Apical constriction induces tissue rupture in a proliferative epithelium

Osswald, Mariana; Barros-Carvalho, André; Carmo, Ana M.; Loyer, Nicolas; Grácio, Patrícia; Sunkel, Cláudio E.; Homem, Catarina C.F.; Januschke, Jens; Morais-de-Sá, Eurico

doi:10.1101/2022.03.02.482459

Cited by 2 publications

(1 citation statement)

References 112 publications

(152 reference statements)

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“…In vivo failure of adherens junctions 24 , 66 , polarity 67 , increased mechanical load 23 and post-apoptotic failure in sealing 68 , 69 leads to hole formation in tissues. During morphogenesis, hole formation is not only essential for Drosophila peripodium elongation 21 but is also crucial for macrophage invasion during Drosophila development 8 .…”

Section: Discussionmentioning

confidence: 99%

Mechanical stress driven by rigidity sensing governs epithelial stability

et al. 2022

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Epithelia act as a barrier against environmental stress and abrasion and in vivo they are continuously exposed to environments of various mechanical properties. The impact of this environment on epithelial integrity remains elusive. By culturing epithelial cells on 2D hydrogels, we observe a loss of epithelial monolayer integrity through spontaneous hole formation when grown on soft substrates. Substrate stiffness triggers an unanticipated mechanical switch of epithelial monolayers from tensile on soft to compressive on stiff substrates. Through active nematic modelling, we find that spontaneous half-integer defect formation underpinning large isotropic stress fluctuations initiate hole opening events. Our data show that monolayer rupture due to high tensile stress is promoted by the weakening of cell-cell junctions that could be induced by cell division events or local cellular stretching. Our results show that substrate stiffness provides feedback on monolayer mechanical state and that topological defects can trigger stochastic mechanical failure, with potential application towards a mechanistic understanding of compromised epithelial integrity during immune response and morphogenesis.

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Section: Discussionmentioning

confidence: 99%

Mechanical stress driven by rigidity sensing governs epithelial stability

et al. 2022

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Rap1 uses Canoe-dependent and Canoe-independent mechanisms to regulate apical contractility and allow embryonic morphogenesis without tissue disruption

Perez-Vale

Yow

et al. 2022

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Embryonic morphogenesis is powered by dramatic changes in cell shape and arrangement, driven by the cytoskeleton and its connections to adherens junctions. This requires robust linkage, allowing morphogenesis without disrupting tissue integrity. The small GTPase Rap1 is a key regulator of cell adhesion, controlling both cadherin-mediated and integrin-mediated processes. We have defined multiple roles in morphogenesis for one Rap1 effector, Canoe/Afadin, which ensures robust junction-cytoskeletal linkage. We now ask what mechanisms regulate Canoe and other junction-cytoskeletal linkers during Drosophila morphogenesis, defining roles for Rap1 and one of its guanine nucleotide exchange factor (GEF) regulators, Dizzy. Rap1 uses Canoe as one effector, regulating junctional planar polarity. However, Rap1 has additional roles in junctional protein localization and balanced apical constriction; in its absence, Bazooka/Par3 localization is fragmented, and cells next to mitotic cells apically constrict and invaginate, disrupting epidermal integrity. In contrast, the GEF Dizzy has phenotypes similar to but slightly less severe than Canoe loss, suggesting this GEF regulates Rap1 action via Canoe. Taken together, these data reveal that Rap1 is a crucial regulator of morphogenesis, likely acting in parallel via Canoe and other effectors, and that different Rap1 GEFs regulate distinct functions of Rap1.

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Apical constriction induces tissue rupture in a proliferative epithelium

Cited by 2 publications

References 112 publications

Mechanical stress driven by rigidity sensing governs epithelial stability

Mechanical stress driven by rigidity sensing governs epithelial stability

Rap1 uses Canoe-dependent and Canoe-independent mechanisms to regulate apical contractility and allow embryonic morphogenesis without tissue disruption

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