Intracellular [Ca2+] transients in voltage clamped cardiac Purkinje fibers

Abstract

The Ca²⁺-activated bioluminescent protein aequorin was used to observe intracellular [Ca²⁺] transients in voltage clamped canine Purkinje fibers. The pattern of luminescence during a voltage clamp pulse was characterized by two components: L₁, which is a rapid initial increase in luminescence and L₂, which is a slower, secondary rise of variable configuration. L₁, L₂, inward current, and contraction were abolished by D 600 (2 μM). Paired clamp pulses. L₁ reprimes more rapidly than L₂; L₁ reprimes within 100 ms, L₂ does not. Clamp pulse duration. Peak inward current was the same for 50 ms or 500 ms clamp pulses; L₁ was either the same or slightly reduced in 50 ms clamp pulses compared to 500 ms clamp pulses. L₂, however, was abolished in repetitively given 50 ms pulses compared to repetitively given 500 ms pulses. When 500 ms pulses were alternated with 50 ms pulses, L₂ was greater in the 50 ms pulse than in the 500 ms pulse. Clamp pulse potential. In the range −35 to 0 mV, peak L₁ and peak inward current occurred at nearly the same time, had the same threshold potential, and had a similar dependence on membrane potential. In the presence of L₂, contractions develop severalfold greater peak tension, time to peak tension is longer, and relaxation is more rapid than in the absence of L₂. It is concluded that Ca²⁺ released from stores accounts for L₂ and most of the ‘activator calcium’. Ca²⁺ from another source accounts for L₁ and activates a small early component of the contraction. L₁ has some properties expected for a signal related to Ca²⁺ entering via slow inward current, but not via Na/Ca exchange.