about
Discrete dynamics model for the speract-activated Ca2+ signaling network relevant to sperm motilityAnalysis of unstable modes distinguishes mathematical models of flagellar motion.Emergent complexity of the cytoskeleton: from single filaments to tissueFunctions and mechanics of dynein motor proteinsSpermatozoa scattering by a microchannel feature: an elastohydrodynamic modelA computational model of dynein activation patterns that can explain nodal cilia rotationIC138 defines a subdomain at the base of the I1 dynein that regulates microtubule sliding and flagellar motilityPropulsion of African trypanosomes is driven by bihelical waves with alternating chirality separated by kinks.Nonlinear instability in flagellar dynamics: a novel modulation mechanism in sperm migration?Distinct roles of 1alpha and 1beta heavy chains of the inner arm dynein I1 of Chlamydomonas flagella.Drosophila sperm motility in the reproductive tract.Cilia-like beating of active microtubule bundlesThe N-DRC forms a conserved biochemical complex that maintains outer doublet alignment and limits microtubule sliding in motile axonemes.The MIA complex is a conserved and novel dynein regulator essential for normal ciliary motility.High-speed holographic microscopy of malaria parasites reveals ambidextrous flagellar waveformsNerve growth factor promotes reorganization of the axonal microtubule array at sites of axon collateral branching.Nonlinear amplitude dynamics in flagellar beating.Slow axonemal dynein e facilitates the motility of faster dynein c.Sensing the mechanical state of the axoneme and integration of Ca2+ signaling by outer arm dynein.Calcium channels in the development, maturation, and function of spermatozoa.Equations of interdoublet separation during flagella motion reveal mechanisms of wave propagation and instability.Three-dimensional structure of the bovine sperm connecting piece revealed by electron cryotomography.Regulation of ciliary motility: conserved protein kinases and phosphatases are targeted and anchored in the ciliary axonemeStrategies for locating the female gamete: the importance of measuring sperm trajectories in three spatial dimensions.An axonemal PP2A B-subunit is required for PP2A localization and flagellar motility.Functional architecture of the outer arm dynein conformational switch.Axonemal radial spokes: 3D structure, function and assembly.ATP Consumption of Eukaryotic Flagella Measured at a Single-Cell LevelA Structural Basis for How Motile Cilia BeatDynamic curvature regulation accounts for the symmetric and asymmetric beats of Chlamydomonas flagella.IC97 is a novel intermediate chain of I1 dynein that interacts with tubulin and regulates interdoublet sliding.An outer arm dynein light chain acts in a conformational switch for flagellar motility.The Trypanosoma brucei flagellum: moving parasites in new directions.Regulation of dynein-driven microtubule sliding by the axonemal protein kinase CK1 in Chlamydomonas flagellaSperm flagella: comparative and phylogenetic perspectives of protein components.Soluble adenylyl cyclase of sea urchin spermatozoa.Multiciliated cellsLag, lock, sync, slip: the many 'phases' of coupled flagella.Spermatozoa as Functional Components of Robotic Microswimmers.Motor regulation results in distal forces that bend partially disintegrated Chlamydomonas axonemes into circular arcs
P2860
Q27330175-5CDCBCFD-65E0-472D-97D3-F51F255B8E9BQ27342489-374DDADB-53F5-448F-90F7-E7C19CE6CAA1Q28238533-207E0F01-91AB-4BCF-9FA6-E2A899ACB32AQ28299219-53F47FD6-31C4-4D7A-9802-A18872E89429Q28646682-635BAE36-9FD0-4351-9FB8-E95953FA22D0Q30376431-4AE90C3C-DD14-4B2E-8A36-71134B186C94Q30488535-DC2B177A-874B-4984-B758-EA0CAA5CA00DQ30491791-301A53C7-4E3B-49AA-B573-4B2428042A6AQ30497413-85576218-4A27-47F7-867E-118B4ED36067Q30498049-2DA1259F-0382-4A4F-9DA0-8C878F6AA674Q30499773-E30F12AC-6B0F-4785-AC2B-2DF44199E8BBQ30504288-68C77AC6-59D8-47CF-8DF5-009BB8C3B22FQ30538731-E37710E7-58F3-4915-9F15-B40213D96F9BQ30538934-39EE1538-C167-4139-A878-6872F3C795F9Q30557752-D4274D4B-3D54-4567-9D80-5DA2E5E3C6AFQ30741119-6C55CE35-B120-49D9-B608-F02636C3CE3FQ30844433-6D4CC5F2-3852-4CC1-A781-2FC4C02240C7Q33736612-5F97385E-FF43-4BB6-B2AD-73AF677ED3CBQ33809670-5134E066-C352-42A7-B36C-416798468A3BQ34052215-EC02A056-1BF7-44D2-AC05-1425A701CE98Q34310307-AE1032FE-E030-4F4C-AF99-64970849BDEAQ34327840-99E7CA43-84CE-41F7-A5AE-544CF70E0E27Q35043160-DCD0F1DC-EEB6-4BCF-AD64-73B43193B945Q35104901-5CC7F157-C602-4E7D-98BA-303C8A540AB2Q35153262-9A3CD776-07EA-427E-A145-6700A67117B5Q35728133-892F58EC-9C30-4DC6-9199-D4B24129BA84Q36060051-80F6D73B-85D8-4AF3-AD07-651BDF032A3EQ36426472-FBA9FC38-2FF0-4FB5-9A21-6B6E83674F35Q36647205-665F96AD-1E9A-42A7-9CB1-4C020E546873Q37047252-A90137A0-4371-4BB6-BAEE-6E4EFB8CF8E6Q37246309-FD74C2DD-F81A-420E-A555-879054FDF87CQ37280412-70B26195-62C9-40FD-B427-5EFBD90C4994Q37291693-7A9759F6-36D1-406C-8170-BDC28E3BE0CDQ37365410-FB294CD0-605D-4868-A5AE-D3D7467F5CDAQ37876572-E8F07347-DDE0-40A3-B489-780D53EAA340Q38234230-06BBC8C0-32E0-4FA2-BA39-3A65D93ABBDBQ38257788-4F272294-B182-4373-A5D4-81235D202BCAQ38594390-33DC4B27-5F8F-4E31-AEF7-AC2850118741Q39190167-FA7B92EA-5E38-438C-9D3C-FC982D6D35F7Q40537514-B72B3885-DD0E-42F5-BDF8-7A638DB48780
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on August 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Thinking about flagellar oscillation.
@en
Thinking about flagellar oscillation.
@nl
type
label
Thinking about flagellar oscillation.
@en
Thinking about flagellar oscillation.
@nl
prefLabel
Thinking about flagellar oscillation.
@en
Thinking about flagellar oscillation.
@nl
P356
P1433
P1476
Thinking about flagellar oscillation.
@en
P2093
Charles J Brokaw
P304
P356
10.1002/CM.20313
P577
2009-08-01T00:00:00Z