How Molecular Motors' Interaction Shapes Flagellar Beat and Its Fluctuations

TL;DR

This study models how direct coupling between molecular motors influences flagellar beating, revealing effects on oscillation stability, period, and fluctuation characteristics through analytical and numerical methods.

Contribution

It introduces a coupled motor activity model within rigid filament frameworks, analyzing the impact of motor interactions on flagellar dynamics and fluctuations.

Findings

Coupling increases characteristic times and beating period.

Large coupling induces bi-stability and motor avalanches.

Fluctuation quality factor varies non-monotonically with coupling.

Abstract

The stochastic dynamics of flagellar beating for micro-swimmers, such as flagellated cells, sperms and microalgae, is widely thought to include a feedback mechanism between flagellar shape and the rate of activation/de-activation of the $N \gg 1$ driving molecular motors. In the context of the so-called rigid filament models, where the axoneme is described by a single degree of freedom $X(t)$, we investigate the effect of direct coupling between the activity dynamics of adjacent motors, parametrized by $K \ge 0$. A functional Fokker-Planck equation for $X$ and the state of the $N$ motors is obtained. In the limit of small coupling $K \ll 1$, we derive a system of equations governing the dynamics of the Fourier modes of the active motor density, obtaining estimates for several observables and the fluctuations' quality factor $Q$. For larger $K$ we resort to numerical simulations. The effect of introducing the coupling $K>0$ is to increase characteristic times and the beating period. Moreover for large $K$s the limit cycle becomes bi-stable, with abrupt avalanches of the motor dynamics. Increasing $K$ is similar to what observed in the case $K=0$ when the confining elastic force is strongly reduced. The quality factor of fluctuations has a non-monotonic behavior: it first increases with $K$, then decreases. This is accompanied by the reduction and eventual disappearance of regions where the fraction of activated motor is nor $0$ neither $1$.