1. With ITP as substrate, the initial burst of Pi-liberation was about 1 mole/4×105g of myosin at high concentrations of MgCl
2 (1-10mM), but it decreased with decrease in the concentration of MgCl
2 below 1mM.
2. The time-course of TCA-labile
32P
i-liberation from the myosin-γ-
32P-ATP system was measured after adding the stoichiometric amount of γ-
32P-ATP to myosin, together with various amounts of ITP, deoxy-ATP or ADP. The amount of initial burst of 32Pi-liberation decreased with increase in the concentration of ITP, deoxy-ATP or ADP, but its initial rate was not affected by adding ATP analogues.
3. The initial rapid liberation of H
+ after mixing the stoichiometric amount of ATP with myosin was measured using a stopped-flow method. The rate of the initial rapid H
+-absorption was too fast to be observed by this method.
4. In addition to the rapid stoichiometric H
+-liberation, a slow stoichiometric liberation was observed with a pH-stat after adding the stoichiometric amount of ATP to myosin. The rate constants of the slow liberation were 0.7 and 0.4min
-1, respectively, in 0.5 and 2.8M KCl. The rate in 0.5M KCl was much lower than that after adding a large amount of ATP. The rate in 2.8M KCl was almost equal to the initial rate after adding a large amount of ATP, but the latter decreased gradually to that in the steady state.
5. The time-course of change in optical density at 293mμ after mixing the stoichiometric amount of ATP with myosin was equal to that of the initial rapid H
+-liberation under the same conditions.
6. When the stoichiometric amount of ATP was mixed with myosin, the ultraviolet spectrum of myosin changed rapidly, as mentioned above, and then the change decayed gradually. The time for half maximum decay, τ
1/2, was about 50 sec. This value was in good agreement with the τ
1/2 value for ADP-liberation from the myosin-phos-phate-ADP complex, _??_
7. The amount of change in the spectrum of myosin induced by ATP remained constant between pH 6.0 and 9.5. The value of τ
1/2 of the decay was maximal at pH 7.5 and decreased on both acidic and alkaline sides. The value of τ
1/2 increased with increase in the KCl concentration.
8. When myosin was incubated with NTP
*** for 2hr in the presence of 2mM ATP, 0.6
M KCl and 10μM MgC1
2, 2 moles of NTP were bound to 4×105
g of myosin and the extra-burst was completely inhibited. However, the stoichiometric initial burst of P
i-liberation and the ATPase activity in the steady state were unaffected, and the ability of myosin to bind to F-actin was preserved.
9. ATP did not induce superprecipitation of actomyosin reconstituted from F-actin and NTP(2)-myosin produced by the method described above. The ATPase activity of actomyosin was slightly inhibited in 0.05M KCl, 10μM MgCl
2 and 0.4mM ATP, and markedly inhibited in 0.01M KCl, 10μM MgCl
2 and 0.1mM ATP, by treatment of myosin with NTP.
10. On the basis of the reaction mechanism of the myosin-ATP system described in this series of papers, a molecular mechanism of muscle contraction was proposed: sliding of F-actin filaments past myosin filaments is induced by a conformational change of myosin coupled with the cyclic phosphorylation and dephosphorylation of myosin, and by the dissociation of actomyosin caused by formation of the myosin-phosphate-ADP complex, _??_. Which of these two reactions occurs depends on the conformation of myosin.
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