Your search keyword '"Tanaka, K. (Kiyoji)"' showing total 6 results

1. Impaired genome maintenance suppresses the growth hormone--insulin-like growth factor 1 axis in mice with Cockayne syndrome.

Author

Pluijm, I. (Ingrid) van der, Garinis, G.A. (George), Brandt, R.M.C. (Renata), Gorgels, T.G.M.F. (Theo), Wijnhoven, S.W.P. (Susan), Diderich, K.E.M. (Karin), Wit, J. (Jan) de, Mitchell, J.R. (James), Oostrom, C.T.M. (Conny) van, Beems, R.B. (Rudolf), Niedernhofer, L.J. (Laura), Velasco, S. (Susana), Friedberg, E.C. (Errol), Tanaka, K. (Kiyoji), Steeg, H. (Harry) van, Hoeijmakers, J.H.J. (Jan), Horst, G.T.J. (Gijsbertus) van der, Pluijm, I. (Ingrid) van der, Garinis, G.A. (George), Brandt, R.M.C. (Renata), Gorgels, T.G.M.F. (Theo), Wijnhoven, S.W.P. (Susan), Diderich, K.E.M. (Karin), Wit, J. (Jan) de, Mitchell, J.R. (James), Oostrom, C.T.M. (Conny) van, Beems, R.B. (Rudolf), Niedernhofer, L.J. (Laura), Velasco, S. (Susana), Friedberg, E.C. (Errol), Tanaka, K. (Kiyoji), Steeg, H. (Harry) van, Hoeijmakers, J.H.J. (Jan), and Horst, G.T.J. (Gijsbertus) van der

Abstract

Cockayne syndrome (CS) is a photosensitive, DNA repair disorder associated with progeria that is caused by a defect in the transcription-coupled repair subpathway of nucleotide excision repair (NER). Here, complete inactivation of NER in Csb(m/m)/Xpa(-/-) mutants causes a phenotype that reliably mimics the human progeroid CS syndrome. Newborn Csb(m/m)/Xpa(-/-) mice display attenuated growth, progressive neurological dysfunction, retinal degeneration, cachexia, kyphosis, and die before weaning. Mouse liver transcriptome analysis and several physiological endpoints revealed systemic suppression of the growth hormone/insulin-like growth factor 1 (GH/IGF1) somatotroph axis and oxidative metabolism, increased antioxidant responses, and hypoglycemia together with hepatic glycogen and fat accumulation. Broad genome-wide parallels between Csb(m/m)/Xpa(-/-) and naturally aged mouse liver transcriptomes suggested that these changes are intrinsic to natural ageing and the DNA repair-deficient mice. Importantly, wild-type mice exposed to a low dose of chronic genotoxic stress recapitulated this response, thereby pointing to a novel link between genome instability and the age-related decline of the somatotroph axis.

Published

2006

2. Translocation of Cockayne syndrome group A protein to the nuclear matrix: possible relevance to transcription-coupled DNA repair.

Author

Kamiuchi, S. (Shinya), Saijo, M. (Masafumi), Citterio, E. (Elisabetta), Jager, M. (Martijn) de, Hoeijmakers, J.H.J. (Jan), Tanaka, K. (Kiyoji), Kamiuchi, S. (Shinya), Saijo, M. (Masafumi), Citterio, E. (Elisabetta), Jager, M. (Martijn) de, Hoeijmakers, J.H.J. (Jan), and Tanaka, K. (Kiyoji)

Abstract

Transcription-coupled repair (TCR) efficiently removes a variety of lesions from the transcribed strand of active genes. By allowing rapid resumption of RNA synthesis, the process is of major importance for cellular resistance to transcription-blocking genotoxic damage. Mutations in the Cockayne syndrome group A or B (CSA or CSB) gene result in defective TCR. However, the exact mechanism of TCR in mammalian cells remains to be elucidated. We found that CSA protein is rapidly translocated to the nuclear matrix after UV irradiation. The translocation of CSA was independent of Xeroderma pigmentosum group C, which is specific to the global genome repair subpathway of nucleotide excision repair (NER) and of the core NER factor Xeroderma pigmentosum group A but required the CSB protein. In UV-irradiated cells, CSA protein colocalized with the hyperphosphorylated form of RNA polymerase II, engaged in transcription elongation. The translocation of CSA was also induced by treatment of the cells with cisplatin or hydrogen peroxide, both of which produce damage that is subjected to TCR but not induced by treatment with dimethyl sulfate, which produces damage that is not subjected to TCR. The hydrogen peroxide-induced translocation of CSA was also CSB dependent. These findings establish a link between TCR and the nuclear matrix mediated by CSA.

Published

2002

3. XAB2, a novel tetratricopeptide repeat protein, involved in transcription-coupled repair and transcription.

Author

Nakatsu, Y. (Yoshimichi), Asahina, H. (Hiroshi), Citterio, E. (Elisabetta), Rademakers, S. (Suzanne), Vermeulen, W. (Wim), Kamiuchi, S. (Shinya), Ping, Y.J., Cheh, K.M., Saijo, M. (Masafumi), Kodo, N. (Naohiko), Matsuda, T. (Toshiro), Hoeijmakers, J.H.J. (Jan), Tanaka, K. (Kiyoji), Nakatsu, Y. (Yoshimichi), Asahina, H. (Hiroshi), Citterio, E. (Elisabetta), Rademakers, S. (Suzanne), Vermeulen, W. (Wim), Kamiuchi, S. (Shinya), Ping, Y.J., Cheh, K.M., Saijo, M. (Masafumi), Kodo, N. (Naohiko), Matsuda, T. (Toshiro), Hoeijmakers, J.H.J. (Jan), and Tanaka, K. (Kiyoji)

Abstract

Nucleotide excision repair is a highly versatile DNA repair system responsible for elimination of a wide variety of lesions from the genome. It is comprised of two subpathways: transcription-coupled repair that accomplishes efficient removal of damage blocking transcription and global genome repair. Recently, the basic mechanism of global genome repair has emerged from biochemical studies. However, little is known about transcription-coupled repair in eukaryotes. Here we report the identification of a novel protein designated XAB2 (XPA-binding protein 2) that was identified by virtue of its ability to interact with XPA, a factor central to both nucleotide excision repair subpathways. The XAB2 protein of 855 amino acids consists mainly of 15 tetratricopeptide repeats. In addition to interacting with XPA, immunoprecipitation experiments demonstrated that a fraction of XAB2 is able to interact with the transcription-coupled repair-specific proteins CSA and CSB as well as RNA polymerase II. Furthermore, antibodies against XAB2 inhibited both transcription-coupled repair and transcription in vivo but not global genome repair when microinjected into living fibroblasts. These results indicate that XAB2 is a novel component involved in transcription-coupled repair and transcription.

Published

2000

4. Interaction of hHR23 with S5a. The ubiquitin-like domain of hHR23 mediates interaction with S5a subunit of 26 S proteasome

Author

Hiyama, H., Yokoi, M., Masutani, C. (Chikahide), Sugasawa, K. (Kaoru), Maekawa, T., Tanaka, K. (Kiyoji), Hanaoka, F. (Fumio), Hoeijmakers, J.H.J. (Jan), Hiyama, H., Yokoi, M., Masutani, C. (Chikahide), Sugasawa, K. (Kaoru), Maekawa, T., Tanaka, K. (Kiyoji), Hanaoka, F. (Fumio), and Hoeijmakers, J.H.J. (Jan)

Abstract

hHR23B is one of two human homologs of the Saccharomyces cerevisiae nucleotide excision repair (NER) gene product RAD23 and a component of a protein complex that specifically complements the NER defect of xeroderma pigmentosum group C (XP-C) cell extracts in vitro. Although a small proportion of hHR23B is tightly complexed with the XP-C responsible gene product, XPC protein, a vast majority exists as an XPC-free form, indicating that hHR23B has additional functions other than NER in vivo. Here we demonstrate that the human NER factor hHR23B as well as another human homolog of RAD23, hHR23A, interact specifically with S5a, a subunit of the human 26 S proteasome using the yeast two-hybrid system. Furthermore, hHR23 proteins were detected with S5a at the position where 26 S proteasome sediments in glycerol gradient centrifugation of HeLa S100 extracts. Intriguingly, hHR23B showed the inhibitory effect on the degradation of (125)I-lysozyme in the rabbit reticulocyte lysate. hHR23 proteins thus appear to associate with 26 S proteasome in vivo. From co-precipitation experiments using several series of deletion mutants, we defined the domains in hHR23B and S5a that mediate this interaction. From these results, we propose that part of hHR23 proteins are involved in the proteolytic pathway in cells.

Published

1999

5. Enhancement of damage-specific DNA binding of XPA by interaction with the ERCC1 DNA repair protein

Author

Nagai, A., Saijo, M. (Masafumi), Kuraoka, I., Matsuda, T. (Toshiro), Kodo, N. (Naohiko), Nakatsu, Y. (Yoshimichi), Mimaki, T., Mino, M., Biggerstaff, M. (Maureen), Wood, R.D. (Richard), Sijbers, A.M. (Anneke), Hoeijmakers, J.H.J. (Jan), Tanaka, K. (Kiyoji), Nagai, A., Saijo, M. (Masafumi), Kuraoka, I., Matsuda, T. (Toshiro), Kodo, N. (Naohiko), Nakatsu, Y. (Yoshimichi), Mimaki, T., Mino, M., Biggerstaff, M. (Maureen), Wood, R.D. (Richard), Sijbers, A.M. (Anneke), Hoeijmakers, J.H.J. (Jan), and Tanaka, K. (Kiyoji)

Abstract

The human XPA and ERCC1 proteins, which are involved in early steps of nucleotide excision repair of DNA, specifically interacted in an in vitro binding assay and a yeast two-hybrid assay. A stretch of consecutive glutamic acid residues in XPA was needed for binding to ERCC1. Binding of XPA to damaged DNA was markedly increased by the interaction of the XPA and ERCC1 proteins. ERCC1 did not enhance binding to DNA when a truncated XPA protein, MF122, was used in place of the XPA protein. MF122 retains damaged DNA binding activity but lacks the region for protein-protein interaction including the E-cluster region. These results suggest that the XPA/ERCC1 interaction may participate in damage-recognition as well as in incision at the 5′ site of damage during nucleotide excision repair.

Published

1995

6. Xeroderma pigmentosum group A correcting protein from Calf Thymus.

Author

Eker, A.P.M. (André), Vermeulen, W. (Wim), Miura, N., Tanaka, K. (Kiyoji), Jaspers, N.G.J. (Nicolaas), Hoeijmakers, J.H.J. (Jan), Bootsma, D. (Dirk), Eker, A.P.M. (André), Vermeulen, W. (Wim), Miura, N., Tanaka, K. (Kiyoji), Jaspers, N.G.J. (Nicolaas), Hoeijmakers, J.H.J. (Jan), and Bootsma, D. (Dirk)

Abstract

A proteinous factor was purified from calf thymus and HeLa cells, which specifically corrects the excision repair defect of xeroderma pigmentosum complementation group A (XP-A) cells. Recovery of UV-induced unscheduled DNA synthesis after microinjection of XP-A cells was used as a quantitative assay for the correcting activity of protein preparations. XP-A correcting protein appears to be very stable as it withstands heating to 100 degrees C and treatment with SDS or 6 M urea. A molecular weight of 40-45 kD was found both under native (gel filtration) and denaturing (SDS-PAGE) conditions. Calf XP-A protein binds to single-stranded DNA more strongly than to double-stranded DNA, but shows no clear preference for UV-irradiated DNA. Polyclonal antibodies raised against human recombinant XP-A protein, which strongly inhibit UV-induced unscheduled DNA synthesis of normal human cells, completely abolished XP-A correcting activity when mixed with calf thymus preparations. This indicates a close relationship between human gene product and the calf protein. In the final preparation two main protein bands were present. Only one band at approx. 41 kD showed both DNA binding activity in Southwestern blots and immune reaction with human XP-A antibody, suggesting that this is the active calf XP-A correcting factor.

Published

1992