TY - JOUR
T1 - 3D hydrogel-based microcapsules as an in vitro model to study tumorigenicity, cell migration and drug resistance
AU - Ertekin, Özlem
AU - Monavari, Mahshid
AU - Krüger, René
AU - Fuentes-Chandía, Miguel
AU - Parma, Beatrice
AU - Letort, Gaelle
AU - Tripal, Philipp
AU - Boccaccini, Aldo R.
AU - Bosserhoff, Anja K.
AU - Ceppi, Paolo
AU - Kappelmann-Fenzl, Melanie
AU - Leal-Egaña, Aldo
N1 - Funding Information:
Aldo Leal-Ega?a acknowledges the financial support provided by the German Research Foundation (LE 3418/2-1). Anja Bosserhoff acknowledges the support by the German Research Foundation (TRR225, project C03). ?zlem Ertekin was supported by the T?B?TAK 2219 International Post-Doctoral Research Fellowship Program (1059B191800689). Miguel Fuentes-Chandia thanks CONICYT for his postdoctoral fellowship. All authors gratefully thank Alexander-Oliver Matthies for preparation of RNA samples and RNA-Seq libraries, Dr. Ralph Palmisano for constructive discussions during the preparation of this work, and the Biomedical Sequencing Facility (BSF) of the CeMM (Vienna, Austria) for sequencing our samples. The use of the spinning disc confocal microscope (Zeiss Spinning Disc Axio Observer Z1) was possible due to the funded project 248122450, from German Research Foundation (DFG). Paolo Ceppi and Beatrice Parma were supported by the Interdisciplinary Center for Clinical Research (IZKF) of the University of Erlangen-Nuremberg.
Funding Information:
The use of the spinning disc confocal microscope (Zeiss Spinning Disc Axio Observer Z1) was possible due to the funded project 248122450, from German Research Foundation (DFG). Paolo Ceppi and Beatrice Parma were supported by the Interdisciplinary Center for Clinical Research (IZKF) of the University of Erlangen-Nuremberg.
Funding Information:
Aldo Leal-Egaña acknowledges the financial support provided by the German Research Foundation (LE 3418/2-1). Anja Bosserhoff acknowledges the support by the German Research Foundation (TRR225, project C03). Özlem Ertekin was supported by the TÜBİTAK 2219 International Post-Doctoral Research Fellowship Program (1059B191800689). Miguel Fuentes-Chandia thanks CONICYT for his postdoctoral fellowship. All authors gratefully thank Alexander-Oliver Matthies for preparation of RNA samples and RNA-Seq libraries, Dr. Ralph Palmisano for constructive discussions during the preparation of this work, and the Biomedical Sequencing Facility (BSF) of the CeMM (Vienna, Austria) for sequencing our samples.
Publisher Copyright:
© 2022 Acta Materialia Inc.
PY - 2022/4/1
Y1 - 2022/4/1
N2 - In this work, we analyzed the reliability of alginate-gelatin microcapsules as artificial tumor model. These tumor-like scaffolds are characterized by their composition and stiffness (∼25 kPa), and their capability to restrict -but not hinder- cell migration, proliferation and release from confinement. Hydrogel-based microcapsules were initially utilized to detect differences in mechano-sensitivity between MCF7 and MDA-MB-231 breast cancer cells, and the endothelial cell line EA.hy926. Additionally, we used RNA-seq and transcriptomic methods to determine how the culture strategy (i.e. 2D v/s 3D) may pre-set the expression of genes involved in multidrug resistance, being then validated by performing cytotoxicological tests and assays of cell morphology. Our results show that both breast cancer cells can generate elongated multicellular spheroids inside the microcapsules, prior being released (mimicking intravasation stages), a behavior which was not observed in endothelial cells. Further, we demonstrate that cells isolated from 3D scaffolds show resistance to cisplatin, a process which seems to be strongly influenced by mechanical stress, instead of hypoxia. We finally discuss the role played by aneuploidy in malignancy and resistance to anticancer drugs, based on the increased number of polynucleated cells found within these microcapsules. Overall, our outcomes demonstrate that alginate-gelatin microcapsules represent a simple, yet very accurate tumor-like model, enabling us to mimic the most relevant malignant hints described in vivo, suggesting that confinement and mechanical stress need to be considered when studying pathogenicity and drug resistance of cancer cells in vitro. Statement of significance: In this work, we analyzed the reliability of alginate-gelatin microcapsules as an artificial tumor model. These scaffolds are characterized by their composition, elastic properties, and their ability to restrict cell migration, proliferation, and release from confinement. Our results demonstrate four novel outcomes: (i) studying cell migration and proliferation in 3D enabled discrimination between malignant and non-pathogenic cells, (ii) studying the cell morphology of cancer aggregates entrapped in alginate-gelatin microcapsules enabled determination of malignancy degree in vitro, (iii) determination that confinement and mechanical stress, instead of hypoxia, are required to generate clones resistant to anticancer drugs (i.e. cisplatin), and (iv) evidence that resistance to anticancer drugs could be due to the presence of polynucleated cells localized inside polymer-based artificial tumors.
AB - In this work, we analyzed the reliability of alginate-gelatin microcapsules as artificial tumor model. These tumor-like scaffolds are characterized by their composition and stiffness (∼25 kPa), and their capability to restrict -but not hinder- cell migration, proliferation and release from confinement. Hydrogel-based microcapsules were initially utilized to detect differences in mechano-sensitivity between MCF7 and MDA-MB-231 breast cancer cells, and the endothelial cell line EA.hy926. Additionally, we used RNA-seq and transcriptomic methods to determine how the culture strategy (i.e. 2D v/s 3D) may pre-set the expression of genes involved in multidrug resistance, being then validated by performing cytotoxicological tests and assays of cell morphology. Our results show that both breast cancer cells can generate elongated multicellular spheroids inside the microcapsules, prior being released (mimicking intravasation stages), a behavior which was not observed in endothelial cells. Further, we demonstrate that cells isolated from 3D scaffolds show resistance to cisplatin, a process which seems to be strongly influenced by mechanical stress, instead of hypoxia. We finally discuss the role played by aneuploidy in malignancy and resistance to anticancer drugs, based on the increased number of polynucleated cells found within these microcapsules. Overall, our outcomes demonstrate that alginate-gelatin microcapsules represent a simple, yet very accurate tumor-like model, enabling us to mimic the most relevant malignant hints described in vivo, suggesting that confinement and mechanical stress need to be considered when studying pathogenicity and drug resistance of cancer cells in vitro. Statement of significance: In this work, we analyzed the reliability of alginate-gelatin microcapsules as an artificial tumor model. These scaffolds are characterized by their composition, elastic properties, and their ability to restrict cell migration, proliferation, and release from confinement. Our results demonstrate four novel outcomes: (i) studying cell migration and proliferation in 3D enabled discrimination between malignant and non-pathogenic cells, (ii) studying the cell morphology of cancer aggregates entrapped in alginate-gelatin microcapsules enabled determination of malignancy degree in vitro, (iii) determination that confinement and mechanical stress, instead of hypoxia, are required to generate clones resistant to anticancer drugs (i.e. cisplatin), and (iv) evidence that resistance to anticancer drugs could be due to the presence of polynucleated cells localized inside polymer-based artificial tumors.
KW - 3D cultures
KW - Drug resistance
KW - Mechanical Stress
KW - Tumor-like microcapsules
KW - Tumor-like model
U2 - 10.1016/j.actbio.2022.02.010
DO - 10.1016/j.actbio.2022.02.010
M3 - Journal article
C2 - 35167953
AN - SCOPUS:85124953234
SN - 1742-7061
VL - 142
SP - 208
EP - 220
JO - Acta Biomaterialia
JF - Acta Biomaterialia
ER -