Biological timekeeping in the presence of stochasticity

Causal ordering of key events in the cell cycle is essential for proper functioning of an organism. Yet, it remains a mystery how a specific temporal program of events is maintained despite ineluctable stochasticity in the biochemical dynamics which dictate timing of cellular events. We propose that if a change of cell fate is triggered by the {\em time-integral} of the underlying stochastic biochemical signal, rather than the original signal, then a dramatic improvement in temporal specificity results. Exact analytical results for stochastic models of hourglass-timers and pendulum-clocks, two important paradigms for biological timekeeping, elucidate how temporal specificity is achieved through time-integration. En route, we introduce a natural representation for time-integrals of stochastic processes, provide an analytical prescription for evaluating corresponding first-passage-time distributions, and uncover a mechanism by which a population of identical cells can spontaneously bifurcate into subpopulations of early and late responders, depending on hierarchy of timescales in the dynamics. Moreover, our approach reveals how time-integration of stochastic signals may be realized biochemically, through a simple chemical reaction scheme.