Tailoring Cellular Function: The Contribution of the Nucleus in Mechanotransduction

Pennacchio, Fabrizio Andrea; Nastały, Paulina; Poli, Alessandro; Maiuri, Paolo

doi:10.3389/fbioe.2020.596746

Cited by 17 publications

(17 citation statements)

References 174 publications

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“…217 The nuclear LINC complex is located below the nuclear envelope and contains lamin, nesprins, and Sad1 and UNC-84 (SUN) proteins. 218,219 Mechanical deformation of the nucleus induces changes in chromatin organization by a mechanism depending on intracellular calcium release and leading to softening of the nuclear envelope, which is crucial in preventing stretch-induced DNA damage. 220,221 There is also a linear scaling relation between collagen content in the ECM and lamin A contents in the nuclear envelope across different stages of fibrosis, indicating that ECM conditions reflect nuclear mechanics and signaling.…”

Section: Cytoskeleton and Nucleus In Mechanosensation And Mechanotransductionmentioning

confidence: 99%

A story of fibers and stress: Matrix‐embedded signals for fibroblast activation in the skin

Sawant

Hinz

Schönborn

et al. 2021

Wound Repair Regeneration

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Our skin is continuously exposed to mechanical challenge, including shear, stretch, and compression. The extracellular matrix of the dermis is perfectly suited to resist these challenges and maintain integrity of normal skin even upon large strains. Fibroblasts are the key cells that interpret mechanical and chemical cues in their environment to turnover matrix and maintain homeostasis in the skin of healthy adults. Upon tissue injury, fibroblasts and an exclusive selection of other cells become activated into myofibroblasts with the task to restore skin integrity by forming structurally imperfect but mechanically stable scar tissue. Failure of myofibroblasts to terminate their actions after successful repair or upon chronic inflammation results in dysregulated myofibroblast activities which can lead to hypertrophic scarring and/or skin fibrosis. After providing an overview on the major fibrillar matrix components in normal skin, we will interrogate the various origins of fibroblasts and myofibroblasts in the skin. We then examine the role of the matrix as signaling hub and how fibroblasts respond to mechanical matrix cues to restore order in the confusing environment of a healing wound.

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Section: Cytoskeleton and Nucleus In Mechanosensation And Mechanotransductionmentioning

confidence: 99%

A story of fibers and stress: Matrix‐embedded signals for fibroblast activation in the skin

Sawant

Hinz

Schönborn

et al. 2021

Wound Repair Regeneration

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“…However, it is important to consider that the augmentation of cytoskeletal stiffness could be not the direct consequence of the nuclear expansion, but the cause of this phenomenon. In fact, contractile actin structures, thanks to the LINC complex (Linker of Nucleoskeleton and CSK), can directly transmit mechanical forces to the nucleus and the genome at its interior, change its shape and regulate gene expression [ 75 ]. In particular, it has been demonstrated that a strict correlation exists between CSK organization, cell spreading and nuclear shape [ 76 ], indicating that the increased content of F-actin and the cell stiffening could be responsible for changes in nuclear shape.…”

Section: Radiation Effects On the Actin Cskmentioning

confidence: 99%

Cytoskeleton Response to Ionizing Radiation: A Brief Review on Adhesion and Migration Effects

et al. 2021

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The cytoskeleton is involved in several biological processes, including adhesion, motility, and intracellular transport. Alterations in the cytoskeletal components (actin filaments, intermediate filaments, and microtubules) are strictly correlated to several diseases, such as cancer. Furthermore, alterations in the cytoskeletal structure can lead to anomalies in cells’ properties and increase their invasiveness. This review aims to analyse several studies which have examined the alteration of the cell cytoskeleton induced by ionizing radiations. In particular, the radiation effects on the actin cytoskeleton, cell adhesion, and migration have been considered to gain a deeper knowledge of the biophysical properties of the cell. In fact, the results found in the analysed works can not only aid in developing new diagnostic tools but also improve the current cancer treatments.

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“…Almost three decades ago, INGBER [73][74][75] coined the term "tensegrity" (tension integration) to describe the information-conducting mechanism through which deformation of cells causes disruption of the self-supporting cortical actin cytoskeleton that is relayed throughout the cell and contributes to mechanosignalling. The actin cytoskeleton also physically interacts with the nuclear lamina, and in this way directly changes the chromatin structure and thus gene expression [76,77]. The tensegrity of cyclically stretched substrates (lungs) has been mathematically modelled [78].…”

Section: Ecm Biomechanics Impact Of Ecm Biomechanics In Terms Of Cell...mentioning

confidence: 99%

Chronic lung diseases: entangled in extracellular matrix

Burgess

Harmsen

2022

Eur Respir Rev

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The extracellular matrix (ECM) is the scaffold that provides structure and support to all organs, including the lung; however, it is also much more than this. The ECM provides biochemical and biomechanical cues to cells that reside or transit through this micro-environment, instructing their responses. The ECM structure and composition changes in chronic lung diseases; how such changes impact disease pathogenesis is not as well understood. Cells bind to the ECM through surface receptors, of which the integrin family is one of the most widely recognised. The signals that cells receive from the ECM regulate their attachment, proliferation, differentiation, inflammatory secretory profile and survival. There is extensive evidence documenting changes in the composition and amount of ECM in diseased lung tissues. However, changes in the topographical arrangement, organisation of the structural fibres and stiffness (or viscoelasticity) of the matrix in which cells are embedded have an undervalued but strong impact on cell phenotype. The ECM in diseased lungs also changes in physical and biomechanical ways that drive cellular responses. The characteristics of these environments alter cell behaviour and potentially orchestrate perpetuation of lung diseases. Future therapies should target ECM remodelling as much as the underlying culprit cells.

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Tailoring Cellular Function: The Contribution of the Nucleus in Mechanotransduction

Cited by 17 publications

References 174 publications

A story of fibers and stress: Matrix‐embedded signals for fibroblast activation in the skin

A story of fibers and stress: Matrix‐embedded signals for fibroblast activation in the skin

Cytoskeleton Response to Ionizing Radiation: A Brief Review on Adhesion and Migration Effects

Chronic lung diseases: entangled in extracellular matrix

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