Size of bacterial ice-nucleation sites measured in situ by radiation inactivation analysis.
about
Bacteria in the leaf ecosystem with emphasis on Pseudomonas syringae-a pathogen, ice nucleus, and epiphytePhysiological and ecological significance of biological ice nucleatorsAirborne Microalgae: Insights, Opportunities, and ChallengesHailstones: a window into the microbial and chemical inventory of a storm cloudBoreal pollen contain ice-nucleating as well as ice-binding 'antifreeze' polysaccharides.Formation of bacterial membrane ice-nucleating lipoglycoprotein complexes.The relevance of nanoscale biological fragments for ice nucleation in clouds.An ice nucleation reporter gene system: identification of inducible pathogenicity genes in Pseudomonas syringae pv. phaseolicola.Novel dimeric β-helical model of an ice nucleation protein with bridged active sitesTwo novel bacterial biosensors for detection of nitrate availability in the rhizosphere.High ice nucleation activity located in blueberry stem bark is linked to primary freeze initiation and adaptive freezing behaviour of the barkNovel method for identifying bacterial mutants with reduced epiphytic fitnessCharacteristics of Insertional Mutants of Pseudomonas syringae with Reduced Epiphytic Fitness.Three separate classes of bacterial ice nucleation structures.Components of ice nucleation structures of bacteria.Principles and biotechnological applications of bacterial ice nucleation.Molecular organisation of the ice nucleation protein InaV from Pseudomonas syringae.Cloning and expression of afpA, a gene encoding an antifreeze protein from the arctic plant growth-promoting rhizobacterium Pseudomonas putida GR12-2.Measurement of ice nucleation-active bacteria on plants and in precipitation by quantitative PCR.Modeling repetitive, non-globular proteinsA biological sensor for iron available to bacteria in their habitats on plant surfaces.High-level expression of ice nuclei in a Pseudomonas syringae strain is induced by nutrient limitation and low temperature.Kinetics of appearance and disappearance of classes of bacterial ice nuclei support an aggregation model for ice nucleus assembly.Characterization of biological ice nuclei from a lichen.Modeling Pseudomonas syringae ice-nucleation protein as a beta-helical protein.Functional display of ice nucleation protein InaZ on the surface of bacterial ghosts.Properties and biotechnological applications of ice-binding proteins in bacteria.Preordering of water is not needed for ice recognition by hyperactive antifreeze proteinsRefreeze experiments with water droplets containing different types of ice nuclei interpreted by classical nucleation theoryPerspectives on the Future of Ice Nucleation Research: Research Needs and Unanswered Questions Identified from Two International WorkshopsThe unstable ice nucleation properties of Snomax® bacterial particlesBiogenic ice nuclei in boundary layer air over two U.S. High Plains agricultural regions
P2860
Q24548485-60541D4E-F26C-4AB4-89E1-7AD63165CEF5Q24675953-0A953976-062A-4CCC-9C5D-B7A1B08C562CQ26775382-088A52B5-D0F6-4DA7-B6FB-3BD125D1E496Q28485259-9FBD5FDE-121E-4E9B-8E02-DE5F1D8505DDQ28817530-B80304C8-5C4D-49D4-B3C2-BC24282C03AEQ30374616-E58AF504-4972-4500-BB20-A21AC17765DFQ30618600-B02FCED9-3E6B-40CE-9CE8-40E55D80EE05Q33564194-F3B6CDF1-279F-4C28-9B90-D7A54ABBB010Q34032649-4DC510A7-D316-49B4-BC08-409C5F7F5F64Q34232799-3DB3C3C9-3351-44E3-936C-74DF7C561624Q34474198-058BC704-668B-4EED-9CA0-6255F0E8E1AEQ35677889-AE6F1504-6658-4502-91D8-44E13A3EC7FAQ35677894-CD8DDD1F-5C37-4519-8EE8-56500C190E6BQ36162259-042FE91B-81D6-4B5E-BECB-EA1478B0CFC7Q36163585-9122ED0C-C090-4DF7-8B0E-C3371A11BF48Q36869269-35164B0D-5C5A-49A1-9AA6-7B4ED4F466ECQ36885220-9E39BA47-3D33-4EC0-A492-2673B5B967D9Q37516276-B6437411-68D0-4666-8175-0A2D1338A4ABQ37545371-7F58F401-FFE4-4510-95FD-67F1BFD88329Q38749681-DB0BD45A-EE72-4D92-90D9-5EF5CD1B7A0FQ39915146-F23F9034-01C6-48B7-A559-F1090940771EQ39929281-53411751-BEA7-4F1D-BD9E-CD1B5B10468FQ39937732-8E2523FE-2713-44FB-BC9D-6DD9D0C0338EQ39946198-22005816-4FF2-487B-8AC3-CEAFF678FBACQ40179553-79365C53-A446-47D3-95DC-945A8C4EC0E6Q49978421-706F7F60-E576-408F-B90E-E6BC62508AD3Q50852183-99AB8F35-2AF6-49B5-BB39-150179424CB4Q57135804-ECAFF31F-7630-4BE0-9BD2-0228313C53D3Q57882708-C326AD51-F478-43BF-BC98-3A00510EA509Q58061172-80512264-E243-451C-84D6-D5397C50C25DQ58089704-E7F674A6-684F-4A64-BD12-9BF2D81EEE29Q58316838-80FB1B69-CEB8-4EBC-84DA-2F9394B7EC70
P2860
Size of bacterial ice-nucleation sites measured in situ by radiation inactivation analysis.
description
1988 nî lūn-bûn
@nan
1988 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
1988 թվականի մարտին հրատարակված գիտական հոդված
@hy
1988年の論文
@ja
1988年論文
@yue
1988年論文
@zh-hant
1988年論文
@zh-hk
1988年論文
@zh-mo
1988年論文
@zh-tw
1988年论文
@wuu
name
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@ast
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@en
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@nl
type
label
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@ast
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@en
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@nl
prefLabel
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@ast
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@en
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@nl
P2860
P356
P1476
Size of bacterial ice-nucleati ...... diation inactivation analysis.
@en
P2093
Govindarajan AG
P2860
P304
P356
10.1073/PNAS.85.5.1334
P407
P577
1988-03-01T00:00:00Z