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Body Mass Parameters, Lipid Profiles and Protein Contents of Zebrafish Embryos and Effects of 2,4-Dinitrophenol ExposureAdaptation of the hydrocarbonoclastic bacterium Alcanivorax borkumensis SK2 to alkanes and toxic organic compounds: a physiological and transcriptomic approachTranscriptome and membrane fatty acid analyses reveal different strategies for responding to permeating and non-permeating solutes in the bacterium Sphingomonas wittichii.ER stress induced by the OCH1 mutation triggers changes in lipid homeostasis in Kluyveromyces lactis.Isolation and characterization of Magnetospirillum sp. strain 15-1 as a representative anaerobic toluene-degrader from a constructed wetland modelSolvent-tolerant bacteria for biotransformations in two-phase fermentation systems.Biotechnological processes for biodiesel production using alternative oils.Glycerophospholipid synthesis and functions in Pseudomonas.Functional Characterization of a 28-Kilobase Catabolic Island from Pseudomonas sp. Strain M1 Involved in Biotransformation of β-Myrcene and Related Plant-Derived Volatiles.Osmotic stress in colony and planktonic cells of Pseudomonas putida mt-2 revealed significant differences in adaptive response mechanisms.Toxicity of synthetic herbicides containing 2,4-D and MCPA moieties towards Pseudomonas putida mt-2 and its response at the level of membrane fatty acid composition.Prediction of the adaptability of Pseudomonas putida DOT-T1E to a second phase of a solvent for economically sound two-phase biotransformations.Monaibacterium marinum, gen. nov, sp. nov, a new member of the Alphaproteobacteria isolated from seawater of Menai Straits, Wales, UK.Draft Genome Sequence of Magnetospirillum sp. Strain 15-1, a Denitrifying Toluene Degrader Isolated from a Planted Fixed-Bed Reactor.In situ protein-SIP highlights Burkholderiaceae as key players degrading toluene by para ring hydroxylation in a constructed wetland model.Biodiversity of soil bacteria exposed to sub-lethal concentrations of phosphonium-based ionic liquids: Effects of toxicity and biodegradation.Adaptive response of Rhodococcus opacus PWD4 to salt and phenolic stress on the level of mycolic acids.Energetics and surface properties of Pseudomonas putida DOT-T1E in a two-phase fermentation system with 1-decanol as second phase.Membrane vesicle formation as a multiple-stress response mechanism enhances Pseudomonas putida DOT-T1E cell surface hydrophobicity and biofilm formation.Isolation and characterization of the E. coli membrane protein production strain Mutant56(DE3).Adaptation of anaerobically grown Thauera aromatica, Geobacter sulfurreducens and Desulfococcus multivorans to organic solvents on the level of membrane fatty acid composition.Adaptation of Escherichia coli to ethanol on the level of membrane fatty acid composition.Two naphthalene degrading bacteria belonging to the genera Paenibacillus and Pseudomonas isolated from a highly polluted lagoon perform different sensitivities to the organic and heavy metal contaminants.The role of energy-efficient biotechnological processes in the waste management industry.Degradation of macrolide antibiotics by ozone: a mechanistic case study with clarithromycin.Biostimulation by methanol enables the methylotrophic yeasts Hansenula polymorpha and Trichosporon sp. to reveal high formaldehyde biodegradation potential as well as to adapt to this toxic pollutant.Changes in fatty acid composition of Chromohalobacter israelensis with varying salt concentrations.Rhamnolipid biosurfactants decrease the toxicity of chlorinated phenols to Pseudomonas putida DOT-T1E.Yeast adaptation to 2,4-dichlorophenoxyacetic acid involves increased membrane fatty acid saturation degree and decreased OLE1 transcription.Adaptation of Rhodococcus erythropolis DCL14 to growth on n-alkanes, alcohols and terpenes.Farewell Prof. Hans‐Jürgen Rehm.Impact of fermentation pH and temperature on freeze-drying survival and membrane lipid composition of Lactobacillus coryniformis Si3.Enterobacter sp. VKGH12 growing with n-butanol as the sole carbon source and cells to which the alcohol is added as pure toxin show considerable differences in their adaptive responses.Biodegradation of diesel/biodiesel blends by a consortium of hydrocarbon degraders: effect of the type of blend and the addition of biosurfactants.Physiology and transcriptome of the polycyclic aromatic hydrocarbon-degrading Sphingomonas sp. LH128 after long-term starvation.Physiological and Transcriptome Response of the Polycyclic Aromatic Hydrocarbon Degrading Novosphingobium sp. LH128 after Inoculation in Soil.Effects of ammonium-based ionic liquids and 2,4-dichlorophenol on the phospholipid fatty acid composition of zebrafish embryos.Formulation and stabilization of an Arthrobacter strain with good storage stability and 4-chlorophenol-degradation activity for bioremediation.Immediate response mechanisms of Gram-negative solvent-tolerant bacteria to cope with environmental stress: cis-trans isomerization of unsaturated fatty acids and outer membrane vesicle secretion.Toxicity of diatom polyunsaturated aldehydes to marine bacterial isolates reveals their mode of action.
P50
Q28547390-9F530C5C-EB49-4609-BE1E-7BBC93C89F2BQ30541054-69E14694-AD7A-4766-94FC-9B130D937BDDQ34074196-E0C6F114-73A1-45B3-8CC7-8E2C40C8318EQ35541089-FDFBC8E6-14DB-491F-B206-A156FFBC3CF6Q36332103-C88A5104-51A2-445C-8472-95E5E6786B00Q36722048-A6E643FE-DA46-4523-8BF6-9F5CA0FE11A6Q37779020-02B995D4-F033-4075-85A4-8B3F88BA569FQ38543216-E4D1B038-ECBA-4D30-AC68-ADF2AE2087D3Q38755946-58D08F02-3813-4318-9F38-80937A519E97Q38904208-39A3B29B-5077-478D-B140-30F892BF4066Q38966373-06173F2E-98C1-4914-9E13-1FB5F021B918Q39799561-85515610-E5E8-489B-887E-2661160D5AE2Q40079807-88F21E27-55B5-4B11-9666-A5D766F80BF4Q40097943-DC24D5E5-DC0C-42F5-A8EF-0516227E88C7Q40264138-18274C18-BCB4-4670-9BD9-970B80A8EAA7Q40499519-7F9F36B7-53C5-4FE6-BF58-939181F3167BQ41048362-935FB99E-1775-44B6-899F-9D06F6DE21A4Q41477104-B4A7A36A-DB20-499C-BF4C-5D0543BBD176Q41850325-514CDB94-90CC-4663-AA71-979B70AE5FBDQ42129196-8A00EC13-D980-44BC-A915-8A640BD63113Q42755779-1F4FE046-1E32-4C35-B574-A174AF7EA55CQ42863422-9B942351-8287-4A21-8784-76E0AFC5E8D9Q43027195-9E847748-057C-40C8-BCE8-C6F5DE71F57AQ43330228-2795937F-D009-4F7B-948F-1CBC9C58E1F7Q43334013-CC1B1415-0001-4A5E-B812-D7C42E245340Q44778880-62BF5D3B-9EC8-4FAD-9D2F-CEB4C0D74355Q45270599-C0B3CEE3-8ED8-4895-B256-4305135061A2Q46062531-3390BA79-EDA1-4467-A79B-42810439A1D7Q46395158-75899FB9-0829-4DB1-A06C-F447488D9F58Q46459437-18A060DC-E814-48EC-A39D-7FB3FF6D49BFQ46569579-0A31B0C1-F927-41F7-9EC9-4AE778458557Q46867302-3DC867C4-CC20-411C-A089-A2F4BA9B15B9Q46922658-F05732D9-6C3A-4547-AE28-C1F9C1C908D4Q47329154-9FEFF47B-D2F8-43CA-B4E0-F9058679708EQ47994113-E910A5B1-C244-47BF-9B51-95390B88AD19Q48104238-0D226C69-7D02-44FE-9DC7-EB809EAAA943Q48226600-D7522553-DEAC-4B59-AF99-14D109A5A6DDQ49488510-1E082B29-3DA9-4451-80DA-77CF91D24AD5Q49950205-5CE2B3BE-1B2B-453B-B483-4C4B44A4508DQ51095245-E63555A0-8D3C-4006-8F21-5268E6077391
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description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Hermann J Heipieper
@ast
Hermann J Heipieper
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Hermann J. Heipieper
@en
Hermann J. Heipieper
@nl
type
label
Hermann J Heipieper
@ast
Hermann J Heipieper
@es
Hermann J. Heipieper
@en
Hermann J. Heipieper
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H. J. Heipieper
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Hermann J Heipieper
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Hermann J Heipieper
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Hermann J. Heipieper
@en
Hermann J. Heipieper
@nl
P106
P31
P496
0000-0002-3723-9600