posted on 2022-05-20, 20:05authored byXinyu Gong, Ruihua Zhang, Jian Wang, Yajun Yan
Transcriptional factors play a crucial
role in regulating cellular
functions. Understanding and altering the dynamic behavior of the
transcriptional factor-based biosensors will expand our knowledge
in investigating biomolecular interactions and facilitating biosynthetic
applications. In this study, we characterized and engineered a TrpR-based
tryptophan repressor system in Escherichia coli.
We found that the reconstructed TrpR1-PtrpO1 biosensor
system exhibited low basal expression and narrow dynamic range in
the presence of tryptophan or its analogue 5-hydroxytryptophan (5-HTP).
Given the application potential of the biosensor, we introduced engineering
approaches in multiple levels to optimize its dynamic behavior. First,
the I57 and V58 residues in the ligand-binding pocket were rationally
mutated in search of variants with altered ligand specificity. Two
TrpR1 variants, V58E and V58K, successfully acquired ligand preference
toward tryptophan and 5-HTP, respectively. The biosensor-induced expression
levels were increased up to 10-fold with those variants. Furthermore,
to pursue broader operational range, we tuned the regulator–operator
binding affinity by mutating the binding box of TrpR1. Collectively,
we demonstrated that the biosynthesis-significant biosensor TrpR1-PtrpO1 can be engineered to acquire extended dynamic ranges
and improved ligand preference. The engineered biosensor variants
with remarkable dynamic behavior can serve as key genetic elements
in high-throughput screening and dynamic regulation in biosynthetic
scenarios.