Bacterial rheotaxis

Marcos, .; Fu, Henry; Powers, Thomas; Stocker, Roman

doi:10.1073/pnas.1120955109

Cited by 250 publications

(234 citation statements)

References 38 publications

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“…Rheotaxis has been observed in organisms as simple as single motile cells such as bacteria (7,(29)(30)(31)(32) and sperm (6,33,34), where hydrodynamics is implicated as the cause of rheotactic behavior (29)(30)(31)(32)(33)(34). In contrast, in the case of zebrafish, a vertebrate, an active response of the animal that involves its sensory nervous system is believed to influence the rheotactic behavior (8).…”

Section: Resultsmentioning

confidence: 99%

Propensity of undulatory swimmers, such as worms, to go against the flow

Yuan¹,

Raizen

Bau³

2015

Proc. Natl. Acad. Sci. U.S.A.

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The ability to orient oneself in response to environmental cues is crucial to the survival and function of diverse organisms. One such orientation behavior is the alignment of aquatic organisms with (negative rheotaxis) or against (positive rheotaxis) fluid current. The questions of whether low-Reynolds-number, undulatory swimmers, such as worms, rheotax and whether rheotaxis is a deliberate or an involuntary response to mechanical forces have been the subject of conflicting reports. To address these questions, we use Caenorhabditis elegans as a model undulatory swimmer and examine, in experiment and theory, the orientation of C. elegans in the presence of flow. We find that when close to a stationary surface the animal aligns itself against the direction of the flow. We elucidate for the first time to our knowledge the mechanisms of rheotaxis in worms and show that rheotaxis can be explained solely by mechanical forces and does not require sensory input or deliberate action. The interaction between the flow field induced by the swimmer and a nearby surface causes the swimmer to tilt toward the surface and the velocity gradient associated with the flow rotates the animal to face upstream. Fluid mechanical computer simulations faithfully mimic the behavior observed in experiments, supporting the notion that rheotaxis behavior can be fully explained by hydrodynamics. Our study highlights the important role of hydrodynamics in the behavior of small undulating swimmers and may assist in developing control strategies to affect the animals’ life cycles.

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Section: Resultsmentioning

confidence: 99%

Propensity of undulatory swimmers, such as worms, to go against the flow

Yuan¹,

Raizen

Bau³

2015

Proc. Natl. Acad. Sci. U.S.A.

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“…Results of this type can be used to design microfluidic devices that can rectify swimmers' motion in interesting ways I close this section by noting that the strong interaction of swimming microorganisms with surfaces is thought to underlie the process of rheotaxis, in which they swim upstream against a bulk flow. Of particular interest recently has been bacterial rheotaxis (Marcos et al 2012), where the chirality of the helical flagella plays an important role in reorientation of cells along the walls bounding the flow. Analogous phenomena have been seen in sperm rheotaxis .…”

Section: Surface Interactions Of Microswimmersmentioning

confidence: 99%

Batchelor Prize Lecture Fluid dynamics at the scale of the cell

Goldstein

2016

J. Fluid Mech.

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The world of cellular biology provides us with many fascinating fluid dynamical phenomena that lie at the heart of physiology, development, evolution and ecology. Advances in imaging, micromanipulation and microfluidics over the past decade have made possible high-precision measurements of such flows, providing tests of microhydrodynamic theories and revealing a wealth of new phenomena calling out for explanation. Here I summarize progress in four areas within the field of 'active matter': cytoplasmic streaming in plant cells, synchronization of eukaryotic flagella, interactions between swimming cells and surfaces and collective behaviour in suspensions of microswimmers. Throughout, I emphasize open problems in which fluid dynamical methods are key ingredients in an interdisciplinary approach to the mysteries of life.

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“…Models of larval fish dispersal patterns within riverine ecosystems are rare (e.g., Wolter and Sukhodolov 2008;Korman et al 2004;Cowan et al 1993). However, models that include rheoreaction have been developed for several organisms and their larval developmental stages (Marcos et al 2012;Mork et al 2012;Booker et al 2008). Kingsford et al (2002) recommended obtaining high-resolution spatial information on navigation, at scales of less than 1 m, before implementation into models of larval fish dispersal (from metres to kilometres).…”

Section: Introductionmentioning

confidence: 99%

Modelling the dispersal of riverine fish larvae: from a raster-based analysis of movement patterns within a racetrack flume to a rheoreaction-based correlated random walk (RCRW) model approach

Glas

Tritthart

Zens

et al. 2017

Can. J. Fish. Aquat. Sci.

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Recruitment of Chondrostoma nasus and similar fish species in rivers is related to spatiotemporal linkages between larval hatching and nursery habitats. Active swimming behaviour contradicts the assumption that passive particle tracing models can serve as a proxy for larval dispersal models. A racetrack flume with an inshore area of near-natural slope was created to observe individual larval trajectories. A new three-step, raster-based analysis was developed to distinguish four types of movement patterns: active upstream, active downstream, active-passive, and passive. Both larval developmental stage-specific and release site-specific occurrences of these movement patterns were experimentally found for nine flow velocity classes (≤0.225 m·s −1 ). These currentinduced movement patterns, and evaluated durations within them, were used to develop a biased and correlated random walk model that includes rheoreaction -a key behavioural response of fish to flow within rivers. The study introduces the concept and application of a rheoreaction-based correlated random walk model, which coupled with a 3D hydrodynamic model, allows prediction of the spatiotemporal effects of various river discharges, morphologies, and restoration scenarios on larval fish dispersal.Résumé : Le recrutement de Chondrostoma nasus et d'espèces de poissons semblables dans les rivières est relié à des liens spatiotemporels entre l'éclosion des larves et les habitats d'alevinage. Le comportement de nage active contredit l'hypothèse voulant que les modèles de suivi de particules passives puissent se substituer aux modèles de dispersion des larves. Un canal de nage ovale avec une zone côtière de pente quasi naturelle a été créé pour observer les trajectoires de larves individuelles. Une nouvelle analyse de mappage en trois étapes a été mise au point pour distinguer quatre types de déplacements, à savoir : actif vers l'amont, actif vers l'aval, actif-passif et passif. Des cas de ces types de déplacements tant à l'étape du développement des larves que pour des sites de lâcher précis ont été observés expérimentalement pour neuf catégories de vitesses d'écoulement (≤0,225 m·s -1 ). Ces motifs de déplacement induits par le courant et leurs durées évaluées ont été utilisés pour développer un modèle de parcours aléatoire biaisé et corrélé qui comprend la rhéoréaction, une réaction comportementale clé des poissons à l'écoulement dans les rivières. L'étude introduit le concept et l'application d'un modèle de parcours aléatoire corrélé basé sur la rhéoréaction qui, jumelé à un modèle hydrodynamique en 3D, permet de prédire les effets spatiotemporels de différents débits, morphologies et scénarios de restauration de rivière sur la dispersion des larves de poisson. [Traduit par la Rédaction]

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Bacterial rheotaxis

Cited by 250 publications

References 38 publications

Propensity of undulatory swimmers, such as worms, to go against the flow

Propensity of undulatory swimmers, such as worms, to go against the flow

Batchelor Prize Lecture Fluid dynamics at the scale of the cell

Modelling the dispersal of riverine fish larvae: from a raster-based analysis of movement patterns within a racetrack flume to a rheoreaction-based correlated random walk (RCRW) model approach

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