posted on 2019-03-05, 00:00authored byJackson O’Brien, Arvind Murugan
Living cells communicate information
about physiological conditions
by producing signaling molecules in a specific timed manner. Different
conditions can result in the same total amount of a signaling molecule,
differing only in the pattern of the molecular concentration over
time. Such temporally coded information can be completely invisible
to even state-of-the-art molecular sensors with high chemical specificity
that respond only to the total amount of the signaling molecule. Here,
we demonstrate design principles for circuits with temporal specificity,
that is, molecular circuits that respond to specific temporal patterns
in a molecular concentration. We consider pulsatile patterns in a
molecular concentration characterized by three fundamental temporal
features: time period, duty fraction, and number of pulses. We develop
circuits that respond to each one of these features while being insensitive
to the others. We demonstrate our design principles using general
chemical reaction networks and with explicit simulations of DNA strand
displacement reactions. In this way, our work develops building blocks
for temporal pattern recognition through molecular computation.