Disruption of cellular signaling pathways by daunomycin through destabilization of nonlamellar membrane structures.

Albeit anthracyclines are widely used in the treatment of solid tumors and leukemias, their mechanism of action has not been elucidated. The present study gives relevant information about the role of nonlamellar membrane structures in signaling pathways, which could explain how anthracyclines can exert their cytocidal action without entering the cell [Tritton, T. R. & Yee, G. (1982) Science 217, 248-250]. The anthracycline daunomycin reduced the formation of the nonlamellar hexagonal (HII) phase (i.e., the hexagonal phase propensity), stabilizing the bilayer structure of the plasma membrane by a direct interaction with membrane phospholipids. As a consequence, various cellular events involved in signal transduction, such as membrane fusion and membrane association of peripheral proteins [e.g., guanine nucleotide-binding regulatory proteins (G proteins and protein kinase C-alpha beta)], where nonlamellar structures (negative intrinsic monolayer curvature strain) are required, were altered by the presence of daunomycin. Functionally, daunomycin also impaired the expression of the high-affinity state of a G protein-coupled receptor (ternary complex for the alpha 2-adrenergic receptor) due to G-protein dissociation from the plasma membrane. In vivo, daunomycin also decreased the levels of membrane-associated G proteins and protein kinase C-alpha beta in the heart. The occurrence of such nonlamellar structures favors the association of these peripheral proteins with the plasma membrane and prevents daunomycin-induced dissociation. These results reveal an important role of the lipid component of the cell membrane in signal transduction and its alteration by anthracyclines.

Functional expression of mouse Mdr1 in an outer membrane permeability mutant of Escherichia coli.

Functional expression of the multidrug resistance protein P-glycoprotein (P-gp) in Escherichia coli is providing an appropriate system for structure/function studies and might provide an invaluable tool to screen potential P-gp substrates and inhibitors. The major problem encountered in such studies, however, is the impermeability of the outer membrane of Gram-negative bacteria, which protects microorganisms against the cytotoxic effects of many lipophilic cancer drugs and blocks accessibility of P-gp reversal agents. In the present study we have constructed, by mutagenesis, a "leaky" (containing a permeable outer membrane) strain of E. coli, which is significantly more susceptible to the toxic effect of known P-gp substrates and cytotoxic agents. Expression of mouse Mdr1 in the mutant confers cross-resistance to daunomycin, quinidine, chloroquine, rhodamine 6G, and puromycin. Most importantly, reserpine and doxorubicin completely abolish Mdr1-mediated rhodamine resistance. The results provide strong support for previous observations, suggesting that Mdr1 can be expressed functionally in E. coli and indicate that the leaky mutant will be useful for further structure/function studies of the heterologously expressed eukaryotic drug efflux protein.