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Query: EC:2.7.7.7 (
DNA polymerase
)
17,007
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The carcinogenic and mutagenic N-nitroso compounds produce GC to AT and TA to GC transition mutations because they alkylate O6 of guanine and O4 of thymine. It has been generally assumed that these mutations occur because O6-alkylguanine forms a stable mispair with thymine and O4-alkylthymine forms a mispair with guanine. Recent studies have shown that this view is mistaken and that the alkylG.T and alkylT.G mispairs are not more stable than their alkylG.C or alkylT.A counterparts. Two possible explanations based on recent structural studies are put forward to account for the miscoding. The first possibility is that the
DNA polymerase
might mistake O6-alkylguanine for adenine, and O4-alkylthymine for cytosine, because of the physical similarity of these bases.
O6-Methylguanine
and adenine are similarly lipophilic and X-ray crystallography of the nucleosides has shown a close similarity in bond angles and lengths between O6-methylguanine and adenine, and between O4-methylthymine and cytosine. The second possible explanation is that the important factor in the miscoding is that the alkylG.T and alkylT.G mispairs retain the Watson-Crick alignment with N1 of the purine juxtaposed to N3 of the pyrimidine while the alkylG.C and alkylT.A pairs adopt a wobble conformation. 31P NMR of DNA duplexes show that the phosphodiester links both 3' and 5' to the C have to be distorted to accommodate the O6-ethylguanine:C pair, whereas there is less distortion of the phosphodiesters 3' and 5' to the T in an ethylG.T pair. Recent kinetic measurements show that the essential aspect of base selection in DNA synthesis is the ease of formation of the phosphodiester links on both the 3' and 5' side of the incoming base. The Watson-Crick alignment of the alkylG.T and alkylT.G mispairs may facilitate formation of these phosphodiester links, and this alignment rather than the strength of the base pairs and the extent of hydrogen bonding between them may be the crucial factor in the miscoding. If either hypothesis is correct it suggests that previously too much emphasis has been placed on the stability of the normal pairs in the replication of DNA.
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PMID:Why do O6-alkylguanine and O4-alkylthymine miscode? The relationship between the structure of DNA containing O6-alkylguanine and O4-alkylthymine and the mutagenic properties of these bases. 223 15
O6-Methylguanine
(m6G) was incorporated site-specifically into two 25-base oligonucleotides differing only in the nucleotide on the 3' side of the modified base. Templates were primed with oligonucleotides terminating one or two bases prior to the site at which incorporation kinetics were to be investigated. Escherichia coli
DNA polymerase I
(
Klenow fragment
) was used to determine the apparent Km and relative Vmax of incorporation of either dCTP or dTTP opposite m6G or G. These data were used to calculate the relative frequency of incorporation opposite the m6G or the unmodified G. When the sequence was 3'-Cm6G-5', there was a 6- to 7-fold preference for formation of a m6G.T pair compared with m6G.C. The m6G.T frequency, based on Vmax/Km, was at least 50-fold greater than that of a G.T pair at the same site. Changing the sequence to 3'-Tm6G-5' had a marked effect on both Km and Vmax of pairs containing m6G and on the incorporation frequency of T opposite m6G, which was then only slightly favored over m6G.C. When replication was started directly opposite m6G, the kinetics appeared unaffected. These data indicate that the frequency of incorporation of C or T opposite m6G in a DNA template is dependent on the flanking neighbors and that a change of even a single base at the 3' position can have a major effect on mutagenic efficiency. Replication using Drosophila Pol alpha gave the same values for relative frequencies. Pairing of either C or T with m6G on the primer terminus did not significantly inhibit extension of the next normal base pair, in contrast to terminal mismatches of unmodified bases. It is concluded that, in the absence of repair, m6G can exhibit widely differing mutation frequencies which, in these experiments, can be as high as 85% of the replicated base. This variation in frequency of changed pairing could contribute to the occurrence of mutational "'hot spots" after replication of damaged DNA.
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PMID:Effect of 3' flanking neighbors on kinetics of pairing of dCTP or dTTP opposite O6-methylguanine in a defined primed oligonucleotide when Escherichia coli DNA polymerase I is used. 268 44
The kinetics of incorporation of deoxynucleotide precursors directed by the promutagenic base, O6-methylguanine (m6Gua), was analyzed during in vitro replication of m6Gua-containing synthetic polydeoxynucleotides by T4 and T5 phage DNA polymerases and Escherichia coli
DNA polymerase I
. When poly(dT,m6dG) and poly(dC,m6dG) with covalently attached primers were replicated, O6-methylguanine paired with either thymine or cytosine but with a much higher preference for thymine. dCTP and dTTP acted as competitive inhibitors of each other during DNA synthesis.
O6-Methylguanine
also directed incorporation of dAMP by T5
DNA polymerase
. This dAMP incorporation was not inhibited by dTTP. Contrary to theoretical predictions that the m6dG X dT pair should be comparable to the dA X dT pair, the presence of m6dG in the template inhibited DNA synthesis. Based on Kappm values, E. coli
DNA polymerase I
showed a much higher preference for dTMP incorporation over dCMP opposite m6dG in the template than T4 and T5 DNA polymerases. At the same time, there was a higher turnover of dCTP than of dTTP by the E. coli enzyme. However, in all cases, the turnover of deoxynucleotides during replication of m6Gua-containing templates was more than that observed with templates without the alkylated base.
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PMID:Base-pairing properties of O6-methylguanine in template DNA during in vitro DNA replication. 637 99
Earlier studies have shown guanine arabinoside (ara-G) is an effective agent against growth of T-cell lines and freshly isolated human T-leukemic cells. However, poor water solubility of ara-G limits clinical use.
2-Amino-6-methoxypurine
arabinoside (506U) is a water-soluble prodrug converted to ara-G by adenosine deaminase. 506U is not a substrate for deoxycytidine kinase, adenosine kinase, or purine nucleoside phosphorylase and is phosphorylated by mitochondrial deoxyguanosine kinase at a rate 4% that of ara-G phosphorylation. Mitochondrial
DNA polymerase
was the least sensitive to ara-GTP inhibition of the five human DNA polymerases tested. [3H]506U was anabolized to ara-G 5'-phosphates in CEM cells but not to phosphorylated metabolites of 506U. 506U was selective for transformed T over B cells and also inhibited growth in two of three monocytic lines tested. 506U given i.v. to cynomolgus monkeys was rapidly converted to ara-G; the ara-G had a half-life of approximately 2 h. 506U had in vivo dose-dependent efficacy against human T-cell tumors in immunodeficient mice. A Phase 1 trial of 506U against refractory hematological malignancies is now in progress at two study sites.
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PMID:2-Amino-6-methoxypurine arabinoside: an agent for T-cell malignancies. 761 70
