Distinct cell shapes determine accurate chemotaxis

Tweedy, Luke; Meier, Börn; Stephan, Jürgen; Heinrich, Doris; Endres, Robert G.

doi:10.1038/srep02606

Cited by 68 publications

(97 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Other groups have reported that migrating fish keratocytes and Dictyostelium cells also exist in a low‐dimensional shape space. Despite their different origins, many cell lines adopt shapes that are strikingly similar.…”

Section: How Many Cell Shapes Are There?mentioning

confidence: 99%

How cells explore shape space: A quantitative statistical perspective of cellular morphogenesis

et al. 2014

View full text Add to dashboard Cite

Through statistical analysis of datasets describing single cell shape following systematic gene depletion, we have found that the morphological landscapes explored by cells are composed of a small number of attractor states. We propose that the topology of these landscapes is in large part determined by cell-intrinsic factors, such as biophysical constraints on cytoskeletal organization, and reflect different stable signaling and/or transcriptional states. Cell-extrinsic factors act to determine how cells explore these landscapes, and the topology of the landscapes themselves. Informational stimuli primarily drive transitions between stable states by engaging signaling networks, while mechanical stimuli tune, or even radically alter, the topology of these landscapes. As environments fluctuate, the topology of morphological landscapes explored by cells dynamically adapts to these fluctuations. Finally we hypothesize how complex cellular and tissue morphologies can be generated from a limited number of simple cell shapes.

show abstract

Section: How Many Cell Shapes Are There?mentioning

confidence: 99%

How cells explore shape space: A quantitative statistical perspective of cellular morphogenesis

et al. 2014

View full text Add to dashboard Cite

show abstract

“…The seemingly endless variety of cell shape seen in chemotaxis can be reasonably well described mathematically by just three principal components, representing cell elongation, cell polarisation and pseudopod splitting or bending [6 ]. Cells adopt characteristic shapes according to the strength (signal/noise) of the chemotactic gradient: in strong gradients they tend to be wedge shaped and move quickly, whereas in weak gradients they typically alternate between pseudopod splitting and cell elongation.…”

Section: Modes and Mechanics Of Movementmentioning

confidence: 99%

Chemotaxis of a model organism: progress with Dictyostelium

Nichols

Veltman

Kay

2015

Current Opinion in Cell Biology

View full text Add to dashboard Cite

“…Early observations in Dictyostelium and neutrophils suggested that small membrane protrusions, called filopodia, preferentially form towards the external gradient [48,49]. Stochastic cell-shape changes in response to gradients may thus act as an additional layer regulating the dynamics of the polarised assembly [50,51]. The increased local membrane area increases the local receptor concentration, and thus likely enhances polarised assembly recruitment locally.…”

Section: Substrate Limitation As Efficient Global Inhibitor In Local mentioning

confidence: 99%

Local sampling paints a global picture: Local concentration measurements sense direction in complex chemical gradients

Hegemann

Peter

2017

BioEssays

View full text Add to dashboard Cite

Detecting and interpreting extracellular spatial signals is essential for cellular orientation within complex environments, such as during directed cell migration or growth in multicellular development. Although the molecular understanding of how cells read spatial signals like chemical gradients is still lacking, recent work has revealed that stochastic processes at different temporal and spatial scales are at the core of this gradient sensing process in a wide range of eukaryotes. Fast biochemical reactions like those underlying GTPase activity dynamics form a functional module together with slower cell morphological changes driven by membrane remodelling. This biochemical-morphological module explores the environment by stochastic local concentration sampling to determine the source of the gradient signal, enabling efficient signal detection and interpretation before polarised growth or migration towards the gradient source is initiated. Here we review recent data describing local sampling and propose a model of local fast and slow feedback counteracted by gradient-dependent substrate limitation to be at the core of gradient sensing by local sampling.

show abstract

Distinct cell shapes determine accurate chemotaxis

Cited by 68 publications

References 33 publications

How cells explore shape space: A quantitative statistical perspective of cellular morphogenesis

How cells explore shape space: A quantitative statistical perspective of cellular morphogenesis

Chemotaxis of a model organism: progress with Dictyostelium

Local sampling paints a global picture: Local concentration measurements sense direction in complex chemical gradients

Contact Info

Product

Resources

About