Your search keyword '"Agama, Keli"' showing total 5 results

1. ALC1/CHD1L, chromatin-remodeling enzyme, is required for efficient base excision repair

Author

Tsuda, Masataka, Cho, Kosai, Ooka, Masato, Shimizu, Naoto, Watanabe, Reiko, Yasui, Akira, Nakazawa, Yuka, Ogi, Tomoo, Harada, Hiroshi, Agama, Keli, Nakamura, Jun, Asada, Ryuta, Fujiike, Haruna, Sakuma, Tetsushi, Yamamoto, Takashi, Murai, Junko, Hiraoka, Masahiro, Koike, Kaoru, Pommier, Yves, Takeda, Shunichi, Hirota, Kouji, Tsuda, Masataka, Cho, Kosai, Ooka, Masato, Shimizu, Naoto, Watanabe, Reiko, Yasui, Akira, Nakazawa, Yuka, Ogi, Tomoo, Harada, Hiroshi, Agama, Keli, Nakamura, Jun, Asada, Ryuta, Fujiike, Haruna, Sakuma, Tetsushi, Yamamoto, Takashi, Murai, Junko, Hiraoka, Masahiro, Koike, Kaoru, Pommier, Yves, Takeda, Shunichi, and Hirota, Kouji

Abstract

type:text, ALC1/CHD1L is a member of the SNF2 superfamily of ATPases carrying a macrodomain that binds poly(ADP-ribose). Poly(ADP-ribose) polymerase (PARP) 1 and 2 synthesize poly(ADP-ribose) at DNA-strand cleavage sites, promoting base excision repair (BER). Although depletion of ALC1 causes increased sensitivity to various DNA-damaging agents (H2O2, UV, and phleomycin), the role played by ALC1 in BER has not yet been established. To explore this role, as well as the role of ALC1’s ATPase activity in BER, we disrupted the ALC1 gene and inserted the ATPase-dead (E165Q) mutation into the ALC1 gene in chicken DT40 cells, which do not express PARP2. The resulting ALC1-/- and ALC1-/E165Q cells displayed an indistinguishable hypersensitivity to methylmethane sulfonate (MMS), an alkylating agent, and to H2O2, indicating that ATPase plays an essential role in the DNA-damage response. PARP1-/- and ALC1-/-/PARP1-/- cells exhibited a very similar sensitivity to MMS, suggesting that ALC1 and PARP1 collaborate in BER. Following pulse-exposure to H2O2, PARP1-/- and ALC1-/-/PARP1-/- cells showed similarly delayed kinetics in the repair of single-strand breaks, which arise as BER intermediates. To ascertain ALC1’s role in BER in mammalian cells, we disrupted the ALC1 gene in human TK6 cells. Following exposure to MMS and to H2O2, the ALC1-/- TK6 cell line showed a delay in single-strand-break repair. We therefore conclude that ALC1 plays a role in BER. Following exposure to H2O2, ALC1-/- cells showed compromised chromatin relaxation. We thus propose that ALC1 is a unique BER factor that functions in a chromatin context, most likely as a chromatin-remodeling enzyme., This work was supported by the JSPS KAKENHI Grant Number (JP16K12598, JP16H02957 and JP16H01314 to KH, JP16H06306 to ST and JP16J02252 to RA), the JSPS Core-to-Core Program (A) Advanced Research Networks (to ST), the Takeda Science Foundation and Yamada Science Foundation (to KH), and the Center for Cancer Research, Intramural Program of the US National Cancer Institute (Z01 BC 006150 to KA and YP). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Published

2017

2. ALC1/CHD1L, a chromatin-remodeling enzyme, is required for efficient base excision repair.

Author

Tsuda, Masataka, Cho, Kosai, Ooka, Masato, Shimizu, Naoto, Watanabe, Reiko, Yasui, Akira, Nakazawa, Yuka, Ogi, Tomoo, Harada, Hiroshi, Agama, Keli, Nakamura, Jun, Asada, Ryuta, Fujiike, Haruna, Sakuma, Tetsushi, Yamamoto, Takashi, Murai, Junko, Hiraoka, Masahiro, Koike, Kaoru, Pommier, Yves, and Takeda, Shunichi

Subjects

CHROMATIN-remodeling complexes, LIVER cancer, RIBOSE, DNA repair, POLYMERASE genetics

Abstract

ALC1/CHD1L is a member of the SNF2 superfamily of ATPases carrying a macrodomain that binds poly(ADP-ribose). Poly(ADP-ribose) polymerase (PARP) 1 and 2 synthesize poly(ADP-ribose) at DNA-strand cleavage sites, promoting base excision repair (BER). Although depletion of ALC1 causes increased sensitivity to various DNA-damaging agents (H2O2, UV, and phleomycin), the role played by ALC1 in BER has not yet been established. To explore this role, as well as the role of ALC1’s ATPase activity in BER, we disrupted the ALC1 gene and inserted the ATPase-dead (E165Q) mutation into the ALC1 gene in chicken DT40 cells, which do not express PARP2. The resulting ALC1-/- and ALC1-/E165Q cells displayed an indistinguishable hypersensitivity to methylmethane sulfonate (MMS), an alkylating agent, and to H2O2, indicating that ATPase plays an essential role in the DNA-damage response. PARP1-/- and ALC1-/-/PARP1-/- cells exhibited a very similar sensitivity to MMS, suggesting that ALC1 and PARP1 collaborate in BER. Following pulse-exposure to H2O2, PARP1-/- and ALC1-/-/PARP1-/- cells showed similarly delayed kinetics in the repair of single-strand breaks, which arise as BER intermediates. To ascertain ALC1’s role in BER in mammalian cells, we disrupted the ALC1 gene in human TK6 cells. Following exposure to MMS and to H2O2, the ALC1-/- TK6 cell line showed a delay in single-strand-break repair. We therefore conclude that ALC1 plays a role in BER. Following exposure to H2O2, ALC1-/- cells showed compromised chromatin relaxation. We thus propose that ALC1 is a unique BER factor that functions in a chromatin context, most likely as a chromatin-remodeling enzyme. [ABSTRACT FROM AUTHOR]

Published

2017

3. Exploring DNA Topoisomerase I Ligand Space in Search of Novel Anticancer Agents.

Author

Drwal, Malgorzata N., Agama, Keli, Wakelin, Laurence P. G., Pommier, Yves, and Griffith, Renate

Subjects

*DNA topoisomerase I, *LIGANDS (Biochemistry), *ANTINEOPLASTIC agents, *TARGETED drug delivery, *CANCER chemotherapy, *ENZYME activation, *ENZYME inhibitors, *CELL-mediated cytotoxicity

Abstract

DNA topoisomerase I (Top1) is over-expressed in tumour cells and is an important target in cancer chemotherapy. It relaxes DNA torsional strain generated during DNA processing by introducing transient single-strand breaks and allowing the broken strand to rotate around the intermediate Top1 - DNA covalent complex. This complex can be trapped by a group of anticancer agents interacting with the DNA bases and the enzyme at the cleavage site, preventing further topoisomerase activity. Here we have identified novel Top1 inhibitors as potential anticancer agents by using a combination of structureand ligand-based molecular modelling methods. Pharmacophore models have been developed based on the molecular characteristics of derivatives of the alkaloid camptothecin (CPT), which represent potent antitumour agents and the main group of Top1 inhibitors. The models generated were used for in silico screening of the National Cancer Institute (NCI, USA) compound database, leading to the identification of a set of structurally diverse molecules. The strategy is validated by the observation that amongst these molecules are several known Top1 inhibitors and agents cytotoxic against human tumour cell lines. The potential of the untested hits to inhibit Top1 activity was further evaluated by docking into the binding site of a Top1 - DNA complex, resulting in a selection of 10 compounds for biological testing. Limited by the compound availability, 7 compounds have been tested in vitro for their Top1 inhibitory activity, 5 of which display mild to moderate Top1 inhibition. A further compound, found by similarity search to the active compounds, also shows mild activity. Although the tested compounds display only low in vitro antitumour activity, our approach has been successful in the identification of structurally novel Top1 inhibitors worthy of further investigation as potential anticancer agents. Ci [ABSTRACT FROM AUTHOR]

Published

2011

4. Collaborative Action of Brca1 and CtIP in Elimination of Covalent Modifications from Double-Strand Breaks to Facilitate Subsequent Break Repair.

Author

Nakamura, Kyoko, Kogame, Toshiaki, Oshiumi, Hiroyuki, Shinohara, Akira, Sumitomo, Yoshiki, Agama, Keli, Pommier, Yves, Tsutsui, Kimiko M., Tsutsui, Ken, Hartsuiker, Edgar, Ogi, Tomoo, Takeda, Shunichi, and Taniguchi, Yoshihito

Subjects

DNA topoisomerases, CAMPTOTHECIN, ETOPOSIDE, CANCER treatment, NUCLEASES, DNA repair

Abstract

Topoisomerase inhibitors such as camptothecin and etoposide are used as anti-cancer drugs and induce double-strand breaks (DSBs) in genomic DNA in cycling cells. These DSBs are often covalently bound with polypeptides at the 3′ and 5′ ends. Such modifications must be eliminated before DSB repair can take place, but it remains elusive which nucleases are involved in this process. Previous studies show that CtIP plays a critical role in the generation of 3′ single-strand overhang at ''clean'' DSBs, thus initiating homologous recombination (HR)-dependent DSB repair. To analyze the function of CtIP in detail, we conditionally disrupted the CtIP gene in the chicken DT40 cell line. We found that CtIP is essential for cellular proliferation as well as for the formation of 3′ single-strand overhang, similar to what is observed in DT40 cells deficient in the Mre11/Rad50/Nbs1 complex. We also generated DT40 cell line harboring CtIP with an alanine substitution at residue Ser332, which is required for interaction with BRCA1. Although the resulting CtIPS332A/-/- cells exhibited accumulation of RPA and Rad51 upon DNA damage, and were proficient in HR, they showed a marked hypersensitivity to camptothecin and etoposide in comparison with CtIP+/-/- cells. Finally, CtIPS332A/-/-BRCA1-/- and CtIP+/-/-BRCA1-/- showed similar sensitivities to these reagents. Taken together, our data indicate that, in addition to its function in HR, CtIP plays a role in cellular tolerance to topoisomerase inhibitors. We propose that the BRCA1-CtIP complex plays a role in the nucleasemediated elimination of oligonucleotides covalently bound to polypeptides from DSBs, thereby facilitating subsequent DSB repair. [ABSTRACT FROM AUTHOR]

Published

2010

5. ALC1/CHD1L, chromatin-remodeling enzyme, is required for efficient base excision repair

Author

Tsuda, Masataka, Cho, Kosai, Ooka, Masato, Shimizu, Naoto, Watanabe, Reiko, Yasui, Akira, Nakazawa, Yuka, Ogi, Tomoo, Harada, Hiroshi, Agama, Keli, Nakamura, Jun, Asada, Ryuta, Fujiike, Haruna, Sakuma, Tetsushi, Yamamoto, Takashi, Murai, Junko, Hiraoka, Masahiro, Koike, Kaoru, Pommier, Yves, Takeda, Shunichi, Hirota, Kouji, Tsuda, Masataka, Cho, Kosai, Ooka, Masato, Shimizu, Naoto, Watanabe, Reiko, Yasui, Akira, Nakazawa, Yuka, Ogi, Tomoo, Harada, Hiroshi, Agama, Keli, Nakamura, Jun, Asada, Ryuta, Fujiike, Haruna, Sakuma, Tetsushi, Yamamoto, Takashi, Murai, Junko, Hiraoka, Masahiro, Koike, Kaoru, Pommier, Yves, Takeda, Shunichi, and Hirota, Kouji

Abstract

ALC1/CHD1L is a member of the SNF2 superfamily of ATPases carrying a macrodomain that binds poly(ADP-ribose). Poly(ADP-ribose) polymerase (PARP) 1 and 2 synthesize poly(ADP-ribose) at DNA-strand cleavage sites, promoting base excision repair (BER). Although depletion of ALC1 causes increased sensitivity to various DNA-damaging agents (H2O2, UV, and phleomycin), the role played by ALC1 in BER has not yet been established. To explore this role, as well as the role of ALC1’s ATPase activity in BER, we disrupted the ALC1 gene and inserted the ATPase-dead (E165Q) mutation into the ALC1 gene in chicken DT40 cells, which do not express PARP2. The resulting ALC1-/- and ALC1-/E165Q cells displayed an indistinguishable hypersensitivity to methylmethane sulfonate (MMS), an alkylating agent, and to H2O2, indicating that ATPase plays an essential role in the DNA-damage response. PARP1-/- and ALC1-/-/PARP1-/- cells exhibited a very similar sensitivity to MMS, suggesting that ALC1 and PARP1 collaborate in BER. Following pulse-exposure to H2O2, PARP1-/- and ALC1-/-/PARP1-/- cells showed similarly delayed kinetics in the repair of single-strand breaks, which arise as BER intermediates. To ascertain ALC1’s role in BER in mammalian cells, we disrupted the ALC1 gene in human TK6 cells. Following exposure to MMS and to H2O2, the ALC1-/- TK6 cell line showed a delay in single-strand-break repair. We therefore conclude that ALC1 plays a role in BER. Following exposure to H2O2, ALC1-/- cells showed compromised chromatin relaxation. We thus propose that ALC1 is a unique BER factor that functions in a chromatin context, most likely as a chromatin-remodeling enzyme., This work was supported by the JSPS KAKENHI Grant Number (JP16K12598, JP16H02957 and JP16H01314 to KH, JP16H06306 to ST and JP16J02252 to RA), the JSPS Core-to-Core Program (A) Advanced Research Networks (to ST), the Takeda Science Foundation and Yamada Science Foundation (to KH), and the Center for Cancer Research, Intramural Program of the US National Cancer Institute (Z01 BC 006150 to KA and YP). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.