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  • 1.
    López-Guajardo, A.
    et al.
    University of Sheffield, UK.
    Zafar, A.
    University of Sheffield, UK.
    Al Hennawi, K.
    University of Sheffield, UK.
    Rossi, V.
    Veneto Institute of Oncology IOV-IRCCS, Italy.
    Alrwaili, A.
    University of Sheffield, UK.
    Medcalf, J. D.
    University of Sheffield, UK.
    Dunning, M.
    University of Sheffield, UK.
    Nordgren, Niklas
    RISE Research Institutes of Sweden, Bioeconomy and Health, Material and Surface Design.
    Pettersson, T.
    KTH Royal Institute of Technology, Sweden.
    Estabrook, I. D.
    University of Sheffield, UK; Technische Universität Dresden, Germany.
    Hawkins, R. J.
    University of Sheffield, UK; African Institute for Mathematical Sciences, Ghana.
    Gad, A. K. B.
    University of Sheffield, UK; University of Madeira, Portugal; Karolinska Institute, Sweden.
    Regulation of cellular contractile force, shape and migration of fibroblasts by oncogenes and Histone deacetylase 62023In: Frontiers in Molecular Biosciences, E-ISSN 2296-889X, Vol. 10, article id 1197814Article in journal (Refereed)
    Abstract [en]

    The capacity of cells to adhere to, exert forces upon and migrate through their surrounding environment governs tissue regeneration and cancer metastasis. The role of the physical contractile forces that cells exert in this process, and the underlying molecular mechanisms are not fully understood. We, therefore, aimed to clarify if the extracellular forces that cells exert on their environment and/or the intracellular forces that deform the cell nucleus, and the link between these forces, are defective in transformed and invasive fibroblasts, and to indicate the underlying molecular mechanism of control. Confocal, Epifluorescence and Traction force microscopy, followed by computational analysis, showed an increased maximum contractile force that cells apply on their environment and a decreased intracellular force on the cell nucleus in the invasive fibroblasts, as compared to normal control cells. Loss of HDAC6 activity by tubacin-treatment and siRNA-mediated HDAC6 knockdown also reversed the reduced size and more circular shape and defective migration of the transformed and invasive cells to normal. However, only tubacin-mediated, and not siRNA knockdown reversed the increased force of the invasive cells on their surrounding environment to normal, with no effects on nuclear forces. We observed that the forces on the environment and the nucleus were weakly positively correlated, with the exception of HDAC6 siRNA-treated cells, in which the correlation was weakly negative. The transformed and invasive fibroblasts showed an increased number and smaller cell-matrix adhesions than control, and neither tubacin-treatment, nor HDAC6 knockdown reversed this phenotype to normal, but instead increased it further. This highlights the possibility that the control of contractile force requires separate functions of HDAC6, than the control of cell adhesions, spreading and shape. These data are consistent with the possibility that defective force-transduction from the extracellular environment to the nucleus contributes to metastasis, via a mechanism that depends upon HDAC6. To our knowledge, our findings present the first correlation between the cellular forces that deforms the surrounding environment and the nucleus in fibroblasts, and it expands our understanding of how cells generate contractile forces that contribute to cell invasion and metastasis. Copyright © 2023 López-Guajardo, Zafar, Al Hennawi, Rossi, Alrwaili, Medcalf, Dunning, Nordgren, Pettersson, Estabrook, Hawkins and Gad.

  • 2.
    Nilsson, Patrik
    et al.
    RISE Research Institutes of Sweden.
    Engström, Åsa
    RISE Research Institutes of Sweden.
    Kaschuk, J J
    Aalto University, Finland.
    Vapaavuori, Jaana
    Aalto University, Finland.
    Larsson, Arvid
    Lund University, Sweden.
    Abitbol, Tiffany
    RISE Research Institutes of Sweden. EPFL, Switzerland.
    Design of experiments to investigate multi-additive cellulose nanocrystal films2022In: Frontiers in Molecular Biosciences, E-ISSN 2296-889X, Vol. 9, article id 988600Article in journal (Refereed)
    Abstract [en]

    Cellulose nanocrystal (CNC) suspensions can self-assemble into chiral nematic films upon the slow evaporation of water. These films are brittle, as indicated by their fracturing instead of plastically deforming once they are fully elastically deformed. This aspect can be mediated to some extent by plasticizing additives, such as glucose and glycerol, however, few reports consider more than one additive at a time or address the influence of additive content on the homogeneity of the self-assembled structure. In this work, design of experiments (DoE) was used to empirically model complex film compositions, attempting to relate additive concentrations in dilute suspension to film properties, and to understand whether outcome specific predictions are possible using this approach. We demonstrate that DoE can be used to predict film properties in multi-additive systems, without consideration given to the different phenomena that occur along the drying process or to the nature of the additives. Additionally, a homogeneity metric is introduced in relation to chiral nematic organization in CNC films, with most of the additive-containing compositions in this work found to reduce the homogeneity of the self-assembly relative to pure CNC films. Copyright © 2022 Nilsson, Engström, Kaschuk, Vapaavuori, Larsson and Abitbol.

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