The cell membrane is the main target of resveratrol as shown by interdisciplinary biomolecular/cellular and biophysical approaches.

One of the research lines developed in our laboratory is focused on the study of the bioactivity of natural substances. Resveratrol (RV) is a polyphenol nonflavonoid compound present in a number of plant species but mainly in the berries of the red grape Vitis vinifera. The powerful antioxidant action of this molecule is well documented. In this work we evaluated the effects of this substance by adopting diverse experimental strategies. In particular, we studied the effects on cell vitality and cycle by MTT and cytofluorimetric assays. In addition, we explored the action of RV on the cell membrane by a well-consolidated biophysical approach: electrorotation. This technique allows assessment of the structure/function of the cell membrane. The results presented here demonstrate that RV shows a modest effect on the biological properties of the cell in terms of cytotoxicity and cell cycle alterations. On the contrary, a significant effect on the membrane structure/function was observed, consisting of an enhanced intramembrane ion transport. The implications and interpretation of these membrane alterations are discussed.

Interactions of DMPC and DMPC/gemini liposomes with the cell membrane investigated by electrorotation.

The electrorotation technique was utilized to investigate the interactions between a mouse fibroblast cell line and zwitterionic liposomes formed by a natural phospholipid or cationic liposomes formulated with the same phospholipid and a cationic gemini surfactant. The application of this technique allowed an accurate characterization of the passive dielectric behavior of the plasma membrane by the determination of its specific capacitance and conductance. Changes of these parameters, upon interaction with the liposomes, are related to variations in the structure and or in the transport properties of the membrane. Cells were exposed to both types of liposomes for 1 or 4h. Electrorotation data show a dramatic reduction of the dielectric parameters of the plasma membrane after one hour treatment. After 4h of treatment the effects are still observed only in the case of the cationic liposomes. Surprisingly, these same treatments did not cause a relevant biological damage as assessed by standard viability tests. A detailed discussion to rationalize this phenomenon is presented.