Directed evolution of specific receptor–ligand pairs for use in the creation of gene switches

Chockalingam, Karuppiah; Chen, Zhilei; Katzenellenbogen, John A.; Zhao, Huimin

doi:10.1073/pnas.0409206102

Cited by 96 publications

(95 citation statements)

References 29 publications

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“…It should be noted that the creation of orthogonal ligand for mutant human estrogen receptors using similar strategy has been previously demonstrated. 12 Second, the F atom in NFCD could be detected by 19 F NMR, which is potentially useful to trace this cofactor in the reaction system. Constructing Mutant Libraries of ME.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Creation of Bioorthogonal Redox Systems Depending on Nicotinamide Flucytosine Dinucleotide

Wang

Hou

et al. 2011

J. Am. Chem. Soc.

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Many enzymes catalyzing biological redox chemistry depend on the omnipresent cofactor, nicotinamide adenine dinucleotide (NAD). NAD is also involved in various nonredox processes. It remains challenging to disconnect one particular NAD-dependent reaction from all others. Here we present a bioorthogonal system that catalyzes the oxidative decarboxylation of L-malate with a dedicated abiotic cofactor, nicotinamide flucytosine dinucleotide (NFCD). By screening the multisite saturated mutagenesis libraries of the NAD-dependent malic enzyme (ME), we identified the mutant ME-L310R/Q401C, which showed excellent activity with NFCD, yet marginal activity with NAD. We found that another synthetic cofactor, nicotinamide cytosine dinucleotide (NCD), also displayed similar activity with the ME mutants. Inspired by these observations, we mutated D-lactate dehydrogenase (DLDH) and malate dehydrogenase (MDH) to DLDH-V152R and MDH-L6R, respectively, and both mutants showed fully active with NFCD. When coupled with DLDH-V152R, ME-L310R/Q401C required only a catalytic amount of NFCD to convert L-malate. Our results opened the window to engineer bioorthogonal redox systems for a wide variety of applications in systems biology and synthetic biology.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Creation of Bioorthogonal Redox Systems Depending on Nicotinamide Flucytosine Dinucleotide

Wang

Hou

et al. 2011

J. Am. Chem. Soc.

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“…The availability of engineered and naturally occurring receptors provides a large set of parts with which to develop new artificial transcription factors. Expanding the repertoire of mutually orthogonal switches has been greatly aided by directed evolution approaches 17,18 . Current efforts to reprogram the ligand-binding specificity of our artificial transcription factors will be presented in the future.…”

Section: Discussionmentioning

confidence: 99%

Rapid Synthesis and Screening of Chemically Activated Transcription Factors with GFP-based Reporters

McIsaac

Oakes

Botstein

et al. 2013

JoVE

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Synthetic biology aims to rationally design and build synthetic circuits with desired quantitative properties, as well as provide tools to interrogate the structure of native control circuits. In both cases, the ability to program gene expression in a rapid and tunable fashion, with no off-target effects, can be useful. We have constructed yeast strains containing the ACT1 promoter upstream of a URA3 cassette followed by the ligandbinding domain of the human estrogen receptor and VP16. By transforming this strain with a linear PCR product containing a DNA binding domain and selecting against the presence of URA3, a constitutively expressed artificial transcription factor (ATF) can be generated by homologous recombination. ATFs engineered in this fashion can activate a unique target gene in the presence of inducer, thereby eliminating both the off-target activation and nonphysiological growth conditions found with commonly used conditional gene expression systems. A simple method for the rapid construction of GFP reporter plasmids that respond specifically to a native or artificial transcription factor of interest is also provided.

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“…For example, most modifications in enantioselectivity or substrate specificity are located in the vicinity of the active site or in the access/exit of reactants/products [58,60,61]. Stability and activity however can be affected by mutations in any part of the protein, close or far from the active site [62], increasing significantly the number of possible mutations. To avoid screening massive number of mutations, one can reduce the region to explore by using functional information (from point mutations, random mutagenesis or deduction from sequence alignments) or when structural information exists (by visual inspection, analysis, etc.…”

Section: Introductionmentioning

confidence: 99%

“…To avoid screening massive number of mutations, one can reduce the region to explore by using functional information (from point mutations, random mutagenesis or deduction from sequence alignments) or when structural information exists (by visual inspection, analysis, etc. ), it would be advantageous to exploit this by concentrating mutations where they might be the most effective [62]. Methods such as saturation mutagenesis (where all other 19 amino acids are tested) on specific positions, generally near the active site, can increase the probability of finding beneficial mutations [63][64][65].…”

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confidence: 99%

Molecular Modeling in Enzyme Design, Toward In Silico Guided Directed Evolution

Monza

Acebes

Lucas

et al. 2017

Directed Enzyme Evolution: Advances and Applications

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Directed evolution creates diversity in subsequent rounds of mutagenesis in the quest of increased protein stability, substrate binding and catalysis. Although this technique does not require any structural/mechanistic knowledge of the system, the frequency of improved mutations is usually low. For this reason, computational tools are increasingly used to focus the search in sequence space, enhancing the efficiency of laboratory evolution. In particular, molecular modeling methods provide a unique tool to grasp the sequence/structure/function relationship The final publication is available at Springer via https://link.springer.com/chapter/10.1007/978-3-319-50413-1_10/fulltext.html of the protein to evolve, with the only condition that a structural model is provided. With this book chapter, we tried to guide the reader through the state of art of molecular modeling, discussing their strengths, limitations and directions. In addition, we suggest a possible future template for in silico directed evolution where we underline two main points: a hierarchical computational protocol combining several different techniques, and a synergic effort between simulations and experimental validation. IntroductionBiotechnology needs catalysts that can work under harsh conditions, catalyze a broad range of substrates, generate maximum amount of product, and tolerate changes in the environment. Enzymes, which are biodegradable and reusable catalysts [1], in addition to remarkable reaction rates, can work in environmentally friendly pH and temperature ranges, and display control over stereochemistry and regioselectivity which makes them ideal for many applications [2,3]. When thinking about enzymes, people normally associate them to expressions such as "perfect catalysts" or "outstanding reaction rate". In fact, there are examples of enzymes that catalyze reactions at extremely high rates such as triose phosphate isomerase, superoxide dismutase or carbonic anhydrase [4]. These are often limited only by the rate of ligand diffusion into the active site (diffusion-controlled rate). Nevertheless, an extensive analysis by Bar-Even et al., of nearly 2000 enzymes, showed that the median maximal turnover rate value over all measured enzymes is about 10 s −1 nowhere close to the values of 10 5 or 10 6 normally associated with catalysts [5,6].So, it would appear that natural enzymes are "just good enough" for the function they must perform in a given organism [7]. One might conclude that if they had evolved to their optimum performance then trying to improve them (from a kinetic point of view) would be attempting the impossible. On the contrary, as seen by the distribution of reaction rates, k cat , most enzymes function at a lower rate than the diffusion-limit and thus, there is space to further increase their kinetic properties to meet industrial needs. Additionally, we need enzymes capable of catalyzing reactions for which no known enzymes exist, to work with different substrates and for particular conditions that are industrially...

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Directed evolution of specific receptor–ligand pairs for use in the creation of gene switches

Cited by 96 publications

References 29 publications

Creation of Bioorthogonal Redox Systems Depending on Nicotinamide Flucytosine Dinucleotide

Creation of Bioorthogonal Redox Systems Depending on Nicotinamide Flucytosine Dinucleotide

Rapid Synthesis and Screening of Chemically Activated Transcription Factors with GFP-based Reporters

Molecular Modeling in Enzyme Design, Toward In Silico Guided Directed Evolution

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