. .. , Examples of self-organization at the macroscopic scale

. .. , 2 Examples of self-organization in cellular systems

, Examples of in vitro cytoskeleton self-organization due to geometrical constrains

, Phase diagram in a reconstituted system

, Oscillations with cytoskeletal filaments and molecular motors within sarcomere

. .. , 12 1.7 A minimal system of microtubules, molecular motors assembles into actively beating bundles, Cortex oscillations of lymphoblast fragments

.. .. Diversity,

. .. Flagellar-axoneme,

, Beating pattern of three eukaryotic flagella

. .. , Beating properties of the Chlamydomonas reinhardtii, p.19

, Beating properties of the bull sperm

, Time series analysis and Fourier modes of beat patterns, p.21

, Beating frequency of bull sperm as a function of the viscosity of the medium, vol.22

B. Viscosity and . .. Pattern,

. .. , Variation of beating properties at high viscosity, p.23

. .. , Effect of flagellum length on beating properties, p.25

, Asymmetric and symmetric motor filament pairs

, The complex structure of the axoneme is reduced to a pair of sliding filaments 26

.. .. Structure-of-g-actin, , p.32

, Persistence length of an actin filament

. .. G-actin, , p.37

, Profilin tunes the kinetics of assembly and disassembly of actin filaments, p.37

, The Arp 2/3 complex mediates branched actin networks, p.38

, Arp2 and Arp 3 have a structure close to that of actin monomers, p.39

, 40 2.10 The three parts of a myosin, A branched actin network results from the autocatalytic branching activity of the Arp2/3 complex

. .. Dimerized/double-headed-myosin-ii, , p.42

. .. Myosin, 42 2.13 Conventional model for the catalytic cycle of myosin, p.43

, Schematic to explain how a conformational change can generate force, p.44

, The swinging lever arm hypothesis

, Filament speed in in vitro motility assay

, Assays with optical tweezers

. .. , Single molecule experiment with a processive motor, p.49

, Single molecule experiment with a non-processive motor, p.50

, Schematic representation of the experiment

. .. Surface-micropatterning-technique, , p.55

, Two examples of patterns drawn on the chrome photomask, p.57

, Chambers are built on a glass slide using double-sided adhesive tape, p.57

, The successive steps in ImageJ software for image analysis, p.63

, Parameterization of the detected line with curvilinear abscissa s and tangent angle ?

, From parallel nucleation lines to parallel and antiparallel actin networks, p.68

. .. , Polymerization dynamics of a parallel network, p.69

, IFluorescence intensity profile of parallel actin networks, p.70

, Myosin-driven bundling of actin filaments

, Distribution of actin-bundle length in the presence of myosin II or of myosin V

, Varying the geometry of the patterns

, Fluorescence image and typical beating pattern of an oscillating actin bundle 74

, Tangent-angle oscillations as a function of position along the actin bundle, vol.76

, The relation between the tangent angle ? and the curvilinear abscissa s along the bundle

, Color plot the tangent angle ?(s, t)

, Comparing beating properties driven by myosin II with respect to those driven by myosin V

, Shape parameters of the beating pattern

. .. , Faster beating with myosin II than with myosin V, p.81

, Birth of a beating myosin V-bundle

, Time evolution of the beating pattern as the actin bundle grows, p.83

. .. , Evolution of beating properties of a growing bundle, vol.84

, Beating properties of a growing bundle

V. .. , Beating pattern properties over an ensemble of actin bundles with myosin II and myosin

, Beating properties over an ensemble of actin bundles with myosin II and myosin V

. .. , Effect of myosin concentration on the oscillation period, p.90

V. .. Myosin, , p.91

, Kinetics of myosin concentration waves compared to that of actin beating, p.93

, V and actin fluorescence signals along a beating actin bundle

M. and .. .. ,

, Comparison of various oscillating systems

, 2 3D and 2D motions of swimming sea urchin spermatozoa, p.103

.. .. ,

, The Arp 2/3 complex for actin affinity depends on curvature of actin filament105

. .. Myosin-v-stabilizes-a-conformation-of-f-actin, , p.106

. .. Myosin, , p.110

, Orchestrated collapse of the actin network at high concentration of myosin II112

, Actin network collapse induced by myosin VI and myosin II, p.113

E. , Réorganisation des filaments d'actine sous l'action de myosines, p.126

, Image de fluorescence et forme du battement caractéristique d'un faisceau d'actine oscillant

E. , Oscillations de l'angle tangent en fonction de la position le long du faisceau d'actine

E. , Relation entre l'angle tangent ? et l'abscisse curviligne le long du faisceau d'actine

E. ;. , Tracé de couleurs de l'angle tangent ?(s, t), p.130

E. , Comparaison des propriétés de battements avec la myosine II par rapport à celles avec la myosine V

E. , Le battement est plus rapide avec myosine II qu'avec myosine V, p.132

. .. E.8-;, Propriétés du battement d'un faisceau en croissance, p.133

E. , Localisation de la myosine V le long du faisceau d'actine en battement . . 134 E.10 Cinétique des vagues de concentration de myosine comparée à celle du battement du faisceau

E. , 11 Intégration du signal de fluorescence de myosin V le long du faisceau d'actine137

E. ,

V. Myosine and .. .. ,

. .. , Flagellar beating properties in different species, p.17

. .. , Changes of flagellar beat properties with viscosity, p.24

, Rate constants for actin polymerization and depolymerization at both ends of the actin filament

. .. , Examples of actin-binding proteins and their function, p.36

V. .. Properties, , p.51

, Actin and actin related proteins

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