There
are many strategies to actuate and control genetic circuits,
including providing stimuli like exogenous chemical inducers, light,
magnetic fields, and even applied voltage, that are orthogonal to
metabolic activity. Their use enables actuation of gene expression
for the production of small molecules and proteins in many contexts.
Additionally, there are a growing number of reports wherein cocultures,
consortia, or even complex microbiomes are employed for the production
of biologics, taking advantage of an expanded array of biological
function. Combining stimuli-responsive engineered cell populations
enhances design space but increases complexity. In this work, we co-opt
nature’s redox networks and electrogenetically route control
signals into a consortium of microbial cells engineered to produce
a model small molecule, tyrosine. In particular, we show how electronically
programmed short-lived signals (i.e., hydrogen peroxide) can be transformed
by one population and propagated into sustained longer-distance signals
that, in turn, guide tyrosine production in a second population building
on bacterial quorum sensing that coordinates their collective behavior.
Two design methodologies are demonstrated. First, we use electrogenetics
to transform redox signals into the quorum sensing autoinducer, AI-1,
that, in turn, induces a tyrosine biosynthesis pathway transformed
into a second population. Second, we use the electrogenetically stimulated
AI-1 to actuate expression of ptsH, boosting the
growth rate of tyrosine-producing cells, augmenting both their number
and metabolic activity. In both cases, we show how signal propagation
within the coculture helps to ensure tyrosine production. We suggest
that this work lays a foundation for employing electrochemical stimuli
and engineered cocultures for production of molecular products in
biomanufacturing environments.