Scutoids are a geometrical solution to three-dimensional packing of epithelia

Gómez-Gálvez, Pedro; Vicente‐Munuera, Pablo; Tagua, Antonio; Forja, Cristina; Castro, Ana; Letrán, Marta; Valencia-Expósito, Andrea; Grima, Clara I.; Bermúdez-Gallardo, Marina; Serrano-Pérez-Higueras, Óscar; Cavodeassi, Florencia; Sotillos, Sol; Martín-Bermudo, Maria D.; Márquez, Alberto; Buceta, Javier; Escudero, Luis

doi:10.1038/s41467-018-05376-1

Cited by 116 publications

(153 citation statements)

References 68 publications

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“…We sought to test this prediction by artificially creating epithelia with wider apical cell area distributions. To this end, we induced the expression of an RNAi targeting the growth regulator gigas/TSC2 [20] in cell patches randomly located within Drosophila wing discs. gigas attenuation results in larger cells because cells repeat S phase without entering M phase [20].…”

Section: Experimental Test: Higher Apical Area Variability Results Inmentioning

confidence: 99%

“…To this end, we induced the expression of an RNAi targeting the growth regulator gigas/TSC2 [20] in cell patches randomly located within Drosophila wing discs. gigas attenuation results in larger cells because cells repeat S phase without entering M phase [20]. Indeed, in mosaic gigas/TCS-RNAi wing discs we observe cells with substantially larger apical areas than in the control, scattered throughout the epithelium (Fig.…”

Section: Experimental Test: Higher Apical Area Variability Results Inmentioning

confidence: 99%

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Minimisation of surface energy drives apical epithelial organisation and gives rise to Lewis’ law

Kokic

Iannini

Villa-Fombuena

et al. 2019

Preprint

100

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The packing of cells in epithelia exhibits striking regularities, regardless of the organism and organ. One of these regularities is expressed in Lewis' law, which states that the average apical cell area is linearly related to the number of neighbours, such that cells with larger apical area have on average more neighbours. The driving forces behind the almost 100-year old Lewis' law have remained elusive. We now provide evidence that the observed apical epithelial packing minimizes surface energy at the intercellular apical adhesion belt. Lewis' law emerges because the apical cell surfaces then assume the most regular polygonal shapes within a contiguous lattice, thus minimising the average perimeter per cell, and thereby surface energy. We predict that the linear Lewis' law generalizes to a quadratic law if the variability in apical areas is increased beyond what is normally found in epithelia. We confirm this prediction experimentally by generating heterogeneity in cell growth in Drosophila epithelia. Our discovery provides a link between epithelial organisation, cell division and growth and has implications for the general understanding of epithelial dynamics.

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Section: Experimental Test: Higher Apical Area Variability Results Inmentioning

confidence: 99%

Section: Experimental Test: Higher Apical Area Variability Results Inmentioning

confidence: 99%

Minimisation of surface energy drives apical epithelial organisation and gives rise to Lewis’ law

Kokic

Iannini

Villa-Fombuena

et al. 2019

Preprint

100

View full text Add to dashboard Cite

show abstract

“…This over-simplification is standard in the field and can possibly provide a plausible, yet basic, understanding of tissue remodeling. However, recent discoveries about the cellular behavior in 3D environments when tissues are subjected to some level of curvature, point towards an intriguing and important role of spatial T1 transitions [50]. In that regard, to what extent the framework presented here depends on the 3D structure of the cells is an interesting subject for further studies.…”

Section: Discussionmentioning

confidence: 94%

Self-sustained Planar Intercalations due to Mechanosignaling Feedbacks Lead to Robust Axis Extension during Morphogenesis

Anbari

Buceta

2019

Preprint

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“…The interplay between different fields of basic science has been revealed as an efficient way to advance in medicine. Physics and mathematics‐related terms like tensegrity, topology and tessellations (see Glossary) are now used to improve understanding of biology and biomedicine . In parallel, a robust and efficient analysis of histopathological images is required due to their increasingly accepted use.…”

Section: Introductionmentioning

confidence: 99%

“…Physics and mathematics-related terms like tensegrity, topology and tessellations (see Glossary) are now used to improve understanding of biology and biomedicine. [1][2][3] In parallel, a robust and efficient analysis of histopathological images is required due to their increasingly accepted use. Image analysis landscape has enormous potential to improve the quality of histological image interpretation, supporting without overruling pathologists in decision-making.…”

Section: Introductionmentioning

confidence: 99%

The topology of vitronectin: A complementary feature for neuroblastoma risk classification based on computer‐aided detection

Vicente‐Munuera

Burgos‐Panadero

Noguera

et al. 2019

Intl Journal of Cancer

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Tumors are complex networks of constantly interacting elements: tumor cells, stromal cells, immune and stem cells, blood/lympathic vessels, nerve fibers and extracellular matrix components. These elements can influence their microenvironment through mechanical and physical signals to promote tumor cell growth. To get a better understanding of tumor biology, cooperation between multidisciplinary fields is needed. Diverse mathematic computations and algorithms have been designed to find prognostic targets and enhance diagnostic assessment. In this work, we use computational digital tools to study the topology of vitronectin, a glycoprotein of the extracellular matrix. Vitronectin is linked to angiogenesis and migration, two processes closely related to tumor cell spread. Here, we investigate whether the distribution of this molecule in the tumor stroma may confer mechanical properties affecting neuroblastoma aggressiveness. Combining image analysis and graph theory, we analyze different topological features that capture the organizational cues of vitronectin in histopathological images taken from human samples. We find that the Euler number and the branching of territorial vitronectin, two topological features, could allow for a more precise pretreatment risk stratification to guide treatment strategies in neuroblastoma patients. A large amount of recently synthesized VN would create migration tracks, pinpointed by both topological features, for malignant neuroblasts, so that dramatic change in the extracellular matrix would increase tumor aggressiveness and worsen patient outcomes.

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Scutoids are a geometrical solution to three-dimensional packing of epithelia

Cited by 116 publications

References 68 publications

Minimisation of surface energy drives apical epithelial organisation and gives rise to Lewis’ law

Minimisation of surface energy drives apical epithelial organisation and gives rise to Lewis’ law

Self-sustained Planar Intercalations due to Mechanosignaling Feedbacks Lead to Robust Axis Extension during Morphogenesis

The topology of vitronectin: A complementary feature for neuroblastoma risk classification based on computer‐aided detection

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