Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
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Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
Compound
Query: EC:5.99.1.2 (
topoisomerase
)
9,166
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The DNA unwinding effects of some 9-aminoacridine derivatives were compared under reaction conditions that could be used to study drug-induced
topoisomerase
II inhibition. An assay was designed to determine drug-induced DNA unwinding by using L1210 topoisomerase I. 9-aminoacridines could be ranked by decreasing unwinding potency: compound C greater than or equal to 9-aminoacridine greater than o-AMSA greater than or equal to compound A greater than compound B greater than m-AMSA.
Ethidium bromide
was more potent than any of the 9-aminoacridines. This assay is a fast and simple method to compare DNA unwinding effects of intercalators. It led to the definition of a drug intrinsic unwinding constant (k). An additional finding was that all 9-aminoacridines and ethidium bromide inhibited L1210 topoisomerase I. Enzyme inhibition was detectable at low enzyme concentrations (less than or equal to 1 unit) and when the kinetics of topoisomerase I-mediated DNA relaxation was studied. Topoisomerase I inhibition was not associated with DNA swivelling or cleavage.
...
PMID:DNA unwinding and inhibition of mouse leukemia L1210 DNA topoisomerase I by intercalators. 281 25
DNA topoisomerase
was isolated from pea leaf chloroplasts. The relaxation activity of this
topoisomerase
was Mg2+ dependent and sensitive to ethidium bromide and novobiocin, a gyrase inhibitor. Chloroplast
topoisomerase
(Topo I) was ATP independent, as shown by the characteristic gel distribution of topoisomers. Topoisomerase, compared with the known eucaryotic topoisomerase I, was not stimulated by polyamines as are spermidine, spermine, and cadaverine.
Ethidium bromide
, DAPI, heparin, nalidixic acid, and m-AMSA (but not camptothecin) were able to inhibit the relaxation activity of chloroplast topo I. Nalidixic acid, novobiocin, m-AMSA, camptothecin, and amiloride were tested for their effects on the
topoisomerase
-catalyzed "cleavage complex" between DNA and chloroplast DNA topoisomerase I.
...
PMID:The influence of antibiotics and antitumor agents on the relaxation activity of Pisum sativum leaf chloroplast topoisomerase I. 779 78
Three aspects of DNA topology were examined in two human squamous cell carcinoma lines of differing radiosensitivity (SQ-9G, D0 = 1.46 Gy; and SQ-20B, D0 = 2.36 Gy). High-salt-extracted nuclei (nucleoids) were taken from gamma-irradiated cells, stained with ethidium bromide and examined by flow cytometry. After 5 Gy, nucleoids from SQ-9G cells became 30% less efficient at adopting positive DNA supercoils than were unirradiated controls. In contrast, only a 4% difference was found with the radioresistant SQ-20B line. Both lines produced positive supercoils more efficiently after irradiation if first exposed to the
topoisomerase
II inhibitor VP16.
Ethidium bromide
titration of nucleoids was consistent with each containing similar numbers and sizes of DNA loops. In each line approximately 30-35% of DNA was accessible to trioxsalen, as shown by inter-strand crosslinking after UV photo-activation. Exhaustive digestion of nuclear DNA by DNase I removed more DNA from the radiosensitive than from the radioresistant cell line (12% vs 28% remaining). This difference was thought to be due to the increased accessibility of SQ-9G DNA in vitro. We suggest that a looser association of SQ-9G DNA with the nuclear matrix both promotes DNase I digestion and affects the ability of SQ-9G nucleoids to maintain positive DNA supercoils after irradiation. These data implicate the DNA matrix attachment region in the expression of radiation sensitivity in the cell lines studied.
...
PMID:A correlation between DNA-nuclear matrix binding and relative radiosensitivity in two human squamous cell carcinoma cell lines. 809 63
A single amino acid change transforms restriction enzyme NaeI to a
topoisomerase
and recombinase (NaeI-L43K) that shows no sequence similarity to these protein families. This transformation appears to result from coupled endonuclease and ligase domains. To further elucidate the relationship between NaeI-L43K and the
topoisomerase
protein family, we studied the effect of the
topoisomerase
inhibitors on NaeI-L43K activity. The intercalative drugs amsacrine, ellipticine, and daunorubicin inhibited NaeI-L43K, whereas the nonintercalating drugs camptothecin, VP-16, and oxolinic acid did not.
Ethidium bromide
also inhibited NaeI-L43K, implying that intercalation is responsible for its inhibition. The effects of the intercalative drugs on the DNA cleavage steps of NaeI and NaeI-L43K were compared. The drugs hardly inhibited DNA cleavage by wild type NaeI but completely inhibited DNA cleavage by NaeI-L43K. This difference in inhibition demonstrates that the L43K amino acid change sensitized NaeI to these drugs. Low concentrations of the intercalative drugs, except for ethidium bromide, enhance production of
topoisomerase
--DNA covalent intermediates but inhibited production of the NaeI-L43K--DNA covalent intermediate. These results imply some unique differences between DNA relaxation by NaeI-L43K and
DNA topoisomerase
. Concomitant with studying inhibition of the cleavage intermediate, NaeI-L43K was found to covalently bond with the 5' end of the cleaved DNA strand.
...
PMID:Changing a leucine to a lysine residue makes NaeI endonuclease hypersensitive to DNA intercalative drugs. 875 63
The classic DNA intercalator, ethidium, was used to probe the effects of (i) intercalation and (ii) covalent modification of the DNA on the catalytic activity of
topoisomerase
II.
Ethidium bromide
, which binds reversibly to DNA via intercalation, does not stimulate
topoisomerase
II-mediated DNA cleavage at concentrations up to 100 microM, indicating that the intercalative binding of this molecule to DNA is not sufficient to alter the activity of the enzyme. In contrast, covalent attachment of the photoreactive ethidium analog to DNA resulted in marked enhancement of
topoisomerase
II-mediated single- and double-stranded DNA cleavage. This increase in DNA cleavage was observed at very low drug binding densities (<1 drug per 10-80 base pairs) which correspond to nanomolar concentrations, as compared with other
topoisomerase
II poisons such as etoposide or m-AMSA which require micromolar concentrations to elicit comparable DNA cleavage levels. Over the past decade,
topoisomerase
II has been an important target for a variety of clinically relevant anticancer agents due to the abilities of these agents to convert this enzyme to a cellular toxin resulting in an increase in the levels of enzyme-mediated DNA breaks. Modification of DNA by covalently attaching a DNA-targeting intercalating agent (i.e., ethidium bromide) resulted in a marked shift of the cleavage/religation equilibrium of the enzyme toward the cleaved state "poison"
topoisomerase
II as observed by the enhancement in single- and double-stranded cleavage; thus, key insight was gained into the mechanism(s) through which DNA binding agents may influence the catalytic properties of
topoisomerase
II. These data demonstrate that conversion of a reversible ethidium-DNA complex to an irreversible adduct results in the transformation of an ineffective intercalating drug into a potent
topoisomerase
II-targeted agent. Finally, they provide support for the recently proposed "positional poisoning model" for the actions of DNA lesions and anticancer drugs on the type II enzyme.
...
PMID:Covalent attachment of ethidium to DNA results in enhanced topoisomerase II-mediated DNA cleavage. 939 21
In order to study DNA replication and expression in wheat mitochondria our laboratory has been seeking to develop a system that supports DNA synthesis and transcription, either in isolated mitochondria from wheat embryos or in a mitochondrial lysate from the same source deprived of endogenous DNA in vitro. We have characterized some of the enzymes involved in the DNA synthesis and transcription process. In this study we describe a
DNA topoisomerase
activity.Broken mitochondria from wheat embryos can actively relax negatively supercoiled DNA (pBR322, pAT153, etc...). The enzyme is intramitochondrial: the activity is detected only when intact organelles are broken by non-ionic detergent. Most of the
topoisomerase
activity found in the broken mitochondria is recovered in the mitochondrial lysate. It is stimulated by Mg(2+) and has an optimum salt concentration, KCl or NaCl, between 50 mM and 100 mM. ATP has no effect on this activity.
Ethidium bromide
, berenil, novobiocine and nalidixic acid, compounds currently used to characterize DNA topoisomerases, do not effect the relaxation of supercoiled DNA by the wheat mitochondrial activity. On the other hand N-ethylmaleimide has a strong inhibitory effect indicating that sulfhydryl groups are essential for enzyme activity. The molecular weight of the enzyme as determined by glycerol gradient sedimentation, is about 110 kd. Another important feature of the mitochondrial lysate
DNA topoisomerase
is the ability to relax positively supercoiled DNA, a property of eukaryotic topoisomerases I.
...
PMID:A DNA topoisomerase type I from wheat embryo mitochondria. 2430 19
