Engineering an allosteric transcription factor to respond to new ligands

Taylor, Noah D.; Garruss, Alexander S.; Moretti, Rocco; Chan, Sammy; Arbing, M.A.; Cascio, Duilio; Rogers, Jameson K.; Isaacs, Farren J.; Kosuri, Sriram; Baker, David; Fields, Stanley; Church, George M.; Raman, Srivatsan

doi:10.1038/nmeth.3696

Cited by 284 publications

(283 citation statements)

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“…Changes in the dimer interfaces of glucocorticoid receptor (GR), one of the hormone nuclear receptors, was found to allosterically affect DNA sequencespecific signaling (44); allosteric changes are crucial for communications between domains and alters the GR structure in response to target DNA binding (45,46). Structural allostery is virtually broadly recognized as an important mechanism for signaling switches of transcription factors and has been used to engineer transcription factors for versatile response to diverse signaling cues (47,48), suggesting that structural allostery might be a general mechanism for nuclear receptors to respond to their ligands. It is plausible that broad AHR ligands might induce diverse structural allostery that might modify target DNA recognition and the C-terminal TAD and lead to distinctly different biological consequences.…”

Section: Discussionmentioning

confidence: 99%

Structural hierarchy controlling dimerization and target DNA recognition in the AHR transcriptional complex

Seok

Lee²,

Li³

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The aryl hydrocarbon receptor (AHR) belongs to the PAS (PER-ARNT-SIM) family transcription factors and mediates broad responses to numerous environmental pollutants and cellular metabolites, modulating diverse biological processes from adaptive metabolism, acute toxicity, to normal physiology of vascular and immune systems. The AHR forms a transcriptionally active heterodimer with ARNT (AHR nuclear translocator), which recognizes the dioxin response element (DRE) in the promoter of downstream genes. We determined the crystal structure of the mammalian AHR-ARNT heterodimer in complex with the DRE, in which ARNT curls around AHR into a highly intertwined asymmetric architecture, with extensive heterodimerization interfaces and AHR interdomain interactions. Specific recognition of the DRE is determined locally by the DNA-binding residues, which discriminates it from the closely related hypoxia response element (HRE), and is globally affected by the dimerization interfaces and interdomain interactions. Changes at the interdomain interactions caused either AHR constitutive nuclear localization or failure to translocate to nucleus, underlying an allosteric structural pathway for mediating ligand-induced exposure of nuclear localization signal. These observations, together with the global higher flexibility of the AHR PAS-A and its loosely packed structural elements, suggest a dynamic structural hierarchy for complex scenarios of AHR activation induced by its diverse ligands.he aryl hydrocarbon receptor (AHR) belongs to the PER-ARNT-SIM (PAS) family transcription factor that mediates broad responses to cellular and environmental cues. The AHR has been shown to be activated by diverse environmental toxicants and endogenous ligands, and play an important role in adaptive metabolism, dioxin toxicity, and normal vascular and immune development (1, 2), ever since it was identified four decades ago for mediating metabolic responses to aryl hydrocarbon toxicants (3, 4) and the acute toxicity of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) (5). The AHR was more recently found to mediate diverse cellular and physiological responses and likely respond to unknown endogenous AHR ligands (1, 2, 6-8). Developmentally, the AHR plays a role in the normal development and function of both the vascular and immune systems (9-12), and has close links to cancer, metabolic, immune, and cardiovascular diseases (13-18).Intense efforts in the past four decades have yielded important insights into the molecular processes governing AHR signaling. Newly synthesized AHR is located in cytosol and associated with the chaperones Hsp90 (19), P23 (20, 21), and AHR associated protein 9 (ARA9, also known as XAP2 or AIP) (22-24). Binding of ligands induces conformational changes in the AHR that lead to exposure of nuclear localization sequences (NLS) (25, 26). Following nuclear translocation, the AHR exchanges chaperones for a transcription partner, ARNT (1) and the AHR-ARNT heterodimer binds near the promoters of target genes at dioxin-response element (DRE...

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Section: Discussionmentioning

confidence: 99%

Structural hierarchy controlling dimerization and target DNA recognition in the AHR transcriptional complex

Seok

Lee²,

Li³

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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“…Apart from allolactose and IPTG, an IPTG analog, n-propyl 1-thio-β- d -galactoside, was reported to exhibit a comparative inducing effect on LacI33. Attempts have been made to engineer it to response to compounds other than its natural inducers, but high induction specificity is still a challenge5. The LacI-L5 mutant obtained here exhibited responsiveness towards lactulose but was not induced by other six disaccharides tested, among which the structures of lactose, melibiose and epilactose only differ from lactulose in the sugar residue at the reducing end.…”

Section: Discussionmentioning

confidence: 99%

“…Engineering the effector specificities of regulatory proteins is an efficient way to develop customized small-molecule biosensors as well as novel gene switches. Some regulatory proteins have been engineered to response to compounds other than their natural inducers345, however, only a few have been confirmed as functional in vivo biosensors in practice678. The specificity, sensitivity and robustness are important features for high-quality in vivo biosensors.…”

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confidence: 99%

Design and application of a lactulose biosensor

Jiang

Chen

et al. 2017

Sci Rep

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In this study the repressor of Escherichia coli lac operon, LacI, has been engineered for altered effector specificity. A LacI saturation mutagenesis library was subjected to Fluorescence Activated Cell Sorting (FACS) dual screening. Mutant LacI-L5 was selected and it is specifically induced by lactulose but not by other disaccharides tested (lactose, epilactose, maltose, sucrose, cellobiose and melibiose). LacI-L5 has been successfully used to construct a whole-cell lactulose biosensor which was then applied in directed evolution of cellobiose 2-epimerase (C2E) for elevated lactulose production. The mutant C2E enzyme with ~32-fold enhanced expression level was selected, demonstrating the high efficiency of the lactulose biosensor. LacI-L5 can also be used as a novel regulatory tool. This work explores the potential of engineering LacI for customized molecular biosensors which can be applied in practice.

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“…Of 17 designs that were experimentally characterized, two were functional for DIG-binding, and optimization of one of these constructs using site-saturation mutagenesis coupled with selections resulted in a 75-fold improvement in binding affinity [54]. Similarly, Taylor and coworkers have reported the redesign of the lac repressor transcription factor for a number of novel inducers using a combination of computational protein design, mutagenesis and gene shuffling [55]. As computational design of binding improves, a potential application of such work would be in tuning the affinity of a biosensor, and thus the operational range, for various applications.…”

Section: Discussionmentioning

confidence: 99%

Biofuel metabolic engineering with biosensors

Morgan

Nadler

Yokoo

et al. 2016

Current Opinion in Chemical Biology

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Metabolic engineering offers the potential to renewably produce important classes of chemicals, particularly biofuels, at an industrial scale. DNA synthesis and editing techniques can generate large pathway libraries, yet identifying the best variants is slow and cumbersome. Traditionally, analytical methods like chromatography and mass spectrometry have been used to evaluate pathway variants, but such techniques cannot be performed with high throughput. Biosensors - genetically encoded components that actuate a cellular output in response to a change in metabolite concentration - are therefore a promising tool for rapid and high-throughput evaluation of candidate pathway variants. Applying biosensors can also dynamically tune pathways in response to metabolic changes, improving balance and productivity. Here, we describe the major classes of biosensors and briefly highlight recent progress in applying them to biofuel-related metabolic pathway engineering.

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Engineering an allosteric transcription factor to respond to new ligands

Cited by 284 publications

References 60 publications

Structural hierarchy controlling dimerization and target DNA recognition in the AHR transcriptional complex

Structural hierarchy controlling dimerization and target DNA recognition in the AHR transcriptional complex

Design and application of a lactulose biosensor

Biofuel metabolic engineering with biosensors

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