Metabolic engineering of Saccharomyces cerevisiaeSimultaneous overexpression of enzymes of the lower part of glycolysis can enhance the fermentative capacity of Saccharomyces cerevisiae.The roles of galactitol, galactose-1-phosphate, and phosphoglucomutase in galactose-induced toxicity in Saccharomyces cerevisiaeThe interplay of descriptor-based computational analysis with pharmacophore modeling builds the basis for a novel classification scheme for feruloyl esterasesIndustrial systems biology of Saccharomyces cerevisiae enables novel succinic acid cell factoryFed-batch SSCF using steam-exploded wheat straw at high dry matter consistencies and a xylose-fermenting Saccharomyces cerevisiae strain: effect of laccase supplementationCombining substrate specificity analysis with support vector classifiers reveals feruloyl esterase as a phylogenetically informative protein groupThe challenge of improved secretory production of active pharmaceutical ingredients in Saccharomyces cerevisiae: a case study on human insulin analogs.Characterization of global yeast quantitative proteome data generated from the wild-type and glucose repression saccharomyces cerevisiae strains: the comparison of two quantitative methodsMetabolic engineering of ammonium assimilation in xylose-fermenting Saccharomyces cerevisiae improves ethanol production.Alleviation of glucose repression of maltose metabolism by MIG1 disruption in Saccharomyces cerevisiae.Dynamic responses of Pseudomonas fluorescens DF57 to nitrogen or carbon source addition.Identification of biomarkers for genotyping Aspergilli using non-linear methods for clustering and classificationSystems analysis unfolds the relationship between the phosphoketolase pathway and growth in Aspergillus nidulansCharacterization and kinetic analysis of a thermostable GH3 beta-glucosidase from Penicillium brasilianum.Growth and enzyme production by three Penicillium species on monosaccharides.Penicillium brasilianum as an enzyme factory; the essential role of feruloyl esterases for the hydrolysis of the plant cell wall.Metabolic footprinting in microbiology: methods and applications in functional genomics and biotechnology.Lipidomic profiling of Saccharomyces cerevisiae and Zygosaccharomyces bailii reveals critical changes in lipid composition in response to acetic acid stressSilencing MIG1 in Saccharomyces cerevisiae: effects of antisense MIG1 expression and MIG1 gene disruption.Increasing NADH oxidation reduces overflow metabolism in Saccharomyces cerevisiaeThe Presence of Pretreated Lignocellulosic Solids from Birch during Saccharomyces cerevisiae Fermentations Leads to Increased Tolerance to Inhibitors--A Proteomic Study of the EffectsShort-term adaptation during propagation improves the performance of xylose-fermenting Saccharomyces cerevisiae in simultaneous saccharification and co-fermentation.Fueling industrial biotechnology growth with bioethanol.Reconstruction of the yeast Snf1 kinase regulatory network reveals its role as a global energy regulator.Membrane engineering of S. cerevisiae targeting sphingolipid metabolism.ALD5, PAD1, ATF1 and ATF2 facilitate the catabolism of coniferyl aldehyde, ferulic acid and p-coumaric acid in Saccharomyces cerevisiae.Teaching microbial physiology using glucose repression phenomenon in baker's yeast as an example.Lignocellulosic ethanol production at high-gravity: challenges and perspectives.Investigation of the impact of MIG1 and MIG2 on the physiology of Saccharomyces cerevisiae.Elucidation of the role of Grr1p in glucose sensing by Saccharomyces cerevisiae through genome-wide transcription analysis.Glucose control in Saccharomyces cerevisiae: the role of Mig1 in metabolic functions.Identification of in vivo enzyme activities in the cometabolism of glucose and acetate by Saccharomyces cerevisiae by using 13C-labeled substrates.Improvement of galactose uptake in Saccharomyces cerevisiae through overexpression of phosphoglucomutase: example of transcript analysis as a tool in inverse metabolic engineering.The chemical nature of phenolic compounds determines their toxicity and induces distinct physiological responses in Saccharomyces cerevisiae in lignocellulose hydrolysatesAn expanded role for microbial physiology in metabolic engineering and functional genomics: moving towards systems biology.The impact of phosphate scarcity on pharmaceutical protein production in S. cerevisiae: linking transcriptomic insights to phenotypic responses.The influence of HMF and furfural on redox-balance and energy-state of xylose-utilizing Saccharomyces cerevisiae.Physiological responses to acid stress by Saccharomyces cerevisiae when applying high initial cell densityStudies of the production of fungal polyketides in Aspergillus nidulans by using systems biology tools.
P50
Q24548524-B1FFBB40-18EA-4A24-ACF2-CFC563D6CE29Q27938497-A64887A5-E6A1-4DE1-9CBC-2A904DF5CD33Q28276973-7A4881B2-D59E-42E2-B219-2EC8AB4CE2EEQ28293620-BE3153DD-7513-461C-8D95-76A276D111BAQ28485207-5C26A6EA-9667-4CFD-9FFB-E36DBC465228Q28661415-CB753640-3453-4593-A166-63084A3EEC58Q28749210-9CC29C28-27A8-427C-A902-A6F013791E1FQ30429479-E319545A-C2D8-4F87-AE44-813B7F1B642BQ30491950-EE839EB7-933F-4592-93AE-6E1CAD2ECA65Q30503625-F21B8B5B-334C-44D5-A242-56EC22DB5B7EQ30532178-E4A447EC-59A9-4D8C-9BEA-98DF671AEDE8Q32062553-E8D49A94-CB30-4C62-8E8E-FBFF8D1A2C9AQ33316834-75CF70A7-A977-4A33-8FB2-B9FA34A19B1DQ33389182-C4FAD153-853D-4677-842C-C606B11396F0Q33503691-4D00A70C-313F-4F5B-A42E-3AF62F21F418Q34311348-4AFD51A1-E862-4D8F-BD3B-43DD3EC2F0B8Q34633678-A6259720-0EF5-43B6-BC86-C1270ACC1F03Q34803595-3079F904-A1B0-4994-9C3B-74ED2A763480Q34984587-A3121D6A-040F-4701-950B-6969F7D8C0ACQ35202135-F58A199A-A30F-4374-87D1-0C54DE7F2448Q35844477-30702E3C-17BD-483F-95E5-9D71F243594EQ35916046-E15FAE75-16EC-4789-ACF8-788597206733Q36393284-4BED31C1-85EF-46A6-AEB7-BA7D150F8667Q36904540-8B00E4AD-F3F0-4F22-88F8-4885D70B10C4Q37481996-BFAFE75E-504B-44F8-AAC1-B2229A5411A0Q37618072-63F78422-3F46-464F-A328-20E9CB1C30DBQ37644402-4373A413-6D02-4575-9D68-754DDB492123Q37884515-BDEAC6DD-13AD-48CE-986F-F3CE6A7EB38CQ38162615-E708281B-C5C5-4328-99D4-057315030241Q38326244-959EEC73-152B-4AB5-85C8-EB94F28FA1AFQ38334039-C80C5388-EBEA-4B6B-A0C7-A300391CAEF9Q38339959-CB1F8604-5B76-4416-AA5D-6E1D44636D17Q39774551-97528E7F-FB98-4C1A-97E9-35D5397CC22CQ39800927-7888FF74-CE2E-44EC-9AC4-BECAE07B1FBCQ40551434-A676AD04-DD34-426F-86BB-BC086BBAAF26Q40593223-59D90C12-D7CF-474F-9D23-B4DEF6A968EBQ40637536-12975512-8FC3-4EE5-B42B-5EE827D65858Q41073704-A378C321-1CBE-40B0-B9BD-A535E13A9EE7Q41662655-E78B5421-C109-45A9-8D14-013CACD2E947Q41833686-C13F315B-847D-4437-9473-7DA7110D0420
P50
description
Swedish microbiologist and professor
@en
Zweeds microbiologe
@nl
microbiologa svedese
@it
microbiologista sueca
@pt
microbiologiste suédoise
@fr
microbiòloga sueca
@ca
microbióloga sueca
@ast
microbióloga sueca
@es
microbióloga sueca
@gl
mikrobiolog och professor
@sv
name
Lisbeth Olsson
@ast
Lisbeth Olsson
@ca
Lisbeth Olsson
@en
Lisbeth Olsson
@es
Lisbeth Olsson
@fr
Lisbeth Olsson
@ga
Lisbeth Olsson
@nl
Lisbeth Olsson
@sl
Lisbeth Olsson
@sq
Lisbeth Olsson
@sv
type
label
Lisbeth Olsson
@ast
Lisbeth Olsson
@ca
Lisbeth Olsson
@en
Lisbeth Olsson
@es
Lisbeth Olsson
@fr
Lisbeth Olsson
@ga
Lisbeth Olsson
@nl
Lisbeth Olsson
@sl
Lisbeth Olsson
@sq
Lisbeth Olsson
@sv
prefLabel
Lisbeth Olsson
@ast
Lisbeth Olsson
@ca
Lisbeth Olsson
@en
Lisbeth Olsson
@es
Lisbeth Olsson
@fr
Lisbeth Olsson
@ga
Lisbeth Olsson
@nl
Lisbeth Olsson
@sl
Lisbeth Olsson
@sq
Lisbeth Olsson
@sv
P1006
P214
P244
P268
P269
P1006
P106
P1412
P21
P213
0000 0001 1629 1234
P214
P244
nb2007026442
P268
P269
P27
P31
P569
1963-11-22T00:00:00Z
P734
P735
P7859
lccn-nb2007026442