Uncoupling of 3â²-Phosphatase and 5â²-Kinase Functions in Budding Yeast
Polynucleotide kinase is a bifunctional enzyme containing both DNA 3â²-phosphatase and 5â²-kinase activities seemingly suited to the coupled repair of single-strand nicks in which the phosphate has remained with the 3â²-base. We show that the yeast Saccharomyces cerevisiae is able to repair trans...
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| Veröffentlicht in: | The Journal of biological chemistry 2001-05, Vol.276 (18), p.15073 |
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| container_title | The Journal of biological chemistry |
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| creator | John R. Vance Thomas E. Wilson |
| description | Polynucleotide kinase is a bifunctional enzyme containing both DNA 3â²-phosphatase and 5â²-kinase activities seemingly suited
to the coupled repair of single-strand nicks in which the phosphate has remained with the 3â²-base. We show that the yeast Saccharomyces cerevisiae is able to repair transformed dephosphorylated linear plasmids by non-homologous end joining with considerable efficiency
independently of the end-processing polymerase Pol4p. Homology searches and biochemical assays did not reveal a 5â²-kinase
that would account for this repair, however. Instead, open reading frame YMR156C (here named TPP1 ) is shown to encode only a polynucleotide kinase-type 3â²-phosphatase. Tpp1p bears extensive similarity to the ancient l -2-halo-acid dehalogenase and DDDD phosphohydrolase superfamilies, but is specific for double-stranded DNA. It is present
at high levels in cell extracts in a functional form and so does not represent a pseudogene. Moreover, the phosphatase-only
nature of this gene is shared by Saccharomyces mikatae YMR156C and Arabidopsis thaliana K15M2.3. Repair of 3â²-phosphate and 5â²-hydroxyl lesions is thus uncoupled in budding yeast as compared with metazoans. Repair
of transformed dephosphorylated plasmids, and 5â²-hydroxyl blocking lesions more generally, likely proceeds by a cycle of base
removal and resynthesis. |
| doi_str_mv | 10.1074/jbc.M011075200 |
| format | Article |
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to the coupled repair of single-strand nicks in which the phosphate has remained with the 3â²-base. We show that the yeast Saccharomyces cerevisiae is able to repair transformed dephosphorylated linear plasmids by non-homologous end joining with considerable efficiency
independently of the end-processing polymerase Pol4p. Homology searches and biochemical assays did not reveal a 5â²-kinase
that would account for this repair, however. Instead, open reading frame YMR156C (here named TPP1 ) is shown to encode only a polynucleotide kinase-type 3â²-phosphatase. Tpp1p bears extensive similarity to the ancient l -2-halo-acid dehalogenase and DDDD phosphohydrolase superfamilies, but is specific for double-stranded DNA. It is present
at high levels in cell extracts in a functional form and so does not represent a pseudogene. Moreover, the phosphatase-only
nature of this gene is shared by Saccharomyces mikatae YMR156C and Arabidopsis thaliana K15M2.3. Repair of 3â²-phosphate and 5â²-hydroxyl lesions is thus uncoupled in budding yeast as compared with metazoans. Repair
of transformed dephosphorylated plasmids, and 5â²-hydroxyl blocking lesions more generally, likely proceeds by a cycle of base
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to the coupled repair of single-strand nicks in which the phosphate has remained with the 3â²-base. We show that the yeast Saccharomyces cerevisiae is able to repair transformed dephosphorylated linear plasmids by non-homologous end joining with considerable efficiency
independently of the end-processing polymerase Pol4p. Homology searches and biochemical assays did not reveal a 5â²-kinase
that would account for this repair, however. Instead, open reading frame YMR156C (here named TPP1 ) is shown to encode only a polynucleotide kinase-type 3â²-phosphatase. Tpp1p bears extensive similarity to the ancient l -2-halo-acid dehalogenase and DDDD phosphohydrolase superfamilies, but is specific for double-stranded DNA. It is present
at high levels in cell extracts in a functional form and so does not represent a pseudogene. Moreover, the phosphatase-only
nature of this gene is shared by Saccharomyces mikatae YMR156C and Arabidopsis thaliana K15M2.3. Repair of 3â²-phosphate and 5â²-hydroxyl lesions is thus uncoupled in budding yeast as compared with metazoans. Repair
of transformed dephosphorylated plasmids, and 5â²-hydroxyl blocking lesions more generally, likely proceeds by a cycle of base
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to the coupled repair of single-strand nicks in which the phosphate has remained with the 3â²-base. We show that the yeast Saccharomyces cerevisiae is able to repair transformed dephosphorylated linear plasmids by non-homologous end joining with considerable efficiency
independently of the end-processing polymerase Pol4p. Homology searches and biochemical assays did not reveal a 5â²-kinase
that would account for this repair, however. Instead, open reading frame YMR156C (here named TPP1 ) is shown to encode only a polynucleotide kinase-type 3â²-phosphatase. Tpp1p bears extensive similarity to the ancient l -2-halo-acid dehalogenase and DDDD phosphohydrolase superfamilies, but is specific for double-stranded DNA. It is present
at high levels in cell extracts in a functional form and so does not represent a pseudogene. Moreover, the phosphatase-only
nature of this gene is shared by Saccharomyces mikatae YMR156C and Arabidopsis thaliana K15M2.3. Repair of 3â²-phosphate and 5â²-hydroxyl lesions is thus uncoupled in budding yeast as compared with metazoans. Repair
of transformed dephosphorylated plasmids, and 5â²-hydroxyl blocking lesions more generally, likely proceeds by a cycle of base
removal and resynthesis.</abstract><pub>American Society for Biochemistry and Molecular Biology</pub><pmid>11278831</pmid><doi>10.1074/jbc.M011075200</doi></addata></record> |
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| ispartof | The Journal of biological chemistry, 2001-05, Vol.276 (18), p.15073 |
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| language | eng |
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| source | EZB-FREE-00999 freely available EZB journals; Alma/SFX Local Collection |
| title | Uncoupling of 3â²-Phosphatase and 5â²-Kinase Functions in Budding Yeast |
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