On the role of calcium diffusion and its rapid buffering in intraflagellar signaling.

We have considered the realistic mechanism of rapid Ca 2+ (calcium ion) buffering within the wave of calcium ions progressing along the flagellar axoneme. This buffering is an essential part of the Ca 2+ signaling pathway aimed at controlling the bending dynamics of flagella. It is primarily achieved by the mobile region of calmodulin molecules and by stationary calaxin, as well as by the part of calmodulin bound to calcium/calmodulin-dependent kinase II and kinase C. We derived and elaborated a model of Ca 2+ diffusion within a signaling wave in the presence of these molecules which rapidly buffer Ca 2+ . This approach has led to a single nonlinear transport equation for the Ca 2+ wave that contains the effects brought about by both as necessary buffers for signaling. The presence of mobile buffer calmodulin gives rise to a transport equation that is not strictly diffusive but also exhibits a sink-like effect. We solved straightforwardly the final transport equation in an analytical framework and obtained the implied function of calcium concentration. The effective diffusion coefficient depends on local Ca 2+ concentration. It is plausible that these buffers' presence can impact Ca 2+ wave speed and shape, which are essential for decoding Ca 2+ signaling in flagella. We present the solution of the transport equation for a few specified cases with physiologically reasonable sets of parameters involved.