about
Function and evolutionary origin of unicellular camera-type eye structureCiliary photoreceptors in the cerebral eyes of a protostome larvaThe photochemical determinants of color vision: revealing how opsins tune their chromophore's absorption wavelengthMicrofluidic high-throughput selection of microalgal strains with superior photosynthetic productivity using competitive phototaxis.Genome of Acanthamoeba castellanii highlights extensive lateral gene transfer and early evolution of tyrosine kinase signalingPhototaxis and the origin of visual eyesPhylostratigraphic profiles reveal a deep evolutionary history of the vertebrate head sensory systemsNonmagnetotactic multicellular prokaryotes from low-saline, nonmarine aquatic environments and their unusual negative phototactic behaviorTemporal sampling, resetting, and adaptation orchestrate gradient sensing in sperm.Phototaxis beyond turning: persistent accumulation and response acclimation of the microalga Chlamydomonas reinhardtii.Comparative genomics uncovers novel structural and functional features of the heterotrimeric GTPase signaling system.Fidelity of adaptive phototaxisThe phylogenetic position of ctenophores and the origin(s) of nervous systems.Protistology: How to build a microbial eye.Motility enhancement through surface modification is sufficient for cyanobacterial community organization during phototaxis.Genetic analysis reveals the identity of the photoreceptor for phototaxis in hormogonium filaments of Nostoc punctiforme.Generalized receptor law governs phototaxis in the phytoplankton Euglena gracilisEukaryotic G protein-coupled receptors as descendants of prokaryotic sodium-translocating rhodopsins.Green Algae as Model Organisms for Biological Fluid DynamicsPhototactic behavior of the Armand pine bark weevil, Pissodes punctatusThe 'division of labour' model of eye evolution.The evolution of eyes and visually guided behaviour.Roles of ion transport in control of cell motility.The evolution of vision.Tactic, reactive, and functional droplets outside of equilibrium.How exaptations facilitated photosensory evolution: Seeing the light by accident.CALCIUM RELEASE FROM INTRACELLULAR STORES IS NECESSARY FOR THE PHOTOPHOBIC RESPONSE IN THE BENTHIC DIATOM NAVICULA PERMINUTA (BACILLARIOPHYCEAE)(1).Spatial and temporal changes of parasitic chytrids of cyanobacteria.Neuronal connectome of a sensory-motor circuit for visual navigation.The evolution of phototransduction and eyes.Dynamic switching between escape and avoidance regimes reduces Caenorhabditis elegans exposure to noxious heat.Dynamics of a deformable active particle under shear flow.Inactivity Is Nycthemeral, Endogenously Generated, Homeostatically Regulated, and Melatonin Modulated in a Free-Living Platyhelminth Flatworm.Photoreception in Phytoplankton.Comparative genomic analysis of the 'pseudofungus' Hyphochytrium catenoides.Programmable artificial phototactic microswimmer.Swinging motion of active deformable particles in Poiseuille flow.Autonomous reciprocating migration of an active material.Cyclic AMP-regulated opposing and parallel effects of serotonin and dopamine on phototaxis in the Marmorkrebs (marbled crayfish).The subject as cause and effect of evolution.
P2860
Q21131810-BD75E174-E88E-403D-8127-FD1D5833921BQ22001214-2E93D277-62F2-417A-8338-BEC4D7EF9269Q27004446-B31DE8D0-945D-40DA-BCD9-D26F5DF556C5Q27348921-36BCD16C-32DB-4533-92EE-3593782CC947Q27499704-FA30D5B7-BC9F-404F-B453-9A88B61DA700Q28603841-368CD954-A37F-4C5D-B601-F0C3DFDA9739Q28708481-C8B4C564-E539-4396-A9E6-20EABF44EF92Q30494492-1ECDE8B8-318C-4726-8853-A229433863E9Q30525037-E651967B-4E9C-4CBE-9C61-0EA0C305A9FBQ30855763-4FDAE361-2F72-4BBF-9559-5C1752217D16Q33779660-93FD02C6-655B-4B55-96C7-75E5D1F0FCCFQ33953429-CD34833D-C005-44C3-BE8E-68FBB280102AQ34043827-6E7C3640-E491-4D84-89F4-55040A4F196DQ34483078-61295C2D-1A6D-4C59-B67A-6E83B7FD7E11Q34987950-D198808D-A637-40DC-919A-E5E7276D87D9Q35100523-73453F24-0D19-44A9-AE45-A9F540920863Q35699510-57CA68B0-B88E-446C-8E83-AABE45D16B88Q35809744-06CC3537-B288-4323-A1FE-776A559044FFQ36292597-A9989162-7D05-4817-A604-9CF25BB0ABEAQ37074367-185E1095-C1CA-4216-B217-E32104771F72Q37589947-C1D60B99-9529-49A0-B907-4EE96BFC19B8Q37589952-6A86F4EF-53F9-4CD7-B2A4-4906AF96F6F5Q38110508-61528825-72AB-4C00-A0EB-7E7B26E2FF25Q38217988-C1C779A9-78DC-4EBD-943D-E41D9CA837B6Q38854303-B9CCAE3B-A1E5-461F-B23F-4C9D44DC2394Q39344105-31BB43A2-E7DE-45C6-B4FE-4E3E99763B0EQ39891561-64D59CBB-3C55-4D77-8366-8899A91D26BAQ40125690-DADCA11C-1C65-493B-AC14-DA9DDD89A363Q40777288-0E5DA936-6E14-48FB-A106-3B37F1EE50BBQ42662987-DEDA70F8-39F3-4432-97E0-0D47A0C18834Q44935496-9764BC74-5D34-4906-A3EF-46DFC09ACF1AQ46054738-1285A7A8-354E-4317-80D5-609C9D362FE8Q46299438-5243FE68-C57F-46DF-9716-C77CFC8DAFBBQ46538881-901EB52C-66C0-4853-A3F5-2582C7105B86Q47555942-E5AD50BC-29C5-4C59-A5BD-9F6CF945DB88Q47647101-81AF2BE0-1E43-4944-942B-92FA2D43398DQ47671850-1627FD42-A69A-4012-9FB8-5DCB0391161AQ47861028-81E65493-99DB-4176-AA83-2D876B90F567Q47975499-32A8295C-58D4-46AE-97C7-235E0E9CCF49Q48177857-14C4B251-5E6E-4310-B549-8BFF052AC322
P2860
description
2009 nî lūn-bûn
@nan
2009 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
Evolution of phototaxis
@ast
Evolution of phototaxis
@en
type
label
Evolution of phototaxis
@ast
Evolution of phototaxis
@en
prefLabel
Evolution of phototaxis
@ast
Evolution of phototaxis
@en
P2860
P356
P1476
Evolution of phototaxis
@en
P2860
P304
P356
10.1098/RSTB.2009.0072
P407
P577
2009-10-01T00:00:00Z
2009-10-12T00:00:00Z