posted on 2022-11-10, 17:15authored byAustin Stone, Jordan Ryan, Xun Tang, Xiao-Jun Tian
The
effects of host resource limitations on the function of synthetic
gene circuits have gained significant attention over the past years.
Hosts, having evolved resource capacities optimal for their own genome,
have been repeatedly demonstrated to suffer from the added burden
of synthetic genetic programs, which may in return pose deleterious
effects on the circuit’s function. Three resource controller
archetypes have been proposed previously to mitigate resource distribution
problems in dynamic circuits: the local controller, the global controller,
and a “negatively competitive” regulatory (NCR) controller
that utilizes synthetic competition to combat resource competition.
The dynamics of negative feedback forms of these controllers have
been previously investigated, and here we extend the analysis of these
resource allocation strategies to the incoherent feedforward loop
(iFFL) topology. We demonstrate that the three iFFL controllers can
attenuate Winner-Take-All resource competition between two bistable
switches. We uncover that the parameters associated with the synthetic
competition in the NCR iFFL controller are paramount to its increased
efficacy over the local controller type, while the global controllers
demonstrate to be relatively ineffectual. Interestingly, unlike the
negative feedback counterpart topologies, iFFL controllers exhibit
a unique coupling of switch activation thresholds which we term the
“coactivation threshold shift” effect. Finally, we demonstrate
that a nearly fully orthogonal set of bistable switches could be achieved
by pairing an NCR controller with an appropriate level of controller
resource consumption.