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8. Physical Flow Effects Can Dictate Plankton Population Dynamics

Author

Woodward, Jonathan Reid, Pitchford, Jonathan William, and Bees, Martin Alan

Abstract

Oceanic flows do not necessarily mix planktonic species. Differences in individual organisms’ physical and hydrodynamic properties can cause changes in drift normal to the mean flow, leading to segregation between species. This physically-driven heterogeneity may have important consequences at the scale of population dynamics. Here, we describe how one form of physical forcing, circulating flows with different inertia effects between phytoplankton and zooplankton, can dramatically alter excitable plankton bloom dynamics. This may impact our understanding of the initiation and development of harmful algal blooms (HABs), which have significant negative ecological and socio-economic consequences. We study this system in detail, providing spatio-temporal dynamics for particular scenarios, and summarising large-scale behaviour via spatially averaged bifurcation diagrams. The key message is that, across a large range of parameter values, fluid flow can induce plankton blooms and mean-field population dynamics that are distinct from those predicted for well-mixed systems. The implications for oceanic population dynamic studies are manifest: we argue that the formation of HABs will depend strongly on the physical and biological state of the ecosystem, and that local increases in zooplankton heterogeneity are likely to precede phytoplankton blooms

Published
2019

9. Microbial mutualism at a distance: The role of geometry in diffusive exchanges

Author

Peaudecerf, F. J., Bunbury, F., Bhardwaj, V., Bees, Martin Alan, Smith, A. G., Goldstein, R. E., and Croze, O. A.

Abstract

The exchange of diffusive metabolites is known to control the spatial patterns formed by microbial populations, as revealed by recent studies in the laboratory. However, the matrices used, such as agarose pads, lack the structured geometry of many natural microbial habitats, including in the soil or on the surfaces of plants or animals. Here we address the important question of how such geometry may control diffusive exchanges and microbial interaction. We model mathematically mutualistic interactions within a minimal unit of structure: two growing reservoirs linked by a diffusive channel through which metabolites are exchanged. The model is applied to study a synthetic mutualism, experimentally parametrized on a model algal-bacterial co-culture. Analytical and numerical solutions of the model predict conditions for the successful establishment of remote mutualisms, and how this depends, often counterintuitively, on diffusion geometry. We connect our findings to understanding complex behavior in synthetic and naturally occurring microbial communities.

Published
2018

11. Simultaneous two-color imaging in digital holographic microscopy

Author

Farthing, Nicola Ellen, Findlay, Rachel Christina, Jikeli, Jan F., Walrad, Pegine Bavonne, Bees, Martin Alan, and Wilson, Laurence George

Subjects
genetic structures
Abstract

We demonstrate the use of two-color digital holographic microscopy (DHM) for imaging microbiological subjects. The use of two wavelengths significantly reduces artifacts present in the reconstructed data, allowing us to image weakly scattering objects in close proximity to strongly-scattering objects. We demonstrate this by reconstructing the shape of the flagellum of a single-cell eukaryotic parasite Leishmania mexicana in close proximity to a more strongly-scattering cell body. Our approach also yields a reduction of approximately one third in the axial position uncertainty when tracking the motion of swimming cells at low magnification, which we demonstrate with a sample of Escherichia coli bacteria mixed with polystyrene beads. The two-wavelength system that we describe introduces minimal additional complexity into the optical system, and provides significant benefits.

Published
2017

12. Simultaneous two-color imaging in digital holographic microscopy

Author

Farthing, Nicola E., Findlay, Rachel C., Jikeli, Jan F., Walrad, Pegine B., Bees, Martin A., and Wilson, Laurence G.

Subjects
genetic structures, Article
Abstract

We demonstrate the use of two-color digital holographic microscopy (DHM) for imaging microbiological subjects. The use of two wavelengths significantly reduces artifacts present in the reconstructed data, allowing us to image weakly-scattering objects in close proximity to strongly-scattering objects. We demonstrate this by reconstructing the shape of the flagellum of a unicellular eukaryotic parasite Leishmania mexicana in close proximity to a more strongly-scattering cell body. Our approach also yields a reduction of approximately one third in the axial position uncertainty when tracking the motion of swimming cells at low magnification, which we demonstrate with a sample of Escherichia coli bacteria mixed with polystyrene beads. The two-wavelength system that we describe introduces minimal additional complexity into the optical system, and provides significant benefits.

Published
2017

13. Advances in Bioconvection.

Author

Bees, Martin A.

Abstract

The term "bioconvection" describes hydrodynamic instabilities and patterns in suspensions of biased swimming microorganisms. Hydrodynamic instabilities arise from coupling between cell swimming behaviors; physical properties of the cells, such as density; and fluid flows. For instance, a combination of viscous and gravitational torques can lead to cells swimming toward downwelling fluid. If the cells are more dense than the fluid, then a gyrotactic instability results. Phototaxis describes the directed response of cells to light, which can also lead to instability. Bioconvection represents a classic system where macroscopic phenomena arise from microscopic cellular behavior in relatively dilute systems. There are ecological consequences for bioconvection and the mechanisms involved as well as potential for industrial exploitation. The focus of this review is on progress measuring and modeling gyrotactic and phototactic bioconvection. It builds on two earlier reviews of bioconvection and recent interest in active matter, describing progress and highlighting open problems. [ABSTRACT FROM AUTHOR]

Published
2020
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14. Bugs on a Slippery Plane : Understanding the Motility of Microbial Pathogens with Mathematical Modelling

Author

Pushkin, Dmitri O, Bees, Martin A, and Leake, Mark C.

Abstract

Many pathogenic microorganisms live in close association with surfaces, typically in thin films that either arise naturally or that they themselves create. In response to this constrained environment, the cells adjust their behaviour and morphology, invoking communication channels and inducing physical phenomena that allow for rapid colonization of biomedically relevant surfaces or the promotion of virulence factors. Thus, it is very important to measure and theoretically understand the key mechanisms for the apparent advantage obtained from swimming in thin films. We discuss experimental measurements of flows around a peritrichously flagellated bacterium constrained in a thin film, derive a simplified mathematical theory and Green's functions for flows in a thin film with general slip boundary conditions, and establish connections between theoretical and experimental results. This article aims to highlight the importance of mathematics as a tool to unlock qualitative mechanisms associated with experimental observations in the medical and biological sciences.

Published
2016

16. Gyrotactic swimmer dispersion in pipe flow: testing the theory.

Author

Croze, Ottavio A., Bearon, Rachel N., and Bees, Martin A.

Subjects
PIPE flow, BIOLOGICAL fluid dynamics, SWIMMING
Abstract

Suspensions of microswimmers are a rich source of fascinating new fluid mechanics. Recently we predicted the active pipe flow dispersion of gyrotactic microalgae, whose orientation is biased by gravity and flow shear. Analytical theory predicts that these active swimmers disperse in a markedly distinct manner from passive tracers (Taylor dispersion). Dispersing swimmers display non-zero drift and effective diffusivity that is non-monotonic with Péclet number. Such predictions agree with numerical simulations, but hitherto have not been tested experimentally. Here, to facilitate comparison, we obtain new solutions of the axial dispersion theory accounting both for swimmer negative buoyancy and a local nonlinear response of swimmers to shear, provided by two alternative microscopic stochastic descriptions. We obtain new predictions for suspensions of the model swimming alga Dunaliella salina, whose motility and buoyant mass we parametrise using tracking video microscopy. We then present a new experimental method to measure gyrotactic dispersion using fluorescently stained D. salina and provide a preliminary comparison with predictions of a non-zero drift above the mean flow for each microscopic stochastic description. Finally, we propose further experiments for a full experimental characterisation of gyrotactic dispersion measures and discuss the implications of our results for algal dispersion in industrial photobioreactors. [ABSTRACT FROM AUTHOR]

Published
2017
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17. The Orientation of Swimming Biflagellates in Shear Flows.

Author

O'Malley, Stephen and Bees, Martin

Subjects
*FLAGELLATA, *SHEAR flow, *ALGAE, *HYDRODYNAMICS, *BIOREACTORS, *POPULATION dynamics, *CHLAMYDOMONAS
Abstract

Biflagellated algae swim in mean directions that are governed by their environments. For example, many algae can swim upward on average (gravitaxis) and toward downwelling fluid (gyrotaxis) via a variety of mechanisms. Accumulations of cells within the fluid can induce hydrodynamic instabilities leading to patterns and flow, termed bioconvection, which may be of particular relevance to algal bioreactors and plankton dynamics. Furthermore, knowledge of the behavior of an individual swimming cell subject to imposed flow is prerequisite to a full understanding of the scaled-up bulk behavior and population dynamics of cells in oceans and lakes; swimming behavior and patchiness will impact opportunities for interactions, which are at the heart of population models. Hence, better estimates of population level parameters necessitate a detailed understanding of cell swimming bias. Using the method of regularized Stokeslets, numerical computations are developed to investigate the swimming behavior of and fluid flow around gyrotactic prolate spheroidal biflagellates with five distinct flagellar beats. In particular, we explore cell reorientation mechanisms associated with bottom-heaviness and sedimentation and find that they are commensurate and complementary. Furthermore, using an experimentally measured flagellar beat for Chlamydomonas reinhardtii, we reveal that the effective cell eccentricity of the swimming cell is much smaller than for the inanimate body alone, suggesting that the cells may be modeled satisfactorily as self-propelled spheres. Finally, we propose a method to estimate the effective cell eccentricity of any biflagellate when flagellar beat images are obtained haphazardly. [ABSTRACT FROM AUTHOR]

Published
2012
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18. A tale of three taxes: photo-gyro-gravitactic bioconvection.

Author

Williams, C. Rosie and Bees, Martin Alan

Subjects
*HYDRODYNAMICS, *TAXIS (Biology), *PHOTOTAXIS, *CHLAMYDOMONAS, *LIGHTING, *MICROORGANISMS
Abstract

The term bioconvection encapsulates the intricate patterns in concentration, due to hydrodynamic instabilities, that may arise in suspensions of non-neutrally buoyant, biased swimming microorganisms. The directional bias may be due to light (phototaxis), gravity (gravitaxis), a combination of viscous and gravitational torques (gyrotaxis) or other taxes.: The aim of this study is to quantify experimentally the wavelength of the initial pattern to form from an initially well-mixed suspension of unicellular, swimming green algae as a function of concentration and illumination. As this is the first such study, it is necessary to develop a robust and meticulous methodology to achieve this end. The phototactic, gyrotactic and gravitactic alga Chlamydomonas augustae was employed, with various red or white light intensities from above or below, as the three not altogether separable taxes were probed. Whilst bioconvection was found to be unresponsive to changes in red light, intriguing trends were found for pattern wavelength as a function of white light intensity, depending critically on the orientation of the illumination. These trends are explored to help unravel the mechanisms. Furthermore, comparisons are made with theoretical predictions of initial wavelengths from a recent model of photo-gyrotaxis, encouragingly revealing good qualitative agreement. [ABSTRACT FROM AUTHOR]

Published
2011
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19. The role of time delays in a non-autonomous host–parasitoid model of slug biocontrol with nematodes

Author

Schley, David and Bees, Martin A.

Subjects
*NEMATODES, *PARASITOIDS, *PHYSIOLOGICAL control systems, *PARASITES
Abstract

Abstract: Motivated by the difficulty in designing efficacious biocontrol strategies for dominant, agriculturally damaging slug species using naturally occurring parasitic nematodes, we investigate theory for the significant impact of stage structured delays on a non-autonomous host–parasitoid system. Initially, we mathematically strengthen existing stability results for a general class of autonomous system with delays at different trophic levels using analytical and numerical continuation methods. These results are employed to guide theoretical analyses of the effect of delays in a particular, seasonally forced, host–parasitoid system that can model aspects of slug–nematode biocontrol dynamics. Significantly, the model reveals a log-dose response consistent with experiments, and suggests that the optimal timing and frequency of applications is highly dependent on the form of the control required. We find that short-term high-level as well as less dramatic but sustained control are both possible by varying the timing of application. Moreover, we establish that resonance can occur between application and slug life-cycle frequencies inducing potentially undesirable large amplitude fluctuations in slug numbers. Finally, we assess the practicality of planning a crop protection response in the field. [Copyright &y& Elsevier]

Published
2006
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20. A Discrete Slug Population Model Determined by Egg Production.

Author

Schley, David and Bees, Martin A.

Subjects
*SLUGS (Mollusks), *ANIMAL populations
Abstract

Slugs are significant pests in agriculture (as well as a nuisance to gardeners), and it is therefore important to understand their population dynamics for the construction of efficient and effective control measures. Differential equation models of slug populations require the inclusion of large (variable) temporal delays, and strong seasonal forcing results in a non-autonomous system. This renders such models open to only a limited amount of rigorous analysis. In this paper, we derive a novel batch model based purely upon the quantity of eggs produced at different times of the year. This model is open to considerable reduction; from the resulting two variable discrete-time system it is possible to reconstruct the dynamics of the full population across the year and give conditions for extinction or global stability and persistence. Furthermore, the steady state temporal population distribution displays qualitatively different behavior with only small changes in the survival probability of slugs. The model demonstrates how small variations in the favorability of different years may result in widely different slug population fluctuations between consecutive years, and is in good agreement with field data. [ABSTRACT FROM AUTHOR]

Published
2002
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21. The role of boundary conditions on the stability of confined active matter : a numerical instability analysis on momentum-conserving active matter

Author

Sparkes, Matthew, Pushkin, Dmitri, and Bees, Martin

Abstract

Active matter is comprised of active particles whose underlying property is their ability to exert mechanical stresses on their environment by the conversion of stored or ambient free-energy. At sufficient particle number density, orientational order emerges due to steric, mechanical or behavioural mechanisms, generating collective motion in motile suspensions. On micrometre length scales, active particles such as bacteria can be categorised by their swimming type: `extensile' swimmers push themselves through their medium using flagellum, whereas `contractile' swimmers pull themselves. Activity drives an instability in ordered extensile (contractile) suspensions due to bend (splay) deformations in the suspension orientation (director) which generate active flow and enhance the director perturbation by shear-induced torque. This work comprises a two-part comprehensive extension to this fundamental instability in both 2D and 3D, and both unbounded and confined regimes. Active flow propagates in the same plane as the deformation that caused it, and in part one of this work, we show this causes a de-coupling of the governing equations in the unbounded 3D regime, resulting in the dominance of bend modes for extensile suspensions. Our main result concerns a new chirality term in the Jeffrey orbit equations which re-couples the governing equations by rotating the director out-of-plane from activity induced shear, and in an imposed-shear regime, enhances the instability growth rate by up to 10% versus the unbounded regime when alignment-to-shear and chiral-rotation effects are both present. In part two, we connect bulk growth rates to regimes of weak and strong confinement and show the critical confinement length h^c to suppress growth in 2D regime is related to the wavelength of maximum growth in the unbounded regime, and show further that alternative boundary conditions can reduce this critical value by an order of magnitude. The culmination of this work is the exploration of alternative steady states and boundary conditions for the suspension orientation: the effects of rotating the suspension relative to the boundaries, investigating torque-free boundary conditions, imposing a `swimmer slip' condition on the substrate, and the effects of inclination. We find regimes for which alignment-to-shear is stabilising, regimes where alignment-to-shear is de-stabilising, and predict new steady states using a steady torque-balanced equation for the director. This work invites discussion on appropriate boundary conditions for active matter by providing insight into the dynamics of 3D regimes of confinement, with experimentally realisable predictions for low Reynolds number suspensions. As part of an ongoing research narrative, this work utilises a robust codebase, broadly extendable to new regimes of interest, and will be published at a later date.

Published
2022

22. The fluid dynamics of nascent biofilms

Author

Farthing, Nicola, Bees, Martin, and Wilson, Laurence

Abstract

Bacteria are often found in surface associated structures called biofilms, composed of individual bacterial cells along with various extra-cellular components. They are a leading cause of antibiotic resistant infections and are a global issue. In this thesis, the focus is on the very early stages of biofilm formation and, in particular, the effect of bacterial motility on biofilm formation is investigated. Various microscopy techniques are used to determine that surface attached bacteria maintain moving flagella, which induce a flow around the bacteria. The flow due to such surface-attached bacteria has not previously been reported. In this thesis, holographic microscopy is used to determine the shape of the flow. The flow is found to be different when cells are exposed to a lactam analogue (which is thought to disrupt biofilm formation by interfering with cell-cell communication). In this thesis, a suggested explanation for this change in flow is an increase in flagellar reversal rate when the cells are exposed to the lactam analogue compared to a control set is presented. A simple model of the surface-attached cell with a motile flagellum is developed to capture the key elements of the flow. This simple model relies on singularity solutions to the Stokes equations and has low computational expenditure. This ease of computation allows the simulation of multiple cells so that the effect of the cells' induced flow on cell-cell communication can be investigated. Particle dispersion is found to be enhanced in the presence of simulated cells with the control reversal rate in comparison to those with the lactam reversal rate. This suggests that one effect of the lactam analogue is to lessen the transport of cell-cell communication molecules.

Published
2019

23. The role of quorum sensing in bacterial colony dynamics

Author

Alfiniyah, Cicik, Bees, Martin, and Wood, Jamie

Subjects
510
Abstract

The quorum sensing (QS) signalling system allows colonies of bacteria to coordinate gene expression to optimise behaviour at low and high cell densities, giving rise to individual and group responses, respectively. The main aim of this thesis is to understand better the important roles of QS in bacterial colony dynamics. Thus a mathematical description was developed to thoroughly explore key mechanisms and parameter sensitivity. The nature of the QS system depends very much on the species. Pseudomonas aeruginosa was chosen as a model species for this study. P. aeruginosa is a Gram-negative bacterium that is responsible for a wide range of chronic infections in humans. Its QS signalling system is known to involve the las, rhl and pqs systems; this thesis focuses on the first two. The las system includes the LasR regulator and LasI synthase, which direct the synthesis of autoinducer 3O-C12-HSL. Similarly, the rhl system consists of the RhlR regulator and RhlI synthase, directing the synthesis of autoinducer C4-HSL. The mathematical model of the las system displays hysteresis phenomena and excitable dynamics. In essence, the system can have two stable steady states reflecting low and high signal molecule production, separated by one unstable steady state. This feature of the las system can give rise to excitable pulse generation with important downstream impact on the rhl system. The las system is coupled to the rhl system in two ways. First, LasR and 3O-C12-HSL activate the expression of their counterpart in the rhl system. Second, 3O-C12-HSL blocks activation of RhlR by C4-HSL. Furthermore, the las-rhl interaction provides a `quorum memory' that allows cells to trigger rhamnolipid production when they are at the edge of colony. It was demonstrated how the dynamical QS system in individual cells and with coupling between cells can affect the dynamics of the bacterial colony.

Published
2017

24. Wound healing : a multidisciplinary approach : combining mathematical models and biological experiments

Author

Gothard, Elizabeth Jane, Coles, Mark, and Bees, Martin

Subjects
617.1
Abstract

Cutaneous wound repair occurs as a continuous process in both space and time; however, studies of healing mechanisms and outcomes frequently generate spatially and temporally sparse datasets. We propose a range of techniques that allow the size, cellular processes and scar tissue properties of wounds to be measured and predicted at high spatial and temporal resolution. A non-invasive wound imaging system is shown to provide reliable measurements of wound diameter, perimeter and surface area, but is less reliable in producing 3D metrics such as volume and depth. Wound size and time post healing have a combined effect on reliability, with more reliable measurements obtained at earlier timepoints. A semi-automated pipeline is found to be appropriate for determining the cellular composition of the wound space, but cannot be applied to areas of healthy epidermis due to the close packing of keratinocytes. A range of mathematical models are employed to predict cell numbers within the wound space. An extended domain, partial differential equation model with spatial control of cell proliferation and migration is found to best recapitulate the cellular dynamics observed in vivo. However, if epidermal stratification is to be incorporated, an agent-based description may be preferable. Finally, we formulate a model system that can predict the alignment of collagen fibres and fibroblasts over continuous orientation space. Parameter sets that include large shear forces (which may result from elongated wound geometries or interventions such as suturing) can produce skewed distributions of orientation that cannot be established using discontinuous approaches. Together, this suite of computational approaches provides a powerful set of tools with which the mechanisms of cutaneous wound healing can be investigated, quantified and elucidated.

Published
2016

25. Microbial mutualism at a distance: The role of geometry in diffusive exchanges.

Author

Peaudecerf, François J., Bunbury, Freddy, Bhardwaj, Vaibhav, Bees, Martin A., Smith, Alison G., Goldstein, Raymond E., and Croze, Ottavio A.

Subjects
*DIFFUSION, *METABOLITES, *MICROORGANISM populations, *BIOCHEMISTRY
Abstract

The exchange of diffusive metabolites is known to control the spatial patterns formed by microbial populations, as revealed by recent studies in the laboratory. However, the matrices used, such as agarose pads, lack the structured geometry of many natural microbial habitats, including in the soil or on the surfaces of plants or animals. Here we address the important question of how such geometry may control diffusive exchanges and microbial interaction. We model mathematically mutualistic interactions within a minimal unit of structure: two growing reservoirs linked by a diffusive channel through which metabolites are exchanged. The model is applied to study a synthetic mutualism, experimentally parametrized on a model algal-bacterial co-culture. Analytical and numerical solutions of the model predict conditions for the successful establishment of remote mutualisms, and how this depends, often counterintuitively, on diffusion geometry. We connect our findings to understanding complex behavior in synthetic and naturally occurring microbial communities. [ABSTRACT FROM AUTHOR]

Published
2018
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26. Simultaneous two-color imaging in digital holographic microscopy.

Author

Farthing NE, Findlay RC, Jikeli JF, Walrad PB, Bees MA, and Wilson LG

Abstract

We demonstrate the use of two-color digital holographic microscopy (DHM) for imaging microbiological subjects. The use of two wavelengths significantly reduces artifacts present in the reconstructed data, allowing us to image weakly-scattering objects in close proximity to strongly-scattering objects. We demonstrate this by reconstructing the shape of the flagellum of a unicellular eukaryotic parasite Leishmania mexicana in close proximity to a more strongly-scattering cell body. Our approach also yields a reduction of approximately one third in the axial position uncertainty when tracking the motion of swimming cells at low magnification, which we demonstrate with a sample of Escherichia coli bacteria mixed with polystyrene beads. The two-wavelength system that we describe introduces minimal additional complexity into the optical system, and provides significant benefits., Competing Interests: Disclosures The authors declare that there are no conflicts of interest related to this article.

Published
2017
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27. Dispersion of swimming algae in laminar and turbulent channel flows: consequences for photobioreactors.

Author

Croze OA, Sardina G, Ahmed M, Bees MA, and Brandt L

Subjects
Biomechanical Phenomena, Computer Simulation, Rheology, Time Factors, Hydrodynamics, Microalgae physiology, Models, Biological, Movement physiology, Photobioreactors, Water Movements
Abstract

Shear flow significantly affects the transport of swimming algae in suspension. For example, viscous and gravitational torques bias bottom-heavy cells to swim towards regions of downwelling fluid (gyrotaxis). It is necessary to understand how such biases affect algal dispersion in natural and industrial flows, especially in view of growing interest in algal photobioreactors. Motivated by this, we here study the dispersion of gyrotactic algae in laminar and turbulent channel flows using direct numerical simulation (DNS) and a previously published analytical swimming dispersion theory. Time-resolved dispersion measures are evaluated as functions of the Péclet and Reynolds numbers in upwelling and downwelling flows. For laminar flows, DNS results are compared with theory using competing descriptions of biased swimming cells in shear flow. Excellent agreement is found for predictions that employ generalized Taylor dispersion. The results highlight peculiarities of gyrotactic swimmer dispersion relative to passive tracers. In laminar downwelling flow the cell distribution drifts in excess of the mean flow, increasing in magnitude with Péclet number. The cell effective axial diffusivity increases and decreases with Péclet number (for tracers it merely increases). In turbulent flows, gyrotactic effects are weaker, but discernable and manifested as non-zero drift. These results should have a significant impact on photobioreactor design.

Published
2013
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28. Differential dynamic microscopy: a high-throughput method for characterizing the motility of microorganisms.

Author

Martinez VA, Besseling R, Croze OA, Tailleur J, Reufer M, Schwarz-Linek J, Wilson LG, Bees MA, and Poon WC

Subjects
Light, Microscopy methods, Scattering, Radiation, Cell Tracking methods, Chlamydomonas reinhardtii physiology, Escherichia coli physiology, Locomotion
Abstract

We present a fast, high-throughput method for characterizing the motility of microorganisms in three dimensions based on standard imaging microscopy. Instead of tracking individual cells, we analyze the spatiotemporal fluctuations of the intensity in the sample from time-lapse images and obtain the intermediate scattering function of the system. We demonstrate our method on two different types of microorganisms: the bacterium Escherichia coli (both smooth swimming and wild type) and the biflagellate alga Chlamydomonas reinhardtii. We validate the methodology using computer simulations and particle tracking. From the intermediate scattering function, we are able to extract the swimming speed distribution, fraction of motile cells, and diffusivity for E. coli, and the swimming speed distribution, and amplitude and frequency of the oscillatory dynamics for C. reinhardtii. In both cases, the motility parameters were averaged over ∼10(4) cells and obtained in a few minutes., (Copyright © 2012 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published
2012
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29. Unexpected bipolar flagellar arrangements and long-range flows driven by bacteria near solid boundaries.

Author

Cisneros LH, Kessler JO, Ortiz R, Cortez R, and Bees MA

Subjects
Algorithms, Biofilms, Flagella ultrastructure, Models, Statistical, Movement, Quorum Sensing, Reproducibility of Results, Bacillus subtilis physiology, Bacterial Physiological Phenomena, Flagella physiology
Abstract

Experiments and mathematical modeling show that complex flows driven by unexpected flagellar arrangements are induced when peritrichously flagellated bacteria are confined in a thin layer of fluid, between asymmetric boundaries. The flagella apparently form a dynamic bipolar assembly rather than the single bundle characteristic of free swimming bacteria, and the resulting flow is observed to circulate around the cell body. It ranges over several cell diameters, in contrast to the small extent of the flows surrounding free swimmers. Results also suggest that flagellar bundles on bacteria that lie flat on a solid substrate have an effective rotation rate slower than "free" flagella. This discovery extends our knowledge of the dynamic geometry of bacteria and their flagella, and reveals new mechanisms for motility-associated molecular transport and intercellular communication.

Published
2008
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