Michael P. Gamcsik

Role of glutathione in cellular resistance to alkylating agents

Both elevated glutathione levels and increased activity of the enzyme glutathione S-transferase have been associated with the resistance of cells to alkylating agents. We have demonstrated that one mechanism of this resistance is the inactivation of the alkylating agents by conjugation with glutathione. This conjugation can be catalyzed by glutathione S-transferase. For the nitrogen mustard agents we have studied, both the spontaneous and enzyme catalyzed reactions proceed through the aziridinium intermediates of the alkylating agents, and the alpha isoenzymes of GST are involved. In a study of cyclophosphamide resistant medulloblastoma cell lines elevated cellular concentrations of glutathione correlated well with the resistance of the cell lines.

Formation, intracellular distribution and efflux of glutathione-bimane conjugates in drug-sensitive and -resistant MCF-7 cells

Abstract The rate of reaction of monochlorobimane with glutathione (GSH) was measured in native human mammary MCF-7 adenocarcinoma cells (MCF-7wt) and sublines displaying resistance to 4-hydroperoxycyclophosphamide (MCF-7hc) and adriamycin (MCF-7adr) prior to examination by epifluorescence and confocal microscopy. After a 60-min incubation period at 37 °C, essentially all GSH was conjugated in the MCF-7wt and MCF-7adr cell lines whereas only 80% of the GSH was conjugated in the MCF-7hc line. All three lines displayed significant export of the conjugate from the cell during this period, with the MCF-7adr line displaying the most rapid efflux with 85% of the conjugate exported within 60 min. Epifluorescence microscopy detected an approximately 20% increase in integrated fluorescence intensity in the nuclear region in all three lines. Confocal microscopy however, indicated that most of the cells examined showed a homogeneous fluorescence distribution. The cells grown in monolayers were found to be thicker in the nuclear region suggesting that the observed increase in fluorescence intensity in the nuclear region in the images from epifluorescence microscopy was probably derived from fluorescence from an out-of-focus plane. Cells depleted of GSH with buthionine sulfoximine followed by treatment with mBCl showed significant fluorescence intensity resulting from nonspecific binding of this probe. These studies illustrate the need for measuring the rate of GSH conjugate export and for determining probe specificity, and emphasizes the need for using confocal techniques for the quantitative evaluation of the distribution of intracellular fluorescence.

Kinetics of the conjugation of aniline mustards with glutathione and thiosulfate

The rates of the non-enzymatic conjugation of the substituted aniline mustards, melphalan, chlorambucil and p-(N,N-bis(2-chloroethyl))toluidine with glutathione and thiosulfate were determined using nuclear magnetic resonance spectroscopy. Using this method, the disappearance of drug and the formation of both the mono-thioether and bis-thioether conjugates can be monitored directly. For glutathione conjugation, the rate constants for the formation of the first and second aziridinium intermediates were similar. With thiosulfate conjugation, the rate constant for the formation of the first aziridinium intermediate is greater than the rate constant for the formation of the second aziridinium. This demonstrates that the type of nucleophile has a significant influence on the overall alkylating activity of these bifunctional mustards. The bisthioether adduct formed from the reaction between p-(N,N-bis([2-13C]-2-chloroethyl))toluidine and glutathione and thiosulfate can be identified and scrambling of the 13C label in the product provides strong evidence that the alkylation must occur through an aziridinium intermediate.

Two-Dimensional NMR Study of Bleomycin and Its Zinc(II) Complex: Reassignment of 13C Resonances

Two-dimensional NMR experiments--one bond 1H-13C correlation spectroscopy and heteronuclear multiple bond correlation spectroscopy, both performed in the reverse detection mode--have been employed to unambiguously assign all of the 13C resonances of the antibiotic bleomycin and its zinc(II) complex. Previous 1H resonance assignments of bleomycin (Chen et al. (1977) Biochemistry 16, 2731-2738) were confirmed on the basis of homonuclear Hartmann-Hahn and homonuclear COSY experiments. The 13C assignments differ substantially from those previously obtained by other investigators (Naganawa et al., (1977) J. Antibiot. 30, 388-396; Dabrowiak et al., (1978) Biochemistry 17, 4090-4096) but are in agreement with those reported by Akkerman et al. (1988) (Magn. Reson. Chem. 26, 793-802). The more recent study employed similar two-dimensional correlation experiments (performed in the direct detection mode) in conjunction with attached proton tests. Their study often required model compound data to identify carbonyls adjacent to aliphatic moieties. Previous 13C NMR studies of the structure, pH titration, and molecular dynamics of bleomycin and its zinc complex have been reinterpreted in terms of the revised assignments.

NMR Studies of the Interaction of Bleomycin with (dC-dG)3

The interaction of bleomycin A2 and Zn(II)-bleomycin A2 with the oligonucleotide (dC-dG)3 has been monitored by nuclear magnetic resonance spectroscopy. Binding of the drug to the oligonucleotide is indicated by an upfield shift of the bithiazole proton resonances consistent with partial intercalation of this group between base pairs. The effect of temperature and ionic strength on the binding of both free bleomycin and the Zn(II) complex has been studied. Consistent with earlier studies on polynucleotides, the rate of exchange between the free drug and the drug-oligonucleotide complex is rapid on the 1H NMR chemical shift time scale. Binding of the oligonucleotide induced changes in resonances assigned to protons in the metal-binding region of Zn(II)-bleomycin. Intermolecular nuclear Overhauser effect enhancements between bleomycin and the oligonucleotide have not been detected.