Orchestration of tissue‐scale mechanics and fate decisions by polarity signalling

Gomes, Martim; Iden, Sandra

doi:10.15252/embj.2020106787

Cited by 6 publications

(4 citation statements)

References 171 publications

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“…The epidermis is an excellent example of a polarized tissue. The polarity machinery, cellular adhesion and mechanical forces are coordinated to shape epidermal development and morphogenesis [ 133 ]. As mentioned, IGF-1/PI3K/mTORC2 signaling axis is crucial for epidermal stratification and barrier formation.…”

Section: Concluding Remarks and Perspectivesmentioning

confidence: 99%

Role of mTOR Signaling Cascade in Epidermal Morphogenesis and Skin Barrier Formation

Wang

Eming

Ding

2022

Biology

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The skin epidermis, with its capacity for lifelong self-renewal and rapid repairing response upon injury, must maintain an active status in metabolism. Mechanistic target of rapamycin (mTOR) signaling is a central controller of cellular growth and metabolism that coordinates diverse physiological and pathological processes in a variety of tissues and organs. Recent evidence with genetic mouse models highlights an essential role of the mTOR signaling network in epidermal morphogenesis and barrier formation. In this review, we focus on the recent advances in understanding how mTOR signaling networks, including upstream inputs, kinases and downstream effectors, regulate epidermal morphogenesis and skin barrier formation. Understanding the details of the metabolic signaling will be critical for the development of novel pharmacological approaches to promote skin barrier regeneration and to treat epidermal barrier defect-associated diseases.

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Section: Concluding Remarks and Perspectivesmentioning

confidence: 99%

Role of mTOR Signaling Cascade in Epidermal Morphogenesis and Skin Barrier Formation

Wang

Eming

Ding

2022

Biology

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“…Its outermost stratified epidermis is continuous with epidermal appendages like hair follicles and sweat glands (Chuong and Noveen, 1999). Proliferative, undifferentiated basal layer keratinocytes (KCs) attach to the underlying basement membrane and, following asymmetric cell division or delamination, progressively differentiate to constitute the spinous, granular and cornified layers (Blanpain and Fuchs, 2006;Dias Gomes and Iden, 2021;Gonzales and Fuchs, 2017;Ray and Lechler, 2011). The epidermis also hosts other resident cell types with crucial functions for the organism: neural-crest derived melanocytes (MCs) provide melanin for hair colorization and to protect KCs from ultraviolet (UV) damage (D'Orazio et al, 2013), whereas Langerhans cells (LCs) and dendritic epidermal T cells (DETCs) constitute a first line of defense against environmental pathogens and malignant transformation in murine skin (Deckers et al, 2018;MacLeod et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Lrig1- and Wnt-dependent niches dictate segregation of resident immune cells and melanocytes in murine tail epidermis

et al. 2022

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The barrier-forming, self-renewing mammalian epidermis comprises keratinocytes, pigment-producing melanocytes, and resident immune cells as first-line host defense. In murine tail skin, interfollicular epidermis patterns into pigmented ′scale′ and hypopigmented ′interscale′ epidermis. Why and how mature melanocytes accumulate in scale epidermis is unresolved. Here, we delineate a cellular hierarchy among epidermal cell types that determines skin patterning. Already during postnatal development, melanocytes co-segregate with newly forming scale compartments. Intriguingly, this process coincides with partitioning of both Langerhans cells and dendritic epidermal T-cells to interscale epidermis, suggesting functional segregation of pigmentation and immune surveillance. Analysis of non-pigmented mice and of mice lacking melanocytes or resident immune cells revealed that immunocyte patterning is melanocyte- and melanin-independent, and, vice versa, immune cells do not control melanocyte localization. Instead, genetically enforced progressive scale fusion upon Lrig1 deletion showed that melanocytes and immune cells dynamically follow epithelial scale:interscale patterns. Importantly, disrupting Wnt-Lef1 function in keratinocytes caused melanocyte mislocalization to interscale epidermis, implicating canonical Wnt signaling in organizing the pigmentation pattern. Together, this work uncovered cellular and molecular principles underlying the compartmentalization of tissue functions in skin.

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“…The three-dimensional shape of cells is often not uniform. Cells can polarize with asymmetrically distributed subcellular organelles or molecules along one or more axes, thus executing unique physiological functions. − For example, embryonic development and stem cell asymmetric division rely on the establishment of anterior-posterior or apical-basal polarity, respectively, to generate daughter cells with distinct fates; , the differences in morphology and structure between the apical and basal domains of epithelial cells ensure their exocrine, absorptive, and barrier functions . Extensive investigations on cell polarity reveal that the asymmetric clustering of certain proteins (e.g., the evolutionarily conserved Par3/Par6/aPKC complex) beneath local membrane regions is a common phenomenon and prerequisite for the establishment of polarity.…”

Section: Introductionmentioning

confidence: 99%

Phase Separation in Cell Polarity

Wei

Wen

2021

Biochemistry

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Cells are biochemically and morphologically polarized, which allows them to produce different cell shapes for various functions. Remarkably, some polarity protein complexes are asymmetrically recruited and concentrated on limited membrane regions, which is essential for the establishment and maintenance of diverse cell polarity. Though the components and mutual interactions within these protein complexes have been extensively investigated, how these proteins autonomously concentrate at local membranes and whether they have the same organization mechanism in the condensed assembly as that in aqueous solution remain elusive. A number of recent studies suggest that these highly concentrated polarity protein assemblies are membraneless biomolecular condensates which form through liquid–liquid phase separation (LLPS) of specific proteins. In this perspective, we summarize the LLPS-driven condensed protein assemblies found in asymmetric cell division, epithelial cell polarity, and neuronal synapse formation and function. These findings suggest that LLPS may be a general strategy for cells to achieve local condensation of specific proteins, thus establishing cell polarity.

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Orchestration of tissue‐scale mechanics and fate decisions by polarity signalling

Cited by 6 publications

References 171 publications

Role of mTOR Signaling Cascade in Epidermal Morphogenesis and Skin Barrier Formation

Role of mTOR Signaling Cascade in Epidermal Morphogenesis and Skin Barrier Formation

Lrig1- and Wnt-dependent niches dictate segregation of resident immune cells and melanocytes in murine tail epidermis

Phase Separation in Cell Polarity

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