Your search keyword '"Komatsu, Kenshi"' showing total 27 results

1. Mechanistic insights into the survival curve of HeLa cells with a short shoulder and their S phase-specific sensitivity†

Author

Komatsu, Kenshi and Tauchi, Hiroshi

Abstract

HeLa cells are a cell line with two unique cellular features: a short-shouldered survival curve and two peaks of radioresistance during the cell cycle phase, while their underlying mechanisms remain unclear. We herein proposed that these radiobiological features are due to a common mechanism by which radiation suppresses homologous recombination repair (HRR) in a dose-dependent manner. This radio-suppression of HRR is mediated by an intra-S checkpoint and reduces survivals of cells in S phase, especially early S phase, resulting in both short shoulder and radioresistance with two peaks in the cell cycle. This new explanation may not be limited to HeLa cells since a similar close association of these features is also observed in other type of cells.

Published

2024

2. Induction of somatic mutations by low concentrations of tritiated water (HTO): evidence for the possible existence of a dose-rate threshold

Author

Nagashima, Haruki, Hayashi, Yuki, Sakamoto, Yuki, Komatsu, Kenshi, and Tauchi, Hiroshi

Abstract

Tritium is a low energy beta emitter and is discharged into the aquatic environment primarily in the form of tritiated water (HTO) from nuclear power plants or from nuclear fuel reprocessing plants. Although the biological effects of HTO exposures at significant doses or dose rates have been extensively studied, there are few reports concerning the biological effects of HTO exposures at very low dose rates. In the present study using a hyper-sensitive assay system, we investigated the dose rate effect of HTO on the induction of mutations. Confluent cell populations were exposed to HTO for a total dose of 0.2 Gy at dose rates between 4.9 mGy/day and 192 mGy/day by incubating cells in medium containing HTO. HTO-induced mutant frequencies and mutation spectra were then investigated. A significant inflection point for both the mutant frequency and mutation spectra was found between 11 mGy/day and 21.6 mGy/day. Mutation spectra analysis revealed that a mechanistic change in the nature of the mutation events occurred around 11 mGy/day. The present observations and published experimental results from oral administrations of HTO to mice suggest that a threshold dose-rate for HTO exposures might exist between 11 mGy/day and 21.6 mGy/day where the nature of the mutation events induced by HTO becomes similar to those seen in spontaneous events.

Published

2021

3. ATM-mediated mitochondrial damage response triggered by nuclear DNA damage in normal human lung fibroblasts

Author

Shimura, Tsutomu, Sasatani, Megumi, Kawai, Hidehiko, Kamiya, Kenji, Kobayashi, Junya, Komatsu, Kenshi, and Kunugita, Naoki

Abstract

ABSTRACTIonizing radiation (IR) elevates mitochondrial oxidative phosphorylation (OXPHOS) in response to the energy requirement for DNA damage responses. Reactive oxygen species (ROS) released during mitochondrial OXPHOS may cause oxidative damage to mitochondria in irradiated cells. In this paper, we investigated the association between nuclear DNA damage and mitochondrial damage following IR in normal human lung fibroblasts. In contrast to low-doses of acute single radiation, continuous exposure of chronic radiation or long-term exposure of fractionated radiation (FR) induced persistent Rad51 and γ-H2AX foci at least 24 hours after IR in irradiated cells. Additionally, long-term FR increased mitochondrial ROS accompanied with enhanced mitochondrial membrane potential (ΔΨm) and mitochondrial complex IV (cytochrome c oxidase) activity. Mitochondrial ROS released from the respiratory chain complex I caused oxidative damage to mitochondria. Inhibition of ATM kinase or ATM loss eliminated nuclear DNA damage recognition and mitochondrial radiation responses. Consequently, nuclear DNA damage activates ATM which in turn increases ROS level and subsequently induces mitochondrial damage in irradiated cells.In conclusion, we demonstrated that ATM is essential in the mitochondrial radiation responses in irradiated cells. We further demonstrated that ATM is involved in signal transduction from nucleus to the mitochondria in response to IR.

Published

2017

4. A comparison of radiation-induced mitochondrial damage between neural progenitor stem cells and differentiated cells

Author

Shimura, Tsutomu, Sasatani, Megumi, Kawai, Hidehiko, Kamiya, Kenji, Kobayashi, Junya, Komatsu, Kenshi, and Kunugita, Naoki

Abstract

ABSTRACTMitochondria play a key role in maintaining cellular homeostasis during stress responses, and mitochondrial dysfunction contributes to carcinogenesis, aging, and neurologic disease. We here investigated ionizing radiation (IR)-induced mitochondrial damage in human neural progenitor stem cells (NSCs), their differentiated counterparts and human normal fibroblasts. Long-term fractionated radiation (FR) with low doses of X-rays for 31 d enhanced mitochondrial activity as evident by elevated mitochondrial membrane potential (ΔΨm) and mitochondrial complex IV (cytochrome c oxidase) activity to fill the energy demands for the chronic DNA damage response in differentiated cells. Subsequent reduction of the antioxidant glutathione via continuous activation of mitochondrial oxidative phosphorylation caused oxidative stress and genomic instability in differentiated cells exposed to long-term FR. In contrast, long-term FR had no effect on the mitochondrial activity in NSCs. This cell type showed efficient DNA repair, no mitochondrial damage, and resistance to long-term FR. After high doses of acute single radiation (SR) (> 5 Gy), cell cycle arrest at the G2 phase was observed in NSCs and human fibroblasts. Under this condition, increase in mitochondria mass, mitochondrial DNA, and intracellular reactive oxygen species (ROS) levels were observed in the absence of enhanced mitochondrial activity. Consequently, cellular senescence was induced by high doses of SR in differentiated cells.In conclusion, we demonstrated that mitochondrial radiation responses differ according to the extent of DNA damage, duration of radiation exposure, and cell differentiation.

Published

2017

5. Severe mitochondrial damage associated with low-dose radiation sensitivity in ATM- and NBS1-deficient cells

Author

Shimura, Tsutomu, Kobayashi, Junya, Komatsu, Kenshi, and Kunugita, Naoki

Abstract

ABSTRACTLow-dose radiation risks remain unclear owing to a lack of sufficient studies. We previously reported that low-dose, long-term fractionated radiation (FR) with 0.01 or 0.05 Gy/fraction for 31 d inflicts oxidative stress in human fibroblasts due to excess levels of mitochondrial reactive oxygen species (ROS). To identify the small effects of low-dose radiation, we investigated how mitochondria respond to low-dose radiation in radiosensitive human ataxia telangiectasia mutated (ATM)- and Nijmegen breakage syndrome (NBS)1-deficient cell lines compared with corresponding cell lines expressing ATM and NBS1. Consistent with previous results in normal fibroblasts, low-dose, long-term FR increased mitochondrial mass and caused accumulation of mitochondrial ROS in ATM- and NBS1-complemented cell lines. Excess mitochondrial ROS resulted in mitochondrial damage that was in turn recognized by Parkin, leading to mitochondrial autophagy (mitophagy). In contrast, ATM- and NBS1-deficient cells showed defective induction of mitophagy after low-dose, long-term FR, leading to accumulation of abnormal mitochondria; this was determined by mitochondrial fragmentation and decreased mitochondrial membrane potential. Consequently, apoptosis was induced in ATM- and NBS1-deficient cells after low-dose, long-term FR. Antioxidant N-acetyl-L-cysteine was effective as a radioprotective agent against mitochondrial damage induced by low-dose, long-term FR among all cell lines, including radiosensitive cell lines. In conclusion, we demonstrated that mitochondria are target organelles of low-dose radiation. Mitochondrial response influences radiation sensitivity in human cells. Our findings provide new insights into cancer risk estimation associated with low-dose radiation exposure.

Published

2016

6. Nijmegen breakage syndrome and DNA double strand break repair by NBS1 complex.

Author

Matsuura, Shinya, Kobayashi, Junya, Tauchi, Hiroshi, and Komatsu, Kenshi

Abstract

The isolation of the NBS1 gene revealed the molecular mechanisms of DSB repair. In response to DNA damage, histone H2AX in the vicinity of DSBs is phosphorylated by ATM. NBS1 then targets the MRE11/RAD50 complex to the sites of DSBs through interaction of the FHA/BRCT domain with γ-H2AX. NBSI complex binds to damaged-DNA directly, and HR repair is initiated. To collaborate DSB repair, ATM also regulates cell cycle checkpoints at GI, G2, and intra-S phases via phosphorylation of SMC, CHK2 and FANCD2. The phosphorylation of these proteins require NBS1 complex. Thus, NBSI has at least two important roles in genome maintenance, as a DNA repair protein in HR pathway and as a signal modifier in intra-S phase checkpoints. NBSI is also known to be involved in maintenance of telomores, which have DSB-like structures and defects here can cause telomcric fusion. Therefore, NBS1 should be a multi-functional protein for the maintenance of genomic integrity. Further studies on NBS1 will provide insights into the mechanisms of DNA damage response and the network of these factors involved in genomic stability. [Copyright &y& Elsevier]

Published

2004

7. ATM regulates Cdt1 stability during the unperturbed S phase to prevent re-replication

Author

Iwahori, Satoko, Kohmon, Daisuke, Kobayashi, Junya, Tani, Yuhei, Yugawa, Takashi, Komatsu, Kenshi, Kiyono, Tohru, Sugimoto, Nozomi, and Fujita, Masatoshi

Abstract

Ataxia-telangiectasia mutated (ATM) plays crucial roles in DNA damage responses, especially with regard to DNA double-strand breaks (DSBs). However, it appears that ATM can be activated not only by DSB, but also by some changes in chromatin architecture, suggesting potential ATM function in cell cycle control. Here, we found that ATM is involved in timely degradation of Cdt1, a critical replication licensing factor, during the unperturbed S phase. At least in certain cell types, degradation of p27Kip1was also impaired by ATM inhibition. The novel ATM function for Cdt1 regulation was dependent on its kinase activity and NBS1. Indeed, we found that ATM is moderately phosphorylated at Ser1981 during the S phase. ATM silencing induced partial reduction in levels of Skp2, a component of SCFSkp2ubiquitin ligase that controls Cdt1 degradation. Furthermore, Skp2 silencing resulted in Cdt1 stabilization like ATM inhibition. In addition, as reported previously, ATM silencing partially prevented Akt phosphorylation at Ser473, indicative of its activation, and Akt inhibition led to modest stabilization of Cdt1. Therefore, the ATM-Akt-SCFSkp2pathway may partly contribute to the novel ATM function. Finally, ATM inhibition rendered cells hypersensitive to induction of re-replication, indicating importance for maintenance of genome stability.

Published

2014

8. Generation and Characterization of Severe Combined Immunodeficiency Rats

Author

Mashimo, Tomoji, Takizawa, Akiko, Kobayashi, Junya, Kunihiro, Yayoi, Yoshimi, Kazuto, Ishida, Saeko, Tanabe, Koji, Yanagi, Ami, Tachibana, Asato, Hirose, Jun, Yomoda, Jun-ichiro, Morimoto, Shiho, Kuramoto, Takashi, Voigt, Birger, Watanabe, Takeshi, Hiai, Hiroshi, Tateno, Chise, Komatsu, Kenshi, and Serikawa, Tadao

Abstract

Severe combined immunodeficiency (SCID) mice, the most widely used animal model of DNA-PKcs (Prkdc) deficiency, have contributed enormously to our understanding of immunodeficiency, lymphocyte development, and DNA-repair mechanisms, and they are ideal hosts for allogeneic and xenogeneic tissue transplantation. Here, we use zinc-finger nucleases to generate rats that lack either the Prkdcgene (SCID) or the Prkdcand Il2rggenes (referred to as F344-scid gamma[FSG] rats). SCID rats show several phenotypic differences from SCID mice, including growth retardation, premature senescence, and a more severe immunodeficiency without “leaky” phenotypes. Double-knockout FSG rats show an even more immunocompromised phenotype, such as the abolishment of natural killer cells. Finally, xenotransplantation of human induced pluripotent stem cells, ovarian cancer cells, and hepatocytes shows that SCID and FSG rats can act as hosts for xenogeneic tissue grafts and stem cell transplantation and may be useful for preclinical testing of new drugs.

Published

2012

9. Genistein, isoflavonoids in soybeans, prevents the formation of excess radiation-induced centrosomes via p21 up-regulation

Author

Shimada, Mikio, Kato, Akihiro, Habu, Toshiyuki, and Komatsu, Kenshi

Abstract

► The extra centrosomes were induced in cells treated with eight genotoxic agents. ► These agents were divided into two categories with respect to the regulation of p21. ► The extra centrosomes were modulated by p21-mediated CDK2/4 kinase activity. ► Genistein suppressed the excess radiation-induced centrosomes via p21 up-regulation.

Published

2011

10. Possible Role of WRN Protein in Cellular Response Induced by a Little DNA Damage

Author

Kobayashi, Junya, Okui, Michiyo, Komatsu, Kenshi, and Chen, David J.

Abstract

AbstractWerner syndrome (WS) is an autosomal recessive disorder associated with premature aging and cancer predisposition caused by mutations at the WRN gene. Several recent reports suggest that accumulation of DNA damage could lead to premature cellular aging. Therefore, WRN might function in DNA damage response, particularly DNA repair. Here, we investigated the role of WRN in DNA repair and genome integrity. WRN protein rapidly accumulated at DNA damage sites and formed discrete nuclear foci only during S phase, but not in G1 phase. WRN-defective WS cells showed the spontaneous accumulation of γ-H2AX (DSB marker), suggesting that WRN could function to repair the S phase-dependent DNA damage. However, WS cells showed homologous recombination (HR) at normal level, although HR repair functions preferentially during the S phase. Translesion DNA synthesis (TLS) is known as another repair pathway for S phase-dependent DNA damage. WS cells exhibit an increase in spontaneous focus formation of polη and Rad18, which are important for TLS regulation. WS cells also showed the spontaneous ubiquitination of PCNA and increased polη-related gene mutation. Taken together, WRN could work for the regulation of TLS pathway and might also be important to maintain genome integrity under a little DNA damage by tritium.

Published

2011

11. Assessment of Biological Effect of Tritiated Water by Using Hypersensitive System

Author

Tauchi, Hiroshi, Imamura, Hiroto, Inoue, Masanao, Komatsu, Kenshi, and Tachibana, Akira

Abstract

AbstractAn exposure of human or animals to tritium radiation from nuclear fusion reactor is expected to be a low dose and with low dose-rate. We are focusing on the biological effects of tritiated water (HTO) given at low dose and/or with low dose rate. Hypersensitive assay systems for radiation biological experiments using cultured mammalian cells or transgenic mice have been established and their availability for assessment of biological effects of HTO were tested. A hypersensitive detection system for mutagenesis at Hprt locus was established by using hamster cells carrying a human X-chromosome. The cells present more than 50-fold sensitivity for Hprt-deficient mutation, and this allowed us to detect a significant elevation of mutation frequency by radiations at the dose of less than 0.2 Gy.Because the reverse dose rate effect has been reported for mutation induction by high LET radiation such as neutrons, we first tested whether the reverse dose rate effects could be seen for HTO (tritium beta-rays) or not. No significant change in mutation frequency by HTO was observed in the range of dose rates between 0.05 cGy/h and 2.0 cGy/h, whereas clear reverse dose rate effects was observed in the case of fission neutrons or carbon beam. The result suggests that the reverse dose rate effect does not apply in the case of mutation induction by HTO. In addition, mutation spectrum in the mutants induced by HTO was similar to those in spontaneously induced mutants, suggesting that exposure to a certain level of HTO could enhance the spontaneous mutagenesis.

Published

2011

12. Two major factors involved in the reverse dose-rate effect for somatic mutation induction are the cell cycle position and LET value.

Author

Tauchi, Hiroshi, Waku, Hiroyuki, Matsumoto, Eigo, Yara, Sayaka, Okumura, Shino, Iwata, Yoshiyuki, Komatsu, Kenshi, Furusawa, Yoshiya, Eguchi-Kasai, Kiyomi, and Tachibana, Akira

Abstract

To study mechanisms which could be involved in the reverse dose rate effect observed during mutation induction after exposure to high LET radiation, synchronized mouse L5178Y cells were exposed to carbon 290 MeV/n beams with different LET values at the G2/M, G1, G1/S or S phases in the cell cycle. The frequency of Hprt-deficient (6-thioguanine-resistant) mutant induction was subsequently determined. The results showed that after exposure to high LET value radiation (50.8 and 76.5 keV/microm), maximum mutation frequencies were seen at the G2/M phase, but after exposure to lower LET radiation (13.3 keV/microm), the highest mutation frequencies were observed at the G1 phase. The higher LET beam always produced higher mutation frequencies in the G2/M phase than in the G1 phase, regardless of radiation dose. These results suggest that cells in the G2/M phase is hyper-sensitive for mutation induction from high LET radiation, but not to mutation induction from low LET radiation. Molecular analysis of mutation spectra showed that large deletions (which could include almost entire exons) of the mouse Hprt gene were most efficiently induced in G2/M cells irradiated with high LET radiation. These entire exon deletions were not as frequent in cells exposed to lower LET radiation. This suggests that inappropriate recombination repair might have occurred in response to condensed damage in condensed chromatin in the G2/M phase. In addition, by using a hyper-sensitive mutation detection system (GM06318-10 cells), a reverse dose-rate effect was clearly observed after exposure to carbon beams with higher LET values (66 keV/microm), but not after exposure to beams with lower LET values (13.3 keV/microm). Thus, G2/M sensitivity towards mutation induction, and the dependence on radiation LET values could both be major factors involved in the reverse dose rate effect produced by high LET radiation.

Published

2009

13. Emerging connection between centrosome and DNA repair machinery.

Author

Shimada, Mikio and Komatsu, Kenshi

Abstract

Centrosomes function in proper cell division in animal cells. The centrosome consists of a pair of centrioles and the surrounding pericentriolar matrix (PCM). After cytokinesis, daughter cells each acquire one centrosome, which subsequently duplicates at the G1/S phase in a manner that is dependent upon CDK2/cyclin-E activity. Defects in the regulation of centrosome duplication lead to tumorigenesis through abnormal cell division and resulting inappropriate chromosome segregation. Therefore, maintenance of accurate centrosome number is important for cell fate. Excess number of centrosomes can be induced by several factors including ionizing radiation (IR). Recent studies have shown that several DNA repair proteins localize to the centrosome and are involved in the regulation of centrosome number possibly through cell cycle checkpoints or direct modification of centrosome proteins. Furthermore, it has been reported that the development of microcephaly is likely caused by defective expression of centrosome proteins, such as ASPM, which are also involved in the response to IR. The present review highlights centrosome duplication in association with genotoxic stresses and the regulatory mechanism mediated by DNA repair proteins.Translated and modified from Radiat. Biol. Res. Comm. Vol.43; 343-356 (2008.12, in Japanese).

Published

2009

14. Monoallelic BUB1B mutations and defective mitotic‐spindle checkpoint in seven families with premature chromatid separation (PCS) syndrome

Author

Matsuura, Shinya, Matsumoto, Yoshiyuki, Morishima, Ken‐ichi, Izumi, Hideki, Matsumoto, Hiroshi, Ito, Emi, Tsutsui, Keisuke, Kobayashi, Junya, Tauchi, Hiroshi, Kajiwara, Yoshinori, Hama, Seiji, Kurisu, Kaoru, Tahara, Hidetoshi, Oshimura, Mitsuo, Komatsu, Kenshi, Ikeuchi, Tatsuro, and Kajii, Tadashi

Abstract

Cancer‐prone syndrome of premature chromatid separation (PCS syndrome) with mosaic variegated aneuploidy (MVA) is a rare autosomal recessive disorder characterized by growth retardation, microcephaly, childhood cancer, premature chromatid separation of all chromosomes, and mosaicism for various trisomies and monosomies. Biallelic BUB1B mutations were recently reported in five of eight families with MVA syndrome (probably identical to the PCS syndrome). We here describe molecular analysis of BUB1B (encoding BubR1) in seven Japanese families with the PCS syndrome. Monoallelic BUB1B mutations were found in all seven families studied: a single‐base deletion (1833delT) in four families; and a splice site mutation, a nonsense mutation, and a missense mutation in one family each. Transcripts derived from the patients with the 1833delT mutation and the splice site mutation were significantly reduced, probably due to nonsense‐mediated mRNA decay. No mutation was found in the second alleles in the seven families studied, but RT‐PCR of BUB1B and Western blot analysis of BubR1 indicated a modest decrease of their transcripts. BubR1 in the cells from two patients showed both reduced protein expression and diminished kinetochore localization. Their expression level of p55cdc, a specific activator of anaphase‐promoting complex, was normal but its kinetochore association was abolished. Microcell‐mediated transfer of chromosome 15 (containing BUB1B) into the cells restored normal BubR1 levels, kinetochore localization of p55cdc, and the normal responses to colcemid treatment. These findings indicate the involvement of BubR1 in p55cdc‐mediated mitotic checkpoint signaling, and suggest that >50% decrease in expression (or activity) of BubR1 is involved in the PCS syndrome. © 2006 Wiley‐Liss, Inc.

Published

2006

15. No induction of p53 phosphorylation and few focus formation of phosphorylated H2AX suggest efficient repair of DNA damage during chronic low-dose-rate irradiation in human cells.

Author

Ishizaki, Kanji, Hayashi, Yuko, Nakamura, Hideaki, Yasui, Yoshihiro, Komatsu, Kenshi, and Tachibana, Akira

Abstract

Human fibroblast cells obtained from a normal individual and immortalized by introduction of the hTERT gene were irradiated with 0 to 5 Gy of acute high-dose-rate radiation (1.8 Gy/min) or chronic low-dose-rate radiation (0.3 mGy/min) in the G0 phase, and p53 activation was studied. After high-dose-rate irradiation, a dose-dependent induction of Ser15 phosphorylation was observed, whereas after low-dose-rate irradiation almost none was observed. Then we analyzed the focus formation of phosphorylated histone H2AX protein, which is closely correlated with the induction of double-strand breaks. High-dose-rate radiation induced a significant number of foci in a dose-dependent manner, whereas, low-dose-rate radiation could induce only a few foci even at the highest dose. These results strongly suggest that DNA damage induced by low-dose-rate radiation such as a double-strand break is efficiently repaired during chronic irradiation.

Published

2004

16. Studies of Mutagenesis Caused by Low Dose Rate Tritium Radiation Using a Novel Hyper-Sensitive Detection System

Author

Tauchia, Hiroshi, Ichimasa, Michiko, Ichimasa, Yusuke, Shiraishi, Takahiro, Morishima, Kenichi, Matsuura, Shinya, and Komatsu, Kenshi

Abstract

ABSTRACTA novel hyper-sensitive detection system was developed to detect Hprt-deficient mutations using Hprt deficient hamster fibroblast cells which carry a normal human X-chromosome. The system has been found to be 100-fold more sensitive for detecting mutations than the conventional system which uses an internal Hprtgene. The mutation frequency induced by 1 Gy of tritium radiation at different dose rates (0.9, 0.4, 0.04, and 0.018 Gy/h) was measured. No significant differences in mutation frequencies were observed within the range of dose rates used, suggesting that if a reverse dose-rate effect exists, it may not be observable with tritium radiation at dose rates over 0.018 Gy/h. Interestingly, molecular analysis of the Hprtlocus in Hprt-deficient mutants induced by tritium showed that deletion sizes observed in the hamster cell’s human X-chromosome under these conditions are much smaller in cells exposed at 0.04 (and 0.018 Gy/h) than in cells exposed at 0.9 Gy/h. This phenomenon seems to be specific for tritium radiation because it was not apparent after exposure to γ-rays. The novel hyper-sensitive detection system used here is useful for analysis of the mutagenic effects of low doses of tritium radiation delivered at low dose rates.

Published

2002

17. Chk2 Activation Dependence on Nbs1 after DNA Damage

Author

Buscemi, Giacomo, Savio, Camilla, Zannini, Laura, Miccichè, Francesca, Masnada, Debora, Nakanishi, Makoto, Tauchi, Hiroshi, Komatsu, Kenshi, Mizutani, Shuki, Khanna, KumKum, Chen, Phil, Concannon, Patrick, Chessa, Luciana, and Delia, Domenico

Abstract

The checkpoint kinase Chk2 has a key role in delaying cell cycle progression in response to DNA damage. Upon activation by low-dose ionizing radiation (IR), which occurs in an ataxia telangiectasia mutated (ATM)-dependent manner, Chk2 can phosphorylate the mitosis-inducing phosphatase Cdc25C on an inhibitory site, blocking entry into mitosis, and p53 on a regulatory site, causing G1arrest. Here we show that the ATM-dependent activation of Chk2 by γ- radiation requires Nbs1, the gene product involved in the Nijmegen breakage syndrome (NBS), a disorder that shares with AT a variety of phenotypic defects including chromosome fragility, radiosensitivity, and radioresistant DNA synthesis. Thus, whereas in normal cells Chk2 undergoes a time-dependent increased phosphorylation and induction of catalytic activity against Cdc25C, in NBS cells null for Nbs1 protein, Chk2 phosphorylation and activation are both defective. Importantly, these defects in NBS cells can be complemented by reintroduction of wild-type Nbs1, but neither by a carboxy-terminal deletion mutant of Nbs1 at amino acid 590, unable to form a complex with and to transport Mre11 and Rad50 in the nucleus, nor by an Nbs1 mutated at Ser343 (S343A), the ATM phosphorylation site. Chk2 nuclear expression is unaffected in NBS cells, hence excluding a mislocalization as the cause of failed Chk2 activation in Nbs1-null cells. Interestingly, the impaired Chk2 function in NBS cells correlates with the inability, unlike normal cells, to stop entry into mitosis immediately after irradiation, a checkpoint abnormality that can be corrected by introduction of the wild-type but not the S343A mutant form of Nbs1. Altogether, these findings underscore the crucial role of a functional Nbs1 complex in Chk2 activation and suggest that checkpoint defects in NBS cells may result from the inability to activate Chk2.

Published

2001

18. Chk2 Activation Dependence on Nbs1 after DNA Damage

Author

Buscemi, Giacomo, Savio, Camilla, Zannini, Laura, Miccichè, Francesca, Masnada, Debora, Nakanishi, Makoto, Tauchi, Hiroshi, Komatsu, Kenshi, Mizutani, Shuki, Khanna, KumKum, Chen, Phil, Concannon, Patrick, Chessa, Luciana, and Delia, Domenico

Abstract

ABSTRACTThe checkpoint kinase Chk2 has a key role in delaying cell cycle progression in response to DNA damage. Upon activation by low-dose ionizing radiation (IR), which occurs in an ataxia telangiectasia mutated (ATM)-dependent manner, Chk2 can phosphorylate the mitosis-inducing phosphatase Cdc25C on an inhibitory site, blocking entry into mitosis, and p53 on a regulatory site, causing G1arrest. Here we show that the ATM-dependent activation of Chk2 by γ- radiation requires Nbs1, the gene product involved in the Nijmegen breakage syndrome (NBS), a disorder that shares with AT a variety of phenotypic defects including chromosome fragility, radiosensitivity, and radioresistant DNA synthesis. Thus, whereas in normal cells Chk2 undergoes a time-dependent increased phosphorylation and induction of catalytic activity against Cdc25C, in NBS cells null for Nbs1 protein, Chk2 phosphorylation and activation are both defective. Importantly, these defects in NBS cells can be complemented by reintroduction of wild-type Nbs1, but neither by a carboxy-terminal deletion mutant of Nbs1 at amino acid 590, unable to form a complex with and to transport Mre11 and Rad50 in the nucleus, nor by an Nbs1 mutated at Ser343 (S343A), the ATM phosphorylation site. Chk2 nuclear expression is unaffected in NBS cells, hence excluding a mislocalization as the cause of failed Chk2 activation in Nbs1-null cells. Interestingly, the impaired Chk2 function in NBS cells correlates with the inability, unlike normal cells, to stop entry into mitosis immediately after irradiation, a checkpoint abnormality that can be corrected by introduction of the wild-type but not the S343A mutant form of Nbs1. Altogether, these findings underscore the crucial role of a functional Nbs1 complex in Chk2 activation and suggest that checkpoint defects in NBS cells may result from the inability to activate Chk2.

Published

2001

19. The Forkhead-associated Domain of NBS1 Is Essential for Nuclear Foci Formation after Irradiation but Not Essential for hRAD50·hMRE11·NBS1 Complex DNA Repair Activity*

Author

Tauchi, Hiroshi, Kobayashi, Junya, Morishima, Ken-ichi, Matsuura, Shinya, Nakamura, Asako, Shiraishi, Takahiro, Ito, Emi, Masnada, Debora, Delia, Domenico, and Komatsu, Kenshi

Abstract

NBS1 (p95), the protein responsible forNijmegen breakage syndrome, shows a weak homology to the yeast Xrs2 protein at the N terminus region, known as the forkhead-associated (FHA) domain and the BRCA1 C terminus domain. The protein interacts with hMRE11 to form a complex with a nuclease activity for initiation of both nonhomologous end joining and homologous recombination. Here, we show in vivodirect evidence that NBS1 recruits the hMRE11 nuclease complex into the cell nucleus and leads to the formation of foci by utilizing different functions from several domains. The amino acid sequence at 665–693 on the C terminus of NBS1, where a novel identical sequence with yeast Xrs2 protein was found, is essential for hMRE11 binding. The hMRE11-binding region is necessary for both nuclear localization of the complex and for cellular radiation resistance. On the other hand, the FHA domain regulates nuclear foci formation of the multiprotein complex in response to DNA damage but is not essential for nuclear transportation of the complex and radiation resistance. Because the FHA/BRCA1 C terminus domain is widely conserved in eukaryotic nuclear proteins related to the cell cycle, gene regulation, and DNA repair, the foci formation could be associated with many phenotypes of Nijmegen breakage syndrome other than radiation sensitivity.

Published

2001

20. Expression of Full-Length NBS1 Protein Restores Normal Radiation Responses in Cells from Nijmegen Breakage Syndrome Patients

Author

Ito, Atsushi, Tauchi, Hiroshi, Kobayashi, Junya, Morishima, Kenichi, Nakamura, Asako, Hirokawa, Yutaka, Matsuura, Shinya, Ito, Katsuhide, and Komatsu, Kenshi

Abstract

Cells from Nijmegen breakage syndrome (NBS) display multiple phenotypes, such as chromosomal instability, hypersensitivity to cell killing from ionizing radiation, and possibly abnormal cell cycle checkpoints. NBS1, a gene mutated in NBS patients, appears to encode a possible repair protein, which could form the foci of a sensor-like molecular complex capable of detecting DNA double strand breaks, however, it has no kinase domain for signaling DNA damage. Here, we report that the stable expression of NBS1 cDNA in NBS cells after transfection results in the complete restoration of foci formation in the nucleus, and in normal cell survival after irradiation. The prolonged G2 block observed after irradiation was also abolished by expression of NBS1, providing additional confirmation that the G2 checkpoint is abrogated in NBS cells. These results suggest that a defective NBS1 protein could be the sole cause of the NBS phenotype, and that NBS1 likely interacts with another protein(s) to produce the entire range of NBS phenotypic expression.

Published

1999

21. Radiation Induction of p53 in Cells from Nijmegen Breakage Syndrome Is Defective but Not Similar to Ataxia-Telangiectasia

Author

Matsuura, Kanji, Balmukhanov, Timur, Tauchi, Hiroshi, Weemaes, Corry, Smeets, Domique, Chrzanowska, Krystyna, Endou, Satoru, Matsuura, Shinnya, and Komatsu, Kenshi

Abstract

p53-mediated signal transduction after exposure to ionizing radiation was examined in cells from patients with Nijmegen breakage syndrome (NBS), an autosomal recessive disease characterized by microcephaly, immunodeficiency, predisposition to malignancy, and a high sensitivity to ionizing radiation. NBS cells accumulated p53 protein in a dose-dependent fashion, with a peak level 2 hrs after irradiation with 5 Gy. However, the maximal level of p53 protein in NBS cells was constantly lower than in normal cells. Moreover, this attenuation of p53 induction was confirmed by decreased levels of p21WAF1protein, which is transcriptionally regulated by p53 protein. This defective induction of p53 protein in NBS is similar to that in ataxia-telangiectasia (AT), although the induced levels of p53 protein in NBS appeared to be the intermediate between normal cells and AT cells. This moderate p53 induction in NBS cells is consistent with the relatively mild radiation sensitivity and the abnormal cell cycle regulation post-irradiation, as present in NBS. Furthermore, all NBS cell lines used here exhibited time courses of p53 induction similar to normal cells, which is in contrast with p53 induction in AT cells, where the maximum induction shows a delay of approximately 2 hrs compared with normal cells. These evidences suggest a different function of each gene product in an upstream p53 response to radiation-induced DNA damage.

Published

1998

22. Fine Localization of the Nijmegen Breakage Syndrome Gene to 8q21: Evidence for a Common Founder Haplotype

Author

Cerosaletti, Karen M., Lange, Ethan, Stringham, Heather M., Weemaes, Corry M.R., Smeets, Dominique, Sölder, B., Belohradsky, B.H., Taylor, A. Malcolm R., Karnes, Pamela, Elliott, Alison, Komatsu, Kenshi, Gatti, Richard A., Boehnke, Michael, and Concannon, Pat

Abstract

Nijmegen breakage syndrome (NBS) is a rare autosomal recessive disorder characterized by microcephaly, a birdlike face, growth retardation, immunodeficiency, lack of secondary sex characteristics in females, and increased incidence of lymphoid cancers. NBS cells display a phenotype similar to that of cells from ataxia-telangiectasia patients, including chromosomal instability, radiation sensitivity, and aberrant cell-cycle–checkpoint control following exposure to ionizing radiation. A recent study reported genetic linkage of NBS to human chromosome 8q21, with strong linkage disequilibrium detected at marker D8S1811 in eastern European NBS families. We collected a geographically diverse group of NBS families and tested them for linkage, using an expanded panel of markers at 8q21. In this article, we report linkage of NBS to 8q21 in 6/7 of these families, with a maximum LOD score of 3.58. Significant linkage disequilibrium was detected for 8/13 markers tested in the 8q21 region, including D8S1811. In order to further localize the gene for NBS, we generated a radiation-hybrid map of markers at 8q21 and constructed haplotypes based on this map. Examination of disease haplotypes segregating in 11 NBS pedigrees revealed recombination events that place the NBS gene between D8S1757 and D8S270. A common founder haplotype was present on 15/18 disease chromosomes from 9/11 NBS families. Inferred (ancestral) recombination events involving this common haplotype suggest that NBS can be localized further, to an interval flanked by markers D8S273 and D8S88.

Published

1998

23. Sequence Analysis of an 800-kb Genomic DNA Region on Chromosome 8q21 That Contains the Nijmegen Breakage Syndrome Gene,NBS1

Author

Tauchi, Hiroshi, Matsuura, Shinya, Isomura, Minoru, Kinjo, Takao, Nakamura, Asako, Sakamoto, Shuichi, Kondo, Noriko, Endo, Satoru, Komatsu, Kenshi, and Nakamura, Yusuke

Abstract

An 800-kb region on chromosome 8q21, which complements the phenotype of cells from Nijmegen breakage syndrome patients, is a candidate for the locus of the underlying gene, termedNBS1.The sequence of this 800-kb region of DNA indicated that the size of this segment is 755,832 bp with an additional 36-kb gap. From this region, we identified four genes includingNBS1,a gene coding for a 27-kDa vitamin D-dependent calcium-binding protein (27-kDa calbindin), the mitochondrial 2,4-dienoyl-CoA reductase gene, and a novel gene,C8orf1/hT41.All four genes were aligned in a 250-kb centromeric portion of the region, and no gene was found in the remaining telomeric portion containing 500 kb. The genomic organization of theC8orf1/hT41andNBS1genes has been analyzed using the computer programs GRAIL 2 and GENSCAN. They predicted and successfully found more than 93% of the exons, even a small 54-bp exon, indicating that one or more exons in any gene can be identified by these programs. GENSCAN was more efficient at locating the four genes than GRAIL 2 and identified 15 of the 16 exons of theNBS1gene. This 800-kb region contained repetitive sequences, including 179 copies of theAlusequence (1 copy/4.2 kb), 123 copies of the L1 sequence (1 copy/6.1 kb), 107 copies of the LTR sequence (1 copy/7.1 kb), and 63 copies of the MER sequence (1 copy/12 kb). There was a slight but not significant difference in the repetitive content of the gene-rich region and the remaining noncoding region. Our results indicate that computer-assisted methods are useful and powerful for identifying exons of both known and novel genes.

Published

1999

24. NBS1 and multiple regulations of DNA damage response

Author

Komatsu, Kenshi

Abstract

DNA damage response is finely tuned, with several pathways including those for DNA repair, chromatin remodeling and cell cycle checkpoint, although most studies to date have focused on single pathways. Genetic diseases characterized by genome instability have provided novel insights into the underlying mechanisms of DNA damage response. NBS1, a protein responsible for the radiation-sensitive autosomal recessive disorder Nijmegen breakage syndrome, is one of the first factors to accumulate at sites of DNA double-strand breaks (DSBs). NBS1 binds to at least five key proteins, including ATM, RPA, MRE11, RAD18 and RNF20, in the conserved regions within a limited span of the C terminus, functioning in the regulation of chromatin remodeling, cell cycle checkpoint and DNA repair in response to DSBs. In this article, we reviewed the functions of these binding proteins and their comprehensive association with NBS1.

Published

2016

25. Mutations in the FHA-domain of ectopically expressed NBS1 lead to radiosensitization and to no increase in somatic mutation rates via a partial suppression of homologous recombination

Author

Ohara, Maki, Funyu, Yumi, Ebara, Shunsuke, Sakamoto, Yuki, Seki, Ryota, Iijima, Kenta, Ohishi, Akiko, Kobayashi, Junya, Komatsu, Kenshi, Tachibana, Akira, and Tauchi, Hiroshi

Abstract

Ionizing radiation induces DNA double-strand breaks (DSBs). Mammalian cells repair DSBs through multiple pathways, and the repair pathway that is utilized may affect cellular radiation sensitivity. In this study, we examined effects on cellular radiosensitivity resulting from functional alterations in homologous recombination (HR). HR was inhibited by overexpression of the forkhead-associated (FHA) domain-mutated NBS1 (G27D/R28D: FHA-2D) protein in HeLa cells or in hamster cells carrying a human X-chromosome. Cells expressing FHA-2D presented partially (but significantly) HR-deficient phenotypes, which were assayed by the reduction of gene conversion frequencies measured with a reporter assay, a decrease in radiation-induced Mre11 foci formation, and hypersensitivity to camptothecin treatments. Interestingly, ectopic expression of FHA-2D did not increase the frequency of radiation-induced somatic mutations at the HPRT locus, suggesting that a partial reduction of HR efficiency has only a slight effect on genomic stability. The expression of FHA-2D rendered the exponentially growing cell population slightly (but significantly) more sensitive to ionizing radiation. This radiosensitization effect due to the expression of FHA-2D was enhanced when the cells were irradiated with split doses delivered at 24-h intervals. Furthermore, enhancement of radiation sensitivity by split dose irradiation was not seen in contact-inhibited G0/G1 populations, even though the cells expressed FHA-2D. These results suggest that the FHA domain of NBS1 might be an effective molecular target that can be used to induce radiosensitization using low molecular weight chemicals, and that partial inhibition of HR might improve the effectiveness of cancer radiotherapy.

Published

2014

26. Editorial

Author

Komatsu, Kenshi

Published

2014

27. Radiation dose to mouse liver cells from ingestion of tritiated foodor water

Author

Komatsu, Kenshi, Okumura, Yutaka, and Sakamoto, Kiyohiko

Subjects

JAPAN

Published

1990