Membrane adhesion in reconstituted proteoliposomes containing the light-harvesting chlorophyll ab-protein complex: The role of charged surface groups

The light-harvesting chlorophyll $\text{a}\text{b}$-protein complexes (LHCP) of spinach, pea, and barley thylakoids apparently contain four nonidentical polypeptide subunits of between 29,000 and 23,000 daltons on highly resolving sodium dodecyl sulfate-polyacrylamide gradient gels. Trypsin treatment of the spinach complex degraded at least the two major subunits by approximately 2000 daltons and resulted in a three-subunit pattern on gels. Proteoliposomes reconstituted with LHCP and the chloroplast diacyl lipids aggregated markedly in the presence of cations but vesicles containing LHCP prepared from trypsin-treated thylakoids did not. Amino acid analysis of native- and trypsin-treated LHCP indicated that the fragment(s) released by trypsin, which is essential for cation-induced stacking of thylakoids, contains lysine and arginine, but not aspartate or glutamate, and is thus cationic. Carboxyl groups on the surface of LHCP were charge neutralized using a water-soluble carbodiimide (1-ethyl-(3-dimethylaminopropyl)carbodiimide) plus ¹⁴C]glycine ethyl ester. Only two or three sites were labeled per 26,000-dalton polypeptide equivalent and only a minor fraction of this (22–24%) was located in the surface fragment(s) released by trypsin. Both LHCP and LHCP proteoliposomes, after carboxyl modification, aggregated avidly at low salt concentrations. The findings suggest that exposed anionic groups on the surface of LHCP contribute to an electrostatic repulsive force between membranes which must be attenuated, either by cation binding or chemical neutralization, before membrane-membrane adhesion can occur. In line with this the binding of Mn²⁺ by LHCP (approximately four Mn²⁺ bound/26,000-dalton polypeptide equivalent) was sharply decreased after carboxyl modification.