Bleomycin is a metal- and oxygen-dependent DNA cleaver. The chemistry of DNA damage has been proposed to involve rate-limiting abstraction of the 4'-hydrogen. A DNA fragment has been prepared that contains [4'-2H]thymidine residues of high isotopic content. Primary kinetic isotope effects have been directly observed at individual thymidine residues with DNA sequencing technology.
The thiol-activated neocarzinostatin chromophore cleaves duplex oligonucleotides containing the sequence-TGTTTGA-, producing 3'-phosphoglycolate and 3'-phosphate fragments at T, indicating the involvement of 4'- as well as 5'-chemistry at this residue. Substitution of deuterium for hydrogen at the C-4' position of the affected T leads to a kinetic isotope effect (kH/kD) of 4.0 on the formation of the glycolate-ended product, whereas deuterium at C-5' of the same T reveals kH/kD of 1.6 in the formation of the phosphate-ended product. The proportion of the products representing 4'- and 5'-chemistry can be shifted on the basis of isotope selection effects. A second product resulting from 4'-chemistry, the abasic site associated with 4'-hydroxylation, has been identified as an alkali-labile site, and as a pyridazine derivative formed after cleavage by hydrazine. A comparable isotope effect on its production (kH/kD = 3.7) relative to that of 3'-phosphoglycolate production is consistent with a common intermediate, a putative 4'-peroxy radical, in their formation. The formation of both products of 4'-chemistry is oxygen-dependent, and the internal partitioning between them (3'-phosphate or 3'-phosphoglycolate) is influenced by thiols. Moreover, the nitroaromatic radiation sensitizer misonidazole can substitute for dioxygen, yielding 3'-phosphoglycolate and alkali-labile 3'-phosphate ends, indicative of 4'-chemistry. In addition to the internal partitioning of 4'-chemistry, thiols also affect the overall extent of cleavage (4' plus 5') and the relative partitioning between both sites of attack (4' or 5').
Sequence-specific isotope effects on the cleavage of DNA at thymidine residues by activated iron.bleomycin (Fe.BLM) have been observed upon incorporation of [4'-2H]thymidine into the DNA. The effects may be quantitated by end-labeling the DNA with phosphorus-32, generating a sequence ladder by gel electrophoresis, and measuring the relative damage at cleavage sites by autoradiography or phosphorimager technology. Results with DNA deuteriated at other positions of the deoxyribose ring, such as, the 5'- or 2'-carbon, afford no isotope effect suggesting high regiospecificity for the BLM-mediated carbon-hydrogen bond cleavage. The magnitude of the 4'-isotope effects for Fe.BLM ranges from 2 to 7 (+/- 0.3) and is not sensitive to changes in the partition ratio of the two proposed cleavage pathways. However, the isotope effect is sensitive to structural changes in BLM, such as with tallysomycin, and to changes in metal and cleavage mechanism, such as with Co.BLM. The variability of the effects are discussed in light of the factors responsible for the observation of V/K isotope effects. The findings suggest that the kinetics, thermodynamics, and geometry of carbon-hydrogen bond cleavage by Fe.BLM permit the observation of large isotope effects on this chemical step. Fe.BLM may be viewed, therefore, as a special case.
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