Flagellar photoresponses ofChlamydomonascells held on micropipettes: II. Change in flagellar beat pattern

Ursula Rüffer; Wilhelm Nultsch

doi:10.1002/cm.970180404

Analysis of the Flagellar Beat Pattern of Male Ectocarpus Siliculosus Gametes (Phaeophyta) in Relation to Chemotactic Stimulation by Female Cells

Journal of Experimental Biology ◽

10.1242/jeb.92.1.53 ◽

1981 ◽

Vol 92 (1) ◽

pp. 53-66

Author(s):

ANNETTE GELLER ◽

DIETER G. MÜLLER

Keyword(s):

Linear Correlation ◽

Mode Of Action ◽

High Speed ◽

Sex Attractant ◽

Cell Axis ◽

Ectocarpus Siliculosus ◽

Bending Waves ◽

Flagellar Beat ◽

Beat Pattern ◽

Negative Linear Correlation

Heterocontic male Ectocarpus siliculosus gametes respond to the sex-attractant ectocarpen by changing their locomotive behaviour. However, the mode of action of the flagella is not changed by the presence of ectocarpen. High-speed cinemicrography shows that gametes moving close to a coverglass perform planar bending waves with their front flagellum. Straight or slightly curved swimming paths are generated by enhanced upward bends of the front flagellum to compensate for the asymmetrical insertion of both flagella. Narrower curves are connected with increasing downward bends of the front flagellum. There is a negative linear correlation between the average deflexion of the front flagellum (μm) from the cell axis and the radius of track (correlation coefficient 0.94). Additionally, freely swimming gametes exhibit elliptical and rotary wave motions, suggesting a relationship between thigmotaxis and mode of action of the front flagellum. The rigid hind flagellum performs one rapid sideward beat when the gametes swim in narrow curves. This appears to provide a steering function.

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Targeted inactivation of the mouse epididymal beta-defensin 41 alters sperm flagellar beat pattern and zona pellucida binding

Molecular and Cellular Endocrinology ◽

10.1016/j.mce.2016.03.013 ◽

2016 ◽

Vol 427 ◽

pp. 143-154 ◽

Cited By ~ 15

Author(s):

Ida Björkgren ◽

Luis Alvarez ◽

Nelli Blank ◽

Melanie Balbach ◽

Heikki Turunen ◽

...

Keyword(s):

Zona Pellucida ◽

Flagellar Beat ◽

Beat Pattern ◽

Targeted Inactivation

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A minimal robophysical model of quadriflagellate self-propulsion

10.1101/2021.03.14.434582 ◽

2021 ◽

Author(s):

Kelimar Diaz ◽

Tommie L. Robinson ◽

Yasemin Ozkan Aydin ◽

Enes Aydin ◽

Daniel I. Goldman ◽

...

Keyword(s):

Central Body ◽

Swimming Performance ◽

M Cell ◽

Trot Gait ◽

Flagellar Beat ◽

Beat Pattern ◽

Aqueous Environments ◽

Cilia And Flagella ◽

Microalgal Species ◽

Phase Relationships

AbstractLocomotion at the microscale is remarkably sophisticated. Microorganisms have evolved diverse strategies to move within highly viscous environments, using deformable, propulsion-generating appendages such as cilia and flagella to drive helical or undulatory motion. In single-celled algae, these appendages can be arranged in different ways around an approximately 10µm cell body, and coordinated in distinct temporal patterns. Inspired by the observation that some quadriflagellates (bearing four flagella) have an outwardly similar morphology and flagellar beat pattern, yet swim at different speeds, this study seeks to determine whether variations in swimming performance could arise solely from differences in swimming gait. Robotics approaches are particularly suited to such investigations, where the phase relationships between appendages can be readily manipulated. Here, we developed autonomous, algae-inspired robophysical models that can self-propel in a viscous fluid. These macroscopic robots (length and width = 8.5 cm, height = 2 cm) have four independently actuated ‘flagella’ that oscillate back and forth under low-Reynolds number conditions (Re∼ 𝒪(10−1)). We tested the swimming performance of these robot models with appendages arranged in one of two distinct configurations, and coordinated in one of three distinct gaits. The gaits, namely the pronk, the trot, and the gallop, correspond to gaits adopted by distinct microalgal species. When the appendages are inserted perpendicularly around a central ‘body’, the robot achieved a net performance of 0.15−0.63 body lengths per cycle, with the trot gait being the fastest. Robotic swimming performance was found to be comparable to that of the algal microswimmers across all gaits. By creating a minimal robot that can successfully reproduce cilia-inspired drag-based swimming, our work paves the way for the design of next-generation devices that have the capacity to autonomously navigate aqueous environments.

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Reconstruction of the three-dimensional beat pattern underlying swimming behaviors of sperm

The European Physical Journal E ◽

10.1140/epje/s10189-021-00076-z ◽

2021 ◽

Vol 44 (7) ◽

Author(s):

A. Gong ◽

S. Rode ◽

G. Gompper ◽

U. B. Kaupp ◽

J. Elgeti ◽

...

Keyword(s):

Three Dimensional ◽

Intrinsic Property ◽

Human Sperm ◽

Bending Waves ◽

Flagellar Beat ◽

Beat Pattern ◽

Glass Interface ◽

Two Space Dimensions ◽

Swimming Trajectories ◽

Physical And Chemical

Abstract The eukaryotic flagellum propels sperm cells and simultaneously detects physical and chemical cues that modulate the waveform of the flagellar beat. Most previous studies have characterized the flagellar beat and swimming trajectories in two space dimensions (2D) at a water/glass interface. Here, using refined holographic imaging methods, we report high-quality recordings of three-dimensional (3D) flagellar bending waves. As predicted by theory, we observed that an asymmetric and planar flagellar beat results in a circular swimming path, whereas a symmetric and non-planar flagellar beat results in a twisted-ribbon swimming path. During swimming in 3D, human sperm flagella exhibit torsion waves characterized by maxima at the low curvature regions of the flagellar wave. We suggest that these torsion waves are common in nature and that they are an intrinsic property of beating axonemes. We discuss how 3D beat patterns result in twisted-ribbon swimming paths. This study provides new insight into the axoneme dynamics, the 3D flagellar beat, and the resulting swimming behavior. Graphic abstract

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Control of helical navigation by three-dimensional flagellar beating

10.1101/2020.09.27.315606 ◽

2020 ◽

Author(s):

Dario Cortese ◽

Kirsty Y. Wan

Keyword(s):

High Speed ◽

Three Dimensional ◽

Axial Rotation ◽

Live Cells ◽

High Speed Imaging ◽

Flagellar Beat ◽

Motile Cells ◽

Beat Pattern ◽

Swimming Trajectories ◽

Realistic Geometries

Helical swimming is a ubiquitous strategy for motile cells to generate self-gradients for environmental sensing. The model biflagellate Chlamydomonas reinhardtii rotates at a constant 1 – 2 Hz as it swims, but the mechanism is unclear. Here, we show unequivocally that the rolling motion derives from a persistent, non-planar flagellar beat pattern. This is revealed by high-speed imaging and micromanipulation of live cells. We construct a fully-3D model to relate flagellar beating directly to the free-swimming trajectories. For realistic geometries, the model reproduces both the sense and magnitude of the axial rotation of live cells. We show that helical swimming requires further symmetry-breaking between the two flagella. These functional differences underlie all tactic responses, particularly phototaxis. We propose a control strategy by which cells steer towards or away from light by modulating the sign of biflagellar dominance.

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SpermQ–A Simple Analysis Software to Comprehensively Study Flagellar Beating and Sperm Steering

Cells ◽

10.3390/cells8010010 ◽

2018 ◽

Vol 8 (1) ◽

pp. 10 ◽

Cited By ~ 14

Author(s):

Jan Hansen ◽

Sebastian Rassmann ◽

Jan Jikeli ◽

Dagmar Wachten

Keyword(s):

Female Genital Tract ◽

Time Lapse ◽

Dark Field ◽

Comprehensive Analysis ◽

Analysis Software ◽

Environmental Signals ◽

Common Time ◽

Flagellar Beat ◽

Beat Pattern ◽

Motile Cilia

Motile cilia, also called flagella, are found across a broad range of species; some cilia propel prokaryotes and eukaryotic cells like sperm, while cilia on epithelial surfaces create complex fluid patterns e.g., in the brain or lung. For sperm, the picture has emerged that the flagellum is not only a motor but also a sensor that detects stimuli from the environment, computing the beat pattern according to the sensory input. Thereby, the flagellum navigates sperm through the complex environment in the female genital tract. However, we know very little about how environmental signals change the flagellar beat and, thereby, the swimming behavior of sperm. It has been proposed that distinct signaling domains in the flagellum control the flagellar beat. However, a detailed analysis has been mainly hampered by the fact that current comprehensive analysis approaches rely on complex microscopy and analysis systems. Thus, knowledge on sperm signaling regulating the flagellar beat is based on custom quantification approaches that are limited to only a few aspects of the beat pattern, do not resolve the kinetics of the entire flagellum, rely on manual, qualitative descriptions, and are only a little comparable among each other. Here, we present SpermQ, a ready-to-use and comprehensive analysis software to quantify sperm motility. SpermQ provides a detailed quantification of the flagellar beat based on common time-lapse images acquired by dark-field or epi-fluorescence microscopy, making SpermQ widely applicable. We envision SpermQ becoming a standard tool in flagellar and motile cilia research that allows to readily link studies on individual signaling components in sperm and distinct flagellar beat patterns.

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A steering mechanism for phototaxis in Chlamydomonas

Journal of The Royal Society Interface ◽

10.1098/rsif.2014.1164 ◽

2015 ◽

Vol 12 (104) ◽

pp. 20141164 ◽

Cited By ~ 38

Author(s):

Rachel R. Bennett ◽

Ramin Golestanian

Keyword(s):

Light Intensity ◽

Mechanical Model ◽

Light Signal ◽

Negative Phototaxis ◽

Forward Motion ◽

Flagellar Beat ◽

Beat Pattern ◽

Steering Mechanism ◽

Run And Tumble ◽

Robust To Noise

Chlamydomonas shows both positive and negative phototaxis. It has a single eyespot near its equator, and as the cell rotates during the forward motion, the light signal received by the eyespot varies. We use a simple mechanical model of Chlamydomonas that couples the flagellar beat pattern to the light intensity at the eyespot to demonstrate a mechanism for phototactic steering that is consistent with observations. The direction of phototaxis is controlled by a parameter in our model, and the steering mechanism is robust to noise. Our model shows switching between directed phototaxis when the light is on and run-and-tumble behaviour in the dark.

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Tubulin glycylation controls axonemal dynein activity, flagellar beat, and male fertility

Science ◽

10.1126/science.abd4914 ◽

2021 ◽

Vol 371 (6525) ◽

pp. eabd4914

Author(s):

Sudarshan Gadadhar ◽

Gonzalo Alvarez Viar ◽

Jan Niklas Hansen ◽

An Gong ◽

Aleksandr Kostarev ◽

...

Keyword(s):

Posttranslational Modifications ◽

Male Fertility ◽

Electron Tomography ◽

Structural Basis ◽

Cellular Functions ◽

Flagellar Beat ◽

Cryo Electron Tomography ◽

Axonemal Dynein ◽

Dynein Arms ◽

Cilia And Flagella

Posttranslational modifications of the microtubule cytoskeleton have emerged as key regulators of cellular functions, and their perturbations have been linked to a growing number of human pathologies. Tubulin glycylation modifies microtubules specifically in cilia and flagella, but its functional and mechanistic roles remain unclear. In this study, we generated a mouse model entirely lacking tubulin glycylation. Male mice were subfertile owing to aberrant beat patterns of their sperm flagella, which impeded the straight swimming of sperm cells. Using cryo–electron tomography, we showed that lack of glycylation caused abnormal conformations of the dynein arms within sperm axonemes, providing the structural basis for the observed dysfunction. Our findings reveal the importance of microtubule glycylation for controlled flagellar beating, directional sperm swimming, and male fertility.

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Soliton content of arbitrarily shaped light pulses in fibers analysed using a soliton-radiation beat pattern

Applied Physics B ◽

10.1007/s00340-006-2513-6 ◽

2006 ◽

Vol 86 (3) ◽

pp. 407-411 ◽

Cited By ~ 12

Author(s):

M. Böhm ◽

F. Mitschke

Keyword(s):

Light Pulses ◽

Beat Pattern

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Temperature effects on anaphase chromosome movement in the spermatocytes of two species of crane flies (Nephrotoma suturalis Loew and Nephrotoma ferruginea Fabricius)

Journal of Cell Science ◽

10.1242/jcs.39.1.29 ◽

1979 ◽

Vol 39 (1) ◽

pp. 29-52

Author(s):

C.J. Schaap ◽

A. Forer

Keyword(s):

Sex Chromosomes ◽

Temperature Effects ◽

Sex Chromosome ◽

Beat Frequency ◽

General Pattern ◽

Force Production ◽

Temperature Shift ◽

Ciliary Beat Frequency ◽

Chromosome Movement ◽

Flagellar Beat

Using phase-contrast cinemicrography on living crane fly (Nephrotoma suturalis Loew and Nephrotoma ferruginea Fabricius) spermatocytes, we have studied the effects of a range of temperatures (6–30 degrees C) on the anaphase I chromosome-to-pole movements of both autosomes and sex chromosomes. In contrast to previous work we have been able to study chromosome-to-pole velocities of autosomes without concurrent pole-to-pole elongation. In these cells we found that the higher the temperature, the faster was the autosomal chromosomes movement. From reviewing the literature we find that the general pattern of the effects of temperature on chromosome movement is similar whether or not pole-to-pole elongation occurs simultaneously with the chromosome-to-pole movement. Changes in cellular viscosities calculated from measurements of particulate Brownian movement do not seem to be able to account for the observed velocity differences due to temperature. Temperature effects on muscle contraction speed, flagellar beat frequency, ciliary beat frequency, granule flow in nerves, and chromosome movement have been compared, as have the activation energies for the rate-limiting steps in these motile systems: no distinction between possible mechanisms of force production is possible using these comparisons. The data show that even the different autosomes within single spermatocytes usually move at different speeds. These velocity differences cannot simply be related to chromosome size as the autosomes are visually indistinguishable. The sex chromosomes start their anaphase poleward movement after that of the autosomes, and move more slowly (by a factor of about 4), but their velocities appear to be affected by temperature in the same fashion as those of the autosomes. The interval between the onset of autosome anaphase and sex chromosome anaphase is also affected by temperature: the higher the temperature, the shorter the interval between the 2 stages. We have observed abnormalities in sex chromosome segregation, which may be due to temperature, but have not determined what the exact temperature shift conditions are that cause these abnormalities.

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