I. Enami et al., IS THE PRIMARY CAUSE OF THERMAL INACTIVATION OF OXYGEN EVOLUTION IN SPINACH PS-II MEMBRANES RELEASE OF THE EXTRINSIC 33 KDA PROTEIN OR OF MN, Biochimica et biophysica acta. Bioenergetics, 1186(1-2), 1994, pp. 52-58
Incubation of PS II membranes at 45-50 degrees C for several min resul
ted in strong inactivation of oxygen evolution, concomitant with relea
se of Mn and the extrinsic proteins of 33, 23 and 17 kDa. No correlati
on was found between loss of the activity and release of the 33 kDa pr
otein or Mn. However, involvement of the protein release in the mechan
ism of heat-inactivation was suggested by stabilization of the activit
y against heat-treatment by immobilization of the 33 kDa protein with
a water-soluble carbodiimide. Furthermore, a linear correlation was fo
und between extents of heat-inactivation and amounts of the 33 kDa pro
tein released in the presence of 50 mM CaCl2, which greatly accelerate
d inactivation of oxygen evolution, release of the 33 kDa protein and
aggregation of PS II membranes at high temperatures. Evidence was obta
ined indicating that the 33 kDa protein released at high temperatures
rebinds to its functional site when temperature is lowered but CaCl2 s
uppresses rebinding of the protein by promoting intensive-aggregation
of the membranes. Thus, the activity survived in the presence of CaCl2
is proportional to the amounts of the protein remained attached to th
e membranes during heat-treatment. By contrast, release of Mn was not
affected by addition of CaCl2 so that enhanced inactivation of oxygen
evolution was not accompanied by corresponding increase in the amount
of Mn released. It is concluded, therefore, that the primary cause of
heat-inactivation of oxygen evolution is dissociation of the 33 kDa pr
otein but not that of Mn.