Project description:Interactions between cancer cells and surrounding stromal cells are critical for tumor biology and treatment response. We compare drug screening results from conventional 2D cancer cell lines with 3D tumor tissues and find that, on average, three times more drugs are effective in 3D microtumors. We confirmed the effectiveness of doramapimod, a compound that reduces 3D microtumor viability and suppresses tumor growth in mouse models, has no effect on cancer cell growth in monolayers. Mechanistically, doramapimod targets DDR1/2 and MAPK12 kinases in cancer-associated fibroblasts (CAFs), decreasing extracellular matrix (ECM) production and enhancing interferon signaling. These kinases regulate ECM through GLI1 activity in CAFs, independently of canonical hedgehog signaling. Inhibiting the DDR1/2-MAPK12-GLI axis enhances the effectiveness of chemotherapy and immunotherapy in patient tumor slices and preclinical models. These findings highlight the importance of DDR1/2-MAPK12-GLI axis in CAF function and demonstrate the utility of 3D tissue models in identifying microenvironment-specific therapeutic targets.

Project description:The first step in metastasis is dissemination of tumor cells into the surrounding tissue, or stroma. In carcinomas, cancers of epithelial origin, tumor cells must first breach the basement membrane (BM), a network that encapsulates the tumor. As tumor progresses, other cell types that reside in the stroma, such as carcinoma-associated fibroblasts (CAFs) accumulate around the tumor. Whether CAFs can help cancer cells to breach the BM remains an open question. Here we show that CAFs promote cancer cell invasion by physically remodeling the BM. Using a novel 3D in vitro model we observed that primary CAFs isolated from colon cancer patients stimulate cancer cell invasion through a native mesenteric BM. This stimulated invasion is the result of the physical presence of CAFs rather than an increased invasive potential of cancer cells. In the presence of CAFs, cancer cells can invade the BM in a matrix metalloproteinase-independent manner. Using live imaging, we found that CAFs actively pull and stretch the BM, leading to the formation of gaps through which cancer cells can migrate. Notably, CAF-mediated gap-widening is independent of proteolysis but relies on actomyosin contractility. We propose that CAFs exert mechanical forces that alter the organization and the physical properties of the BM, making it permissive for cancer cell invasion.

Project description:Purpose: The goals of this study are to compare mammary tumor transcriptome profiling with or without DDR1 in immunocompetent mice in an unbiased way. Methods: In vitro samples: DDR1 WT or KO in vitro cultured E0771 cells were sequenced. Rag1-/- samples: DDR1 WT or KO E0771 cells were injected in Rag1-/- mice, and tumors were harvested and sequenced. C57BL/6 samples: DDR1 WT or KO E0771 cells were firstly inoculated into Rag1-/- mice. When tumor volume reached approximately 200~300 mm3 (usually 20 days after inoculation), 60 mg of tumor organoid were transplanted to WT C57BL/6 mice. Tumor samples were collected on day 4 after transplantation for RNA-seq. Antibody treatment samples: DDR1 KO E0771 cells were reconstituted with human DDR1, then injected into C57BL/6 mice. Isotype control IgG or anti-hDDR1 ECD antibody treatment (10mg/kg intrutumural) started when tumor volume reached approximately 100 mm3. Tumor samples were collected on day 6 after treatment for RNA-seq. Results: Approximately 50 million sequence reads were obtained per sample and identified more than 20,000 transcript isoforms. Conclusions: The RNA-seq results represents the detailed analysis of DDR1 WT/KO mammary tumor transcriptomes in immunocompetent mice C57BL/6.

Project description:Cholangiocarcinomas (CCA) are characterized by their desmoplastic and hypervascularized tumor microenvironment (TME) which is mainly composed of tumor cells and cancer-associated fibroblasts (CAFs). CAFs play a pivotal role in tumor progression, angiogenesis, metastasis and the development of therapy resistance. To our knowledge, no continuous human in vivo-like co-culture model is available for research. Therefore, we aimed to establish a new model that mimics the desmoplastic environment typically seen in CCA. Proteomic data comparing the new CCA tumor cell line with our co-culture tumor model (CCTM) indicated a higher correlation of the CCTM with physiological CCA characteristics according to literature. A pro-angiogenic TME that is typically observed in CCA could also be simulated in the CCTM group. Further analysis of secreted proteins revealed CAFs to be the main source for these angiogenic factors. Our CCTM represents a new, reproducible and easy-to-handle 3D CCA model for preclinical studies focusing on CCA-stromal crosstalk, tumor angiogenesis and invasion, the immunosuppressive microenvironment and the involvement of CAFs in the way that drug resistance develops.

Project description:Cancer associated fibroblasts (CAFs) are the major cellular component of the tumor microenvironment and they have been shown to stimulate tumor growth, epithelial-to-mesenchymal transition (EMT), invasion and radio-resistance. We used microarrays to investigate the influence of CAFs on the gene expression profile of HNSCC cells in 3D co-cultures

Project description:Patient derived organoids (PDOs) have been established as a 3D culture model which closely recapitulates the in vivo tumor biology. However, one limitation of this culture model is the lack of tumor microenvironment which has a significant role in tumor progression and drug response. To address this, we established and molecularly characterized a novel 3D co-culture model of colorectal cancer (CRC) based on PDOs and patient matched fibroblasts. Both normal and cancer associated fibroblasts, NFs and CAFs respectively, were able to support organoid growth without addition of niche factors to the media. Additionally, co-cultures showed closer resemblance to primary patient material than organoid mono-cultures as evaluated by histology. Finally, RNA gene expression signatures of tumor cells and fibroblasts isolated from mono- or co-cultures demonstrated that co-cultures support greater cell type heterogeneity. In this proteomics dataset we compared pairs of NFs and CAFs derived from five patients. Collectively, we present a newly established human derived organoid-fibroblast model which, closely recapitulates in vivo tumor heterogeneity and involves the tumor microenvironment.

Project description:Cancer-associated fibroblasts (CAFs) are an integral part of the tumor microenvironment often linked to drug resistance. Here, we report that CAFs, but not normal fibroblasts, can promote either resistance or unexpected drug sensitization of different lung cancer cells. Using unbiased secretomics, transcriptomics and tyrosine phosphoproteomics, we observed differential expression of several IGF1R signaling components, such as IGF-binding proteins and IGF1/2, and downstream signaling effects on cancer cells by fibroblasts. IGF1/2 treatment or IGFBP5 silencing in CAFs reversed, while addition of exogenous IGFBPs or pharmacological IGF1R inhibitors phenocopied the sensitizing effects. Combining IGF1R and EGFR inhibitors synergized in 2D and 3D models of different drug-resistant and naïve EGFR-mutant lung cancer cells and decreased tumor growth in vivo. These results suggest that multiple resistance mechanisms coexist within the same cancer cells, that CAFs context-dependently cause drug resistance or sensitization, and that understanding both of these differential mechanisms leads to improved therapeutic approaches.

Project description:Cancer-associated fibroblasts (CAFs) are an integral part of the tumor microenvironment often linked to drug resistance. Here, we report that CAFs, but not normal fibroblasts, can promote either resistance or unexpected drug sensitization of different lung cancer cells. Using unbiased secretomics, transcriptomics and tyrosine phosphoproteomics, we observed differential expression of several IGF1R signaling components, such as IGF-binding proteins and IGF1/2, and downstream signaling effects on cancer cells by fibroblasts. IGF1/2 treatment or IGFBP5 silencing in CAFs reversed, while addition of exogenous IGFBPs or pharmacological IGF1R inhibitors phenocopied the sensitizing effects. Combining IGF1R and EGFR inhibitors synergized in 2D and 3D models of different drug-resistant and naïve EGFR-mutant lung cancer cells and decreased tumor growth in vivo. These results suggest that multiple resistance mechanisms coexist within the same cancer cells, that CAFs context-dependently cause drug resistance or sensitization, and that understanding both of these differential mechanisms leads to improved therapeutic approaches.

Project description:Medulloblastomas (MBs) and Glioblastomas (GBMs) are high-incidence central nervous system tumors. Different origin sites and changes in the tissue microenvironment have been associated with onset and progression. Here, we describe differences between the ECM signature of these tumors. We compared the proteomic profiles of MB and GBM decellularized tumor samples among each other and their normal decellularized brain site counterparts. Our analysis reveals that 19 proteins were differentially expressed in MBs, 28 proteins in GBMs, and 11 proteins in both MBs and GBMs. Next, we validated key findings by protein tissue array with 53 MB and 55 GBM cases and evaluated the clinical relevance of the identified differentially expressed proteins through their analysis on publicly available datasets, 763 MB samples from microarray-GSE50161, and 115 GBM samples from RNAseq-TCGA. We report a shift towards a denser fibrillary ECM as well as a clear alteration in the glycoprotein signature, which influences the tumor pathophysiology.

Project description:Invasive lung adenocarcinoma (LADC) is classified histologically as lepidic, acinar, papillary, micropapillary, or solid. We found that A549 human LADC cells formed tumors with distinct histological features—solid-type or acinar-type tumors—depending on the site of development in immunodeficient mice and that a solid-to-acinar transition (SAT) could be induced by cancer-associated fibroblasts (CAFs) in 3D cocultures with A549. To clarify the molecular mechanisms contributing to SAT induction, we performed RNA-seq analysis of four A549 tumor cell samples derived from solid- or acinar-type tumor tissue formed in vivo or from 3D tumor colonies formed in the presence or absence of CAFs in vitro.