2020
DOI: 10.1038/s41467-020-14314-z
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Organizing genome engineering for the gigabase scale

Abstract: Engineering the entire genome of an organism enables large-scale changes in organization, function, and external interactions, with significant implications for industry, medicine, and the environment. Improvements to DNA synthesis and organism engineering are already enabling substantial changes to organisms with megabase genomes, such as Escherichia coli and Saccharomyces cerevisiae. Simultaneously, recent advances in genome-scale modeling are increasingly informing the design of metabolic networks. However,… Show more

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Cited by 20 publications
(14 citation statements)
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References 120 publications
(106 reference statements)
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“…SBOL supports the representation of abstraction hierarchies across multiple scales of bioengineering, from individual molecules to multi-cellular compositions and complete synthetic genomes (Bartley et al, 2020 ). The SBOL data model supports a wide variety of important use cases for synthetic biology and bioengineering, including visualization (McLaughlin et al, 2016 ), sequence design automation (Zhang et al, 2017 ), sharing of genetic design information (McLaughlin et al, 2018 ), metabolic engineering (Kuwahara et al, 2017 ), and generation of dynamical models from sequence representations (Misirli et al, 2018 ).…”
Section: Discussionmentioning
confidence: 99%
“…SBOL supports the representation of abstraction hierarchies across multiple scales of bioengineering, from individual molecules to multi-cellular compositions and complete synthetic genomes (Bartley et al, 2020 ). The SBOL data model supports a wide variety of important use cases for synthetic biology and bioengineering, including visualization (McLaughlin et al, 2016 ), sequence design automation (Zhang et al, 2017 ), sharing of genetic design information (McLaughlin et al, 2018 ), metabolic engineering (Kuwahara et al, 2017 ), and generation of dynamical models from sequence representations (Misirli et al, 2018 ).…”
Section: Discussionmentioning
confidence: 99%
“…Synthetic biology offers vast opportunity to investigate the function of BGCs, even cryptic ones or those identified in metagenomic assemblies, in a heterologous host. The possibility to generate long synthetic DNA fragments (Eisenstein, 2020 ) and advanced DNA assembly strategies (Bartley et al, 2020 ) allow for synthesis of entire clusters including de novo design of BGCs with host promoters and regulatory elements for better heterologous expression. Selection of a host and the design of DNA constructs suitable for the host (presence/absence of introns, codon usage, choice of vectors, and burden of foreign DNA) are the most important success limiting factors in heterologous expression, but they can be overcome with new design tools.…”
Section: Connecting Genotype and Phenotype To Facilitate Bioprospectimentioning
confidence: 99%
“…In recent years, advances in genomic measurement technologies for data generation, the establishment of data repositories, and the development of WCM simulation platforms have significantly facilitated the derivation of WCMs [see (Goldberg et al, 2018) for a review]. Nevertheless, the implementation of WCM-based design-build-test cycles for genome-scale engineering requires further challenges to be addressed (Bartley et al, 2020).…”
Section: What's Next? Going Beyond the Prototypementioning
confidence: 99%
“…We foresee that automation will play a fundamental role in the derivation of WCMs for eukaryotic organisms and in their application to design complex processes. Ideally, we would like to introduce automation at different stages, such as data extraction from the literature, model derivation, and model/data integration both within the model fitting and validation steps, and when comparing in silico design prediction with in vivo tests (Bartley et al, 2020). This, in turn, will require the adoption of standards for both data and model repositories.…”
Section: What's Next? Going Beyond the Prototypementioning
confidence: 99%