about
Influence of Polyphenols on Bacterial Biofilm Formation and Quorum-sensingMembers of the genus Burkholderia: good and bad guysTwo quorum sensing systems control biofilm formation and virulence in members of the Burkholderia cepacia complexExplosive cell lysis as a mechanism for the biogenesis of bacterial membrane vesicles and biofilmsGlobal regulation of quorum sensing and virulence by VqsR in Pseudomonas aeruginosaAttenuation of Pseudomonas aeruginosa virulence by quorum sensing inhibitorsDetection of N-acylhomoserine lactones in lung tissues of mice infected with Pseudomonas aeruginosa.Proteome analysis of intraclonal diversity of two Pseudomonas aeruginosa TB clone isolates.The AHL- and BDSF-dependent quorum sensing systems control specific and overlapping sets of genes in Burkholderia cenocepacia H111.Establishment of new genetic traits in a microbial biofilm community.Towards the proteome of Burkholderia cenocepacia H111: setting up a 2-DE reference map.Detection of quorum-sensing-related molecules in Vibrio scophthalmi.Multiple roles of Pseudomonas aeruginosa TBCF10839 PilY1 in motility, transport and infection.Quantitative detection of changes in the leaf-mesophyll tonoplast proteome in dependency of a cadmium exposure of barley (Hordeum vulgare L.) plants.Evidence for a plant-associated natural habitat for Cronobacter spp.Genes involved in Cronobacter sakazakii biofilm formation.A proteomics approach to study synergistic and antagonistic interactions of the fungal-bacterial consortium Fusarium oxysporum wild-type MSA 35.N-acyl homoserinelactone-mediated gene regulation in gram-negative bacteria.Structure and function of the symbiosis partners of the lung lichen (Lobaria pulmonaria L. Hoffm.) analyzed by metaproteomics.Structural and functional characterization of diffusible signal factor family quorum-sensing signals produced by members of the Burkholderia cepacia complex.Burkholderia species are major inhabitants of white lupin cluster roots.Different protein expression profiles in cheese and clinical isolates of Enterococcus faecalis revealed by proteomic analysis.Construction of self-transmissible green fluorescent protein-based biosensor plasmids and their use for identification of N-acyl homoserine-producing bacteria in lake sediments.Inhibition of lipopolysaccharide transport to the outer membrane in Pseudomonas aeruginosa by peptidomimetic antibiotics.A novel siderophore-independent strategy of iron uptake in the genus Burkholderia.Identity and effects of quorum-sensing inhibitors produced by Penicillium species.Identification of Burkholderia cenocepacia strain H111 virulence factors using nonmammalian infection hosts.Identification of Burkholderia pseudomallei genes required for the intracellular life cycle and in vivo virulence.Genus-wide acid tolerance accounts for the biogeographical distribution of soil Burkholderia populations.Two GacA-dependent small RNAs modulate the quorum-sensing response in Pseudomonas aeruginosaResponse of Burkholderia cenocepacia H111 to micro-oxia.Proteomic profiling of Cronobacter turicensis 3032, a food-borne opportunistic pathogen.Quorum sensing triggers the stochastic escape of individual cells from Pseudomonas putida biofilmsThe IclR-family regulator BapR controls biofilm formation in B. cenocepacia H111.Quorum sensing : a novel target for the treatment of biofilm infections.Integrated whole-genome screening for Pseudomonas aeruginosa virulence genes using multiple disease models reveals that pathogenicity is host specific.σ54-Dependent Response to Nitrogen Limitation and Virulence in Burkholderia cenocepacia Strain H111Pseudomonas aeruginosa and Burkholderia cepacia in cystic fibrosis: genome evolution, interactions and adaptation.Quorum sensing: the power of cooperation in the world of Pseudomonas.Soil metaproteomics - Comparative evaluation of protein extraction protocols.
P50
Q21559385-285FD0B1-74FC-42AB-8E5B-B55B2A0862C1Q26745920-7E3C9491-E3BB-473D-8C76-367E90F9C3C5Q26827817-CE4F6288-C626-4142-8E93-3CC4BCF0A2A4Q27320770-FE05B370-5760-4222-AE6A-7CF2903CD14BQ28493065-1CFB3F8D-50AA-4742-A687-F089B6FA19A9Q29615282-5CD826E4-7CE9-4E7D-84C0-D3515B6F5368Q30938731-0B8E1ED1-181F-4518-AF11-2129FC7944DAQ31076649-0599CFCF-6E46-4643-8A14-4245115E689BQ31107317-C3F61F36-B428-4CCB-BD9C-21F876D1BA33Q32062585-37C36A9F-5188-4C36-A3CA-736E5255AD43Q33227430-18DBE079-0475-43B5-B76B-EA4C501F47E5Q33359801-45DC1A1F-4548-4961-AFA0-7EBEB2FF5565Q33389371-A57F9F30-12F6-4F77-B65F-5A0EC584EC7CQ33434612-694B3BBB-11AA-4FCC-B7A9-81714D517DD0Q33502492-12A76190-C0AF-49F8-930A-9F9B50A9CCC9Q33527768-64342DDE-D35D-4045-8D68-AAA4050AB514Q33656824-93FABF9B-8C39-4E84-AB32-D4D5E8E14541Q33905344-69835D2E-F103-478B-A357-82D830200DB2Q33908880-F0790246-F899-4484-B685-D6EDDB169FEDQ33983468-53E09C4F-3A56-4F81-87BF-323C4B42983EQ34015986-0E8D80C7-EAFE-4F21-8291-56CFADFE74DCQ34116138-4F67F1BF-04DE-4D7E-A8F4-182E2A7889A2Q34119592-79AC89DA-B9A2-452A-9A76-379EF7937DDEQ34341210-5B826B28-EA64-461C-997D-CC9F8123D8ABQ34393086-C387DF24-5C14-43A2-8F85-D9128C308433Q34415933-4703AB46-5821-4764-A038-1FB698BD9596Q34454921-C9340938-E95A-45AF-A6CC-278C1A8CA11FQ34681050-E51BC0CA-939E-4C3A-A55D-B0C94D920B84Q34940937-F32AE83D-2393-4C5C-A3C0-AC5E6EEC4F83Q34976787-8F904A94-8C23-4331-8DF9-D2B09E4D6D9CQ34984150-7C85F48F-C89F-4F53-A7C5-60E008F92CF0Q34992749-60694AA3-B7D7-41D0-AA25-709E3EC40A57Q35023061-53A6A3C7-C4D4-4BA5-9DF6-4CDB3ED8F41DQ35128396-44AB2730-BDF0-48DC-BBEE-4EF4214C8B0EQ35192239-81935427-22AA-472D-A1E7-AC66D5CD2E4AQ35595533-A1CBE3CA-57F0-409F-9F5C-DEE798F5F0C2Q35914056-173E2DE7-888F-45F9-87F5-9067F791A03DQ35922691-4326E202-66C5-42DD-A1AA-833E373F0A2CQ36091799-4DBA5255-CC24-4094-9FFC-162CF9DA781DQ36147433-6C8BC395-8105-4EDC-BAF7-A320FA26A814
P50
description
researcher
@en
wetenschapper
@nl
name
Eberl L
@nl
Leo Eberl
@en
type
label
Eberl L
@nl
Leo Eberl
@en
altLabel
Eberl L
@en
prefLabel
Eberl L
@nl
Leo Eberl
@en
P106
P31
P496
0000-0002-7241-0864