Metabolic engineering: Techniques for analysis of targets for genetic manipulations

Nielsen, Jens

doi:10.1002/(sici)1097-0290(19980420)58:2/3<125::aid-bit3>3.0.co;2-n

Cited by 142 publications

(67 citation statements)

References 36 publications

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“…The goal of metabolic engineering is the rational design and implementation of changes in an organism's properties to alter its metabolism in the desired manner [1]. One particular area of interest is the possibility of increasing rates and yields of amino acid synthesis by micro-organisms.…”

Section: Introductionmentioning

confidence: 99%

“…If this enzyme is over-expressed, then inevitably its flux control coefficient falls and the flux control coefficient of one or more of the other enzymes rises, so that another point in the pathway becomes a more significant focus for further action. A theoretical method for identifying a set of linked changes on the basis of control 1 To whom correspondence should be addressed (e-mail JP.Mazat!phys-mito.u-bordeaux2.fr).…”

Section: Introductionmentioning

confidence: 99%

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Control of the threonine-synthesis pathway in Escherichia coli: a theoretical and experimental approach

Chassagnole

Fell

Raïs

et al. 2001

Biochemical Journal

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A computer simulation of the threonine-synthesis pathway in Escherichia coli Tir-8 has been developed based on our previous measurements of the kinetics of the pathway enzymes under near-physiological conditions. The model successfully simulates the main features of the time courses of threonine synthesis previously observed in a cell-free extract without alteration of the experimentally determined parameters, although improved quantitative fits can be obtained with small parameter adjustments. At the concentrations of enzymes, precursors and products present in cells, the model predicts a threonine-synthesis flux close to that required to support cell growth. Furthermore, the first two enzymes operate close to equilibrium, providing an example of a near-equilibrium feedback-inhibited enzyme. The predicted flux control coefficients of the pathway enzymes under physiological conditions show that the control of flux is shared between the first three enzymes : aspartate kinase, aspartate semialdehyde dehydrogenase and homoserine dehydrogenase,

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Control of the threonine-synthesis pathway in Escherichia coli: a theoretical and experimental approach

Chassagnole

Fell

Raïs

et al. 2001

Biochemical Journal

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“…The quantitative analysis of metabolic networks and other metabolic engineering techniques have traditionally been applied to optimize cellular function primarily for the purpose of enhancing the production of specialty chemicals from prokaryotic cells, yeasts, fungi and to some limited extent, mammalian cells [44,45]. However, prior to the application of metabolic engineering techniques, the network map of the metabolic pathways for the cell or tissue of interest must be constructed.…”

Section: Integrated Metabolic and Signaling Networkmentioning

confidence: 99%

Biological network analyses: computational genomics and systems approaches

Walton

Chan

2006

Molecular Simulation

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The complex responses of cells to stimuli are the aggregate of alterations at the genetic, protein, metabolic and cellular levels. The immense quantities of data now available from high-throughput genomic, proteomic and metabolomic sources require specialized analytical approaches. The integration of such data for the computational elucidation and analysis of cellular pathways and networks is an area of considerable current interest. As the quantity of available data continues to increase, strategies to extract the useful information from the data will continue to provide answers to important biological questions. Chemical engineers are actively involved in this field that has taken on the global title of "Systems Biology". These research groups have made considerable impact from both the computational and experimental standpoints. This commentary describes some of the recent contributions of chemical engineering researchers to the computational analysis of highthroughput, multi-source data as described in recent publications and presentations from the 2005 AIChE Annual Meeting.

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“…This includes adjustment of the amount and kinetic properties of metabolic enzymes as well as the regulatory networks that govern the expression of pathway components, which in most cases is achieved through genetic engineering [1,2]. Thanks to the development of mathematical models of metabolism, the concepts of metabolic engineering have been successfully applied to the engineering of microbial metabolism, for example to increase the amount of desired amino acids or fermentation products [3], as well as the production of plant specialized metabolites in yeast, such as artemisinic acid [4].…”

Section: Introductionmentioning

confidence: 99%

The role of membrane transport in metabolic engineering of plant primary metabolism

Weber

Bräutigam

2013

Current Opinion in Biotechnology

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Plant cells are highly compartmentalized and so is their metabolism. Most metabolic pathways are distributed across several cellular compartments, which requires the activities of membrane transporters to catalyze the flux of precursors, intermediates, and end products between compartments. Metabolites such as sucrose and amino acids have to be transported between cells and tissues to supply, for example, metabolism in developing seeds or fruits with precursors and energy. Thus, rational engineering of plant primary metabolism requires a detailed and molecular understanding of the membrane transporters. This knowledge however still lags behind that of soluble enzymes. Recent advances include the molecular identification of pyruvate transporters at the chloroplast and mitochondrial membranes and of a new class of transporters called SWEET that are involved in the release of sugars to the apoplast.

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Metabolic engineering: Techniques for analysis of targets for genetic manipulations

Cited by 142 publications

References 36 publications

Control of the threonine-synthesis pathway in Escherichia coli: a theoretical and experimental approach

Control of the threonine-synthesis pathway in Escherichia coli: a theoretical and experimental approach

Biological network analyses: computational genomics and systems approaches

The role of membrane transport in metabolic engineering of plant primary metabolism

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