Copepods induce paralytic shellfish toxin production in marine dinoflagellates. - Wikidata - wikimedia - TriplyDB

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

http://www.wikidata.org/entity/Q51725686

about

Predator-induced fleeing behaviors in phytoplankton: a new mechanism for harmful algal bloom formation?Ecology and bioprospecting The globally distributed genus Alexandrium: multifaceted roles in marine ecosystems and impacts on human health PSP toxin levels and plankton community composition and abundance in size-fractionated vertical profiles during spring/summer blooms of the toxic dinoflagellate Alexandrium fundyense in the Gulf of Maine and on Georges Bank, 2007, 2008, and 2010: 2 Comparative gene expression in toxic versus non-toxic strains of the marine dinoflagellate Alexandrium minutum.Multispecies mass mortality of marine fauna linked to a toxic dinoflagellate bloom.A molecular and co-evolutionary context for grazer induced toxin production in Alexandrium tamarense.Metabolomics and proteomics reveal impacts of chemically mediated competition on marine plankton.The relevance of marine chemical ecology to plankton and ecosystem function: an emerging field.Predator lipids induce paralytic shellfish toxins in bloom-forming algae Dangerous Relations in the Arctic Marine Food Web: Interactions between Toxin Producing Pseudo-nitzschia Diatoms and Calanus Copepodites Modelling the Stoichiometric Regulation of C-Rich Toxins in Marine Dinoflagellates.Marine chemical ecology: chemical signals and cues structure marine populations, communities, and ecosystems.Predator cues reduce intraspecific trait variability in a marine dinoflagellate Intraspecific chemical communication in microalgae.Solid phase extraction and metabolic profiling of exudates from living copepods.Mycosporine-like amino acids and marine toxins--the common and the different An overview on the marine neurotoxin, saxitoxin: genetics, molecular targets, methods of detection and ecological functions.Formation of harmful algal blooms cannot be explained by allelopathic interactions Transcriptomic responses in the bloom-forming cyanobacterium Microcystis induced during exposure to zooplankton.Chemical ecology of the marine plankton.A review on factors affecting microcystins production by algae in aquatic environments.Diverse seed banks favour adaptation of microalgal populations to future climate conditions.Transcriptomic profiling of Alexandrium fundyense during physical interaction with or exposure to chemical signals from the parasite Amoebophrya.Allelopathy as an emergent, exploitable public good in the bloom-forming microalga Prymnesium parvum.Effects of predator lipids on dinoflagellate defence mechanisms - increased bioluminescence capacity.Chemical Response of the Toxic Dinoflagellate Karenia mikimotoi Against Grazing by Three Species of Zooplankton.Selective Grazing by a Tropical Copepod (Notodiaptomus iheringi) Facilitates Microcystis Dominance.Intraspecific facilitation by allelochemical mediated grazing protection within a toxigenic dinoflagellate population.Grazer-induced transcriptomic and metabolomic response of the chain-forming diatom Skeletonema marinoi.A co-culturing/metabolomics approach to investigate chemically mediated interactions of planktonic organisms reveals influence of bacteria on diatom metabolism Growth phase of the diatom Skeletonema marinoi influences the metabolic profile of the cells and the selective feeding of the copepod Calanus spp Evidence for Strain-Specific Exometabolomic Responses of the Coccolithophore Emiliania huxleyi to Grazing by the Dinoflagellate Oxyrrhis marina Understanding cyanobacteria-zooplankton interactions in a more eutrophic world Effects of co-existing microalgae and grazers on the production of hemolytic toxins in Karenia mikimotoi

P2860

Q28484120-AAAE3873-09F1-4914-9734-2E697B69F3A6 Q28728193-61ECF6C7-8298-4748-87B4-8E52DDA5CE8B Q28732311-513F102B-869B-4D8D-9551-D2C1F9CC0250 Q33457558-56A1703A-1128-4E7C-B316-F4516A4E5936 Q33559069-B5E9C516-9488-432C-B0AF-35DFB154B173 Q33637386-B1184B44-2F3D-430A-AC08-3BD17EBE179D Q33760685-C7767DC9-182A-4620-A938-8037EE3508B7 Q33790055-21133770-AD6E-4E68-AD6A-CF3E919894DE Q34087539-019F9CBB-70DE-4C15-9718-5EA9D3AD44BF Q35644692-14A5D039-0DA0-4655-B387-B3A699BF6DEA Q35667441-85A9700E-1E1A-43C7-82B5-3A9211A80168 Q35784779-BFFBE379-05B4-4273-9785-F01274348E1F Q36049139-3A1E7DDF-9D49-45A4-82A3-E0D6009393BA Q36292197-95E0F9BF-65D7-4356-B3CB-464C09410A3D Q36317927-1196477B-22E6-406A-96E4-40515E9AD47D Q36469566-A7404031-8A55-4117-94D4-93827DC18432 Q36851577-279197F3-EF89-42C0-94E0-3F930614A3C5 Q36994197-F9919529-71B1-4492-B2D5-800E1331ED1B Q37256895-14DA6740-6266-484D-868E-351467C2D92B Q37644057-7671D74D-C04F-4136-AB49-049818FF1B21 Q38140641-1B6E6977-ABD0-4D4A-AC98-BA17CB787DAA Q38732400-59609C16-1349-4D20-A7E3-6650321A941F Q38903546-F18838D3-D29B-47A5-B3C2-D5FAE8F36F54 Q40806851-34AD5F73-9F01-4CFF-8045-553469CF4C5B Q41955812-7EA9712A-53E5-4185-B795-24E0A3D3F7EB Q42375970-7A325143-C0B4-40F9-8B55-50869D472B15 Q46796785-420C7D3C-9F0C-4E33-A2BF-7BA33E72BAB9 Q51148231-313C1590-F1A4-44E5-9B54-701CED60C0EC Q51392932-72F52D91-BBC3-4762-9C25-B02B801794F6 Q51730674-C61A9998-9020-4E97-834D-848E6A816FB7 Q56935739-F185D43A-940D-4609-94C7-CC375167D90C Q56935885-3C1975DE-BE64-4BD2-BA45-A40380C2A288 Q57900368-9E0C9C30-4E2E-47D2-8044-57AD7B12D918 Q58319537-CA0FCC82-EE50-40FD-A12E-2D4C1A83C8B5 Q58763893-49759F1A-CE0B-43BE-A7D2-5896F8E1D51A

P2860

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

http://www.wikidata.org/entity/Q51725686

description

2006 nî lūn-bûn

@nan

2006年の論文

@ja

2006年学术文章

@wuu

2006年学术文章

@zh

2006年学术文章

@zh-cn

2006年学术文章

@zh-hans

2006年学术文章

@zh-my

2006年学术文章

@zh-sg

2006年學術文章

@yue

2006年學術文章

@zh-hant

name

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

@en

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

@nl

type

label

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

@en

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

@nl

prefLabel

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

@en

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

@nl

P1433

Q51725686-EB690C0F-9F0C-4B3A-82D4-5AB5FB934E0A

P1476

Q51725686-98304921-C734-46C9-B1AC-6A9409A0C4D8

P2093

Q51725686-28892F2A-4C02-44A9-9EBC-3092B359B2C5

Q51725686-6E1FF5EC-94F0-4C83-8AB9-7C234FE9A6B8

Q51725686-77E21255-03E8-4928-805C-DA695467E0AF

Q51725686-7AF7B334-F1D8-468E-B7B0-83C6FAD02FB4

P2860

Q51725686-266CCD1B-509E-4E2C-8CFA-729927D85F2B

Q51725686-4DDA5AEB-9269-4C4D-8E73-337620A85FC1

Q51725686-52DE03BC-5BBC-4EB6-B5D8-9351006D246A

Q51725686-6199DEE1-8D21-471A-A517-69D82DC9428D

Q51725686-66E875B7-7B84-4F39-BCE9-35FA05BED784

Q51725686-735BC000-A879-4B77-B4FC-AAE8A299ABBB

Q51725686-74F9FA6C-B2C1-4DEC-9434-E10947A5A440

Q51725686-7C9B539C-AAF5-4047-AD32-EFFB17B546BC

Q51725686-8ED23F4B-5E74-4AE5-9EA8-DC11137002C6

Q51725686-94EACD02-CFDD-4F11-B7D5-5E08AECE2C44

P304

Q51725686-2B3AA301-78EA-4EC3-A998-C2C8DCA344D9

P31

Q51725686-B0E9E442-6BFE-475F-8512-6DEF15DC91C9

P356

Q51725686-A6326452-2CF2-46F1-ABF3-EA7262482DCD

P433

Q51725686-7E77E434-A0FB-45C6-A4B2-726F66EF191C

P478

Q51725686-907729EA-6214-410D-B05F-73EB50EA33AC

P577

Q51725686-AD5BFC41-586D-4B18-9237-98D198C591B3

P5875

Q51725686-2638B82F-B8F2-49D8-A69D-27AFD35699DB

P698

Q51725686-DF1EF96C-DCCF-4202-B825-A9B1DBA50CE1

P932

Q51725686-D7A861C3-64E2-442E-AB4B-AA22852E9104

P356

P1433

Proceedings of the Royal Society B

P1476

Copepods induce paralytic shellfish toxin production in marine dinoflagellates.

@en

P2093

Erik Selander

http://www.w3.org/2001/XMLSchema#string

Gunilla Toth

http://www.w3.org/2001/XMLSchema#string

Henrik Pavia

http://www.w3.org/2001/XMLSchema#string

Peter Thor

http://www.w3.org/2001/XMLSchema#string

P2860

The chemical defense ecology of marine unicellular plankton: constraints, mechanisms, and impacts

Chemical signaling processes in the marine environment.

A watery arms race.

Chemical signals in the marine environment: dispersal, detection, and temporal signal analysis.

Community and ecosystem level consequences of chemical cues in the plankton.

Water-borne cues induce chemical defense in a marine alga (Ascophyllum nodosum)

Copepod hatching success in marine ecosystems with high diatom concentrations.

Variability in toxicity of the dinoflagellate Alexandrium tamarense in response to different nitrogen sources and concentrations.

Analysis of PSP toxins in Norwegian mussels by a post-column derivatization HPLC method.

Marine dinoflagellates show induced life-history shifts to escape parasite infection in response to water-borne signals.

P304

1673-1680

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1098/RSPB.2006.3502

http://www.w3.org/2001/XMLSchema#string

P433

1594

http://www.w3.org/2001/XMLSchema#string

P478

273

http://www.w3.org/2001/XMLSchema#string

P577

2006-07-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

7013225

http://www.w3.org/2001/XMLSchema#string

P698

16769640

http://www.w3.org/2001/XMLSchema#string

P932

1634929

http://www.w3.org/2001/XMLSchema#string