Nuclear membrane sphingomyelin-cholesterol changes in rat liver after hepatectomy.

Sphingomyelin and cholesterol play an important role in stabilising the plasma membranes architecture and in many physiological process such as cell growth and differentiation. Degradation of sphingomyelin by exogenous sphingomyelinase induces a decrease of cholesterol due either to an increase of esterification or to a reduced biosynthesis. Variations of sphingomyelin due to the presence of a neutral-sphingomyelinase and of sphingomyelin-synthase have been recently shown in rat liver nuclear membranes. The aim of this research is to study the relation between sphingomyelin and cholesterol in the nuclear membranes following sphingomyelinase activation and during cell proliferation. The nuclear membranes, isolated from liver nuclei, were analysed for their content in protein, nucleic acids, and lipids (sphingomyelin and cholesterol) before and after sphingomyelinase activation and during hepatic regeneration. The activities of nuclear membrane SM-syntase and sphingomyelinase were also determined. The results confirmed that also in the nuclear membranes sphingomyelinase, especially exogenous, causes a strong decrease in cholesterol. The increase observed of sphingomyelin during the first 18 h after hepatectomy followed by a decrease at 24 h, due to the different activity of the enzymes, is accompanied by similar behaviour of cholesterol. This confirms the effect of neutral-sphingomyelinase on cholesterol, due to an increase of esterification process. Changes in cholesterol content modify the nuclear membranes fluidity and, as consequence, mRNA transport as previously shown. It can therefore be concluded that the neutral sphingomyelinase, present in the nuclei, may, across this mechanism, regulate the cell function.

Handling of doxorubicin by the LLC-PK1 kidney epithelial cell line.

The characteristics of doxorubicin handling have been studied in the cultured kidney epithelial cell line LLC-PK1, which has structure and function similar to those of renal tubular cells and expresses P-glycoprotein. The uptake of doxorubicin by LLC-PK1 cells was time dependent, reaching a steady state at about 4 hr, and reduced at low temperature; the initial uptake was saturable. The efflux of doxorubicin from LLC-PK1 cells was also temperature dependent but, even at 37 degrees C, a significant percentage of the drug remained associated with the cells after 180 min, which suggests a strong cellular binding, and the fluorescence microscopy revealed that the drug was concentrated in intracellular organelles. Substances that are substrates for P-glycoprotein, such as verapamil, vinblastine, vincristine and quinidine, significantly increased doxorubicin concentrations in LLC-PK1 cells. Similar results were obtained with the metabolic inhibitors sodium metavanadate and 2,4-dinitrophenol. On the other hand, the uptake was not affected by the classic organic cation transport drugs cimetidine, decynium 22 or decynium 24, nor by the organic anion drug probenecid. These results indicate that, in LLC-PK1 cells, doxorubicin enters by passive diffusion, is trapped in intracellular organelles and then is extruded from cells by a mechanism that probably involves P-glycoprotein. On the contrary, substances that interfere with the renal organic cation or anion secretory system have no effect on doxorubicin net accumulation in these cells.