Delayed activation of calcium pump during transient increases in cellular Ca2+ concentration and K+ conductance in hyperpolarizing human red cells.

The net Ca2+ influx was increased in human red cells in suspension by adding moderate concentrations of the Ca2+ ionophore A23187, and due to the increased cellular Ca2+ concentration [( Ca]i) the K+ channels opened (the 'Gardos effect'). At low K+ concentration and with the protonophore CCCP in the buffer-free medium the cells hyperpolarized and the extracellular pH (pH0) increased, enhancing the A23187-mediated net Ca2+ influx. This elicited a prolonged response, viz. a primary transient increase of pH0 and [Ca]i followed by one or more spontaneous pH0 and [Ca]i transients. We explored the pump-mediated Ca2+ efflux by blocking the A23187-mediated Ca2+ flux with CoCl2 at appropriate times during the prolonged response. The Ca2+ pumping was higher during the descendent than during the ascendent phase of the primary transient at equal values of [Ca]i. The data were analyzed using a mathematical model that accounts for the prolonged oscillatory response, including pH0 and [Ca]i. In conclusion, the activation of the Ca2+ pump is delayed due to slow binding of cellular calmodulin, which is a hysteretic response to a rapid increase of the cellular Ca2+ concentration. This mechanism may be important for generation and execution of transient signals in other types of cell.