Actomyosin, vimentin and LINC complex pull on osteosarcoma nuclei to deform on micropillar topography

Wakhloo, Nayana Tusamda; Anders, Sebastian; Badique, Florent; Eichhorn, Mélanie; Brigaud, Isabelle; Petithory, Tatiana; Vassaux, Maxime; Milan, Jean-Louis; Freund, Jean‐Noël; Rühe, Jürgen; Davidson, Patricia M.; Pieuchot, Laurent; Anselme, Karine

doi:10.1101/822445

Cited by 7 publications

(8 citation statements)

References 38 publications

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“…[50] Furthermore, it was shown that when nesprins were knockdown in osteosarcoma cells, their nuclear deformability was decreased which proved the essential role of nesprins in actomyosin contractility and nucleo-cytoskeletal connections. [51] In summary, based on the results and the literature data, we confirm that in addition to the actin cytoskeleton, nuclear envelope protein Lamin A/C and LINC protein Nesprin-2 have fundamental roles in nuclear localization and in intercellular interactions between inner nuclear and outer cytoskeletal components of the cells.…”

Section: Expression Of Lamin A/c and Nesprin-2 Before And After Drug supporting

confidence: 78%

“…The reason of the loss of deformation can be explained with the need of actomyosin contractility for the movement and dislocation of the cells and their nuclei. [49][50][51] Lamin A/C and Nesprin-2 directly interact with actin filaments of the cells. CytoD caused the disruption of actin filament formation by inhibiting their polymerization, and therefore, cells lost actomyosin contractility, the transfer of mechanobiological stimuli is hampered and therefore, deformability is decreased.…”

Section: Expression Of Lamin A/c and Nesprin-2 Before And After Drug mentioning

confidence: 99%

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Micropatterned Surfaces Expose the Coupling between Actin Cytoskeleton‐Lamin/Nesprin and Nuclear Deformability of Breast Cancer Cells with Different Malignancies

2020

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Mechanotransduction proteins transfer mechanical stimuli through nucleo‐cytoskeletal coupling and affect the nuclear morphology of cancer cells. However, the contribution of actin filament integrity has never been studied directly. It is hypothesized that differences in nuclear deformability of cancer cells are influenced by the integrity of actin filaments. In this study, transparent micropatterned surfaces as simple tools to screen cytoskeletal and nuclear distortions are presented. Surfaces decorated with micropillars are used to culture and image breast cancer cells and quantify their deformation using shape descriptors (circularity, area, perimeter). Using two drugs (cytochalasin D and jasplakinolide), actin filaments are disrupted. Deformation of cells on micropillars is decreased upon drug treatment as shown by increased circularity. However, the effect is much smaller on benign MCF10A than on malignant MCF7 and MDAMB231 cells. On micropatterned surfaces, molecular analysis shows that Lamin A/C and Nesprin‐2 expressions decreased but, after drug treatment, increased in malignant cells but not in benign cells. These findings suggest that Lamin A/C, Nesprin‐2 and actin filaments are critical in mechanotransduction of cancer cells. Consequently, transparent micropatterned surfaces can be used as image analysis platforms to provide robust, high throughput measurements of nuclear deformability of cancer cells, including the effect of cytoskeletal elements.

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Section: Expression Of Lamin A/c and Nesprin-2 Before And After Drug supporting

confidence: 78%

Section: Expression Of Lamin A/c and Nesprin-2 Before And After Drug mentioning

confidence: 99%

Micropatterned Surfaces Expose the Coupling between Actin Cytoskeleton‐Lamin/Nesprin and Nuclear Deformability of Breast Cancer Cells with Different Malignancies

2020

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“…Defective nuclear mechanosensing was evidenced by downregulation of Lamin A/C mRNA expression and corresponded to up-regulated HDAC mRNA expression and lower histone acetylation, thereby suggesting reduced bone regenerative capacity. The cytoskeleton, LINC complex, and the physical attachment to nuclear lamins have been shown to be highly important in nuclear integrity, chromatin remodeling, and subsequent differentiation or cell reprogramming (34,35). Multiple mechanisms have been suggested for Lamin A/C contribution to transcriptional changes.…”

Section: Discussionmentioning

confidence: 99%

Nuclear mechanosensing controls MSC osteogenic potential through HDAC epigenetic remodeling

Killaars

Walker

Anseth

2020

Proc. Natl. Acad. Sci. U.S.A.

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Cells sense mechanical cues from the extracellular matrix to regulate cellular behavior and maintain tissue homeostasis. The nucleus has been implicated as a key mechanosensor and can directly influence chromatin organization, epigenetic modifications, and gene expression. Dysregulation of nuclear mechanosensing has been implicated in several diseases, including bone degeneration. Here, we exploit photostiffening hydrogels to manipulate nuclear mechanosensing in human mesenchymal stem cells (hMSCs) in vitro. Results show that hMSCs respond to matrix stiffening by increasing nuclear tension and causing an increase in histone acetylation via deactivation of histone deacetylases (HDACs). This ultimately induces osteogenic fate commitment. Disrupting nuclear mechanosensing by disconnecting the nucleus from the cytoskeleton up-regulates HDACs and prevents osteogenesis. Resetting HDAC activity back to healthy levels rescues the epigenetic and osteogenic response in hMSCs with pathological nuclear mechanosensing. Notably, bone from patients with osteoarthritis displays similar defective nuclear mechanosensing. Collectively, our results reveal that nuclear mechanosensing controls hMSC osteogenic potential mediated by HDAC epigenetic remodeling and that this cellular mechanism is likely relevant to bone-related diseases.

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“…It has been widely known that 2D geometry can affect diverse cellular responses such as cell shape, proliferation, differentiation, mechanoresponsive marker expression, and underlying mechanism has been suggested that confined adhesive area which can be tuned by geometry of 2D patterns cause interfacial tension at the boundary [ 6 , 12 ]. As both topography and adhesiveness of the surface may play essential roles in cellular behavior [ 43 ], we treat the whole surface of the 3D geometry to be adhesive so that we can elucidate the roles of 3D geometry independent of chemical adhesiveness.…”

Section: Discussionmentioning

confidence: 99%

Mechanical Adaptations of Epithelial Cells on Various Protruded Convex Geometries

Granick

et al. 2020

Cells

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The shape of epithelial tissue supports physiological functions of organs such as intestinal villi and corneal epithelium. Despite the mounting evidence showing the importance of geometry in tissue microenvironments, the current understanding on how it affects biophysical behaviors of cells is still elusive. Here, we cultured cells on various protruded convex structure such as triangle, square, and circle shape fabricated using two-photon laser lithography and quantitatively analyzed individual cells. Morphological data indicates that epithelial cells can sense the sharpness of the corner by showing the characteristic cell alignments, which was caused by actin contractility. Cell area was mainly influenced by surface convexity, and Rho-activation increased cell area on circle shape. Moreover, we found that intermediate filaments, vimentin, and cytokeratin 8/18, play important roles in growth and adaptation of epithelial cells by enhancing expression level on convex structure depending on the shape. In addition, microtubule building blocks, α-tubulin, was also responded on geometric structure, which indicates that intermediate filaments and microtubule can cooperatively secure mechanical stability of epithelial cells on convex surface. Altogether, the current study will expand our understanding of mechanical adaptations of cells on out-of-plane geometry.

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Actomyosin, vimentin and LINC complex pull on osteosarcoma nuclei to deform on micropillar topography

Cited by 7 publications

References 38 publications

Micropatterned Surfaces Expose the Coupling between Actin Cytoskeleton‐Lamin/Nesprin and Nuclear Deformability of Breast Cancer Cells with Different Malignancies

Micropatterned Surfaces Expose the Coupling between Actin Cytoskeleton‐Lamin/Nesprin and Nuclear Deformability of Breast Cancer Cells with Different Malignancies

Nuclear mechanosensing controls MSC osteogenic potential through HDAC epigenetic remodeling

Mechanical Adaptations of Epithelial Cells on Various Protruded Convex Geometries

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