Sequence Preference for Strand Cleavage of Gapped Duplexes by Dynemicin A: Possible Mechanism of Sequence-Dependent Double-Stranded Breaks

Sequence Preference for Strand Cleavage of Gapped Duplexes by Dynemicin A: Possible Mechanism of Sequence-Dependent Double-Stranded Breaks

A double-stranded DNA cleavage mechanism by a novel enediyne type antitumor antibiotic, dynemicin A, has been investigated through sequence-dependent strand breakage of a series of duplexes containing a single nucleotide gap. We found that (1) dynemicin A breaks specifically at the 3'-shifted p...

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Bibliographic Details
Published in:Biochemistry (Easton) Vol. 34; no. 31; pp. 9944 - 9950
Main Authors: Kusakabe, Tetsuya, Uesugi, Motonari, Sugiura, Yukio
Format: Journal Article
Language:English
Published: United States American Chemical Society 08-08-1995
Subjects:
Alkenes
Anthraquinones - metabolism
Anthraquinones - pharmacology
Antibiotics, Antineoplastic - metabolism
Antibiotics, Antineoplastic - pharmacology
Base Sequence
DNA - drug effects
DNA Damage
DNA, Superhelical - drug effects
Enediynes
Intercalating Agents - pharmacology
Models, Chemical
Molecular Sequence Data
Oligodeoxyribonucleotides
Thioglycolates
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Summary:A double-stranded DNA cleavage mechanism by a novel enediyne type antitumor antibiotic, dynemicin A, has been investigated through sequence-dependent strand breakage of a series of duplexes containing a single nucleotide gap. We found that (1) dynemicin A breaks specifically at the 3'-shifted position by one base opposite the gap, (2) the strong cleavage is detected at 5'-Pu_Pu/3'-PyPuPy sequences, and (3) dynemicin H (aromatized form of dynemicin A) gives only a small inhibition effect (20%) on the cleavage of gapped duplex by dynemicin A. The long half-life of aromatization of dynemicin A (118 min, in the presence of DNA) obtained from HPLC analysis provides enough time for the second cleavage. The present results strongly indicate a two-step mechanism for the double-stranded DNA scission of dynemicin A. Namely, this double-stranded break is caused by two drug molecules, each of which cuts one DNA strand.
Bibliography:istex:5C86E5E868C95CD59D437BA9D69F16D9FC2073FF
ark:/67375/TPS-M93RFTVQ-2
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ISSN:0006-2960
1520-4995
DOI:10.1021/bi00031a017