about
Microbial production of 1-octanol: A naturally excreted biofuel with diesel-like propertiesImprovement of glucaric acid production in E. coli via dynamic control of metabolic fluxes.Field trial evaluation of the accumulation of omega-3 long chain polyunsaturated fatty acids in transgenic Camelina sativa: Making fish oil substitutes in plantsExpanding Metabolic Engineering Algorithms Using Feasible Space and Shadow Price Constraint Modules.Liposomes modified with cardiolipin can act as a platform to regulate the potential flux of NADP+-dependent isocitrate dehydrogenase.Isobutanol production in Synechocystis PCC 6803 using heterologous and endogenous alcohol dehydrogenases.Investigation of useful carbon tracers for 13C-metabolic flux analysis of Escherichia coli by considering five experimentally determined flux distributions.UP Finder: A COBRA toolbox extension for identifying gene overexpression strategies for targeted overproduction.Genome-scale model guided design of Propionibacterium for enhanced propionic acid production.Comparison of orthologous cyanobacterial aldehyde deformylating oxygenases in the production of volatile C3-C7 alkanes in engineered E. coli.Metabolic engineering of Ustilago trichophora TZ1 for improved malic acid production.Metabolic engineering of Schizosaccharomyces pombe via CRISPR-Cas9 genome editing for lactic acid production from glucose and cellobiose.A comprehensive evaluation of constraining amino acid biosynthesis in compartmented models for metabolic flux analysis.YaliBricks, a versatile genetic toolkit for streamlined and rapid pathway engineering in Yarrowia lipolytica.Development of a high efficiency integration system and promoter library for rapid modification of Pseudomonas putida KT2440.Overexpression of the primary sigma factor gene sigA improved carotenoid production by Corynebacterium glutamicum: Application to production of β-carotene and the non-native linear C50 carotenoid bisanhydrobacterioruberin.System wide cofactor turnovers can propagate metabolic stability between pathways.Flux Balance Analysis Indicates that Methane Is the Lowest Cost Feedstock for Microbial Cell Factories.Development of a plasmid-based expression system in Clostridium thermocellum and its use to screen heterologous expression of bifunctional alcohol dehydrogenases (adhEs).Tet-On lentiviral transductants lose inducibility when silenced for extended intervals in mammary epithelial cells.Creating metabolic demand as an engineering strategy in Pseudomonas putida - Rhamnolipid synthesis as an example.Microbial synthesis of a branched-chain ester platform from organic waste carboxylates.Excessive by-product formation: A key contributor to low isobutanol yields of engineered Saccharomyces cerevisiae strains.Genome sequence and analysis of Escherichia coli production strain LS5218.Eliminating a global regulator of carbon catabolite repression enhances the conversion of aromatic lignin monomers to muconate in Pseudomonas putida KT2440.Engineering Escherichia coli for the production of terpene mixture enriched in caryophyllene and caryophyllene alcohol as potential aviation fuel compounds.Conversion and assimilation of furfural and 5-(hydroxymethyl)furfural by Pseudomonas putida KT2440.The Saccharomyces cerevisiae pheromone-response is a metabolically active stationary phase for bio-production.A genetic screen for increasing metabolic flux in the isoprenoid pathway of Saccharomyces cerevisiae: Isolation of SPT15 mutants using the screen.A genetic screen for increasing metabolic flux in the isoprenoid pathway of Saccharomyces cerevisiae: Isolation of SPT15 mutants using the screen.Mitochondrial targeting increases specific activity of a heterologous valine assimilation pathway in Saccharomyces cerevisiae.Improving the flux distributions simulated with genome-scale metabolic models of Saccharomyces cerevisiae.Acidithiobacillus ferrooxidans's comprehensive model driven analysis of the electron transfer metabolism and synthetic strain design for biomining applications.Enhanced fatty acid production in engineered chemolithoautotrophic bacteria using reduced sulfur compounds as energy sources.Promiscuous plasmid replication in thermophiles: Use of a novel hyperthermophilic replicon for genetic manipulation of Clostridium thermocellum at its optimum growth temperature.Interaction of storage carbohydrates and other cyclic fluxes with central metabolism: A quantitative approach by non-stationary 13C metabolic flux analysis.Molecular Cloning Designer Simulator (MCDS): All-in-one molecular cloning and genetic engineering design, simulation and management software for complex synthetic biology and metabolic engineering projects.Computational metabolic engineering strategies for growth-coupled biofuel production by Synechocystis.Selection Finder (SelFi): A computational metabolic engineering tool to enable directed evolution of enzymes.Synechocystis PCC 6803 overexpressing RuBisCO grow faster with increased photosynthesis.
P1433
Q28602241-F146CF66-D780-45EA-A14D-C72CCEDEC438Q36163648-6AC964ED-3EDE-4719-8366-B3F2C369F428Q36713916-E5FEAE8C-4C98-4EC5-B90E-0955B30AE741Q41774826-72D6ACA0-1843-449A-81C7-AD9D302162A3Q44594057-757E38EF-D54C-45BE-88C8-5EA5AA695172Q45421572-34DCC7FE-178C-4E18-8324-2A68E9CEC6D9Q45747102-2B68E9BB-AFB7-4B2F-BC39-3B3E5EEC70C2Q45935586-F7C5B63B-9E75-41C2-B1FF-F4B965E0952CQ46236965-6040B210-5CB9-4059-A40D-A28DA3C5BA52Q46251422-40020C43-1F9D-4EB4-A815-4168A01BD636Q46260666-2566AFF1-F0F3-4245-9F15-F402D071AC4CQ47099054-66551823-16CE-4F45-9269-B503E38C0446Q47099315-8723957C-B2D5-4E4F-BFAB-BDED9C5D2620Q47104210-4F8FB8CA-5E11-456A-9850-26D40B58BD60Q47104312-D9D4E9CC-7FD9-442E-B870-F345E8A58B93Q47119031-5F538133-4827-451D-8EA3-9F5F94B6E75EQ47133036-8EF6B7D8-3ED8-4947-8220-C1C166288F7AQ47133517-7E83F2D5-E404-4A58-B9D6-D7B213311212Q47134941-1487185E-030B-43C7-9A7A-80DCA2C82837Q47138259-561DC3A0-5F7B-43B5-A40C-A3150C7078E3Q47142561-F623C0EA-D325-44B4-B516-14772FB9BC11Q47145514-52DD1F86-0D58-4B9C-9E05-E572F10AE14FQ47148449-DF087EC2-4D10-4A57-BB92-AE42278796E1Q47163819-786A4F1E-ACA8-4E34-8CCB-5D3E95797B01Q47300858-DB8D4E6A-6FC8-427C-9C45-EB1EE8C4B526Q49702335-4C9596E4-1708-4E6D-8E17-1C9CF8F0BD05Q50140020-F80FA05C-EFAF-463E-A7EA-784B54F2F481Q50145945-9CD0D66D-4AA6-4201-B1A6-C0E53525394DQ50146060-6ACFEF83-EBB8-40E2-9D9B-CA1F0954C552Q50180819-614BC490-3B35-49ED-B35B-3435E3A3A997Q50196162-BA6F40C5-C6C8-4821-BCCF-0EEBEFC91EF8Q50196257-37B8FF48-7BE7-4E63-BD85-7534735EA05DQ50199378-C48C4FC1-D9C8-4848-AA26-418ED561274DQ50221597-0BD70441-1C47-4B5D-B402-68D1CF8EF3E4Q50233220-B8E5D3DD-C743-495F-873E-2C71CCB59BE9Q50233836-FF06EF2A-2C34-499D-B497-1F6DECA77191Q50238026-A12304AF-5D04-4A4F-80C6-F94DBA0BBE2DQ50241541-7DE9B956-6818-47E4-94D3-14C61BFBB420Q50254524-1FBE38F1-43FB-4A20-862E-E35D9B050AD8Q50256317-8CF590F2-9E6E-4E8E-905D-876653EE66A5
P1433
description
journal
@en
revista científica
@es
wetenschappelijk tijdschrift van Elsevier
@nl
wissenschaftliche Fachzeitschrift
@de
name
Metabolic engineering communications
@ast
Metabolic engineering communications
@en
Metabolic engineering communications
@es
Metabolic engineering communications
@nl
type
label
Metabolic engineering communications
@ast
Metabolic engineering communications
@en
Metabolic engineering communications
@es
Metabolic engineering communications
@nl
altLabel
Metab Eng Commun
@en
Metabolic Engineering Communications
@en
prefLabel
Metabolic engineering communications
@ast
Metabolic engineering communications
@en
Metabolic engineering communications
@es
Metabolic engineering communications
@nl
P31
P3181
P1055
P1156
21100369715
P123
P1277
P1476
Metabolic engineering communications
@en
P236
P3181
P5115
P5963
metabolic-engineering-communications