Amoeboid migration mode adaption in quasi-3D spatial density gradients of varying lattice geometry

Gorelashvili, Mari; Emmert, Martin; Hodeck, Kai F.; Heinrich, Doris

doi:10.1088/1367-2630/16/7/075012

Cited by 27 publications

(26 citation statements)

References 35 publications

(51 reference statements)

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“…The height and diameter of the pillars is the same (8 µm) and comparable to the typical size of a D. discoideum cell, which varies between 8-15 µm 40 . This ratio between pillar height and cell size is sufficient to keep the motion of starved D. discoideum two-dimensional, meaning the pillars act as obstacles, as observed in previous studies 38,41 . Cells fully mounting the pillars are rarely observed and excluded from the data.…”

Section: Figure 1dsupporting

confidence: 63%

“…Fabrication of pillar gradient structures. PDMS (Sylgard 184 Silicon Elastomer Kit, Dow Corning, MI, USA) micro-pillars were made as previously described in 41 using standard photolithography techniques. The micro-pillars were positioned in a trigonal array.…”

Section: Methodsmentioning

confidence: 99%

“…We analyzed the xytrajectories with in-house Matlab (version 2018b, The Mathworks, Inc., Natick, MA, U.S.A.) analysis program. Using the recorded displacements, and registered imaging times, we calculated movement statistics, like instantaneous velocities, turning angles and mean-square displacements (MSD), as previously published 38,41 .…”

Section: Methodsmentioning

confidence: 99%

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Chemotaxis and topotaxis add vectorially for amoeboid cell migration

Wondergem

Mytiliniou

Wit

et al. 2019

Preprint

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3. Data modelling, computational biology and predictive medicine, AbstractCells encounter a wide variety of physical and chemical cues when navigating their native environments. However, their response to multiple simultaneous cues is not yet clear. In particular, the influence of topography, in the presence of a chemotactic gradient, on their migratory behavior is understudied. Here, we investigate the effects of topographical guidance on highly motile amoeboid cell migration (topotaxis) generated by asymmetrically placed micropillars. The micropillar field allows for an additional, natural chemotactic gradient in two different directions, thereby revealing the relevance of topotaxis in the presence of cell migration directed by chemical gradients (chemotaxis). Interestingly, we found that the topotactic drift generated by the pillar field is conserved during chemotaxis. We show that the drifts generated by both these cues add up linearly. A coarse-grained analysis as a function of pillar spacing subsequently revealed that the strength and direction of the topotactic drift is determined by (i) the pore size, (ii) space between pores, and (iii) the effective diffusion constant of the cells. Finally, we argue that topotaxis must be conserved during chemotaxis, as it is an emergent property of both the asymmetric properties of the pillar field and the inherent stochasticity of (biased) amoeboid migration.

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Section: Figure 1dsupporting

confidence: 63%

Section: Methodsmentioning

confidence: 99%

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Chemotaxis and topotaxis add vectorially for amoeboid cell migration

Wondergem

Mytiliniou

Wit

et al. 2019

Preprint

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“…25 A text le is created, containing the X-Y coordinates for each time point. The cell trajectories were analyzed by the MATLAB® algorithm "CellMovement", 21,26 distinguishing two modes of cell migration: directed cell runs and quasi-random migration phases. It utilizes a local mean squared displacement (LMSD), which is calculated for every time point t i over a rolling time window of 16 frames (corresponding to a duration T ¼ 112 s) as a function of different lag times s: 27…”

Section: Migration Analysismentioning

confidence: 99%

Nanostructured surfaces of biodegradable silica fibers enhance directed amoeboid cell migration in a microtubule-dependent process

Emmert

Witzel

Rothenburger-Glaubitt

et al. 2017

RSC Adv.

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Cell motion and in particular amoeboid migration is crucial for the survival of living organisms. To advance biomedical research, a constant need for novel materials and surface structures arises, improving immigration of cells into artificial structures used for tissue engineering and for advancing therapy in modern medicine. This work focuses on investigating amoeboid single-cell migration on intrinsically nano-structured, biodegradable silica fibers in comparison to chemically equivalent plain glass surfaces. Cell migration trajectories are classified into directed runs and quasi-random migration by a local mean squared displacement (LMSD) analysis. We find that directed movement on silica fibers is enhanced in a significant manner by the fibers' nanoscale surface-patterns. Further, cell adhesion on the silica fibers is a microtubule-mediated process. Cells lacking microtubules detach from the fibers, but adhere well to glass surfaces. Knock-out mutants of myosin II migrating on the fibers are as active as cells with active myosin II, while the migration of the knock-out mutants is hindered on plain glass. Identifying relevant cytoskeletal compounds for cell migration in 2D vs. 3D will help to optimize materials or surfaces that boost specific migration strategies to open up new opportunities for innovative diagnostic and therapeutic concepts

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“…Depending on the obstacle density, crawling was found at low density of obstacles [11] and directed and random phases can even be differentiated. In high density regions, the motion is rather directed from obstacle-to-obstacle [12].…”

Section: Introductionmentioning

confidence: 99%

Recovering a stochastic process from super-resolution noisy ensembles of single-particle trajectories

Hozé

Holcman²

2015

Phys. Rev. E

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Recovering a stochastic process from noisy ensembles of single-particle trajectories is resolved here using the coarse-grained Langevin equation as a model. The massive redundancy contained in single-particle tracking data allows recovering local parameters of the underlying physical model. We use several parametric and nonparametric estimators to compute the first and second moments of the process, to recover the local drift, its derivative, and the diffusion tensor, and to deconvolve the instrumental from the physical noise. We use numerical simulations to also explore the range of validity for these estimators. The present analysis allows defining what can exactly be recovered from statistics of super-resolution microscopy trajectories used for characterizing molecular trafficking underlying cellular functions.

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Amoeboid migration mode adaption in quasi-3D spatial density gradients of varying lattice geometry

Cited by 27 publications

References 35 publications

Chemotaxis and topotaxis add vectorially for amoeboid cell migration

Chemotaxis and topotaxis add vectorially for amoeboid cell migration

Nanostructured surfaces of biodegradable silica fibers enhance directed amoeboid cell migration in a microtubule-dependent process

Recovering a stochastic process from super-resolution noisy ensembles of single-particle trajectories

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