1 research outputs found
Transcription Factor-Based Screens and Synthetic Selections for Microbial Small-Molecule Biosynthesis
Continued advances in metabolic engineering are increasing
the
number of small molecules being targeted for microbial production.
Pathway yields and productivities, however, are often suboptimal,
and strain improvement remains a persistent challenge given that the
majority of small molecules are difficult to screen for and their
biosynthesis does not improve host fitness. In this work, we have
developed a generalized approach to screen or select for improved
small-molecule biosynthesis using transcription factor-based biosensors.
Using a tetracycline resistance gene 3′ of a small-molecule
inducible promoter, host antibiotic resistance, and hence growth rate,
was coupled to either small-molecule concentration in the growth medium
or a small-molecule production phenotype. Biosensors were constructed
for two important chemical classes, dicarboxylic acids and alcohols,
using transcription factor-promoter pairs derived from <i>Pseudomonas
putida</i>, <i>Thauera butanivorans</i>, or <i>E. coli</i>. Transcription factors were selected for specific
activation by either succinate, adipate, or 1-butanol, and we demonstrate
product-dependent growth in <i>E. coli</i> using all three
compounds. The 1-butanol biosensor was applied in a proof-of-principle
liquid culture screen to optimize 1-butanol biosynthesis in engineered <i>E. coli</i>, identifying a pathway variant yielding a 35% increase
in 1-butanol specific productivity through optimization of enzyme
expression levels. Lastly, to demonstrate the capacity to select for
enzymatic activity, the 1-butanol biosensor was applied as synthetic
selection, coupling <i>in vivo</i> 1-butanol biosynthesis
to <i>E. coli</i> fitness, and an 120-fold enrichment for
a 1-butanol production phenotype was observed following a single round
of positive selection