Tricia Y. J. Loo scite author profile

Eyespots on the wings of nymphalid butterflies represent colorful examples of pattern formation, yet the developmental origins and mechanisms underlying eyespot center differentiation are still poorly understood. Using CRISPR-Cas9 we re-examine the function of Distal-less (Dll) as an activator or repressor of eyespots, a topic that remains controversial. We show that the phenotypic outcome of CRISPR mutations depends upon which specific exon is targeted. In Bicyclus anynana , exon 2 mutations are associated with both missing and ectopic eyespots, and also exon skipping. Exon 3 mutations, which do not lead to exon skipping, produce only null phenotypes, including missing eyespots, lighter wing coloration and loss of scales. Reaction-diffusion modeling of Dll function, using Wnt and Dpp as candidate morphogens, accurately replicates these complex crispant phenotypes. These results provide new insight into the function of Dll as a potential activator of eyespot development, scale growth and melanization, and suggest that the tuning of Dll expression levels can generate a diversity of eyespot phenotypes, including their appearance on the wing.

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Slit-Robo Signalling Establishes a Sphingosine-1-Phosphate Gradient to Polarise Fin Mesenchyme and Establish Fin Morphology

Mahabaleshwar

P.V.

Loo

et al. 2021

Preprint

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Immigration of mesenchymal cells into the growing fin and limb buds drives distal outgrowth, with subsequent tensile forces between these cells essential for fin and limb morphogenesis. Morphogens derived from the apical domain of the fin, orientate limb mesenchyme cell polarity, migration, division and adhesion. The zebrafish mutant stomp displays defects in fin morphogenesis including blister formation and associated loss of orientation and adhesion of immigrating fin mesenchyme cells. Positional cloning of stomp identified a mutation in the gene encoding the axon guidance ligand, Slit3. We provide evidence that Slit ligands derived from immigrating mesenchyme act via Robo receptors at the Apical Ectodermal Ridge (AER) to promote release of sphingosine-1-phosphate (S1P). S1P subsequently diffuses back to the mesenchyme to promote their polarisation, orientation, positioning and adhesion to the interstitial matrix of the fin fold. We thus demonstrate coordination of the Slit-Robo and S1P signalling pathways in fin fold morphogenesis. Our work introduces a mechanism regulating the orientation, positioning and adhesion of its constituent cells.

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Slit‐Robo signalling establishes a Sphingosine‐1‐phosphate gradient to polarise fin mesenchyme

et al. 2022

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Immigration of mesenchymal cells into the growing fin and limb buds drives distal outgrowth, with subsequent tensile forces between these cells essential for fin and limb morphogenesis. Morphogens derived from the apical domain of the fin, orientate limb mesenchyme cell polarity, migration, division and adhesion. The zebrafish mutant stomp displays defects in fin morphogenesis including blister formation and associated loss of orientation and adhesion of immigrating fin mesenchyme cells. Positional cloning of stomp identifies a mutation in the gene encoding the axon guidance ligand, Slit3. We provide evidence that Slit ligands derived from immigrating mesenchyme act via Robo receptors at the apical ectodermal ridge (AER) to promote release of sphingosine‐1‐phosphate (S1P). S1P subsequently diffuses back to the mesenchyme to promote their polarisation, orientation, positioning and adhesion to the interstitial matrix of the fin fold. We thus demonstrate the coordination of the Slit‐Robo and S1P signalling pathways in fin fold morphogenesis. Our work introduces a mechanism regulating the orientation, positioning and adhesion of its constituent cells.

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Echolocation-like model of directed cell migration within growing tissues

Loo

Mahabaleshwar²,

Carney

et al. 2022

Preprint

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During development and regeneration, cells migrate to specific locations within growing tissues. These cells can respond to both biochemical signals and mechanical cues, resulting in directed migration. Such migration is often highly stereotypic. Yet, how cells respond to migratory signals in a robust manner within a growing domain remains an open problem. Here, we propose a model of directed migration in growing tissues motivated by echolocation. The migrating cells generate a signaling gradient that induces a response signal from the moving system boundary. This response signal mediates cellular adhesion to the surrounding matrix and hence modulates the cell migration. We find that such a mechanism can align a series of cells at stable positions within growing systems and can effectively scale to system size. Finally, we discuss the relevance of such a model to fibroblast migration and location within the developing zebrafish caudal fin, which may be regulated by opposing signaling gradients of Slit-Robo pathway components.Significance StatementHow do cells reliably migrate within growing environments? Here, we show that cells can take advantage of an echolocation-like process, whereby they induce a response from the tissue boundary. As they approach the boundary, the response signal strengthens and brings the cell to a fixed position from the boundary. This simple system may be applicable to fibroblast migration in the fin.

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Tricia Y. J. Loo

Activation of butterfly eyespots by Distal-less is consistent with a reaction-diffusion process

Slit-Robo Signalling Establishes a Sphingosine-1-Phosphate Gradient to Polarise Fin Mesenchyme and Establish Fin Morphology

Slit‐Robo signalling establishes a Sphingosine‐1‐phosphate gradient to polarise fin mesenchyme

Echolocation-like model of directed cell migration within growing tissues

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