Topological data analysis of zebrafish patterns

McGuirl, Melissa R.; Volkening, Alexandria; Sandstede, Björn

doi:10.1073/pnas.1917763117

Cited by 71 publications

(58 citation statements)

References 67 publications

(274 reference statements)

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“…Signals by melanophores and xanthophores are proposed to determine the specific morphologies adopted by iridophores. Consistent with this idea, quantitative models incorporating proposed dynamic morphological changes of individual iridophores are able to produce stripe patterning and robustness 23,24 .…”

Section: Introductionmentioning

confidence: 68%

In situdifferentiation of iridophore crystallotypes underlies zebrafish stripe patterning

Gur

Bain

Johnson

et al. 2020

Preprint

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22Skin color patterns are ubiquitous in nature, evolve rapidly, and impact social 23 behavior 1 , predator avoidance 2 , and protection from ultraviolet irradiation 3 . A 24 leading model system for vertebrate skin patterning is the zebrafish 4-7 ; its 25 alternating blue stripes and yellow interstripes depend on guanine crystal-26 containing cells called iridophores that reflect light. It was suggested that the 27 zebrafish's alternating color pattern arises from a single type of iridophore 28 migrating differentially to stripes and interstripes 7-9 . When we tracked iridophores, 29 however, we found they did not migrate between stripes and interstripes but 30 instead differentiated and proliferated in place based on their micro-environment. 31RNA seq analysis further revealed stripe and interstripe iridophores had different 32 transcriptomic states, while cryogenic scanning electron microscopy and micro-33 X-ray diffraction showed they had different guanine crystal organizations and 34 responsiveness to norepinephrine, all indicating that stripe and interstripe 35 iridophores are different cell types. Based on these results, we present a new 36 model of skin patterning in zebrafish in which distinct iridophore crystallotypes 37 containing specialized, physiologically responsive, subcellular organelles arise in 38 stripe and interstripe zones by in situ differentiation. In this model, pattern 39 phenotype depends not only on interactions among pigment cells that affect their 40 arrangements, but also on factors that specify subcellular organization and 41 physiological responsiveness of specialized organelles. 42 43 Introduction 1 Biological patterning is ubiquitous in nature, but mechanisms underlying its 2 establishment and maintenance have been well-documented in only a few instances that 3 are unlikely to represent the full spectrum of pattern-forming systems 6,10 . Indeed, 4 patterning can arise in response to graded positional information or by self-organization 5 of interacting cells, and it can require alternative specification of cell-types from a 6 common progenitor or sorting-out of cells that are heterogeneous already. Elucidating 7 the mechanisms required to pattern cells in diverse tissues and organs is fundamental to 8 understanding development and how phenotypes evolve.9The alternating dark (blue) and light (yellow) pigmented stripe pattern of adult 10 zebrafish Danio rerio (Fig. 1a) is a useful model for dissecting patterning 11 mechanisms 4,5,7,11,12 . Cells within the dark stripes include black pigment-containing 12 melanophores; cells in the light stripes (known as "interstripes") include orange-pigment 13 containing xanthophores; and both dark stripes and light interstripes contain specialized 14 cells called iridophores 13,14 . Iridophores are the major players for skin pattern 15 establishment and reiteration in zebrafish. They behave as reflective cells, exhibiting 16 angular-dependent changes in hue-iridescence-owing to membrane-bound reflecting 17 platelets of crystalline guanine 14-16...

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Section: Introductionmentioning

confidence: 68%

In situdifferentiation of iridophore crystallotypes underlies zebrafish stripe patterning

Gur

Bain

Johnson

et al. 2020

Preprint

View full text Add to dashboard Cite

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“…Such inference methods have been proposed to quantify aspects of signalling dynamics from observed morphogen concentrations in different taxa (Dewar et al 2010), though again often using phenomenological reaction kinetics that are undoubtedly a caricature of the real morphogen signalling dynamics. Similar ideas have been used to quantify and classify the role of different aspects of agent-based models of pattern formation (such as stochasticity and interactions) in models of zebrafish pigmentation (McGuirl et al 2020). If the underlying morphogen interactions are known, and hence, the nonlinearities are given, then these techniques provide a powerful way for using observations to determine key features of the morphogen dynamics.…”

Section: Introductionmentioning

confidence: 99%

Bespoke Turing Systems

2021

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Reaction–diffusion systems are an intensively studied form of partial differential equation, frequently used to produce spatially heterogeneous patterned states from homogeneous symmetry breaking via the Turing instability. Although there are many prototypical “Turing systems” available, determining their parameters, functional forms, and general appropriateness for a given application is often difficult. Here, we consider the reverse problem. Namely, suppose we know the parameter region associated with the reaction kinetics in which patterning is required—we present a constructive framework for identifying systems that will exhibit the Turing instability within this region, whilst in addition often allowing selection of desired patterning features, such as spots, or stripes. In particular, we show how to build a system of two populations governed by polynomial morphogen kinetics such that the: patterning parameter domain (in any spatial dimension), morphogen phases (in any spatial dimension), and even type of resulting pattern (in up to two spatial dimensions) can all be determined. Finally, by employing spatial and temporal heterogeneity, we demonstrate that mixed mode patterns (spots, stripes, and complex prepatterns) are also possible, allowing one to build arbitrarily complicated patterning landscapes. Such a framework can be employed pedagogically, or in a variety of contemporary applications in designing synthetic chemical and biological patterning systems. We also discuss the implications that this freedom of design has on using reaction–diffusion systems in biological modelling and suggest that stronger constraints are needed when linking theory and experiment, as many simple patterns can be easily generated given freedom to choose reaction kinetics.

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“…It is possible to calculate the correlation between the cophenetic distance and the distances in the matrix of Fig 18(a) (the cophenetic correlation [ 63 ]). For our simulations, Ward’s hierarchical clustering provides the largest cophenetic correlation when compared with other clustering approaches, such as single-linkage [ 53 ]. Thus, the Ward dendrogram gives the most faithful representation of the distance matrix, which is why we use it.…”

Section: Resultsmentioning

confidence: 99%

“…In this work, we use techniques of topological data analysis with some data taken from experiments and a modest amount of data from numerical simulations so as to explain techniques and results in a clear manner. However, our techniques are scalable and could be used in studies involving large amounts of data, as, for example, those generated to characterize zebrafish patterns by combining machine learning and topological data analysis [ 53 ].…”

Section: Introductionmentioning

confidence: 99%

Tracking collective cell motion by topological data analysis

2020

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By modifying and calibrating an active vertex model to experiments, we have simulated numerically a confluent cellular monolayer spreading on an empty space and the collision of two monolayers of different cells in an antagonistic migration assay. Cells are subject to inertial forces and to active forces that try to align their velocities with those of neighboring ones. In agreement with experiments in the literature, the spreading test exhibits formation of fingers in the moving interfaces, there appear swirls in the velocity field, and the polar order parameter and the correlation and swirl lengths increase with time. Numerical simulations show that cells inside the tissue have smaller area than those at the interface, which has been observed in recent experiments. In the antagonistic migration assay, a population of fluidlike Ras cells invades a population of wild type solidlike cells having shape parameters above and below the geometric critical value, respectively. Cell mixing or segregation depends on the junction tensions between different cells. We reproduce the experimentally observed antagonistic migration assays by assuming that a fraction of cells favor mixing, the others segregation, and that these cells are randomly distributed in space. To characterize and compare the structure of interfaces between cell types or of interfaces of spreading cellular monolayers in an automatic manner, we apply topological data analysis to experimental data and to results of our numerical simulations. We use time series of data generated by numerical simulations to automatically group, track and classify the advancing interfaces of cellular aggregates by means of bottleneck or Wasserstein distances of persistent homologies. These techniques of topological data analysis are scalable and could be used in studies involving large amounts of data. Besides applications to wound healing and metastatic cancer, these studies are relevant for tissue engineering, biological effects of materials, tissue and organ regeneration.

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Topological data analysis of zebrafish patterns

Cited by 71 publications

References 67 publications

In situdifferentiation of iridophore crystallotypes underlies zebrafish stripe patterning

In situdifferentiation of iridophore crystallotypes underlies zebrafish stripe patterning

Bespoke Turing Systems

Tracking collective cell motion by topological data analysis

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