Highly multiplexed design of an allosteric transcription factor to sense novel ligands.
Kyle K NishikawaJackie ChenJustin F AchesonSvetlana V HarbaughPhil HussMax FrenkelNathan NovyHailey R SierenElla C LodewykDaniel H LeeJorge L ChavezBrian G FoxSrivatsan RamanPublished in: bioRxiv : the preprint server for biology (2024)
Allosteric transcription factors (aTF), widely used as biosensors, have proven challenging to design for detecting novel molecules because mutation of ligand-binding residues often disrupts allostery. We developed Sensor-seq, a high-throughput platform to design and identify aTF biosensors that bind to non-native ligands. We screened a library of 17,737 variants of the aTF TtgR, a regulator of a multidrug exporter, against six non-native ligands of diverse chemical structures - four derivatives of the cancer therapeutic tamoxifen, the antimalarial drug quinine, and the opiate analog naltrexone - as well as two native flavonoid ligands, naringenin and phloretin. Sensor-seq identified novel biosensors for each of these ligands with high dynamic range and diverse specificity profiles. The structure of a naltrexone-bound design showed shape-complementary methionine-aromatic interactions driving ligand specificity. To demonstrate practical utility, we developed cell-free detection systems for naltrexone and quinine. Sensor-seq enables rapid, scalable design of new biosensors, overcoming constraints of natural biosensors.
Keyphrases
- transcription factor
- single cell
- high throughput
- cell free
- label free
- rna seq
- small molecule
- dna binding
- endoplasmic reticulum stress
- loop mediated isothermal amplification
- drug resistant
- papillary thyroid
- squamous cell carcinoma
- multidrug resistant
- copy number
- alcohol use disorder
- mass spectrometry
- electronic health record