Abstract
Kinetic and structural studies of both muscle and non-muscle myosins have revealed that the enzymatic cycle of these motors frequently contains more than one actomyosin ADP state. Interestingly, the rate of ADP release in myosin motors is thought to be the main determinant of sliding velocity in muscle, suggesting strain dependent ADP release may be a critical mechanism of mechanochemical coupling. Our previous work has demonstrated that labeling myosin V in the upper 50 kDa domain with the biarsenical dye FlAsH (MV FlAsH) can serve as an acceptor for fluorescence resonance energy transfer studies with mant labeled nucleotides. We also determined that this donor-acceptor pair likely monitors opening/closing of the nucleotide binding pocket. Currently, we utilized the FRET signal to examine the kinetics of nucleotide binding pocket opening during the process of mantADP release from acto-MV FlAsH. We obtained evidence that the nucleotide binding pocket goes from a closed to an open conformation prior to the release of ADP. We also explored the temperature dependence of the closed to open transition and nucleotide release steps. We find that at lower temperatures the closed conformation is favored while at higher temperature the open conformation is favored. The more rapid ADP release step which follows nucleotide binding pocket opening is also temperature dependent. Therefore, since both steps are temperature-dependent they likely require significant conformational changes. We also compared our FRET results to the rate of ATP-induced dissociation from actin in the presence of ADP monitored by light scatter. Understanding how strain alters either of these two steps may be critical for elucidating the structural mechanism of strain-dependent ADP release in myosins.
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