Engineering repressors with coevolutionary cues facilitates toggle switches with a master reset

Dimas, Rey P; Jiang, Xianli; Paz, Jose Alberto de la; Morcos, Faruck; Chan, Ching-Kit

doi:10.1093/nar/gkz280

Cited by 24 publications

(23 citation statements)

References 64 publications

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“…For example, by assuming that the distribution of possible ancestors remains consistent over evolutionary time, pools of ancestral sequences can be constructed such that their Hamiltonians match the extant distribution of family members. Lastly, our model can direct protein-design approaches that utilize the Hamiltonian and conditional probability to design and optimize novel protein functions into existing protein scaffolds (77).…”

Section: Discussionmentioning

confidence: 99%

Epistatic contributions promote the unification of incompatible models of neutral molecular evolution

Paz

Nartey

Yuvaraj

et al. 2020

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

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We introduce a model of amino acid sequence evolution that accounts for the statistical behavior of real sequences induced by epistatic interactions. We base the model dynamics on parameters derived from multiple sequence alignments analyzed by using direct coupling analysis methodology. Known statistical properties such as overdispersion, heterotachy, and gamma-distributed rate-across-sites are shown to be emergent properties of this model while being consistent with neutral evolution theory, thereby unifying observations from previously disjointed evolutionary models of sequences. The relationship between site restriction and heterotachy is characterized by tracking the effective alphabet dynamics of sites. We also observe an evolutionary Stokes shift in the fitness of sequences that have undergone evolution under our simulation. By analyzing the structural information of some proteins, we corroborate that the strongest Stokes shifts derive from sites that physically interact in networks near biochemically important regions. Perspectives on the implementation of our model in the context of the molecular clock are discussed.

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Section: Discussionmentioning

confidence: 99%

Epistatic contributions promote the unification of incompatible models of neutral molecular evolution

Paz

Nartey

Yuvaraj

et al. 2020

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

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“…Presently, we can successfully engineer cells to sense exogenous inputs [46,47], and control gene expression [48][49][50][51] and communication [52][53][54]. Synthetic interactions within a microbial consortia are typically engineered using the natural quorum sensing system for bacteria [55,56], or different pheromones in fungi [57,58]; but adhesion proteins or ion channels can be also used [59,60].…”

Section: Introductionmentioning

confidence: 99%

Synthetic Biology for Terraformation Lessons from Mars, Earth, and the Microbiome

Conde-Pueyo

Vidiella

Sardanyés

et al. 2020

Life

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What is the potential for synthetic biology as a way of engineering, on a large scale, complex ecosystems? Can it be used to change endangered ecological communities and rescue them to prevent their collapse? What are the best strategies for such ecological engineering paths to succeed? Is it possible to create stable, diverse synthetic ecosystems capable of persisting in closed environments? Can synthetic communities be created to thrive on planets different from ours? These and other questions pervade major future developments within synthetic biology. The goal of engineering ecosystems is plagued with all kinds of technological, scientific and ethic problems. In this paper, we consider the requirements for terraformation, i.e., for changing a given environment to make it hospitable to some given class of life forms. Although the standard use of this term involved strategies for planetary terraformation, it has been recently suggested that this approach could be applied to a very different context: ecological communities within our own planet. As discussed here, this includes multiple scales, from the gut microbiome to the entire biosphere.

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“…In previous studies, we established a module-swapping strategy to develop hybrid regulators with LacI family proteins, in which the resulting regulators possess desirable and predictable combinations of DNA-binding and ligand-binding properties originated from different native regulators (18,19). Based on this discovery, we constructed a set of hybrid regulators that enable flexible connections between small molecule sensing and promoter control.…”

Section: Introductionmentioning

confidence: 99%

“…Based on this discovery, we constructed a set of hybrid regulators that enable flexible connections between small molecule sensing and promoter control. These engineered parts were harnessed to establish two novel circuit designs with potential biotechnological applications, including a Passcode kill switch (18), and a system of multiple toggle switches with a master OFF signal (19). These studies show that transcriptional regulators are promising for creating robust, modular parts that facilitate cell engineering.…”

Section: Introductionmentioning

confidence: 99%

Engineering DNA recognition and allosteric response properties of TetR family proteins by using a module-swapping strategy

Dimas

Jordan

Jiang

et al. 2019

Nucleic Acids Research

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The development of synthetic biological systems requires modular biomolecular components to flexibly alter response pathways. In previous studies, we have established a module-swapping design principle to engineer allosteric response and DNA recognition properties among regulators in the LacI family, in which the engineered regulators served as effective components for implementing new cellular behavior. Here we introduced this protein engineering strategy to two regulators in the TetR family: TetR (UniProt Accession ID: P04483) and MphR (Q9EVJ6). The TetR DNA-binding module and the MphR ligand-binding module were used to create the TetR-MphR. This resulting hybrid regulator possesses DNA-binding properties of TetR and ligand response properties of MphR, which is able to control gene expression in response to a molecular signal in cells. Furthermore, we studied molecular interactions between the TetR DNA-binding module and MphR ligand-binding module by using mutant analysis. Together, we demonstrated that TetR family regulators contain discrete and functional modules that can be used to build biological components with novel properties. This work highlights the utility of rational design as a means of creating modular parts for cell engineering and introduces new possibilities in rewiring cellular response pathways.

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Engineering repressors with coevolutionary cues facilitates toggle switches with a master reset

Cited by 24 publications

References 64 publications

Epistatic contributions promote the unification of incompatible models of neutral molecular evolution

Epistatic contributions promote the unification of incompatible models of neutral molecular evolution

Synthetic Biology for Terraformation Lessons from Mars, Earth, and the Microbiome

Engineering DNA recognition and allosteric response properties of TetR family proteins by using a module-swapping strategy

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