Abstract
Alpha-crystallin, a major protein of mammalian lens, consists of two subunits, alpha A-crystallin and alpha B-crystallin. They interact to form an aggregate and play a prominent role in the maintenance of lens transparency. We evaluated the interaction between these subunits via surface plasmon resonance (SPR) using four combinations of immobilized protein and analyte: 1) AA: alpha A-crystallin was ligand immobilized onto the sensor and alpha A-crystallin was passed over the ligand, 2) AB: ligand - alpha A-crystallin, analyte - alpha B-crystallin, 3) BB: ligand - alpha B-crystallin, analyte- alpha B-crystallin, 4) BA: ligand - alpha B-crystallin, analyte - alpha A-crystallin. The order of rate of dissociation was AA ≈ BA > BB ≈ AB. We also examined the dissociation of gamma irradiated alpha A- and alpha B-crystallins. As radiation dose increased, so did the dissociation rate of all of the crystallins. The order of rate of dissociation of irradiated crystallins was BB > AB ≈ BA > AA. The results indicate that BB is the most susceptible to gamma-irradiation and that alpha B-crystallin forms a more stable aggregate than alpha A-crystallin under normal conditions. However, when alpha B is irradiated the aggregate becomes unstable.
