Microbial cell factories provide an environmentally friendly
and
sustainable platform capable of utilizing inexpensive substrates to
produce chemicals. However, modifying the strain through metabolic
engineering to enhance the synthesis of the target product often disrupts
the rational allocation of metabolic flux, leading to suboptimal production
efficiency in the strain. In this study, to achieve rational allocation
of metabolic flux, we designed two autonomous dynamic regulatory systems
with good universality and portability: a single-function regulatory
switch (SFRS) and a dual-function regulatory switch (DFRS), by integrating
quorum sensing (QS) systems and stationary phase promoters. As a proof
of concept, the SFRS was used to reallocate the metabolic flux distribution,
dividing the strain production process into precursor accumulation
and product synthesis phases to reduce the toxicity of premature cadaverine
accumulation on cells. This increased the cadaverine titer to 62.5
g/L with a productivity of 1.7 g/L/h in a 5 L fermenter. Additionally,
the DFRS was implemented to balance the metabolic flux between cell
growth and product synthesis, decoupling cell growth from succinate
synthesis. This increased the succinate titer to 128.2 g/L with a
productivity of 1.8 g/L/h in a 5 L fermenter. These results emphasize
the potential of SFRS and DFRS as powerful metabolic flux regulation
tools to enhance the production of valuable chemicals.