surrounded by a 15 cm thick iron wall and a 10 cm thick paraffin wall that reduced the γ ray and neutron levels in the chamber to 2% and 25% of the background levels, respectively. Although the growth of Paramecium tetraurelia was not impaired by short-term radioprotection (around 10 days), which disagreed with the findings of Planel et al., decreased growth was observed after long-term (40-50 days) radiation shielding. When mouse lymphoma L5178Y cells were incubated inside or outside of the shielding chamber for 7 days, the number of cells present on the 6th and 7th days under the shielding conditions was significantly lower than that present under the non-shielding conditions. These inhibitory effects on cell growth were abrogated by the addition of a ¹³⁷Cs γ-ray source disk to the chamber. Furthermore, no growth retardation was observed in XRCC4-deficient mouse M10 cells, which display impaired DNA double strand break repair.

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The Novel Surveillance Mechanism of the Trp53-Dependent S-Phase Checkpoint Ensures Chromosome Damage Repair and Preimplantation-Stage Development of Mouse Embryos Fertilized with X-Irradiated Sperm

et al. 2002

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Cell cycle checkpoints and apoptosis function as surveillance mechanisms in somatic tissues. However, some of these mechanisms are lacking or are restricted during the preimplantation stage. Previously, we reported the presence of a novel Trp53-dependent S-phase checkpoint that suppresses pronuclear DNA synthesis in mouse zygotes fertilized with X-irradiated sperm (sperm-irradiated zygotes) (Shimura et al., Mol. Cell. Biol. 22, 2220-2228, 2002). Here we studied the role of the Trp53-dependent S-phase checkpoint in the early stage of development of sperm-irradiated zygotes. In the Trp53(+/+) genetic background, all of the sperm-irradiated zygotes cleaved successfully to the two-cell stage despite the fact that half of them carried a sub-2N amount of DNA. These zygotes progressed normally to the eight-cell stage and then implanted, but the subsequent fetal development was suppressed in a dose-dependent manner. In contrast, sperm-irradiated Trp53(-/-) embryos lacking an S-phase checkpoint exhibited an abnormal segregation of chromosomes at the first cleavage, even though they carried an apparently normal 2N amount of DNA. They were morphologically abnormal with numerous micronuclei, and they degenerated before reaching the eight-cell stage. As a consequence, no implants were observed for sperm-irradiated Trp53(-/-) embryos. These results suggest that the Trp53-dependent S-phase checkpoint is a surveillance mechanism involved in the repair of chromosome damage and ensures the preimplantation-stage development of sperm-irradiated embryos.

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