Ditrisarubicin B

DNA binding characteristics of ditrisarubicin B were studied by the fluorescence titration technique. Ditrisarubicin B bound to calf thymus DNA with an affinity higher than any we have ever seen among anthracyclines. The apparent association constant (Kapp) of ditrisarubicin B was 2.36 X 10(8) M-1, which is 22.7 times larger than that of doxorubicin. The apparent number of binding sites (napp) of ditrisarubicin B per nucleotide of DNA was 0.164, and this value is identical with that of doxorubicin. Betaclamycin A, which has a trisaccharide chain at C-7 but no carbohydrate at C-10 in the aglycone, interacted with DNA to give a Kapp of 5.92 X 10(6) M-1 and napp of 0.178. These results suggest to us that the high affinity of ditrisarubicin B for DNA is caused by the existence of a glycosidic chain at C-10.

DNase I and three DNA chemical footprinting agents were used to compare the DNA binding properties of the anthracycline antitumor antibiotics daunomycin, aclacinomycin A, and ditrisarubicin B. These anthracyclines contain a tetracyclic chromophore which intercalates into DNA and a monosaccharide, trisaccharide, and two trisaccharide side chains, respectively. These side chains consist of between one and three 2,6-dideoxy, 1,4-diaxially linked sugars. Three chemical probes, fotemustine, dimethyl sulfate, 4-(2'-bromoethyl)phenol, and the enzymic probe DNase I were used in the footprinting experiments. The chemical probes provided a clear picture of the binding pattern at 37 degrees C and more detailed information than that obtained using the standard DNase I footprinting assay. All three anthracyclines showed preferred binding to 5'-GT-3' sequences in both the chemical and enzymatic footprinting. DNase I footprinting showed that the number of base pairs of DNA protected from cleavage increased with the number of saccharide groups present at particular sites and is consistent with DNA binding of the saccharide side chains. Alkylation of runs of guanine by fotemustine was inhibited by all three anthracyclines, while alkylation by dimethyl sulfate was enhanced for most guanines. The probe 4-(2'-bromoethyl)phenol showed that all three anthracyclines completely protected all of the adenines in the minor groove from alkylation, and enhanced major groove guanine alkylation was observed with aclacinomycin A, daunomycin, and, to a much lesser extent, ditrisarubicin B. These results are consistent with intercalation of the aglycone ring and binding of the rigid, hydrophobic saccharide side chains in the minor groove. Footprinting of four methyl glycosides related to the anthracyclines showed no evidence of DNA binding with any of the agents studied.

DNase I footprinting has been used to examine the sequence selective binding of ditrisarubicin B, a novel anthracycline antibiotic, to DNA. At 37 degrees C no footprinting pattern is observed, the drug protects all sites from enzymic cleavage with equal efficiency. At 4 degrees C a footprinting pattern is induced with low drug concentrations which is different from that produced by daunomycin. The best binding sites contain the dinucleotide step GpT (ApC) and are located in regions of alternating purines and pyrimidines.