Recapitulating mammary gland development and breast cancer cell migration in vitro using 3D engineered scaffolds

Hume, Robert David

January 2018

The adult mammary gland is comprised of a bi-layered epithelium of luminal and myoepithelial cells surrounded by an adipocyte-rich fat pad, a highly collagenous extra-cellular matrix (ECM) and a number of other stromal and endothelial cell types. Mammary stem cells (MaSCs) reside within the epithelium and these are capable of repopulating a mammary fat pad that is devoid of epithelium, upon transplantation. It was sought to recapitulate this process of MaSCs repopulating a fat pad using a synthetic fat pad, engineered from a collagen scaffold invested with adipocytes, to provide an in vitro 3D model. Fluorescently tagged murine Axin2-expressing cells were obtained from transgenic mice and seeded into these scaffolds and cultured, mimicking the process of fat pad repopulation. Immunohistochemical analysis demonstrated that Axin2+ myoepithelial cells were rarely capable of forming bi-layered structures that expressed correct myoepithelial localisation and resemblance to a luminal morphology. Breast tumours surrounded by anisotropic (directional) collagen fibres running perpendicular to the tumour boundary are more aggressive and associated with poor patient prognosis. To recapitulate this anisotropic collagen phenotype in vitro, an ice-templating technique was used to modify the structure of the collagen scaffolds producing both non-directional (isotropic) and anisotropic internal architectures. Tumour cells from various breast cancer cell lines were seeded into both isotropic and anisotropic scaffolds to investigate whether this approach could distinguish cell type-specific migratory ability and whether anisotropy affected migration efficiency. Following analysis by confocal microscopy and ImageJ, anisotropic scaffolds were observed to enhance the migratory potential of MDA-MB-231 breast cancer cells. These results highlight the importance of collagen alignment and provide a reproducible method to quantitatively measure cell migration in 3D for cells derived from different breast cancer subtypes. Building on these data, the protocol was adapted to permit the direct investigation of tumour biopsy material. Given the heterogeneity of breast tumours, it was considered important to maintain tumour architecture and stromal components. Thus, murine mammary tumour fragments from two different established mammary cancer models were utilised and cultured in anisotropic collagen scaffolds in the presence or absence of adipocytes to allow an investigation of their influence on tumour cell migration. Further experiments included addition of various therapeutic drugs followed by immunofluorescence microscopy coupled with an optical clearing technique. These data demonstrated the utility of the model in determining both the rate and capacity of tumour cells to migrate through the engineered stroma while shedding light also on the mode of migration. Moreover, the response of different mammary tumour types to chemotherapeutic drugs could be could be readily quantified. To humanize the fat pad for subsequent human tissue analysis, human mesenchymal stem cells (MSC) were obtained from reduction mammoplasties and immortalised, before differentiating them into adipocytes within anisotropic collagen scaffolds. Human breast cancer cells were fluorescently tagged for tracking using lentiviral methods and were seeded into scaffolds invested with differentiated MSCs. Both cell types were successfully co-cultured for 7 days and imaged using multiphoton methods.

Engineering PNIPAAm Biomaterial Scaffolds to Model Microenvironmental Regulation of Glioblastoma Stem-Like Cells

January 2017

abstract: Following diagnosis of a glioblastoma (GBM) brain tumor, surgical resection, chemotherapy and radiation together yield a median patient survival of only 15 months. Importantly, standard treatments fail to address the dynamic regulation of the brain tumor microenvironment that actively supports tumor progression and treatment resistance. Moreover, specialized niches within the tumor microenvironment maintain a population of highly malignant glioblastoma stem-like cells (GSCs). GSCs are resistant to traditional chemotherapy and radiation therapy and are likely responsible for near universal rates of tumor recurrence and associated morbidity. Thus, disrupting microenvironmental support for GSCs could be critical to more effective GBM therapies. Three-dimensional (3D) culture models of the tumor microenvironment are powerful tools for identifying key biochemical and biophysical inputs that may support or inhibit malignant behaviors. Here, we developed synthetic poly(N-isopropylacrylamide-co-Jeffamine M-1000® acrylamide) or PNJ copolymers as a model 3D system for culturing GBM cell lines and low-passage patient-derived GSCs in vitro. These temperature responsive scaffolds reversibly transition from soluble to insoluble in aqueous solution by heating from room temperature to body temperature, thereby enabling easy encapsulation and release of cells in a 3D scaffold. We also designed this system with the capacity for presenting the cell-adhesion peptide sequence RGD for adherent culture conditions. Using this system, we identified conditions that promoted GBM proliferation, invasion, GSC phenotypes, and radiation resistance. In particular, using two separate patient-derived GSC models, we observed that PNJ scaffolds regulated self-renewal, provided protection from radiation induced cell death, and may promote stem cell plasticity in response to radiation. Furthermore, PNJ scaffolds produced de novo activation of the transcription factor HIF2α, which is critical to GSC tumorigenicity and stem plasticity. All together, these studies establish the robust utility of PNJ biomaterials as in vitro models for studying microenvironmental regulation of GSC behaviors and treatment resistance. / Dissertation/Thesis / Doctoral Dissertation Biomedical Engineering 2017

Biomedical engineering

Brain tumor microenvironment

Brain tumors

Cancer stem cells

Cancer tissue engineering

poly(N-isopropylacrylamide) copolymers

Temperature responsive scaffolds