Lopez L , Piegari E , Sigaut L , Ponce Dawson S .

	Figure 1. Linescan image with two puffs in the same site. (A) ΔF/F0 fluorescence image with the corresponding color code. (B) Δ F/F0 thresholded binary image.
	Figure 2. Puff amplitude as funcion of puff occurrence. Mean amplitude (symbols) and corresponding standard deviation (vertical lines) of puffs that occurred within the same 1 s interval along the experimental record as a function of the time elapsed since the delivery of the UV pulse.
	Figure 3. Event size distributions obtained with simulations of the intra and intercluster models without Ca2+ accumulation. (A) Distribution obtained with 1000 realizations of the intracluster (local) model using the parameters described in the “Materials and Methods” section (B) Similar to (A), but for the intercluster model without Ca2+ accumulation. See main text for the simulation parameter values.
	Figure 4. Transition between Ca2+-binding limited and IP3-binding limited cases in the event size distribution of the inter-cluster model. (A) Similar to Figure 3B but using a mean number of IP3-bound IP3R's equal to 4. (B) Similar to (A) but using a mean number of IP3-bound IP3R's equal to 20.
	Figure 5. Distribution of puff amplitudes obtained experimentally. (A) Distribution obtained by pooling together data from 202 puffs observed in 13 cells. Experiments were performed as explained in the “Materials and Methods” sections. (B) Same as (A) but on a logarithmic scale.
	Figure 6. Distribution of puff areas obtained experimentally. (A) Similar to Figure 5 but for the area covered by the puffs. Areas were determined as explained in the “Materials and Methods” section pooling data from 179 puffs observed in 12 cells. (B) Same as (A) but on a logarithmic scale. By fitting a power law relationship to some of the data points we obtain exponents between 1.8 and 2.0 with ℛ2 between 0.77 and 0.81 (if we include data between 800 and 4500 px or between 800 and 4000 px, respectively).
	Figure 7. Distributions of clusters and of receptors involved obtained with simulations of intercluster dynamics with calcium accumulation. (A) Distribution of the number of clusters involved in each signal displayed on a logarithmic scale. By fitting a power law relationship to some of the data points we obtain exponents between 1 and 1.4 with ℛ2 between 0.72 and 0.85 (if we include data between 30 and 80 clusters involved, respectively). (B) Distribution of the number of IP3R's involved on a logarithmic scale. By fitting a power law relationship to some of the data points we obtain exponents between 1 and 1.7 with ℛ2 between 0.76 and 0.92 (if we include data between 20 and 80 IP3R's involved, respectively).
	Figure 8. Dependence of the number of IP3R's that participate of a signal on various parameters. Mean (symbols) and standard deviations (vertical lines around mean) of the number of IP3R's that participate of a signal, No, as a function of the inter-cluster distance, dm (A), of the mean number of IP3-bound IP3R's per cluster, λ (B), of the mean IP3R inhibition time, tinh (C), and of the cytosolic Ca2+ clearing rate, δCa (D). In all the subfigures, the parameters that are not varied are fixed at the values used in section 5.
	Figure 9. Event size distributions obtained for different values of the cytosolic Ca2+ clearing rate. Distribution of the number of IP3R's that participate of the signals when all the parameters are kept at the values used in section 5 except for the cytosolic Ca2+ clearing rate for which we used: (A) δCa = 20/s, (B) δCa = 25/s, (C) δCa = 30/s, (D) δCa = 200/s.
	Figure 10. Number of active IP3R's and of IP3R's that are participating of a signal as a function of time. Number of active IP3R's, Nact (with solid lines) and of open IP3R's, No (with open circles) as a function of time for (A) δCa = 200/s and for (B) δCa = 20/s.

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