Leigh syndrome in an infant resulting from mitochondrial DNA depletion.

Leigh syndrome is an encephalomyelopathy that results from a heterogeneous group of mitochondrial disorders characterized by symmetric brainstem spongioform lesions. An infant born with hypotonia and lactic acidosis was found to have symmetric brainstem lesions on T(2)-weighted magnetic resonance imaging consistent with Leigh syndrome. Muscle biopsy failed to reveal ragged-red fibers or cells devoid of cytochrome C oxidase or succinate dehyrogenase. Southern blot analysis of mitochondrial DNA isolated from the patient's quadriceps muscle indicated severe mitochondrial DNA depletion, which was suggested as the cause for the Leigh syndrome seen in this patient. Consideration of mitochondrial DNA depletion as an etiology when evaluating the patient with Leigh syndrome is encouraged.

Sequence-specific double-strand cleavage of DNA by Fe-bleomycin. 1. The detection of sequence-specific double-strand breaks using hairpin oligonucleotides.

A new method is described for the evaluation of sequence-specific double-strand (ds) cleavage of DNA by Fe-bleomycin (BLM). The method uses high-resolution polyacrylamide gel electrophoresis to separate single-strand (ss) and ds-cleavage products derived from hairpin oligonucleotides that have been designed to contain a specific ds-cleavage site. The BLM induced ss/ds-cleavage ratios ranged from approximately 3.3 to approximately 5.8 at 4 degrees C, with the most efficient ds-cleavage involving the thymidines of a 5'-GTAC/5'-GTAC site. Double-strand cleavage was not detected at several sites that were shown to yield significant ss-breaks. A study of the ss/ds-cleavage ratio at the 5'-GTAC/5'-GTAC site revealed that the ratio remained constant over a 70-fold range in concentration of Fe-BLM and extent of DNA degradation. The ss/ds-cleavage ratios at three sites studied were not significantly affected by the presence of "inert" Co(III)-BLM. The results are consistent with the proposal of Steighner and Povirk (1990) that a single molecule of Fe-BLM is responsible for ds-cleavage. The use of these hairpin oligonucleotides has greatly facilitated quantitative analysis of the ds-cleavage process (Absalon et al., 1995).

Sequence-specific double-strand cleavage of DNA by Fe-bleomycin. 2. Mechanism and dynamics.

The mechanism of iron-bleomycin-mediated ds-cleavage of DNA has been investigated at specific sites within specific sequences using hairpin oligonucleotides (Absalon et al., 1995) and our recently developed technique for determining sequence-specific isotope effects upon oxidative degradation of DNA (Kozarich et al., 1989; Worth et al., 1993). Isotope effects upon ds-cleavage have been observed when the C-4' hydrogen of either nucleotide involved in the ds-break was substituted with deuterium. The values of the isotope effects determined for ss and ds events occurring at the same site were indistinguishable at four sites examined in detail. The results are consistent with a mechanism of ds-cleavage in which the pathways leading to ss- and ds-cleavage partition from a common intermediate subsequent to abstraction of the C-4' hydrogen from the first nucleotide involved in the cleavage. Deuterium substitution at the primary cleavage site of a ds-break failed to result in an equivalent effect on the amount of cleavage at the secondary cleavage site, suggesting that ds-cleavage may be initiated from either of the nucleotides involved in the ds-cleavage event. A kinetic preference for cleavage initiated at the 1 degree site, however, is probable. The requirement in the ds-cleavage process for O2, in addition to that needed to form "activated BLM", has been clearly demonstrated by the absence of ds-cleavage products in reactions performed under anaerobic conditions in which ss-cleavage still occurs. These results support, in part, the basic model for ds-cleavage proposed by Steighner and Povirk [(1990) Proc. Natl. Acad. Sci. U.S.A. 87, 8350-8354], in which a single molecule of BLM effects ds-cleavage and requires reactivation to effect cleavage at the second strand. The essential factor establishing the ratio of ss- to ds-cleavage at a specific site may be related to the efficiency by which Fe-BLM can be reactivated and/or repositioned at a second site for cleavage.

Isotope effects on the cleavage of DNA by bleomycin: mechanism and modulation.

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.

Bleomycin mediated degradation of DNA-RNA hybrids does not involve C-1' chemistry.

Incubation of Fe(II) bleomycin and O2 with a number of 'A'-like DNA-RNA hybrid homopolymers at 4 atm O2 results in formation of base propenal and base in a ratio of approximately 1.0:1.0. This ratio differs dramatically from the corresponding ratio of approximately 10:1.0 observed when activated BLM degrades 'B'-like DNA homopolymers. Experiments were undertaken to determine if the shift to enhanced base production observed in the A-like hybrids is the result of C-1' chemistry in addition to the C-4' chemistry normally observed with B-like DNA under identical conditions. Increased accessibility of the 1'-hydrogen might be anticipated due to widening of the minor groove in the A-like conformers. Experiments using poly([1'-3H]dA) poly(rU) and poly([U-14C]dA) poly(rU) indicated that neither 3H2O nor deoxyribonolactone accompanied adenine release. In addition, studies using poly([4'-2H]dA) poly(rU) and poly([1'-2H]dA) poly(rU) unambiguously establish that the altered base to base propenal ratio is not the result of C-1' chemistry, but a direct consequence of C-4' chemistry.

Stereochemical studies of the beta-elimination reactions at aldehydic abasic sites in DNA: endonuclease III from Escherichia coli, sodium hydroxide, and Lys-Trp-Lys.

The DNA strand cleavage reaction catalyzed by endonuclease III from Escherichia coli (endo III) on the 3'-side of aldehyde abasic sites proceeds by a syn beta-elimination involving abstraction of the 2'-pro-S proton and formation of a trans alpha,beta-unsaturated aldose product; we previously reported the same stereochemical course for the reaction catalyzed by UV endonuclease V from bacteriophage T4 (UV endo V) [Mazumder, A., Gerlt, J. A., Rabow, L., Absalon, M. J., Stubbe, J., & Bolton, P. H. (1989) J. Am. Chem. Soc. 111, 8029-8030]. Since the UV endo V does not contain an 4Fe-4S center, the 4Fe-4S center present in endo III need not be assigned a unique role in the beta-elimination reaction. The beta-elimination reactions that occur under alkaline conditions (0.1 N NaOH) and in the presence of the tripeptide Lys-Trp-Lys proceed by anti beta-elimination mechanisms involving abstraction of the 2'-pro-R proton and formation of a trans alpha,beta-unsaturated aldose product. The different stereochemical outcomes of the enzymatic and nonenzymatic beta-elimination reactions support the hypothesis that the enzyme-catalyzed reactions may involve general-base-catalyzed abstraction of the 2'-pro-S proton by the internucleotidic phosphodiester leaving group.