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2009
Burnouf D. Y., Wagner J. E.
Kinetics of deoxy-CTP incorporation opposite a dG-C8-N-2-aminofluorene adduct by a high-fidelity DNA polymerase Journal Article
In: J Mol Biol, vol. 386, no. 4, pp. 951-61, 2009, (1089-8638 (Electronic) Journal Article Research Support, Non-U.S. Gov't).
Abstract | BibTeX | Tags: Adducts, Bacillus, Catalytic, Cytidine, Deoxyguanosine/*metabolism, DNA, DNA-Directed, Domain, DUMAS, Elements, Fluorenes/*metabolism, Guanine, Kinetics, Oligonucleotides/metabolism, Phosphorothioate, Polymerase/*metabolism, Specificity, stearothermophilus/enzymology, Substrate, Titrimetry, Triphosphate/*metabolism
@article{,
title = {Kinetics of deoxy-CTP incorporation opposite a dG-C8-N-2-aminofluorene adduct by a high-fidelity DNA polymerase},
author = { D. Y. Burnouf and J. E. Wagner},
year = {2009},
date = {2009-01-01},
journal = {J Mol Biol},
volume = {386},
number = {4},
pages = {951-61},
abstract = {The model carcinogen N-2-acetylaminofluorene covalently binds to the C8 position of guanine to form two adducts, the N-(2'-deoxyguanosine-8-yl)-aminofluorene (G-AF) and the N-2-(2'-deoxyguanosine-8-yl)-acetylaminofluorene (G-AAF). Although they are chemically closely related, their biological effects are strongly different and they are processed by different damage tolerance pathways. G-AF is bypassed by replicative and high-fidelity polymerases, while specialized polymerases ensure synthesis past of G-AAF. We used the DNA polymerase I fragment of a Bacillus stearothermophilus strain as a model for a high-fidelity polymerase to study the kinetics of incorporation of deoxy-CTP (dCTP) opposite a single G-AF. Pre-steady-state kinetic experiments revealed a drastic reduction in dCTP incorporation performed by the G-AF-modified ternary complex. Two populations of these ternary complexes were identified: (i) a minor productive fraction (20%) that readily incorporates dCTP opposite the G-AF adduct with a rate similar to that measured for the adduct-free ternary complexes and (ii) a major fraction of unproductive complexes (80%) that slowly evolve into productive ones. In the light of structural data, we suggest that this slow rate reflects the translocation of the modified base within the active site, from the pre-insertion site into the insertion site. By making this translocation rate limiting, the G-AF lesion reveals a novel kinetic step occurring after dNTP binding and before chemistry.},
note = {1089-8638 (Electronic)
Journal Article
Research Support, Non-U.S. Gov't},
keywords = {Adducts, Bacillus, Catalytic, Cytidine, Deoxyguanosine/*metabolism, DNA, DNA-Directed, Domain, DUMAS, Elements, Fluorenes/*metabolism, Guanine, Kinetics, Oligonucleotides/metabolism, Phosphorothioate, Polymerase/*metabolism, Specificity, stearothermophilus/enzymology, Substrate, Titrimetry, Triphosphate/*metabolism},
pubstate = {published},
tppubtype = {article}
}
The model carcinogen N-2-acetylaminofluorene covalently binds to the C8 position of guanine to form two adducts, the N-(2'-deoxyguanosine-8-yl)-aminofluorene (G-AF) and the N-2-(2'-deoxyguanosine-8-yl)-acetylaminofluorene (G-AAF). Although they are chemically closely related, their biological effects are strongly different and they are processed by different damage tolerance pathways. G-AF is bypassed by replicative and high-fidelity polymerases, while specialized polymerases ensure synthesis past of G-AAF. We used the DNA polymerase I fragment of a Bacillus stearothermophilus strain as a model for a high-fidelity polymerase to study the kinetics of incorporation of deoxy-CTP (dCTP) opposite a single G-AF. Pre-steady-state kinetic experiments revealed a drastic reduction in dCTP incorporation performed by the G-AF-modified ternary complex. Two populations of these ternary complexes were identified: (i) a minor productive fraction (20%) that readily incorporates dCTP opposite the G-AF adduct with a rate similar to that measured for the adduct-free ternary complexes and (ii) a major fraction of unproductive complexes (80%) that slowly evolve into productive ones. In the light of structural data, we suggest that this slow rate reflects the translocation of the modified base within the active site, from the pre-insertion site into the insertion site. By making this translocation rate limiting, the G-AF lesion reveals a novel kinetic step occurring after dNTP binding and before chemistry.
2004
Przykorska A., Solecka K., Olszak K., Keith G., Nawrot B., Kuligowska E.
Wheat (Triticum vulgare) chloroplast nuclease ChSI exhibits 5' flap structure-specific endonuclease activity Journal Article
In: Biochemistry, vol. 43, no. 35, pp. 11283-94, 2004, (0006-2960 Journal Article).
Abstract | BibTeX | Tags: &, Acid, Catalysis, Chloroplasts/*enzymology, Conformation, Desorption-Ionization, DNA, Endonucleases/*chemistry/isolation, Exonucleases/chemistry/metabolism, Flap, Gov't, Hydrolysis, KEITH, Kinetics, Laser, Mass, Matrix-Assisted, Non-U.S., Nucleic, Oligonucleotides/chemical, Plant/chemistry/metabolism, purification/*metabolism, Relationship, Single-Stranded/chemistry/metabolism, Specificity, Spectrometry, Structure-Activity, Substrate, Support, synthesis/metabolism, Thermodynamics, Triticum/*enzymology
@article{,
title = {Wheat (Triticum vulgare) chloroplast nuclease ChSI exhibits 5' flap structure-specific endonuclease activity},
author = { A. Przykorska and K. Solecka and K. Olszak and G. Keith and B. Nawrot and E. Kuligowska},
year = {2004},
date = {2004-01-01},
journal = {Biochemistry},
volume = {43},
number = {35},
pages = {11283-94},
abstract = {The structure-specific ChSI nuclease from wheat (Triticum vulgare) chloroplast stroma has been previously purified and characterized in our laboratory. It is a single-strand-specific DNA and RNA endonuclease. Although the enzyme has been initially characterized and used as a structural probe, its biological function is still unknown. Localization of the ChSI enzyme inside chloroplasts, possessing their own DNA that is generally highly exposed to UV light and often affected by numerous redox reactions and electron transfer processes, might suggest, however, that this enzyme could be involved in DNA repair. The repair of some types of DNA damage has been shown to proceed through branched DNA intermediates which are substrates for the structure-specific DNA endonucleases. Thus we tested the substrate specificity of ChSI endonuclease toward various branched DNAs containing 5' flap, 5' pseudoflap, 3' pseudoflap, or single-stranded bulged structural motifs. It appears that ChSI has a high 5' flap structure-specific endonucleolytic activity. The catalytic efficiency (k(cat)/K(M)) of the enzyme is significantly higher for the 5' flap substrate than for single-stranded DNA. The ChSI 5' flap activity was inhibited by high concentrations of Mg(2+), Mn(2+), Zn(2+), or Ca(2+). However, low concentrations of divalent cations could restore the loss of ChSI activity as a consequence of EDTA pretreatment. In contrast to other known 5' flap nucleases, the chloroplast enzyme ChSI does not possess any 5'-->3' exonuclease activity on double-stranded DNA. Therefore, we conclude that ChSI is a 5' flap structure-specific endonuclease with nucleolytic activity toward single-stranded substrates.},
note = {0006-2960
Journal Article},
keywords = {&, Acid, Catalysis, Chloroplasts/*enzymology, Conformation, Desorption-Ionization, DNA, Endonucleases/*chemistry/isolation, Exonucleases/chemistry/metabolism, Flap, Gov't, Hydrolysis, KEITH, Kinetics, Laser, Mass, Matrix-Assisted, Non-U.S., Nucleic, Oligonucleotides/chemical, Plant/chemistry/metabolism, purification/*metabolism, Relationship, Single-Stranded/chemistry/metabolism, Specificity, Spectrometry, Structure-Activity, Substrate, Support, synthesis/metabolism, Thermodynamics, Triticum/*enzymology},
pubstate = {published},
tppubtype = {article}
}
The structure-specific ChSI nuclease from wheat (Triticum vulgare) chloroplast stroma has been previously purified and characterized in our laboratory. It is a single-strand-specific DNA and RNA endonuclease. Although the enzyme has been initially characterized and used as a structural probe, its biological function is still unknown. Localization of the ChSI enzyme inside chloroplasts, possessing their own DNA that is generally highly exposed to UV light and often affected by numerous redox reactions and electron transfer processes, might suggest, however, that this enzyme could be involved in DNA repair. The repair of some types of DNA damage has been shown to proceed through branched DNA intermediates which are substrates for the structure-specific DNA endonucleases. Thus we tested the substrate specificity of ChSI endonuclease toward various branched DNAs containing 5' flap, 5' pseudoflap, 3' pseudoflap, or single-stranded bulged structural motifs. It appears that ChSI has a high 5' flap structure-specific endonucleolytic activity. The catalytic efficiency (k(cat)/K(M)) of the enzyme is significantly higher for the 5' flap substrate than for single-stranded DNA. The ChSI 5' flap activity was inhibited by high concentrations of Mg(2+), Mn(2+), Zn(2+), or Ca(2+). However, low concentrations of divalent cations could restore the loss of ChSI activity as a consequence of EDTA pretreatment. In contrast to other known 5' flap nucleases, the chloroplast enzyme ChSI does not possess any 5'-->3' exonuclease activity on double-stranded DNA. Therefore, we conclude that ChSI is a 5' flap structure-specific endonuclease with nucleolytic activity toward single-stranded substrates.
Zukiel R., Nowak S., Barciszewska A. M., Gawronska I., Keith G., Barciszewska M. Z.
A simple epigenetic method for the diagnosis and classification of brain tumors Journal Article
In: Mol Cancer Res, vol. 2, no. 3, pp. 196-202, 2004, (1541-7786 Journal Article).
Abstract | BibTeX | Tags: *DNA, *Epigenesis, 5-Methylcytosine/*analysis, Adult, Aged, and, Brain, Chromatography, DNA, Female, Genetic, Gov't, Human, KEITH, Layer, Male, Methylation, Middle, Neoplasm/*chemistry/*metabolism, Neoplasms/*classification/*diagnosis/genetics/pathology, Non-U.S., Oxidative, oxygen, Reactive, Sensitivity, Species/metabolism, Specificity, Stress, Support, Thin
@article{,
title = {A simple epigenetic method for the diagnosis and classification of brain tumors},
author = { R. Zukiel and S. Nowak and A. M. Barciszewska and I. Gawronska and G. Keith and M. Z. Barciszewska},
year = {2004},
date = {2004-01-01},
journal = {Mol Cancer Res},
volume = {2},
number = {3},
pages = {196-202},
abstract = {The new, simple, and reliable method for the diagnosis of brain tumors is described. It is based on a TLC quantitative determination of 5-methylcytosine (m(5)C) in relation to its damage products of DNA from tumor tissue. Currently, there is evidence that oxidative stress through reactive oxygen species (ROS) plays an important role in the etiology and progression of several human diseases. Oxidative damage of DNA, lipids, and proteins is deleterious for the cell. m(5)C, along with other basic components of DNA, is the target for ROS, which results in the appearance of new modified nucleic acid bases. If so, m(5)C residue constitutes a mutational hotspot position, whether it occurs within a nucleotide sequence of a structural gene or a regulatory region. Here, we show the results of the analysis of 82 DNA samples taken from brain tumor tissues. DNA was isolated and hydrolyzed into nucleotides, which, after labeling with [gamma-(32)P]ATP, were separated on TLC. Chromatograms were evaluated using PhosphorImager and the amounts of 5-methyldeoxycytosine (m(5)dC) were calculated as a ratio (R) of m(5)dC to m(5)dC + deoxycytosine + deoxythymidine spot intensities. The R value could not only be a good diagnostic marker for brain tumors but also a factor differentiating low-grade and high-grade gliomas. Therefore, DNA methylation pattern might be a useful tool to give a primary diagnosis of a brain tumor or as a marker for the early detection of the relapse of the disease. This method has several advantages over those existing nowadays.},
note = {1541-7786
Journal Article},
keywords = {*DNA, *Epigenesis, 5-Methylcytosine/*analysis, Adult, Aged, and, Brain, Chromatography, DNA, Female, Genetic, Gov't, Human, KEITH, Layer, Male, Methylation, Middle, Neoplasm/*chemistry/*metabolism, Neoplasms/*classification/*diagnosis/genetics/pathology, Non-U.S., Oxidative, oxygen, Reactive, Sensitivity, Species/metabolism, Specificity, Stress, Support, Thin},
pubstate = {published},
tppubtype = {article}
}
The new, simple, and reliable method for the diagnosis of brain tumors is described. It is based on a TLC quantitative determination of 5-methylcytosine (m(5)C) in relation to its damage products of DNA from tumor tissue. Currently, there is evidence that oxidative stress through reactive oxygen species (ROS) plays an important role in the etiology and progression of several human diseases. Oxidative damage of DNA, lipids, and proteins is deleterious for the cell. m(5)C, along with other basic components of DNA, is the target for ROS, which results in the appearance of new modified nucleic acid bases. If so, m(5)C residue constitutes a mutational hotspot position, whether it occurs within a nucleotide sequence of a structural gene or a regulatory region. Here, we show the results of the analysis of 82 DNA samples taken from brain tumor tissues. DNA was isolated and hydrolyzed into nucleotides, which, after labeling with [gamma-(32)P]ATP, were separated on TLC. Chromatograms were evaluated using PhosphorImager and the amounts of 5-methyldeoxycytosine (m(5)dC) were calculated as a ratio (R) of m(5)dC to m(5)dC + deoxycytosine + deoxythymidine spot intensities. The R value could not only be a good diagnostic marker for brain tumors but also a factor differentiating low-grade and high-grade gliomas. Therefore, DNA methylation pattern might be a useful tool to give a primary diagnosis of a brain tumor or as a marker for the early detection of the relapse of the disease. This method has several advantages over those existing nowadays.
2001
Carnicelli D., Brigotti M., Rizzi S., Keith G., Montanaro L., Sperti S.
Nucleotides U28-A42 and A37 in unmodified yeast tRNA(Trp) as negative identity elements for bovine tryptophanyl-tRNA synthetase Journal Article
In: FEBS Lett, vol. 492, no. 3, pp. 238-41, 2001, (0014-5793 Journal Article).
Abstract | BibTeX | Tags: Acid, Adenine/chemistry, Animals, Base, Cattle, cerevisiae/genetics, Conformation, Data, Fungal/genetics/metabolism, Gov't, Kinetics, Ligase/*metabolism, Molecular, Non-U.S., Nucleic, RNA, Saccharomyces, Sequence, Species, Specificity, Substrate, Support, Transfer, Trp/chemistry/*metabolism, Tryptophan-tRNA, Uridine/chemistry
@article{,
title = {Nucleotides U28-A42 and A37 in unmodified yeast tRNA(Trp) as negative identity elements for bovine tryptophanyl-tRNA synthetase},
author = { D. Carnicelli and M. Brigotti and S. Rizzi and G. Keith and L. Montanaro and S. Sperti},
year = {2001},
date = {2001-01-01},
journal = {FEBS Lett},
volume = {492},
number = {3},
pages = {238-41},
abstract = {Wild-type bovine and yeast tRNA(Trp) are efficiently aminoacylated by tryptophanyl-tRNA synthetase both from beef and from yeast. Upon loss of modified bases in the synthetic transcripts, mammalian tRNA(Trp) retains the double recognition by the two synthetases, while yeast tRNA(Trp) loses its substrate properties for the bovine enzyme and is recognised only by the cognate synthetase. By testing chimeric bovine-yeast transcripts with tryptophanyl-tRNA synthetase purified from beef pancreas, the nucleotides responsible for the loss of charging of the synthetic yeast transcript have been localised in the anticodon arm. A complete loss of charging akin to that observed with the yeast transcript requires substitution in the bovine backbone of G37 in the anticodon loop with yeast A37 and of C28-G42 in the anticodon stem with yeast U28-A42. Since A37 does not prevent aminoacylation of the wild-type yeast tRNA(Trp) by the beef enzyme, a negative combination apparently emerges in the synthetic transcript after unmasking of U28 by loss of pseudourydilation.},
note = {0014-5793
Journal Article},
keywords = {Acid, Adenine/chemistry, Animals, Base, Cattle, cerevisiae/genetics, Conformation, Data, Fungal/genetics/metabolism, Gov't, Kinetics, Ligase/*metabolism, Molecular, Non-U.S., Nucleic, RNA, Saccharomyces, Sequence, Species, Specificity, Substrate, Support, Transfer, Trp/chemistry/*metabolism, Tryptophan-tRNA, Uridine/chemistry},
pubstate = {published},
tppubtype = {article}
}
Wild-type bovine and yeast tRNA(Trp) are efficiently aminoacylated by tryptophanyl-tRNA synthetase both from beef and from yeast. Upon loss of modified bases in the synthetic transcripts, mammalian tRNA(Trp) retains the double recognition by the two synthetases, while yeast tRNA(Trp) loses its substrate properties for the bovine enzyme and is recognised only by the cognate synthetase. By testing chimeric bovine-yeast transcripts with tryptophanyl-tRNA synthetase purified from beef pancreas, the nucleotides responsible for the loss of charging of the synthetic yeast transcript have been localised in the anticodon arm. A complete loss of charging akin to that observed with the yeast transcript requires substitution in the bovine backbone of G37 in the anticodon loop with yeast A37 and of C28-G42 in the anticodon stem with yeast U28-A42. Since A37 does not prevent aminoacylation of the wild-type yeast tRNA(Trp) by the beef enzyme, a negative combination apparently emerges in the synthetic transcript after unmasking of U28 by loss of pseudourydilation.
1998
Motorin Y., Keith G., Simon C., Foiret D., Simos G., Hurt E., Grosjean H.
The yeast tRNA:pseudouridine synthase Pus1p displays a multisite substrate specificity Journal Article
In: RNA, vol. 4, no. 7, pp. 856-69, 1998, (1355-8382 Journal Article).
Abstract | BibTeX | Tags: *RNA, cerevisiae, Cloning, Fractions/metabolism, Fungal, Fungal/metabolism, Gov't, Hydro-Lyases/biosynthesis/genetics/*metabolism, Molecular, Mutation, Non-U.S., Plant/metabolism, post-transcriptional, Precursors/*metabolism, Processing, Proteins/biosynthesis, Proteins/biosynthesis/genetics/metabolism, Pseudouridine/*biosynthesis, Recombinant, RNA, Saccharomyces, Specificity, Subcellular, Substrate, Support, Transfer/*metabolism
@article{,
title = {The yeast tRNA:pseudouridine synthase Pus1p displays a multisite substrate specificity},
author = { Y. Motorin and G. Keith and C. Simon and D. Foiret and G. Simos and E. Hurt and H. Grosjean},
year = {1998},
date = {1998-01-01},
journal = {RNA},
volume = {4},
number = {7},
pages = {856-69},
abstract = {We have previously shown that the yeast gene PUS1 codes for a tRNA:pseudouridine synthase and that recombinant Pus1p catalyzes, in an intron-dependent way, the formation of psi34 and psi36 in the anticodon loop of the yeast minor tRNA(Ile) in vitro (Simos G et al., 1996, EMBO J 15:2270-2284). Using a set of T7 transcripts of different tRNA genes, we now demonstrate that yeast pseudouridine synthase 1 catalyzes in vitro pseudouridine formation at positions 27 and/or 28 in several yeast cytoplasmic tRNAs and at position 35 in the intron-containing tRNA(Tyr) (anticodon GUA). Thus, Pus1p not only displays a broad specificity toward the RNA substrates, but is also capable of catalyzing the pseudouridine (psi) formation at distinct noncontiguous sites within the same tRNA molecule. The cell-free extract prepared from the yeast strain bearing disrupted gene PUS1 is unable to catalyze the formation of psi27, psi28, psi34, and psi36 in vitro, however, psi35 formation in the intron-containing tRNA(Tyr)(GUA) remains unaffected. Thus, in yeast, only one gene product accounts for tRNA pseudouridylation at positions 27, 28, 34, and 36, whereas for position 35 in tRNA(Tyr), another site-specific tRNA:pseudouridine synthase with overlapping specificity exists. Mapping of pseudouridine residues present in various tRNAs extracted from the PUS1-disrupted strain confirms the in vitro data obtained with the recombinant Pus1p. In addition, they suggest that Pus1p is implicated in modification at positions U26, U65, and U67 in vivo.},
note = {1355-8382
Journal Article},
keywords = {*RNA, cerevisiae, Cloning, Fractions/metabolism, Fungal, Fungal/metabolism, Gov't, Hydro-Lyases/biosynthesis/genetics/*metabolism, Molecular, Mutation, Non-U.S., Plant/metabolism, post-transcriptional, Precursors/*metabolism, Processing, Proteins/biosynthesis, Proteins/biosynthesis/genetics/metabolism, Pseudouridine/*biosynthesis, Recombinant, RNA, Saccharomyces, Specificity, Subcellular, Substrate, Support, Transfer/*metabolism},
pubstate = {published},
tppubtype = {article}
}
We have previously shown that the yeast gene PUS1 codes for a tRNA:pseudouridine synthase and that recombinant Pus1p catalyzes, in an intron-dependent way, the formation of psi34 and psi36 in the anticodon loop of the yeast minor tRNA(Ile) in vitro (Simos G et al., 1996, EMBO J 15:2270-2284). Using a set of T7 transcripts of different tRNA genes, we now demonstrate that yeast pseudouridine synthase 1 catalyzes in vitro pseudouridine formation at positions 27 and/or 28 in several yeast cytoplasmic tRNAs and at position 35 in the intron-containing tRNA(Tyr) (anticodon GUA). Thus, Pus1p not only displays a broad specificity toward the RNA substrates, but is also capable of catalyzing the pseudouridine (psi) formation at distinct noncontiguous sites within the same tRNA molecule. The cell-free extract prepared from the yeast strain bearing disrupted gene PUS1 is unable to catalyze the formation of psi27, psi28, psi34, and psi36 in vitro, however, psi35 formation in the intron-containing tRNA(Tyr)(GUA) remains unaffected. Thus, in yeast, only one gene product accounts for tRNA pseudouridylation at positions 27, 28, 34, and 36, whereas for position 35 in tRNA(Tyr), another site-specific tRNA:pseudouridine synthase with overlapping specificity exists. Mapping of pseudouridine residues present in various tRNAs extracted from the PUS1-disrupted strain confirms the in vitro data obtained with the recombinant Pus1p. In addition, they suggest that Pus1p is implicated in modification at positions U26, U65, and U67 in vivo.
1995
Gabryszuk J., Keith G., Monko M., Kuligowska E., Dirheimer G., Szarkowski J. W., Przykorska A.
Structural specificity of nuclease from wheat chloroplasts stroma Journal Article
In: Nucleic Acids Symp Ser, no. 33, pp. 115-9, 1995, (0261-3166 Journal Article).
Abstract | BibTeX | Tags: &, Acid, Asp/chemistry/genetics/metabolism, Base, Binding, Chloroplasts/*enzymology, Conformation, Data, Endonucleases/isolation, Fungal/chemistry/genetics/metabolism, Gov't, Molecular, Non-U.S., Nucleic, Phe/chemistry/genetics/metabolism, purification/*metabolism, RNA, RNA/chemistry/metabolism, Sequence, Sites, Specificity, Substrate, Support, Transfer, Triticum/*enzymology
@article{,
title = {Structural specificity of nuclease from wheat chloroplasts stroma},
author = { J. Gabryszuk and G. Keith and M. Monko and E. Kuligowska and G. Dirheimer and J. W. Szarkowski and A. Przykorska},
year = {1995},
date = {1995-01-01},
journal = {Nucleic Acids Symp Ser},
number = {33},
pages = {115-9},
abstract = {A single-strand-specific nuclease from wheat chloroplasts (ChS nuclease) was tested as a tool for RNA secondary and tertiary structure investigations, using yeast tRNA(Phe) and yeast tRNA(Asp) as models. In tRNA(Phe) the nuclease introduced main primary cleavages at positions U33, A35 and A36 in the anticodon-loop and G18 and G19 in the D-loop. In tRNA(Asp) the main primary cleavages occurred at positions U33, G34 and U35 in the anticodon-loop and the lower one at position C20:1 in the D-loop. No primary cleavages were observed within the double-stranded stems. Because ChS nuclease has (i) a low molecular weight, (ii) a wide pH range of action (5.0 to 7.5) (iii) no divalent cation requirement in the reaction mixture and (iv) can be obtained as a pure protein in rather large quantities it appeared to be a very good tool for secondary and tertiary structural studies of RNAs.},
note = {0261-3166
Journal Article},
keywords = {&, Acid, Asp/chemistry/genetics/metabolism, Base, Binding, Chloroplasts/*enzymology, Conformation, Data, Endonucleases/isolation, Fungal/chemistry/genetics/metabolism, Gov't, Molecular, Non-U.S., Nucleic, Phe/chemistry/genetics/metabolism, purification/*metabolism, RNA, RNA/chemistry/metabolism, Sequence, Sites, Specificity, Substrate, Support, Transfer, Triticum/*enzymology},
pubstate = {published},
tppubtype = {article}
}
A single-strand-specific nuclease from wheat chloroplasts (ChS nuclease) was tested as a tool for RNA secondary and tertiary structure investigations, using yeast tRNA(Phe) and yeast tRNA(Asp) as models. In tRNA(Phe) the nuclease introduced main primary cleavages at positions U33, A35 and A36 in the anticodon-loop and G18 and G19 in the D-loop. In tRNA(Asp) the main primary cleavages occurred at positions U33, G34 and U35 in the anticodon-loop and the lower one at position C20:1 in the D-loop. No primary cleavages were observed within the double-stranded stems. Because ChS nuclease has (i) a low molecular weight, (ii) a wide pH range of action (5.0 to 7.5) (iii) no divalent cation requirement in the reaction mixture and (iv) can be obtained as a pure protein in rather large quantities it appeared to be a very good tool for secondary and tertiary structural studies of RNAs.
Keith G., Dirheimer G.
Postlabeling: a sensitive method for studying DNA adducts and their role in carcinogenesis Journal Article
In: Curr Opin Biotechnol, vol. 6, no. 1, pp. 3-11, 1995, (0958-1669 Journal Article Review Review, Academic).
Abstract | BibTeX | Tags: *Cell, *Genome, Adducts/*analysis, and, Animals, Base, Cell, Conditions/genetics/pathology, Data, Dilution, Division, DNA, Genetic, Gov't, Human, Models, Molecular, Mutagenesis, Neoplasms/*genetics/pathology, Neoplastic, Non-U.S., Phosphorus, Precancerous, Radioisotope, Radioisotopes, Sensitivity, Sequence, Specificity, Support, Technique, Transformation, Xenobiotics
@article{,
title = {Postlabeling: a sensitive method for studying DNA adducts and their role in carcinogenesis},
author = { G. Keith and G. Dirheimer},
year = {1995},
date = {1995-01-01},
journal = {Curr Opin Biotechnol},
volume = {6},
number = {1},
pages = {3-11},
abstract = {The covalent binding of xenobiotics to DNA is an important trigger of the multistage process that leads to carcinogenesis. 32P-postlabeling represents a highly sensitive method for biomonitoring exposure to genotoxic agents and for cancer risk assessment; it is capable of detecting less than one DNA adduct per human genome. Recent improvements to the technique have shown that the resistance of adducted DNA to enzyme digestion may lead to an overestimation of the number of different adducts present in a sample.},
note = {0958-1669
Journal Article
Review
Review, Academic},
keywords = {*Cell, *Genome, Adducts/*analysis, and, Animals, Base, Cell, Conditions/genetics/pathology, Data, Dilution, Division, DNA, Genetic, Gov't, Human, Models, Molecular, Mutagenesis, Neoplasms/*genetics/pathology, Neoplastic, Non-U.S., Phosphorus, Precancerous, Radioisotope, Radioisotopes, Sensitivity, Sequence, Specificity, Support, Technique, Transformation, Xenobiotics},
pubstate = {published},
tppubtype = {article}
}
The covalent binding of xenobiotics to DNA is an important trigger of the multistage process that leads to carcinogenesis. 32P-postlabeling represents a highly sensitive method for biomonitoring exposure to genotoxic agents and for cancer risk assessment; it is capable of detecting less than one DNA adduct per human genome. Recent improvements to the technique have shown that the resistance of adducted DNA to enzyme digestion may lead to an overestimation of the number of different adducts present in a sample.
1992
Przykorska A., el Adlouni C., Keith G., Szarkowski J. W., Dirheimer G.
Structural specificity of Rn nuclease I as probed on yeast tRNA(Phe) and tRNA(Asp) Journal Article
In: Nucleic Acids Res, vol. 20, no. 4, pp. 659-63, 1992, (0305-1048 Journal Article).
Abstract | BibTeX | Tags: Acid, Asp/chemistry/genetics/*metabolism, Base, cereale, Composition, Conformation, Data, Gov't, Molecular, Non-U.S., Nucleic, Pancreatic/*metabolism, Phe/chemistry/genetics/*metabolism, Ribonuclease, RNA, Secale, Sequence, Specificity, Substrate, Support, Transfer, Yeasts/genetics
@article{,
title = {Structural specificity of Rn nuclease I as probed on yeast tRNA(Phe) and tRNA(Asp)},
author = { A. Przykorska and C. el Adlouni and G. Keith and J. W. Szarkowski and G. Dirheimer},
year = {1992},
date = {1992-01-01},
journal = {Nucleic Acids Res},
volume = {20},
number = {4},
pages = {659-63},
abstract = {A single-strand-specific nuclease from rye germ (Rn nuclease I) was characterized as a tool for secondary and tertiary structure investigation of RNAs. To test the procedure, yeast tRNA(Phe) and tRNA(Asp) for which the tertiary structures are known, as well as the 3'-half of tRNA(Asp) were used as substrates. In tRNA(Phe) the nuclease introduced main primary cuts at positions U33 and A35 of the anticodon loop and G18 and G19 of the D loop. No primary cuts were observed within the double stranded stems. In tRNA(Asp) the main cuts occurred at positions U33, G34, U35, C36 of the anticodon loop and G18 and C20:1 positions in the D loop. No cuts were observed in the T loop in intact tRNA(Asp) but strong primary cleavages occurred at positions psi 55, C56, A57 within that loop in the absence of the tertiary interactions between T and D loops (use of 3'-half tRNA(Asp)). These results show that Rn nuclease I is specific for exposed single-stranded regions.},
note = {0305-1048
Journal Article},
keywords = {Acid, Asp/chemistry/genetics/*metabolism, Base, cereale, Composition, Conformation, Data, Gov't, Molecular, Non-U.S., Nucleic, Pancreatic/*metabolism, Phe/chemistry/genetics/*metabolism, Ribonuclease, RNA, Secale, Sequence, Specificity, Substrate, Support, Transfer, Yeasts/genetics},
pubstate = {published},
tppubtype = {article}
}
A single-strand-specific nuclease from rye germ (Rn nuclease I) was characterized as a tool for secondary and tertiary structure investigation of RNAs. To test the procedure, yeast tRNA(Phe) and tRNA(Asp) for which the tertiary structures are known, as well as the 3'-half of tRNA(Asp) were used as substrates. In tRNA(Phe) the nuclease introduced main primary cuts at positions U33 and A35 of the anticodon loop and G18 and G19 of the D loop. No primary cuts were observed within the double stranded stems. In tRNA(Asp) the main cuts occurred at positions U33, G34, U35, C36 of the anticodon loop and G18 and C20:1 positions in the D loop. No cuts were observed in the T loop in intact tRNA(Asp) but strong primary cleavages occurred at positions psi 55, C56, A57 within that loop in the absence of the tertiary interactions between T and D loops (use of 3'-half tRNA(Asp)). These results show that Rn nuclease I is specific for exposed single-stranded regions.
