Project description:High-Grade Serous Ovarian Carcinoma (HGSOC) is the most common form of ovarian cancer and finding new treatments remains an unmet need. While drug discovery is typically performed in two-dimensional (2D) monolayers, three-dimensional (3D) culture systems better mimic in vivo conditions. However, a comprehensive comparison of 3D vs 2D ovarian cancer models is lacking. Here, we quantitatively compared the whole cell proteomic signatures of 4 ovarian cell lines—PEO1, PEO4, UWB1.289, and UWB1.289+BRCA1— with different status of BRCA genes grown, in 2D and in 3D. Using isobaric labeling proteomics, we quantified 6,404 proteins and identified 371 significantly and commonly altered proteins between 2D and 3D. Proteins upregulated in 3D were enriched for transmembrane transport and NADH:ubiquinone oxidoreductase Complex I, while energy metabolism and cell growth pathways also showed dimensionality-dependent changes. Notably, membrane-associated proteins were downregulated in spheroids, particularly EGFR in PEO1. Furthermore, 3D culture modulated the response to carboplatin, with increased expression of drug resistance-associated proteins, including NDUF family members in all spheroid models. These findings underscore how culture dimensionality influences both the molecular landscape and chemotherapeutic response of HGSOC cells and highlight candidate targets for overcoming carboplatin resistance.

Project description:Proteomics of ovarian cancer cell line A2780 in 2D monolayer and in 3D spheroid culture.

Project description:Proteomics of ovarian cancer cell line SKOV-3 in 2D monolayer and in 3D spheroid culture

Project description:Background. Fallopian tube secretory epithelial cells (FTSECs) have been implicated as a cell-of-origin for high-grade serous epithelial ovarian cancer. However, there are relatively few in vitro models of this tissue type available for use in studies of FTSEC biology and malignant transformation. In vitro three-dimensional (3D) cell culture models aim to recreate the architecture and geometry of tissues in vivo and restore the complex network of cell-cell/cell-matrix interactions that occur throughout the surface of the cell membrane. Results. We have established and characterized 3D spheroid culture models of primary FTSECs. FTSEC spheroids contain central cores of hyaline matrix surrounded by mono- or multi-layer epithelial sheets. We found that 3D culturing alters the molecular characteristics of FTSECs compared to 2D cultures of the same cells. Gene expression profiling identified more than a thousand differentially expressed genes between 3D and 2D cultures of the same FTSEC lines. Pathways significantly under-represented in 3D FTSEC cultures were associated with cell cycle progression and DNA replication. This was also reflected in the reduced proliferative indices observed in 3D spheroids stained for the proliferation marker MIB1. Comparisons with gene expression profiles of fresh fallopian tube tissues revealed that 2D FTSEC cultures clustered with follicular phase tubal epithelium, whereas 3D FTSEC cultures clustered with luteal phase samples. Conclusions. This 3D model of fallopian tube secretory epithelial cells will advance our ability to study the underlying biology and etiology of fallopian tube tissues and the pathogenesis of high-grade serous epithelial ovarian cancer. 3 primary FTSEC lines were plated in 2D, or in 3D on polyHEMA coated plates

Project description:Two-dimensional (2D) culture models are commonly used in cancer research, but fail to recapitulate complex mechanical cues of native tissues. In this study, we developed an ex vivo three-dimensional (3D) lung cancer model by seeding human lung adenocarcinoma cells into decellularised rat lungs and culturing them in a pressure chamber and perfusion system mimicking respiratory motion (RM) and blood flow. In 3D culture, RM promoted cell adhesion and proliferation, enhanced the nuclear translocation of β-catenin and YAP, and increased the expression of integrin β1 and E-cadherin. In addition, upregulation of extracellular matrix- and cell adhesion-related genes was particularly notable. In contrast, in 2D culture, RM suppressed cell proliferation and induced apoptosis, with prominent upregulation of tumour suppressor genes. Our findings demonstrate that dimensionality and mechanical stress synergistically influence lung cancer cell dynamics and underscore the need for 3D models in cancer research that closely replicate the native lung tissue microenvironment.

Project description:Two-dimensional (2D) culture models are commonly used in cancer research, but fail to recapitulate complex mechanical cues of native tissues. In this study, we developed an ex vivo three-dimensional (3D) lung cancer model by seeding human lung adenocarcinoma cells into decellularised rat lungs and culturing them in a pressure chamber and perfusion system mimicking respiratory motion (RM) and blood flow. In 3D culture, RM promoted cell adhesion and proliferation, enhanced the nuclear translocation of β-catenin and YAP, and increased the expression of integrin β1 and E-cadherin. In addition, upregulation of extracellular matrix- and cell adhesion-related genes was particularly notable. In contrast, in 2D culture, RM suppressed cell proliferation and induced apoptosis, with prominent upregulation of tumour suppressor genes. Our findings demonstrate that dimensionality and mechanical stress synergistically influence lung cancer cell dynamics and underscore the need for 3D models in cancer research that closely replicate the native lung tissue microenvironment.

Project description:Platinum chemoresistance results in disease recurrence in patients with high-grade serous ovarian cancer (HGSOC). Recent advances in the treatment of solid tumours using checkpoint inhibitor immunotherapy has not benefited platinum-resistant HGSOC. Epigenetic silencing of genes involved in triggering cell death and apoptosis in HGSOC is known to occur via hypermethylation during development of platinum resistance. DNA methyltransferase (DNMT) inhibitors block methylation from occurring and allow silenced genes to be expressed. In ovarian cancer, DNMT inhibitors alter the epigenome and transcriptome of the tumours, which primarily affected expression of immune reactivation pathways. We aimed to determine the epigenome and transcriptome response to sequential treatment of HGSOC cells with DNMTi followed by standard-of-care carboplatin.

Project description:Platinum chemoresistance results in disease recurrence in patients with high-grade serous ovarian cancer (HGSOC). Recent advances in the treatment of solid tumours using checkpoint inhibitor immunotherapy has not benefited platinum-resistant HGSOC. Epigenetic silencing of genes involved in triggering cell death and apoptosis in HGSOC is known to occur via hypermethylation during development of platinum resistance. DNA methyltransferase (DNMT) inhibitors block methylation from occurring and allow silenced genes to be expressed. In ovarian cancer, DNMT inhibitors alter the epigenome and transcriptome of the tumours, which primarily affected expression of immune reactivation pathways. We aimed to determine the epigenome and transcriptome response to sequential treatment of HGSOC cells with DNMTi followed by standard-of-care carboplatin.

Project description:A 3D multicellular model (MCM) of high grade serous ovarian cancer (HGSOC) consisting of primary human adipocytes, fibroblasts, and mesothelial cells co-cultured with HGSOC cell lines was used to examine the effect of platelets on the ovarian metastasis microenvironment.

Project description:In the United States, high grade serous ovarian cancer (HGSOC) is the most lethal gynecologic malignancy and tumor response to platinum-based chemotherapy is a major determinant of clinical outcome. Although recent efforts have dramatically improved the median survival of advanced ovarian cancer, the initial treatment of the disease has remained the same. The initial therapy includes surgery and chemotherapy and the response rate is very high (85%). Unfortunately, 15% of patients do not respond to this therapy and have platinum-refractory disease. These patients have a very short survival and there is an urgent need to identify novel pharmaceutically targetable pathways to treat these patients. We generated extensive proteomic (global, phospho, ubiquitin, acetylation, pTyr) and RNASeq-based dynamic molecular profiles (+/-carboplatin at 8 and 24 hours) from HGSOC intra-patient cell line pairs (PEA1/PEA2, PEO1/PEO4, PEO14/PEO23) derived from 3 patients before and after acquiring platinum resistance. The molecular profiles revealed a multi-faceted response to carboplatin (e.g., induction of a DNA damage response, ubiquitination of ribosomal proteins, and metabolic changes), as well as novel carboplatin-induced post-translational modifications. Higher oxidative phosphorylation (OXPHOS) and fatty acid beta-oxidation (FAO) pathway expression was observed in resistant compared with sensitive cells. These expression findings were validated via metabolite profiling of cell lines and proteomic profiling of platinum sensitive and refractory HGSOC patient derived xenograft (PDX) models. Both pharmacologic inhibition and CRISPR knockout of CPT1A, which represents the rate limiting step of FAO, sensitizes HGSOC cells to platinum. The metabolic signature identified in the cell line and PDX models is correlated with survival in a previously reported proteomic analysis of HGSOC, and thus FAO is a candidate druggable pathway to overcome platinum resistance.