DNA strand scission by bleomycin in the presence of Cu and Fe was further characterized. It was found that DNA degradation occurred readily upon admixture of Cu(I) or Cu(II) + dithiothreitol + bleomycin, but only where the order of addition precluded initial formation of Cu(II)--bleomycin or where sufficient time was permitted for reduction of the formed Cu(II)--bleomycin to Cu(I)--bleomycin. DNA strand scission mediated by Cu + dithiothreitol + bleomycin was inhibited by the copper-selective agent bathocuproine when the experiment was carried out under conditions consistent with Cu chelation by bathocuproine on the time scale of the experiment. Remarkably, it was found that the extent of DNA degradation obtained with bleomycin in the presence of Fe and Cu was greater than that obtained with either metal ion alone. A comparison of the sequence selectivity of bleomycin in the presence of Cu and Fe using 32P-end-labeled DNA duplexes as substrates revealed significant differences in sites of DNA cleavage and in the extent of cleavage at sites shared in common. For deglycoblemycin and decarbamoylbleomycin, whose metal ligation is believed to differ from that of bleomycin itself, it was found that the relative extents of DNA cleavage in the presence of Cu were not in the same order as those obtained in the presence of Fe. The bleomycin-mediated oxygenation products derived from cis-stilbene were found to differ in type and amount in the presence of added Cu vs. added Fe. Interestingly, while product formation from cis-stilbene was decreased when excess Fe was added to a reaction mixture containing 1:1 Fe(III) and bleomycin, the extent of product formation was enhanced almost 4-fold in reactions that contained 5:1, as compared to 1:1, Cu and bleomycin. The results of these experiments are entirely consistent with the work of Sugiura [Sugiura, Y. (1979) Biochem. Biophys. Res. Commun. 90, 375-383], who first demonstrated the generation of reactive oxygen species upon admixture of O2 and Cu(I)--bleomycin.
This work describes the first automated solid-phase synthesis of metal derivatives of peptide nucleic acid (PNA) oligomers and their interaction with DNA and PNA. PNA constitutes a relatively young and very promising class of DNA analogues with excellent DNA and RNA binding properties. However, PNA lacks a suitable handle that would permit its sensitive detection on its own as well as when hybridized with complementary oligonucleotides. Metal complexes, on the other hand, offer high potential as markers for biomolecules. In this paper, we describe the synthesis of PNA heptamers (tggatcg-gly, where gly is a C-terminal glycine carboxylic acid amide) with two covalently attached metal complexes at the PNA N-terminus, namely a ferrocene carboxylic acid derivative and a tris(bipyridine)ruthenium(II) derivative. We show how all synthesis steps may be carried out with high yield on a DNA synthesizer, including attachment of the metal complexes. The conjugates were characterized by HPLC (>90% purity) and ESI-MS. Binding studies of the purified Ru-PNA heptamer to complementary DNA and PNA and comparison to the isosequential metal-free acetyl PNA heptamer proves that the attached metal complex has an influence on the stability (UV-T(m)) and structure (CD spectroscopy) of the conjugates, possibly by disruption of the nearby A:T base pair.
The chemo- and regioselective TEMPO/BAIB-mediated oxidation of 2,6- and 3,6-dihydroxy 1-thio glycopyranosides to the corresponding 1-thio uronic acid lactones is described. These locked 1-thio glycuronides can directly be used as donors in glycosidation reactions using the Ph(2)SO/Tf(2)O reagent system. Alternatively, selective opening of the lactone bridge liberates a hydroxyl function for ensuing glycosylations.
[structure: see text]. The cyclooctenol derivative 1 can be transformed into the nine-membered ring lactone 3, as well as the amino-containing carbocycles 4 and 5. The corresponding ketone 2 gives access to the conformationally locked azasugar 6.
All lipo-chitin oligosaccharides identified from Rhizobium leguminosarum carry an O-acetyl moiety on C6 of the nonreducing terminal N-acetylglucosamine residue. Previously, we have shown that purified NodL protein, using acetyl-CoA as acetyl donor, in vitro acetylates N-acetylglucosamine, chitin oligosaccharides, and lipo-chitin oligosaccharides. In this paper, the enzymatic properties and substrate specificity of NodL protein were analyzed, using a spectrophotometric assay to quantify NodL transacetylating activity. NodL functions optimally under alkaline conditions. Transacetylating activity has a broad temperature optimum between 28 and 42 degrees C. NodL protein is stable for at least 15 min up to 48 degrees C. Glucosamine, chitosan oligosaccharides, terminally de-N-acetylated chitin derivatives, and cellopentaose were identified as acetyl-accepting substrates for NodL protein. Quantitative substrate specificity studies show that chitin derivatives with a free amino group on the nonreducing terminal residue are the preferred substrates of the NodL protein. Our results strongly indicate that the nonreducing terminally de-N-acetylated chitin oligosaccharides produced by the NodC and NodB enzymes are the in vivo acetyl-accepting substrates for NodL protein.
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