Anne Pihl Bali scite author profile

Only 25% of bacterial membrane transporters have functional annotation owing to the difficulty of experimental study and of accurate prediction of their function. Here we report a sequence-independent method for high-throughput mining of novel transporters. The method is based on ligand-responsive biosensor systems that enable selective growth of cells only if they encode a ligand-specific importer. We developed such a synthetic selection system for thiamine pyrophosphate and mined soil and gut metagenomes for thiamine-uptake functions. We identified several members of a novel class of thiamine transporters, PnuT, which is widely distributed across multiple bacterial phyla. We demonstrate that with modular replacement of the biosensor, we could expand our method to xanthine and identify xanthine permeases from gut and soil metagenomes. Our results demonstrate how synthetic-biology approaches can effectively be deployed to functionally mine metagenomes and elucidate sequence-function relationships of small-molecule transport systems in bacteria.

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Improved biotin, thiamine, and lipoic acid biosynthesis by engineering the global regulator IscR

Bali

Lennox-Hvenekilde

Myling-Petersen

et al. 2020

Metabolic Engineering

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Directed Evolution of Membrane Transport Using Synthetic Selections

2018

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Understanding and engineering solute transporters is important for metabolic engineering and the development of therapeutics. However, limited available experimental data on membrane transporters makes sequence-function relationships complex to predict. Here we apply ligand-responsive biosensor systems that enable selective growth of E. coli cells only if they functionally express an importer that is specific to the biosensor ligand. Using this system in a directed evolution framework, we successfully engineer the specificity of nicotinamide riboside transporters, PnuC, to accept thiamine as a substrate. Our results provide insight into the molecular determinants of substrate recognition of the PnuC transporter family and demonstrate how synthetic biology can be deployed to engineer the substrate spectrum of small molecule transporters.

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Metabolic engineering of Escherichia coli for high-level production of free lipoic acid

Lennox-Hvenekilde

Bali

Gronenberg

et al. 2023

Metabolic Engineering

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Anne Pihl Bali

Functional mining of transporters using synthetic selections

Improved biotin, thiamine, and lipoic acid biosynthesis by engineering the global regulator IscR

Directed Evolution of Membrane Transport Using Synthetic Selections

Metabolic engineering of Escherichia coli for high-level production of free lipoic acid

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