Presynaptic Calcium Dynamics and Transmitter Release Evoked by Single Action Potentials at Mammalian Central Synapses

Saurabh R. Sinha^*, Ling-Gang Wu^# and Peter Saggau^*

Division of Neuroscience, Baylor College of Medicine, Houston, Texas 77030
Abteilung Zellphysiologie, Max-Planck Institut für medizinische Forschung, D-69120 Heidelberg, Germany

ABSTRACT

The relationship between presynaptic calcium transients ([Ca²⁺]_t)and transmitter release evoked by a single stimulus was bothinvestigated experimentally and modeled at a mammalian centralsynapse, the CA3 to CA1 pyramidal cell synapse in guinea pighippocampal slices. In the present study, we compared the low-affinitycalcium indicator furaptra with the higher-affinity indicatorfura-2. The 10-90% rise time of the furaptra transient was 2.4ms compared to 7.8 ms with fura-2; the half-decay time ( ${tau}$ _1/2)was 30 ms for furaptra, compared to 238 ms for fura-2. The half-widthof the calcium influx was 1.8 ms with furaptra, which providesan upper limit to the duration of the calcium current (I_Ca)evoked by an action potential. Modeling the decay time courseof the furaptra transients led to the conclusion that the predominantendogenous calcium buffer in these terminals must have relativelyslow kinetics (k_on < 10⁵/M·s), although the presenceof small amounts of fast buffers cannot be excluded. The relationshipbetween the [Ca²⁺]_t measured with furaptra and the postsynapticresponse was the same as previously observed with fura-2: thepostsynaptic response was proportional to about the fourth power(m ${approx}$ 4) of the amplitude of either [Ca²⁺]_t or calcium influx.Thus, although fura-2 may be locally saturated by the high local[Ca²⁺] responsible for transmitter release, the volume-averagedfura-2 signal accurately reflects changes in this local concentration.The result that both indicators gave similar values for thepower m constrains the amplitude of calcium influx in our model:I_Ca < 1 pA for 1 ms.