Evolved physiological responses of phytoplankton to their integrated growth environment.
about
Interacting Effects of Light and Iron Availability on the Coupling of Photosynthetic Electron Transport and CO2-Assimilation in Marine Phytoplankton.Surplus photosynthetic antennae complexes underlie diagnostics of iron limitation in a cyanobacteriumContrasting strategies of photosynthetic energy utilization drive lifestyle strategies in ecologically important picoeukaryotesTowards the determination of Mytilus edulis food preferences using the dynamic energy budget (DEB) theory.Quantifying Integrated Proteomic Responses to Iron Stress in the Globally Important Marine Diazotroph Trichodesmium.Contrasting Photophysiological Characteristics of Phytoplankton Assemblages in the Northern South China Sea.Predicting the electron requirement for carbon fixation in seas and oceans.The response of Nannochloropsis gaditana to nitrogen starvation includes de novo biosynthesis of triacylglycerols, a decrease of chloroplast galactolipids, and reorganization of the photosynthetic apparatus.The effects of phosphorus limitation on carbon metabolism in diatoms.Carbon use efficiencies and allocation strategies in Prochlorococcus marinus strain PCC 9511 during nitrogen-limited growth.Ocean acidification decreases the light-use efficiency in an Antarctic diatom under dynamic but not constant light.Direct and indirect influence of sulfur availability on phytoplankton evolutionary trajectories.Temperature is a key factor in Micromonas-virus interactions.Controls of primary production in two phytoplankton blooms in the Antarctic Circumpolar Current.Photosynthetic and atmospheric evolution. Introduction.Ocean science. Photosynthesis in the open ocean.Mechanisms that increase the growth efficiency of diatoms in low light.The redox potential of the plastoquinone pool of the cyanobacterium Synechocystis species strain PCC 6803 is under strict homeostatic control.Cellular trade-offs and optimal resource allocation during cyanobacterial diurnal growth.Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth.Phytoplankton growth rate modelling: can spectroscopic cell chemotyping be superior to physiological predictors?Inorganic carbon and pH dependency of photosynthetic rates in Trichodesmium.Functional Redundancy Facilitates Resilience of Subarctic Phytoplankton Assemblages toward Ocean Acidification and High IrradiancePrimary productivity and the coupling of photosynthetic electron transport and carbon fixation in the Arctic OceanTranscriptional responses of three model diatoms to nitrate limitation of growthCombined Phosphorus Limitation and Light Stress Prevent Viral Proliferation in the Phytoplankton Species Phaeocystis globosa, but Not in Micromonas pusillaSummertime phytoplankton blooms and surface cooling in the western south equatorial Indian OceanAssessing Impacts of Nutrient Competition on the Chemical Composition of Individual Microalgae SpeciesRevaluating ocean warming impacts on global phytoplanktonSouthern Ocean wind-driven entrainment enhances satellite chlorophyll-a through the summer
P2860
Q30657713-C8A5E33C-60A4-414A-988A-C5FE815A2F96Q33886197-66F0CD0C-042B-4BE4-8109-74FCF817199AQ33912665-C3040FD0-E4D8-46B8-8AF9-EE9F2420077DQ35362174-85A82D7A-F2DE-4CBC-84AD-37806BB5CA86Q35839751-4440122D-03CB-4E95-A0B1-9A3CF3661C04Q36022304-2EE96A15-7586-42DD-BFE7-8C4BE583F61CQ36680853-CB4D0333-11B1-47B7-9E93-92E26E274E03Q36826428-2CBD2A04-9BD1-457C-95D3-4597873881DFQ38674814-CA8F1398-507B-45A9-8F3B-744555BAADD2Q39001605-CB250D67-8265-4085-9F7D-841519B4B251Q39036060-7885D25D-C9EF-488C-BFF4-C372E837051FQ39311719-10750DBF-12F8-461E-9BE0-DD5E50BC8CEFQ40372946-CF37AF12-A90E-4AE4-9C0E-38A3FD5FB3E8Q42128512-78C2A637-1C51-4AA6-8932-073BD09F6009Q42590815-EE95EE2A-9931-4E70-B201-0DEA73DE24F3Q43228874-1A7A99CB-0D45-4463-A8F2-23F514E48DB1Q46531440-9FA0E502-2792-4E12-89C4-88AE0C241AF2Q46910529-464BB32E-7839-45A3-A1D1-001230256D96Q47760595-727FC065-170D-4C8E-AEAE-1129F49984F0Q50097272-4944E453-90B2-4461-BC2E-D6F6576B600BQ51157806-EEDAA7DA-A44C-4866-938D-46EC7C67A50FQ52585836-66D5D1D1-4F04-4506-A225-D965E56EC0E0Q57705616-8D4E4A14-825D-4071-872D-FF39AD3423F9Q57705618-6B1BFE9B-1506-4BA1-8B3A-80284D601CEAQ57900005-6B1D4369-F879-4982-9103-137D65A26905Q57900743-AC95BFDE-3E3A-4B73-B31F-E9FB2F3AEE76Q58057121-4248D844-1D2F-4787-A380-4B7D97E30E5CQ58126099-678A5872-12A8-4421-BACF-39E74E53B2FCQ58239912-FC876E1A-1CFF-43B4-889F-C2055273C361Q58381342-CE5F547C-08E7-4334-A811-C5212AA68251
P2860
Evolved physiological responses of phytoplankton to their integrated growth environment.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on August 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Evolved physiological responses of phytoplankton to their integrated growth environment.
@en
Evolved physiological responses of phytoplankton to their integrated growth environment.
@nl
type
label
Evolved physiological responses of phytoplankton to their integrated growth environment.
@en
Evolved physiological responses of phytoplankton to their integrated growth environment.
@nl
prefLabel
Evolved physiological responses of phytoplankton to their integrated growth environment.
@en
Evolved physiological responses of phytoplankton to their integrated growth environment.
@nl
P2860
P356
P1476
Evolved physiological responses of phytoplankton to their integrated growth environment.
@en
P2093
Allen J Milligan
Kimberly H Halsey
P2860
P304
P356
10.1098/RSTB.2008.0019
P407
P577
2008-08-01T00:00:00Z