Distribution study of peplomycin in rat kidney revealed by immunocytochemistry using monoclonal antibodies.

Peplomycin (PEP), an anti-tumor antibiotic related structurally to bleomycin, is widely used, especially for squamous cell carcinoma but shows renal toxicity. We prepared monoclonal antibodies (mAbs) against N-(γ-maleimidobutyryloxy)succinimide-conjugated PEP. The mAbs were monospecific for PEP, but did not react with bleomycin and other anticancer antibiotics. The mAbs enabled us to develop an immunocytochemical (ICC) method for detecting the uptake of PEP in the rat kidney. Two hours after a single i.v. administration of PEP, ICC revealed immunostaining for PEP in irregularly shaped cytoplasmic granules of the proximal tubules in which the microvilli were also stained. Also, staining occurred in the distal tubules and collecting ducts, in both of which we observed scattered swollen cells, reminiscent of necrotic cells, in which both the nuclei and cytoplasm reacted strongly with the antibody. Twenty-four hours after injection, PEP in the proximal tubules completely vanished, but yet significant amounts of PEP remained in both the distal tubules and collecting ducts. Distribution patterns of PEP in cells of the kidneys resembled, in some ways, those of our recent ICC studies for an organic cation aminoglycoside antibiotic gentamicin. This ICC suggests that PEP taken up in the proximal tubule cells is localized in the lysosomes, and organic cation transporters and bleomycin hydrolase might be involved in entrance and/or disappearance of PEP in this cell type. Furthermore, the distal tubules and collecting ducts may be the sites readily affected by some chemotherapeutic agents.

Deglyco-peplomycin metal complexes on DNA fibers: a role of the sugar moiety for the stability and the orientation of the complexes.

Binding structures of metal complexes of deglyco-peplomycin (dPEP) on DNA were investigated by comparing dPEP complexes with those of bleomycin (BLM) using DNA fiber EPR spectroscopy. A low spin species of Fe(III)dPEP observed in the DNA pellet changed irreversibly to several high spin species after the fabrication of the DNA fibers. The g values of the high spin species were different from those of Fe(III)BLM. The high spin species could not be nitrosylated reductively to ON-Fe(II)dPEP, suggesting that some nitrogen atoms coordinated to the Fe(III) were displaced on the DNA fibers. On the other hand, O(2)-Co(II)dPEP remained intact on the fibers similarly to O(2)-Co(II)BLM but with an increased randomness in the orientation on the DNA. In contrast to Cu(II)BLM, a considerable amount of Cu(II)dPEP bound almost randomly on B-form DNA fibers. These results indicated that the sugar moiety in peplomycin or bleomycin is playing an important role in enhancing the stability of the metal-binding domain and in the stereospecificity of the binding on DNA.

Mapping of the cleavage-associated bleomycin binding site on DNA with a new method based on site-specific blockage of the minor groove with N2-isobutyrylguanine.

Although the binding of various forms of bleomycin to DNA has been studied extensively, the transient nature of the activated bleomycin species which ultimately attacks DNA has largely precluded direct examination of its physical interactions with DNA. In an attempt to map the minimum binding site required for this species to effect DNA cleavage, several oligonucleotide duplexes were synthesized, each of which contained a single N2-isobutyrylguanine moiety at a specific position in the sequence. These duplexes were end-labeled, and sequence-specific bleomycin-induced cleavage was assessed in each strand of each duplex. Isobutyrylguanine substitution immediately 5' to a primary bleomycin target site suppressed bleomycin-induced cleavage by more than 10-fold. Substitution two bases 5' to a target site suppressed cleavage by about 4-fold, and substitution directly opposite the target site suppressed cleavage by 7-fold. Substitution immediately 3' to the target site, or at other more distant positions 3' or 5', had little or no effect. In cases where cleavage at a primary site was strongly suppressed, cleavage at the corresponding secondary site (the putative site of the second break in a bleomycin-induced double-strand break) was also inhibited, even when the secondary site was several bases away from the isobutyrylguanine substitution. The results suggest that the binding site required for bleomycin-induced DNA cleavage spans a region of approximately 2 or 3 bp in the minor groove, including the base associated with the sugar attacked and one or two bases to its 5' side. Computer-based molecular modeling indicated that these results are consistent with the predictions of recently proposed models in which the bithiazole is intercalated immediately 3' to the cleavage site, and the iron coordination site binds in the minor groove immediately 5' to the cleavage site. Both the empirical data and the modeling studies suggest that N2-isobutyrylguanine substitution effectively blocks the minor groove, but without significantly disturbing DNA secondary structure. Thus, it is proposed that site-specific incorporation of N2-isobutyrylguanine may provide a general method for mapping binding sites of minor groove-binding ligands on DNA.