Daniel Siebert scite author profile

For synthetic biology applications, a robust structural basis is required, which can be constructed either from scratch or in a top-down approach starting from any existing organism. In this study, we initiated the top-down construction of a chassis organism from Corynebacterium glutamicum ATCC 13032, aiming for the relevant gene set to maintain its fast growth on defined medium. We evaluated each native gene for its essentiality considering expression levels, phylogenetic conservation, and knockout data. Based on this classification, we determined 41 gene clusters ranging from 3.7 to 49.7 kbp as target sites for deletion. 36 deletions were successful and 10 genome-reduced strains showed impaired growth rates, indicating that genes were hit, which are relevant to maintain biological fitness at wild-type level. In contrast, 26 deleted clusters were found to include exclusively irrelevant genes for growth on defined medium. A combinatory deletion of all irrelevant gene clusters would, in a prophage-free strain, decrease the size of the native genome by about 722 kbp (22%) to 2561 kbp. Finally, five combinatory deletions of irrelevant gene clusters were investigated. The study introduces the novel concept of relevant genes and demonstrates general strategies to construct a chassis suitable for biotechnological application.

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Corynebacterium glutamicum Chassis C1*: Building and Testing a Novel Platform Host for Synthetic Biology and Industrial Biotechnology

Baumgart

Unthan

Kloß

et al. 2017

ACS Synth. Biol.

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Targeted top-down strategies for genome reduction are considered to have a high potential for providing robust basic strains for synthetic biology and industrial biotechnology. Recently, we created a library of 26 genome-reduced strains of Corynebacterium glutamicum carrying broad deletions in single gene clusters and showing wild-type-like biological fitness. Here, we proceeded with combinatorial deletions of these irrelevant gene clusters in two parallel orders, and the resulting library of 28 strains was characterized under various environmental conditions. The final chassis strain C1* carries a genome reduction of 13.4% (412 deleted genes) and shows wild-type-like growth behavior in defined medium with d-glucose as carbon and energy source. Moreover, C1* proves to be robust against several stresses (including oxygen limitation) and shows long-term growth stability under defined and complex medium conditions. In addition to providing a novel prokaryotic chassis strain, our results comprise a large strain library and a revised genome annotation list, which will be valuable sources for future systemic studies of C. glutamicum.

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Metabolic pathway engineering for production of 1,2-propanediol and 1-propanol by Corynebacterium glutamicum

Siebert

Wendisch

2015

Biotechnol Biofuels

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BackgroundProduction of the versatile bulk chemical 1,2-propanediol and the potential biofuel 1-propanol is still dependent on petroleum, but some approaches to establish bio-based production from renewable feed stocks and to avoid toxic intermediates have been described. The biotechnological workhorse Corynebacterium glutamicum has also been shown to be able to overproduce 1,2-propanediol by metabolic engineering. Additionally, C. glutamicum has previously been engineered for production of the biofuels ethanol and isobutanol but not for 1-propanol.ResultsIn this study, the improved production of 1,2-propanediol by C. glutamicum is presented. The product yield of a C. glutamicum strain expressing the heterologous genes gldA and mgsA from Escherichia coli that encode methylglyoxal synthase gene and glycerol dehydrogenase, respectively, was improved by additional expression of alcohol dehydrogenase gene yqhD from E. coli leading to a yield of 0.131 mol/mol glucose. Deletion of the endogenous genes hdpA and ldh encoding dihydroxyacetone phosphate phosphatase and lactate dehydrogenase, respectively, prevented formation of glycerol and lactate as by-products and improved the yield to 0.343 mol/mol glucose. To construct a 1-propanol producer, the operon ppdABC from Klebsiella oxytoca encoding diol dehydratase was expressed in the improved 1,2-propanediol producing strain ending up with 12 mM 1-propanol and up to 60 mM unconverted 1,2-propanediol. Thus, B12-dependent diol dehydratase activity may be limiting 1-propanol production.ConclusionsProduction of 1,2-propanediol by C. glutamicum was improved by metabolic engineering targeting endogenous enzymes. Furthermore, to the best of our knowledge, production of 1-propanol by recombinant C. glutamicum was demonstrated for the first time.

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Quantitative reasoning in a reconceived view of transfer

Lobato

Siebert

2002

The Journal of Mathematical Behavior

102

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Why Content-Area Literacy Messages Do Not Speak to Mathematics Teachers: A Critical Content Analysis∗

Siebert

Draper

2008

Literacy Research and Instruction

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Different Goals, Similar Practices: Making Sense of the Mathematics and Literacy Instruction in aStandards -Based Mathematics Classroom

Draper¹,

Siebert²

2004

American Educational Research Journal

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This article describes both the process and products of a cooperative inquiry project between two educational researchers—one from literacy education and one from mathematics education. The collaboration took place in an undergraduate, inquiry-based mathematics classroom in which the researchers sought to develop a shared vision of learning and literacy. The researchers discovered that they each used a different learning model to make sense of mathematics instruction, and that both of these models obscured important aspects of learning in a Standards-based mathematics classroom. An alternative model of learning and literacy in mathematics that takes into consideration both models is presented, as well as the process through which the researchers negotiated this shared perspective.

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Exploiting Hydrogenophaga pseudoflava for aerobic syngas-based production of chemicals

Grenz

Baumann

Rückert

et al. 2019

Metabolic Engineering

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What's More Important—Literacy or Content? Confronting the Literacy-Content Dualism

Draper

Smith

Hall

et al. 2005

Action in Teacher Education

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Daniel Siebert

Chassis organism from Corynebacterium glutamicum – a top‐down approach to identify and delete irrelevant gene clusters

Corynebacterium glutamicum Chassis C1*: Building and Testing a Novel Platform Host for Synthetic Biology and Industrial Biotechnology

Metabolic pathway engineering for production of 1,2-propanediol and 1-propanol by Corynebacterium glutamicum

Quantitative reasoning in a reconceived view of transfer

Why Content-Area Literacy Messages Do Not Speak to Mathematics Teachers: A Critical Content Analysis∗

Different Goals, Similar Practices: Making Sense of the Mathematics and Literacy Instruction in aStandards -Based Mathematics Classroom

Exploiting Hydrogenophaga pseudoflava for aerobic syngas-based production of chemicals

What's More Important—Literacy or Content? Confronting the Literacy-Content Dualism

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