What is flagellar swimming? Cilia and flagella are whip-like cell appendages that can exhibit regular bending waves. This active process emerges from the non-equilibrium dynamics of molecular motors distributed along the length of cilia and flagella. Eukaryotic cells can possess many cilia and flagella that beat in a coordinated fashion, thus transporting fluids, as in mammalian airways or the ventricular system inside the brain. Many unicellular organisms posses just one or two flagella, rendering them microswimmers that are propelled through fluids by the flagellar beat including sperm cells and the biflagellate green alga Chlamydomonas.
Objectives. In this thesis in theoretical biological physics, we seek to understand the nonlinear dynamics of flagellar swimming and synchronization. We investigate the flow fields induced by beating flagella and how in turn external hydrodynamic flows change speed and shape of the flagellar beat. This flagellar load-response is a prerequisite for flagellar synchronization. We want to find the physical principals underlying stable synchronization of the two flagella of Chlamydomonas cells.
Results. First, we employed realistic hydrodynamic simulations of flagellar swimming based on experimentally measured beat patterns. For this, we developed analysis tools to extract flagellar shapes from high-speed videoscopy data. Flow-signatures of flagellated swimmers are analysed and their effect on a neighboring swimmer is compared to the effect of active noise of the flagellar beat. We were able to estimate a chemomechanical energy efficiency of the flagellar beat and determine its waveform compliance by comparing findings from experiments, in which a clamped Chlamydomonas is exposed to external flow, to predictions from an effective theory that we designed. These mechanical properties have interesting consequences for the synchronization dynamics of Chlamydomonas, which are revealed by computer simulations. We propose that direct elastic coupling between the two flagella of Chlamydomonas, as suggested by recent experiments, in combination with waveform compliance is crucial to facilitate in-phase synchronization of the two flagella of Chlamydomonas.:1 Introduction
1.1 Physics of cell motility: flagellated swimmers as model system 2
1.1.1 Tissue cells and unicellular eukaryotic organisms have cilia and flagella 2
1.1.2 The conserved architecture of flagella 3
1.1.3 Synchronization in collections of flagella 5
1.2 Hydrodynamics at the microscale 9
1.2.1 Navier-Stokes equation 10
1.2.2 The limit of low Reynolds number 10
1.2.3 Multipole expansion of flow fields 11
1.3 Self-propulsion by viscous forces 13
1.3.1 Self propulsion requires broken symmetries 13
1.3.2 Signatures of flowfields: pusher & puller 15
1.4 Overview of the thesis 16
2 Flow signatures of flagellar swimming
2.1 Self-propulsion of flagellated swimmers 20
2.1.1 Representation of flagellar shapes 20
2.1.2 Computation of hydrodynamic friction forces 21
2.1.3 Material frame and rigid-body transformations 22
2.1.4 The grand friction matrix 23
2.1.5 Dynamics of swimming 23
2.2 The hydrodynamic far field: pusher and puller 26
2.2.1 The flow generated by a swimmer 26
2.2.2 Force dipole characterization 27
2.2.3 Flagellated swimmers alternate between pusher and puller 29
2.2.4 Implications for two interacting Chlamydomonas cells 31
2.3 Inertial screening of oscillatory flows 32
2.3.1 Convection and oscillatory acceleration 33
2.3.2 The oscilet: fundamental solution of unsteady flow 35
2.3.3 Screening length of oscillatory flows 35
2.4 Energetics of flagellar self-propulsion 36
2.4.1 Impact of inertial screening on hydrodynamic dissipation 37
2.4.2 Case study: the green alga Chlamydomonas 38
2.4.3 Discussion: evolutionary optimization and the number of molecular motors 38
2.5 Summary 39
3 The load-response of the flagellar beat
3.1 Experimental collaboration: flagellated swimmers exposed to flows 41
3.1.1 Description of the experimental setup 42
3.1.2 Computed flow profile in the micro-fluidic device 43
3.1.3 Image processing and flagellar tracking 43
3.1.4 Mode decomposition and limit-cycle reconstruction 47
3.1.5 Changes of limit-cycle dynamics: deformation, translation, acceleration 49
3.2 An effective theory of flagellar oscillations 50
3.2.1 A balance of generalized forces 50
3.2.2 Hydrodynamic friction in generalized coordinates 51
3.2.3 Intra-flagellar friction 52
3.2.4 Calibration of active flagellar driving forces 52
3.2.5 Stability of the limit cycle of the flagellar beat 53
3.2.6 Equations of motion 55
3.3 Comparison of theory and experiment 56
3.3.1 Flagellar mean curvature 57
3.3.2 Susceptibilities of phase speed and amplitude 57
3.3.3 Higher modes and stalling of the flagellar beat at high external load 59
3.3.4 Non-isochrony of flagellar oscillations 63
3.4 Summary 63
4 Flagellar load-response facilitates synchronization
4.1 Synchronization to external driving 65
4.2 Inter-flagellar synchronization in the green alga Chlamydomonas 67
4.2.1 Equations of motion for inter-flagellar synchronization 68
4.2.2 Synchronization strength for free-swimming and clamped cells 70
4.2.3 The synchronization strength depends on energy efficiency and waveform compliance 73
4.2.4 The case of an elastically clamped cell 74
4.2.5 Basal body coupling facilitates in-phase synchronization 75
4.2.6 Predictions for experiments 78
4.3 Summary 80
5 Active flagellar fluctuations
5.1 Effective description of flagellar oscillations 84
5.2 Measuring flagellar noise 84
5.2.1 Active phase fluctuations are much larger than thermal noise 84
5.2.2 Amplitude fluctuations are correlated 85
5.3 Active flagellar fluctuations result in noisy swimming paths 86
5.3.1 Effective diffusion of swimming circles of sperm cell 86
5.3.2 Comparison of the effect of noise and hydrodynamic interactions 87
5.4 Summary 88
6 Summary and outlook
6.1 Summary of our results 89
6.2 Outlook on future work 90
A Solving the Stokes equation
A.1 Multipole expansion 95
A.2 Resistive-force theory 96
A.3 Fast multipole boundary element method 97
B Linearized Navier-Stokes equation
B.1 Linearized Navier-Stokes equation 101
B.2 The case of an oscillating sphere 102
B.3 The small radius limit 103
B.4 Greens function 104
C Hydrodynamic friction
C.1 A passive particle 107
C.2 Multiple Particles 107
C.3 Generalized coordinates 108
D Data analysis methods
D.1 Nematic filter 111
D.1.1 Nemat 111
D.1.2 Nematic correlation 111
D.2 Principal-component analysis 112
D.3 The quality of the limit-cycle projections of experimental data 113
E Adler equation
F Sensitivity analysis for computational results
F.1 The distance function of basal coupling 117
F.2 Computed synchronization strength for alternative waveform 118
F.3 Insensitivity of computed load-response to amplitude correlation time 118
List of Symbols
List of Figures
Bibliography
| Identifer | oai:union.ndltd.org:DRESDEN/oai:qucosa:de:qucosa:29698 |
| Date | 15 January 2018 |
| Creators | Klindt, Gary |
| Contributors | Friedrich, Benjamin, Grill, Stephan, Jülicher, Frank, Wagner, Christian, Technische Universität Dresden |
| Source Sets | Hochschulschriftenserver (HSSS) der SLUB Dresden |
| Language | English |
| Detected Language | English |
| Type | doc-type:doctoralThesis, info:eu-repo/semantics/doctoralThesis, doc-type:Text |
| Rights | info:eu-repo/semantics/openAccess |
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