Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:2.7.7.7 (
DNA polymerase
)
17,007
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Quinone
antibiotics, alpha- and beta-rubromycin, were originally found as inhibitors of retroviral reverse transcriptase. We investigated the effects of these agents on DNA metabolic enzymes including DNA and RNA polymerases as retroviral reverse transcriptase is a kind of the polymerase. As expected, we found that alpha- and beta-rubromycin strongly inhibited not only the retroviral reverse transcriptase activity, but the activities of the mammalian DNA polymerases, telomerase and terminal deoxynucleotidyl transferase in vitro. These agents should therefore be classified as
DNA polymerase
inhibitors. The Ki values of alpha-rubromycin against nucleotide substrate were 0.66 and 0.17 microM for
DNA polymerase alpha
and beta (pol. alpha and beta), respectively, and those of beta-rubromycin was 2.40 and 10.5 microM, respectively. Alpha-rubromycin strongly inhibited the pol. beta activity, and showed the strongest pol. beta inhibitory effect reported to date. At least on pol. beta, alpha-rubromycin was suggested to bind to the active region competing with the nucleotide substrate, and subsequently inhibit the catalytic activity. alpha-Rubromycin directly competed with the nucleotide substrate, and indirectly but simultaneously and non-competitively disturbed the template-DNA interaction with pol. beta.
...
PMID:The biochemical mode of inhibition of DNA polymerase beta by alpha-rubromycin. 1104 81
Quinone
methides (QMs) are involved in the metabolism of many drugs and carcinogens as reactive intermediates to form covalent nucleobase adducts in DNA that associate with high mutagenicity. Recently, a plethora of synthetic QM DNA alkylating agents have been developed to form various nucleobase adducts as potential antitumor agents. However, the mutagenic potential of these synthetic QM alkylating agents has not been fully investigated. In this report, N-methylquinolinium QM was developed as a synthetic model to study biological consequences of the formation of nucleobase adducts in a DNA target. N-Methylquinolinium QM was generated in situ via an elimination process from a bis-quaternary ammonium precursor that was synthesized from a quinoline derivative. Alkylation with N-methylquinolinium QM on a DNA target produced mostly a stable N(2)-dG adduct as revealed by gel electrophoresis and DNA digestion assays and confirmed by mass and NMR analyses. The formation of N(2)-dG adducts of a DNA target was found to cause extensive stops in the primer extension with high fidelity
DNA polymerase
T7 and even low fidelity error prone Dpo4. The direct biological impact of a prealkylated green fluorescence protein plasmid with N-methylquinolinium QM was demonstrated as significant suppression of protein expression in A549 cells. Overall, our results suggested that nucleobase-QM adducts could potentially block nucleobase mismatch/translesion in the error-prone process to reduce the mutagenic potential if designed carefully.
...
PMID:DNA alkylation with N-methylquinolinium quinone methide to N2-dG adducts resulting in extensive stops in primer extension with DNA polymerases and subsequent suppression of GFP expression in A549 cells. 2130 16
