Particle-based Multiscale Modeling of Calcium Puff Dynamics

TL;DR

This paper introduces a multiscale model combining stochastic ion diffusion and channel gating to analyze calcium puff dynamics, revealing conditions necessary for puff occurrence and providing insights into their regulation.

Contribution

It presents a novel spatial multiscale model coupling Brownian ion motion with stochastic channel gating to study calcium puff behavior.

Findings

Puffs occur only when channel inhibition time scales are sufficiently large.

The model identifies the regime where calcium puffs are possible.

A mean-field theory delineates the boundary conditions for puff generation.

Abstract

Intracellular calcium is regulated in part by the release of Ca$^{2+}$ ions from the endoplasmic reticulum via inositol-4,5-triphosphate receptor (IP$_3$R) channels (among other possibilities such as RyR and L-type calcium channels). The resulting dynamics are highly diverse, lead to local calcium "puffs" as well as global waves propagating through cells, as observed in {\it Xenopus} oocytes, neurons, and other cell types. Local fluctuations in the number of calcium ions play a crucial role in the onset of these features. Previous modeling studies of calcium puff dynamics stemming from IP$_3$R channels have predominantly focused on stochastic channel models coupled to deterministic diffusion of ions, thereby neglecting local fluctuations of the ion number. Tracking of individual ions is computationally difficult due to the scale separation in the Ca$^{2+}$ concentration when channels are in the open or closed states. In this paper, a spatial multiscale model for investigating of the dynamics of puffs is presented. It couples Brownian motion (diffusion) of ions with a stochastic channel gating model. The model is used to analyze calcium puff statistics. Concentration time traces as well as channel state information are studied. We identify the regime in which puffs can be found and develop a mean-field theory to extract the boundary of this regime. Puffs are only possible when the time scale of channel inhibition is sufficiently large. Implications for the understanding of puff generation and termination are discussed.