RAMAN DIFFERENCE SPECTROSCOPIC STUDIES OF THE MYOSIN S1-CENTER-DOT-MGADP VANADATE COMPLEX

The Raman spectra of the nonbridging V chemical anion O bonds in the m yosin S1.MgADP.Vi complex, often believed to be a transition-state ana logue for the phosphotransfer reaction catalyzed by myosin, and in a v anadate solution model compound have been obtained using Raman differe nce spectroscopic techniques. A symmetric/asymmetric pair of modes at 870 cm(-1) is found for vanadate in solution while three bands are fou nd in the myosin S1.MgADP.Vi complex at 870, 844, and 829 cm(-1). Usin g empirical relationships that relate bond order/bond lengths to stret ch frequencies, the bond order and bond length of the three nonbridgin g V chemical anion O bonds of vanadate in solution were determined to be 1.43 vu (+/- 0.04 vu) and 1.669 Angstrom (+/- 0.004 Angstrom), resp ectively. The average bond order and bond length of the nonbridging V chemical anion O bonds in the S1.MgADP.Vi complex were determined to b e 1.38 vu and 1.683 Angstrom. A normal-mode analysis suggests that the VO32- moiety approaches a planar conformation in the enzymic complex. Ab initio calculations show that a water molecule at the S1 ATPase bi nding site, in line with the apical O-V bond in the ADP-Vi moiety and believed to be the attacking nucleophile in the phosphotransfer reacti on, can account well for the changes in frequencies of vanadate when i t binds to the protein by forming a moderately strong V-O(H-2) bond. H ence, an important role determining the ATPase activity at the active site of myosin appears to be a strategic positioning of this in-line w ater molecule. Assuming that the distortions that vanadate undergoes u pon forming the S1.MgADP.Vi complex are analogous to the changes of th e gamma-phosphate of ATP in the transition state of the myosin-catalyz ed hydrolysis, our results suggest that this reaction proceeds close t o a concerted (S(N)2-like) process.