LOCAL ENVIRONMENTAL-CHANGE FROM THE G-FORM TO F-FORM OF THE ACTIN MOLECULE DETECTED ON ANISOTROPY DECAY MEASUREMENT

The fluorescence intensity has been reported to increase 10 to 25 times when N-(1-pyrene)-iodoacetamide (PIAA)-conjugated actin polymerizes from the G- to the F-form. To elucidate the molecular mechanism underlying this process, we measured the time-averaged anisotropy of PIAA-actin in both the G- and F-forms. The anisotropy ratio of PIAA-G-actin (0.137+/-0.008) was smaller than that of PIAA-F-actin (0.221+/-0.008). Similar results were obtained when N-(1-pyrene)-3-iodopropionamide (PIPA), a PIAA analogue with an extra carbon-chain in its reactive group, was conjugated with actin. The anisotropy ratio increased from 0.096+/-0.042 to 0.199+/-0.035 when PIPA-actin was transformed from the G- to the F-form. Further more, we measured the anisotropy decay of PIAA-actin in both the G- and F-forms. Least-square fitting revealed that the decay pattern was well fitted the wobbling-in-cone model. In the G-form, the pyrene of PIAA actin diffused in a cone region with a vertical half angle of 33.4 degrees. This value decreased to 25.9 degrees when the actin was transformed to the F-form. Because PIAA and PIPA were conjugated at Cys-374 of actin, our results suggest that a small cleft exists in the actin molecule in the vicinity of Cys-374, and this cleft becomes narrow upon polymerization, resulting in an increase in fluorescence intensity.