Composability of regulatory sequences controlling transcription and translation in
            <i>Escherichia coli</i>

Kosuri, Sriram; Goodman, Daniel B.; Cambray, Guillaume; Mutalik, Vivek K.; Gao, Yuan; Arkin, Adam P.; Endy, Drew; Church, George M.

doi:10.1073/pnas.1301301110

Cited by 415 publications

(481 citation statements)

References 46 publications

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“…14,47,48 MAVEs have also been developed to probe the effects of variants in untranslated regions of mRNAs on message stability and protein expression. [16][17][18] Variation in transcriptional regulatory elements is also important, and pathogenic regulatory variants have been identified for a number of Mendelian disorders. [49][50][51][52] One specific example is the alteration of SORT1 (MIM: 602458) expression by a transcriptional regulatory variant that can increase the risk of myocardial infarction by 40%.…”

Section: Annotating Every Possible Variant In Disease-related Functiomentioning

confidence: 99%

“…14,15 The effect of variants on mRNA stability and translation can also be measured by multiplex assays. [16][17][18] Finally, deep mutational scans query the effect of amino acid substitutions on protein function. 19 Because these multiplexed functional assays have the capacity to test 10 4 -10 6 variants per experiment, they are already at the scale required for tackling the VUS problem.…”

Section: Introductionmentioning

confidence: 99%

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Variant Interpretation: Functional Assays to the Rescue

Starita

Ahituv

Dunham

et al. 2017

The American Journal of Human Genetics

316

294

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Classical genetic approaches for interpreting variants, such as case-control or co-segregation studies, require finding many individuals with each variant. Because the overwhelming majority of variants are present in only a few living humans, this strategy has clear limits. Fully realizing the clinical potential of genetics requires that we accurately infer pathogenicity even for rare or private variation. Many computational approaches to predicting variant effects have been developed, but they can identify only a small fraction of pathogenic variants with the high confidence that is required in the clinic. Experimentally measuring a variant's functional consequences can provide clearer guidance, but individual assays performed only after the discovery of the variant are both time and resource intensive. Here, we discuss how multiplex assays of variant effect (MAVEs) can be used to measure the functional consequences of all possible variants in disease-relevant loci for a variety of molecular and cellular phenotypes. The resulting large-scale functional data can be combined with machine learning and clinical knowledge for the development of ''lookup tables'' of accurate pathogenicity predictions. A coordinated effort to produce, analyze, and disseminate large-scale functional data generated by multiplex assays could be essential to addressing the variant-interpretation crisis.

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Section: Annotating Every Possible Variant In Disease-related Functiomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Variant Interpretation: Functional Assays to the Rescue

Starita

Ahituv

Dunham

et al. 2017

The American Journal of Human Genetics

316

294

View full text Add to dashboard Cite

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“…The activity of a promoter depends on the sequences that surround it, in particular, the sequences upstream of the -35 site and downstream of the -10 site a↵ect transcription initiation and promoter escape, respectively [14]. The strength of a ribosome binding site is a↵ected by interactions with the 5' UTR sequence and by complicated secondary structures that form across the 5' UTR sequence and the initial gene coding sequence [15] ( Figure 1A). These facts confound system design because, for example, the same combination of promoter and ribosome binding site will result in di↵erent and unpredictable protein production rates depending on the specific gene being expressed.…”

Section: Modularity Of Basic Partsmentioning

confidence: 99%

Modularity, context-dependence, and insulation in engineered biological circuits

Vecchio¹

2015

Trends in Biotechnology

121

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Abstract. The ability of linking systems together such that they behave as predicted once interacting with each other is an essential requirement for the forward engineering of robust synthetic biological circuits. Unfortunately, because of context dependencies, parts and functional modules often behave unpredictably once interacting in the cellular environment. In this paper, we review some recent advances toward establishing a rigorous engineering framework for insulating parts and modules from their context to improve modularity. Overall, a synergy between engineering better parts and higher-level circuit design that overcome the physical limitations of available parts will be important to resolve the problem of context dependence. Modularity and context-dependence in engineered biological systemsSynthetic biology, that is, the use of molecular biology techniques to forward engineer cellular behavior, is a rising branch of biological research [1]. One aim of the field is to gather a better understanding of natural systems by re-wiring their subsystems and exporting them to new settings. The ability of re-designing living systems has especially potential in the biotechnology industry, promising a number of breakthroughs in human health and the environment. Designing living systems does not simply relay on the engineering of parts, such as proteins or genetic sequences. In contrast, it essentially requires the ability of linking parts together to create sophisticated functionalities. Linking parts together to achieve a predictable behavior is 1

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“…Pero para hacer una casa los troncos deben convertirse en vigas y paneles de dimensiones precisas que permitan la construcción a149 de un edificio más complejo. Mediante este razonamiento, una de las señas de identidad de la Biología sintética es el esfuerzo por partir de secuencias de ADN que determinan funciones deseables y modificarlas para que puedan utilizarse como bloques de construcción (bio-ladrillos) de nuevos objetos bioló-gicos (Kosuri et al, 2013;Mutalik et al, 2013). Partiendo de la situación existente, uno puede pensar en modularizar más y más las funciones y los componentes biológicos para hacerlos más fáciles de combinar, tanto física como funcionalmente.…”

Section: La Ingeniería Genética: Analogía Y Metodologíaunclassified

Biología sintética: la ingeniería al asalto de la complejidad biológica

De Lorenzo

2014

Arbor

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RESUMEN: La Biología sintética no es solo una reformulación contemporánea de las tecnologías del ADN recombinante de los últimos 30 años junto con un lenguaje descriptivo importado de la ingeniería eléctrica e industrial. Es también una nueva clave interpretativa de los sistemas vivos y una declaración de intenciones sobre la utilización y reprogramación de los objetos biológicos en beneficio humano. De la misma forma que la Química científica iniciada por Lavoisier devino en la Ingeniería química que está en la base de nuestra sociedad desarrollada, la Biología ha adquirido un potencial transformador que posiblemente nos lleve a un tipo de industria y de economía muy distinta de la actual. Para ello es esencial identificar los cuellos de botella que limitan el diseño de objetos biológicos desde sus primeros principios y no perder el tren de la Biología sintética en su etapa fundacional, cuando el talento -y no el músculo-es lo determinante.PALABRAS CLAVE: Ingeniería genética; circuitos; sistemas mínimos; partes; dispositivos; módulos; sistemas; chasis; microorganismos; biocombustibles.ABSTRACT: Synthetic Biology is not just a contemporary update of the recombinant DNA technologies of the past 30 years along with a descriptive language imported from electrical and industrial engineering. It is also a new key to interpreting living systems, as well as a declaration of intent about the use and reprogramming of biological objects for human benefit. In the same way that scientific chemistry initiated by Lavoisier evolved into the Chemical Engineering that is the basis of our industrial society, Biology has acquired a transforming potential that will possibly lead to a type of industry and economy very different from the current paradigm. To this end, it is essential to identify bottlenecks that limit the design of biological objects from first principles and not to miss the train of Synthetic Biology at its current foundational stage, when talent -and not muscle-is what really matters.

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Composability of regulatory sequences controlling transcription and translation in Escherichia coli

Cited by 415 publications

References 46 publications

Variant Interpretation: Functional Assays to the Rescue

Variant Interpretation: Functional Assays to the Rescue

Modularity, context-dependence, and insulation in engineered biological circuits

Biología sintética: la ingeniería al asalto de la complejidad biológica

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