Project description:We established an in vivo model of organ-specific colorectal cancer metastasis and demonstrated that the CD110+ tumor initiating cells contribute for colorectal liver metastasis. To gain a deeper understanding of its metastatic capacity, we performed a genome-wide transcriptome analysis on the CD110+ tumor cells derived from primary colon xenografts and their matched liver metastases. Results provide important information of the responses of the CD110+ cells during the process of liver colonization. Total RNA obtained from the CD110+ cells sorted from primary colorectal tumors (CRC102-PT and CRC108-PT) compared to those from the corresponding liver metastases (CRC102-LM and CRC108-LM).

Project description:High-grade osteosarcoma is a malignant primary bone tumor with a peak incidence in puberty. Overall survival of patients with metastatic disease is approximately twenty percent. Mechanisms behind the development of metastases in osteosarcoma are unknown. To identify gene signatures that play a role in metastasis, we performed genome-wide gene expression profiling on pre-chemotherapy biopsies of osteosarcoma patients who developed metastases within 5yrs and patients who did not develop metastases within 5yrs. Pre-chemotherapy biopsies of osteosarcoma patients who developed metastases within 5yrs (n=34) were compared with pre-chemotherapy biopsies of osteosarcoma patients who did not develop metastases within 5yrs (n=19).

Project description:Metastasis is the primary cause of cancer-related mortality and the mechanistically least well understood step of the tumor progression cascade. Employing surgical preclinical metastasis models, we show here that small primary tumors reprogram the body’s vascular endothelium to alter systemic homeostasis and to condition the premetastatic niche for metastatic colonization. Endothelial cells thereby serve as an amplifier of tumor-induced instructive signals. The combined endothelial transcriptomic and serum proteomic screen identified the TGFß pathway signaling specifier LRG1 as an early vascular niche instructor of metastatic colonization. Adjuvant LRG1 inhibition to primary tumor-resected mice delayed metastatic growth and increased overall survival. The study has thereby established the premetastatic systems map of primary tumor-induced vascular changes and identified LRG1 as a therapeutic target for metastasis

Project description:High-grade osteosarcoma is a malignant primary bone tumor with a peak incidence in puberty. Overall survival of patients with metastatic disease is approximately twenty percent. Mechanisms behind the development of metastases in osteosarcoma are unknown. To identify gene signatures that play a role in metastasis, we performed genome-wide gene expression profiling on pre-chemotherapy biopsies of osteosarcoma patients who developed metastases within 5yrs and patients who did not develop metastases within 5yrs.

Project description:We established an in vivo model of organ-specific colorectal cancer metastasis and demonstrated that the CD110+ tumor initiating cells contribute for colorectal liver metastasis. To gain a deeper understanding of its metastatic capacity, we performed a genome-wide transcriptome analysis on the CD110+ tumor cells derived from primary colon xenografts and their matched liver metastases. Results provide important information of the responses of the CD110+ cells during the process of liver colonization.

Project description:Purpose: Lung metastasis is responsible for nearly all deaths caused by osteosarcoma, the most common pediatric bone tumor. How malignant bone cells coerce the lung microenvironment to support metastatic growth is unclear. This study delineates how osteosarcoma cells educate the lung microenvironment during metastatic progression. Experimental design: Using single-cell transcriptomics (scRNA-seq), we characterized genome- and tissue-wide molecular changes induced within lung tissues by disseminated osteosarcoma cells in both immunocompetent murine models of metastasis and patient samples. We confirmed transcriptomic findings at the protein level and determined spatial relationships with multi-parameter immunofluorescence. We evaluated the ability of nintedanib to impair metastatic colonization and prevent osteosarcoma-induced education of the lung microenvironment in both immunocompetent murine osteosarcoma and immunodeficient human xenograft models. Results: Osteosarcoma cells induced acute alveolar epithelial injury upon lung dissemination. scRNA-seq demonstrated that the surrounding lung stroma adopts a chronic, non-resolving wound-healing phenotype similar to that seen in other models of lung injury. Accordingly, metastasis-associated lung demonstrated marked fibrosis, likely due to the accumulation of pathogenic, pro-fibrotic, partially-differentiated epithelial intermediates. Inhibitionintermediates. Inhibition of fibrotic pathways with nintedanib prevented metastatic progression in multiple murine and human xenograft models. Conclusions: Our work demonstrates that osteosarcoma cells co-opt fibrosis to promote metastatic outgrowth. When harmonized with data from adult epithelial cancers, our results support a generalized model wherein aberrant mesenchymal-epithelial interactions are critical for promoting lung metastasis. Adult epithelial carcinomas induce fibrotic pathways in normal lung fibroblasts, whereas osteosarcoma, a pediatric mesenchymal tumor, exhibits fibrotic reprogramming in response to the aberrant wound-healing behaviors of an otherwise normal lung epithelium, which are induced by tumor cell interactions.

Project description:Metastasis results from a complex set of traits acquired by tumor cells, distinct from those necessary for tumorigenesis. Here, we investigate the contribution of enhancer elements to the metastatic phenotype of osteosarcoma. Through epigenomic profiling, we identify substantial differences in signature enhancer-histone marks between near-isogenic pairs of high and low lung-metastatic osteosarcoma cells. We term these regions Metastatic Variant Enhancer Loci (Met-VELs). Met-VELs drive coordinated waves of gene expression during metastatic colonization of the lung. Met-VELs cluster non-randomly, indicating that activity of these enhancers and their associated gene targets is positively selected. Osteosarcoma lung metastasis is inhibited by global interruptions of Met-VEL associated gene expression.

Project description:Pulmonary metastasis is the main cause of medical failure and death of osteosarcoma patients. Despite intensive search for new therapeutic strategies, survival has not improved during the last two decades. Therefore, it’s very urgent to understand the underlying mechanisms of tumor progression to identify targets of novel therapies for osteosarcoma. We used microarrays to identify the metastasis-driving gene during osteosarcoma metastasis Microarrays are performed in ZOS and ZOSM-two syngenic primary human osteosarcoma cell lines with low and high metastatic potential which are established in our lab

Project description:Global gene expression analysis was performed on a panel of 23 osteosarcoma samples of primary and metastatic origin using the Applied Biosystems Gene Expression Array System. When comparing the primary tumours with the metastases, we found a significantly increased expression of genes involved in immunological processes, e.g. coding for cytokines and chemokines, in the metastatic samples, suggesting that these signal molecules play an important role in promoting metastasis. In addition, a comparison of the gene expression in primary samples from patients with or without metastases demonstrated that patients who later developed metastases had high expression of the chemokine (C-X-C motif) receptor 4 (CXCR4), similar to the metastatic samples. Increased knowledge of mechanisms and interactions between specified molecular signalling pathways in osteosarcomas could lead to a more rational strategy for development of targeted therapy. Total RNA was isolated from tumor tissue of osteosarcoma patients. Gene expression patterns of metastatic versus primary samples were compared, as well as primary samples from patients who did or did not later develop metastases.

Project description:Most triple negative breast cancers (TNBCs) are aggressively metastatic with a high degree of intratumoral heterogeneity. We employed patient-derived xenograft models established from the breast tumors of patients with treatment-naïve metastatic TNBC to study clonal dynamics during metastasis. Genomic sequencing coupled with high-complexity barcode-mediated clonal tracking revealed robust alterations in clonal architecture between primary tumors and corresponding metastases that were deterministic rather than stochastic. The presence of numerous rare subclones in each metastatic lesion demonstrated that polyclonal seeding occurred and that heterogeneous populations of low-abundance clones were maintained in metastases. An identical population of subclones was enriched in lung, liver, and brain metastases, demonstrating that primary tumor clones harbor properties enabling them to seed and thrive in multiple organ sites. Further, clones that dominated multi-organ metastases shared a genomic lineage. Thus, intrinsic properties of rare primary tumor subclones enable the seeding and colonization of metastases in multiple organ sites.