Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
about
Genetic resources for advanced biofuel production described with the Gene OntologyGenetic engineering of microorganisms for biodiesel productionEmerging Technologies for the Production of Renewable Liquid Transport Fuels from Biomass Sources Enriched in Plant Cell WallsImproved Acetic Acid Resistance in Saccharomyces cerevisiae by Overexpression of the WHI2 Gene Identified through Inverse Metabolic EngineeringMetabolic engineering of a synergistic pathway for n-butanol production in Saccharomyces cerevisiaen-Butanol production in Saccharomyces cerevisiae is limited by the availability of coenzyme A and cytosolic acetyl-CoABioethanol from lignocellulosic biomass: current findings determine research prioritiesA comparative study of ethanol production using dilute acid, ionic liquid and AFEX™ pretreated corn stoverCombining inhibitor tolerance and D-xylose fermentation in industrial Saccharomyces cerevisiae for efficient lignocellulose-based bioethanol productionA constraint-based model of Scheffersomyces stipitis for improved ethanol productionBiosynthesis of cis,cis-muconic acid and its aromatic precursors, catechol and protocatechuic acid, from renewable feedstocks by Saccharomyces cerevisiaeCytosolic re-localization and optimization of valine synthesis and catabolism enables inseased isobutanol production with the yeast Saccharomyces cerevisiaeThe role of synthetic biology in the design of microbial cell factories for biofuel productionRescuing ethanol photosynthetic production of cyanobacteria in non-sterilized outdoor cultivations with a bicarbonate-based pH-rising strategy.Characterization of acetonitrile-tolerant marine bacterium Exiguobacterium sp. SBH81 and its tolerance mechanism.Identification of novel genes responsible for ethanol and/or thermotolerance by transposon mutagenesis in Saccharomyces cerevisiae.Metabolic engineering and classical selection of the methylotrophic thermotolerant yeast Hansenula polymorpha for improvement of high-temperature xylose alcoholic fermentation.Uncovering the genome-wide transcriptional responses of the filamentous fungus Aspergillus niger to lignocellulose using RNA sequencingGenetic analysis of D-xylose metabolism by endophytic yeast strains of Rhodotorula graminis and Rhodotorula mucilaginosa.Tolerance and adaptive evolution of triacylglycerol-producing Rhodococcus opacus to lignocellulose-derived inhibitorsEnhanced direct fermentation of cassava to butanol by Clostridium species strain BOH3 in cofactor-mediated medium.Identification of Genes Conferring Tolerance to Lignocellulose-Derived Inhibitors by Functional Selections in Soil Metagenomes.Phylogenetic, Molecular, and Biochemical Characterization of Caffeic Acid o-Methyltransferase Gene Family in Brachypodium distachyon.Enhanced Bioconversion of Cellobiose by Industrial Saccharomyces cerevisiae Used for Cellulose UtilizationDesigning industrial yeasts for the consolidated bioprocessing of starchy biomass to ethanol.Xylose isomerase improves growth and ethanol production rates from biomass sugars for both Saccharomyces pastorianus and Saccharomyces cerevisiae.Increased isobutanol production in Saccharomyces cerevisiae by eliminating competing pathways and resolving cofactor imbalance.Understanding physiological responses to pre-treatment inhibitors in ethanologenic fermentations.Metabolic engineering of Saccharomyces cerevisiae: a key cell factory platform for future biorefineries.Biotechnology of non-Saccharomyces yeasts--the ascomycetes.Recent advancements in various steps of ethanol, butanol, and isobutanol productions from woody materials.Strategies for the production of high concentrations of bioethanol from seaweeds: production of high concentrations of bioethanol from seaweeds.Waste valorization by biotechnological conversion into added value products.Microbial inhibitors: formation and effects on acetone-butanol-ethanol fermentation of lignocellulosic biomass.Toxicological challenges to microbial bioethanol production and strategies for improved tolerance.Microbial conversion of pyrolytic products to biofuels: a novel and sustainable approach toward second-generation biofuels.Enhanced xylose fermentation and ethanol production by engineered Saccharomyces cerevisiae strain.Metabolic engineering of Saccharomyces cerevisiae for 2,3-butanediol production.Parallelised online biomass monitoring in shake flasks enables efficient strain and carbon source dependent growth characterisation of Saccharomyces cerevisiae.Ethanol and Volatile Fatty Acid Production from Lignocellulose by Clostridium cellulolyticum.
P2860
Q27028222-2424401F-B3C0-48C6-A467-39D8384C9642Q27690678-E67E46AF-AC00-4F7B-BC63-0203B5AB3857Q28077298-A7F19C66-7BA2-492D-8376-1A05ECD8C125Q28601906-F5D121E3-049E-4140-ABDC-3887D762FEBFQ28602998-565266B2-1C0E-4A8D-8F3E-7D2BED6ED2E6Q28603844-635D74BB-2296-4C22-AA26-2C0D2F9DE693Q28652210-3E72B05C-EC5C-4A03-9828-BFB51A371085Q28658591-BAA648C6-B114-49CC-A49B-9B3D31854471Q28681149-AB98FE60-CC86-4C51-900C-0B57BCA4FDADQ28710556-83DE7F36-6154-40EC-A930-57617194B0DAQ28713061-F1652334-E48B-4EC6-B5DA-B63514E5F10CQ28716711-5501DA64-A628-4ABD-8EBF-3837556106BBQ28743718-89F9B0A0-C265-4AF2-B349-3951AC8BA78CQ33564509-2C094F3A-D584-45A8-9C31-35352D04A263Q33674851-3CE7BF03-65BF-40A0-B229-1A378BFA1806Q33894063-D36405DB-2A70-4609-BFE1-83FA61EB1888Q34091389-F45665BC-D9A4-4387-82CA-D227018BE672Q34388528-DBFE0A96-15A5-407C-B2E9-A00E1501C3FDQ35199969-B527EF48-60AC-498C-8585-18DF71FB35F7Q35686395-F525BFF3-F87F-4F0D-894A-72B4473FE1A0Q36156927-F912770E-6D8A-4E1E-BECD-D5D1F9098010Q36457751-9E317F3A-C675-4F77-BAA4-CAD4EDC5BD61Q36582657-44239755-4DDA-422F-B3C3-E5AA177B2775Q36645428-4FE287FF-24B1-4549-9FDD-192CB291A6FCQ36720746-8D96E694-7223-4F33-ABC2-9E47DD3FF40EQ37037254-F6B286FD-199D-4CF7-8B76-B93E49A58EC1Q37400919-2CFDF0D3-B4AB-406A-9471-BE94034E742FQ37983790-20BFB7A1-C0F3-406F-A9FD-3E562D937BB0Q37990431-EC288F67-8D16-40FE-B596-AC99F267EAA9Q38062850-312FB8B3-F06F-460A-9B81-AFC53A0E5D70Q38072396-EB4FB341-1722-4624-A2CE-1049EDBDF458Q38073650-5C67E0AD-CA69-422A-B935-A3DE712927FDQ38113144-657633C2-083D-42C9-A850-A7F186DF712DQ38255393-B27A2B4C-1990-4EF0-8860-D259AF3050A0Q38596005-C5A8DCF1-A1EE-4C10-8F4F-58EF1C0E614DQ38598391-DB3A00FC-3302-4F78-A913-4C79E7291CCDQ39020470-0A5DD85D-385D-4A86-85A8-0658A0C0C1AEQ39138039-E49F81A5-C618-4D3F-B480-CD6ECAB0CA72Q39562033-5D1BA3A7-6B56-4866-BC30-45296F67C3D9Q39800712-341AB040-6585-4A96-8193-A34482E4A7A3
P2860
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
description
2010 nî lūn-bûn
@nan
2010 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@ast
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@en
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@nl
type
label
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@ast
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@en
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@nl
prefLabel
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@ast
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@en
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels.
@nl
P2093
P2860
P1476
Trends and challenges in the microbial production of lignocellulosic bioalcohol fuels
@en
P2093
Alexander Farwick
Christian Weber
Dawid Brat
Feline Benisch
Heiko Dietz
Thorsten Subtil
P2860
P2888
P304
P356
10.1007/S00253-010-2707-Z
P407
P577
2010-06-10T00:00:00Z
P6179
1003044288