THE ROLE OF PROTEIN CHARGE IN PROTEIN LIPID INTERACTIONS - PH-DEPENDENT CHANGES OF THE ELECTROPHORETIC MOBILITY OF LIPOSOMES THROUGH ADSORPTION OF WATER-SOLUBLE, GLOBULAR-PROTEINS

The role of electrostatics in the adsorption process of proteins to preformed negatively-charged (phosphatidylcholine/phosphatidylglycerol) and neutral (phosphatidylcholine) liposomes was studied. The interaction was monitored at low ionic strength for a set of model proteins as a function of pH. The adsorption behavior of trypsin inhibitor (pI = 4.6), myoglobin (pI = 7.4), ribonuclease (pI = 9.6), and lysozyme (pI = 10.7) with preformed liposomes was investigated, along with changes in the electrophoretic mobility of liposomes through the adsorption of charged proteins. Mean protein charge was determined by acid/base titration. Significant adsorption of the proteins to negatively-charged liposomes was only found at pH values where the number of positive charge moieties exceeds the number of negative charge moieties on the protein by at least three charge units. Negligible adsorption to liposomes composed of zwitterionic lipids was observed in the pH range tested (4-9). The absolute value of the electrophoretic mobilities of negatively-charged, empty liposomes decreased after adsorption of positively-charged proteins. With increasing protein to phospholipid ratio, the drop in the electrophoretic mobility leveled off and reached a plateau; protein adsorption profiles showed a similar shape. Analysis of the data demonstrated that neutralization of the liposome charge due to the adsorption of the positively-charged proteins is the controlling factor in their adsorption. The plateau level reached depended on the type of protein and the pH of the incubation medium. This pH dependency could be ascribed to the mean positive charge of the protein. The effective charge of myoglobin, ribonuclease, and lysozyme (defined as the number of phosphatidylglycerol groups neutralized by one adsorbed protein molecule) was calculated from the charge differences between empty liposomes and protein-coated liposomes using the Gouy-Chapman theory. For lysozyme and myoglobin, an excellent correlation was found between the effective charge and the mean protein charge.