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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.
    Ranji, Parmida
    et al.
    University of Gothenburg, Sweden.
    Jonasson, Emma
    University of Gothenburg, Sweden.
    Andersson, Lisa
    University of Gothenburg, Sweden.
    Filges, Stefan
    University of Gothenburg, Sweden.
    Luna Santamaría, Manuel
    University of Gothenburg, Sweden.
    Vannas, Christoffer
    University of Gothenburg, Sweden; Sahlgrenska University Hospital, Sweden.
    Dolatabadi, Soheila
    University of Gothenburg, Sweden.
    Gustafsson, Anna
    University of Gothenburg, Sweden.
    Myklebost, Ola
    Oslo University Hospital, Norway; University of Bergen, Norway.
    Håkansson, Joakim
    RISE Research Institutes of Sweden, Materials and Production, Methodology, Textiles and Medical Technology. University of Gothenburg, Sweden.
    Fagman, Henrik
    University of Gothenburg, Sweden; Sahlgrenska University Hospital, Sweden.
    Landberg, Göran
    University of Gothenburg, Sweden; Sahlgrenska University Hospital, Sweden.
    Åman, Pierre
    University of Gothenburg, Sweden; Sahlgrenska University Hospital, Sweden.
    Ståhlberg, Anders
    University of Gothenburg, Sweden; Sahlgrenska University Hospital, Sweden.
    Deciphering the role of FUS::DDIT3 expression and tumor microenvironment in myxoid liposarcoma development2024In: Journal of Translational Medicine, E-ISSN 1479-5876, Vol. 22, article id 389Article in journal (Refereed)
    Abstract [en]

    Background: Myxoid liposarcoma (MLS) displays a distinctive tumor microenvironment and is characterized by the FUS::DDIT3 fusion oncogene, however, the precise functional contributions of these two elements remain enigmatic in tumor development. Methods: To study the cell-free microenvironment in MLS, we developed an experimental model system based on decellularized patient-derived xenograft tumors. We characterized the cell-free scaffold using mass spectrometry. Subsequently, scaffolds were repopulated using sarcoma cells with or without FUS::DDIT3 expression that were analyzed with histology and RNA sequencing. Results: Characterization of cell-free MLS scaffolds revealed intact structure and a large variation of protein types remaining after decellularization. We demonstrated an optimal culture time of 3 weeks and showed that FUS::DDIT3 expression decreased cell proliferation and scaffold invasiveness. The cell-free MLS microenvironment and FUS::DDIT3 expression both induced biological processes related to cell-to-cell and cell-to-extracellular matrix interactions, as well as chromatin remodeling, immune response, and metabolism. Data indicated that FUS::DDIT3 expression more than the microenvironment determined the pre-adipocytic phenotype that is typical for MLS. Conclusions: Our experimental approach opens new means to study the tumor microenvironment in detail and our findings suggest that FUS::DDIT3-expressing tumor cells can create their own extracellular niche.

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  • 3.
    Rosendahl, Jennifer
    et al.
    RISE Research Institutes of Sweden, Materials and Production, Chemistry, Biomaterials and Textiles.
    Svanström, Andreas
    University of Gothenburg, Sweden.
    Berglin, Mattias
    RISE Research Institutes of Sweden, Materials and Production, Chemistry, Biomaterials and Textiles.
    Petronis, Sarunas
    RISE Research Institutes of Sweden, Materials and Production, Chemistry, Biomaterials and Textiles.
    Bogestål, Yalda
    RISE Research Institutes of Sweden, Materials and Production, Chemistry, Biomaterials and Textiles.
    Stenlund, Patrik
    RISE Research Institutes of Sweden, Materials and Production, Chemistry, Biomaterials and Textiles.
    Standoft, Simon
    RISE Research Institutes of Sweden, Materials and Production, Chemistry, Biomaterials and Textiles.
    Ståhlberg, Anders
    University of Gothenburg, Sweden; Sahlgrenska University Hospital, Sweden.
    Landberg, Göran
    University of Gothenburg, Sweden; Sahlgrenska University Hospital, Sweden.
    Chinga-Carrasco, Gary
    RISE Research Institutes of Sweden, Bioeconomy and Health, Material and Surface Design. University of Gothenburg, Sweden.
    Håkansson, Joakim
    University of Gothenburg, Sweden.
    3D Printed Nanocellulose Scaffolds as a Cancer Cell Culture Model System2021In: Bioengineering, E-ISSN 2306-5354, Vol. 8, no 7, article id 97Article in journal (Refereed)
    Abstract [en]

    Current conventional cancer drug screening models based on two-dimensional (2D) cell culture have several flaws and there is a large need of more in vivo mimicking preclinical drug screening platforms. The microenvironment is crucial for the cells to adapt relevant in vivo characteristics and here we introduce a new cell culture system based on three-dimensional (3D) printed scaffolds using cellulose nanofibrils (CNF) pre-treated with 2,2,6,6-tetramethylpyperidine-1-oxyl (TEMPO) as the structural material component. Breast cancer cell lines, MCF7 and MDA-MB-231, were cultured in 3D TEMPO-CNF scaffolds and were shown by scanning electron microscopy (SEM) and histochemistry to grow in multiple layers as a heterogenous cell population with different morphologies, contrasting 2D cultured mono-layered cells with a morphologically homogenous cell population. Gene expression analysis demonstrated that 3D TEMPO-CNF scaffolds induced elevation of the stemness marker CD44 and the migration markers VIM and SNAI1 in MCF7 cells relative to 2D control. T47D cells confirmed the increased level of the stemness marker CD44 and migration marker VIM which was further supported by increased capacity of holoclone formation for 3D cultured cells. Therefore, TEMPO-CNF was shown to represent a promising material for 3D cell culture model systems for cancer cell applications such as drug screening.

  • 4.
    Zhang, Heyang
    et al.
    Ghent University, Belgium.
    Bussmann, Jeroen
    Leiden University, Netherlands.
    Huhnke, Florian
    Max Planck Institute for Medical Research, Germany.
    Devoldere, Joke
    Ghent University, Belgium.
    Minnaert, An-Katrien
    Ghent University, Belgium.
    Jiskoot, Wim
    Leiden University, Netherlands.
    Serwane, Friedhelm
    Max Planck Institute for Medical Research, Germany; Ludwig-Maximilian-University Munich, Germany; Munich Cluster for Systems Neurology, Germany.
    Spatz, Joachim
    Max Planck Institute for Medical Research, Germany; University of Heidelberg, Germany.
    Röding, Magnus
    RISE Research Institutes of Sweden, Bioeconomy and Health, Agriculture and Food. Chalmers University of Technology, Sweden; University of Gothenburg, Sweden.
    De Smedt, Stefaan
    Ghent University, Belgium.
    Braeckmans, Kevin
    Ghent University, Belgium.
    Remaut, Katrien
    Ghent University, Belgium.
    Together is Better: mRNA Co-Encapsulation in Lipoplexes is Required to Obtain Ratiometric Co-Delivery and Protein Expression on the Single Cell Level2022In: Advanced Science, E-ISSN 2198-3844, Vol. 9, no 4, article id 2102072Article in journal (Refereed)
    Abstract [en]

    Liposomes can efficiently deliver messenger RNA (mRNA) into cells. When mRNA cocktails encoding different proteins are needed, a considerable challenge is to efficiently deliver all mRNAs into the cytosol of each individual cell. In this work, two methods are explored to co-deliver varying ratiometric doses of mRNA encoding red (R) or green (G) fluorescent proteins and it is found that packaging mRNAs into the same lipoplexes (mingle-lipoplexes) is crucial to efficiently deliver multiple mRNA types into the cytosol of individual cells according to the pre-defined ratio. A mixture of lipoplexes containing only one mRNA type (single-lipoplexes), however, seem to follow the “first come – first serve” principle, resulting in a large variation of R/G uptake and expression levels for individual cells leading to ratiometric dosing only on the population level, but rarely on the single-cell level. These experimental observations are quantitatively explained by a theoretical framework based on the stochasticity of mRNA uptake in cells and endosomal escape of mingle- and single-lipoplexes, respectively. Furthermore, the findings are confirmed in 3D retinal organoids and zebrafish embryos, where mingle-lipoplexes outperformed single-lipoplexes to reliably bring both mRNA types into single cells. This benefits applications that require a strict control of protein expression in individual cells. © 2021 The Authors. 

  • 5.
    Österberg, Klas
    et al.
    University of Gothenburg, Sweden.
    Bogestål, Yalda
    RISE Research Institutes of Sweden, Materials and Production, Product Realisation Methodology.
    Jenndahl, Lachmi
    VERIGRAFT AB, Sweden.
    Gustafsson-Hedberg, Tobias
    VERIGRAFT AB, Sweden.
    Synnergren, Jane
    University of Gothenburg, Sweden; University of Skövde, Sweden.
    Holmgren, Gustav
    University of Skövde, Sweden.
    Bom, Eva
    RISE Research Institutes of Sweden, Materials and Production, Product Realisation Methodology.
    Petronis, Sarunas
    RISE Research Institutes of Sweden, Materials and Production, Product Realisation Methodology.
    Krona, Annika
    RISE Research Institutes of Sweden, Bioeconomy and Health, Agriculture and Food.
    Eriksson, Jonna
    TATAA Biocenter AB, Sweden.
    Rosendahl, Jennifer
    RISE Research Institutes of Sweden, Materials and Production, Product Realisation Methodology.
    Crisostomo, Veronica
    Jesús Usón Minimally Invasive Surgery Centre, Spain; CIBER de Enfermedades Cardiovasculares, Spain; RICORS-TERAV Network, Spain.
    Sanchez-Margallo, Francisco
    Jesús Usón Minimally Invasive Surgery Centre, Spain; CIBER de Enfermedades Cardiovasculares, Spain; RICORS-TERAV Network, Spain.
    Baez-Diaz, Claudia
    Jesús Usón Minimally Invasive Surgery Centre, Spain; CIBER de Enfermedades Cardiovasculares, Spain; RICORS-TERAV Network, Spain.
    Strehl, Raimund
    VERIGRAFT AB, Sweden.
    Håkansson, Joakim
    RISE Research Institutes of Sweden, Materials and Production, Product Realisation Methodology. University of Gothenburg, Sweden.
    Personalized tissue-engineered veins - long term safety, functionality and cellular transcriptome analysis in large animals2023In: Biomaterials Science, ISSN 2047-4830, E-ISSN 2047-4849, Vol. 11, no 11, p. 3860-3877Article in journal (Refereed)
    Abstract [en]

    Tissue engineering is a promising methodology to produce advanced therapy medicinal products (ATMPs). We have developed personalized tissue engineered veins (P-TEV) as an alternative to autologous or synthetic vascular grafts utilized in reconstructive vein surgery. Our hypothesis is that individualization through reconditioning of a decellularized allogenic graft with autologous blood will prime the tissue for efficient recellularization, protect the graft from thrombosis, and decrease the risk of rejection. In this study, P-TEVs were transplanted to vena cava in pig, and the analysis of three veins after six months, six veins after 12 months and one vein after 14 months showed that all P-TEVs were fully patent, and the tissue was well recellularized and revascularized. To confirm that the ATMP product had the expected characteristics one year after transplantation, gene expression profiling of cells from P-TEV and native vena cava were analyzed and compared by qPCR and sequencing. The qPCR and bioinformatics analysis confirmed that the cells from the P-TEV were highly similar to the native cells, and we therefore conclude that P-TEV is functional and safe in large animals and have high potential for use as a clinical transplant graft.

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