Project description:Bone invigorates metstatic seeding [evolving barcode]

Project description:Bone invigorates metastatic seeding

Project description:The paper describes a model of tumor invasion to bone marrow. Created by COPASI 4.26 (Build 213) This model is described in the article: Modeling invasion of metastasizing cancer cells to bone marrow utilizing ecological principles Kun-Wan Chen, Kenneth J Pienta Theoretical Biology and Medical Modelling 2011, 8:36 Abstract: Background: The invasion of a new species into an established ecosystem can be directly compared to the steps involved in cancer metastasis. Cancer must grow in a primary site, extravasate and survive in the circulation to then intravasate into target organ (invasive species survival in transport). Cancer cells often lay dormant at their metastatic site for a long period of time (lag period for invasive species) before proliferating (invasive spread). Proliferation in the new site has an impact on the target organ microenvironment (ecological impact) and eventually the human host (biosphere impact). Results: Tilman has described mathematical equations for the competition between invasive species in a structured habitat. These equations were adapted to study the invasion of cancer cells into the bone marrow microenvironment as a structured habitat. A large proportion of solid tumor metastases are bone metastases, known to usurp hematopoietic stem cells (HSC) homing pathways to establish footholds in the bone marrow. This required accounting for the fact that this is the natural home of hematopoietic stem cells and that they already occupy this structured space. The adapted Tilman model of invasion dynamics is especially valuable for modeling the lag period or dormancy of cancer cells. Conclusions: The Tilman equations for modeling the invasion of two species into a defined space have been modified to study the invasion of cancer cells into the bone marrow microenvironment. These modified equations allow a more flexible way to model the space competition between the two cell species. The ability to model initial density, metastatic seeding into the bone marrow and growth once the cells are present, and movement of cells out of the bone marrow niche and apoptosis of cells are all aspects of the adapted equations. These equations are currently being applied to clinical data sets for verification and further refinement of the models. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:The paper describes a model of tumor invasion to bone marrow. Created by COPASI 4.26 (Build 213) This model is described in the article: Modeling invasion of metastasizing cancer cells to bone marrow utilizing ecological principles Kun-Wan Chen, Kenneth J Pienta Theoretical Biology and Medical Modelling 2011, 8:36 Abstract: Background: The invasion of a new species into an established ecosystem can be directly compared to the steps involved in cancer metastasis. Cancer must grow in a primary site, extravasate and survive in the circulation to then intravasate into target organ (invasive species survival in transport). Cancer cells often lay dormant at their metastatic site for a long period of time (lag period for invasive species) before proliferating (invasive spread). Proliferation in the new site has an impact on the target organ microenvironment (ecological impact) and eventually the human host (biosphere impact). Results: Tilman has described mathematical equations for the competition between invasive species in a structured habitat. These equations were adapted to study the invasion of cancer cells into the bone marrow microenvironment as a structured habitat. A large proportion of solid tumor metastases are bone metastases, known to usurp hematopoietic stem cells (HSC) homing pathways to establish footholds in the bone marrow. This required accounting for the fact that this is the natural home of hematopoietic stem cells and that they already occupy this structured space. The adapted Tilman model of invasion dynamics is especially valuable for modeling the lag period or dormancy of cancer cells. Conclusions: The Tilman equations for modeling the invasion of two species into a defined space have been modified to study the invasion of cancer cells into the bone marrow microenvironment. These modified equations allow a more flexible way to model the space competition between the two cell species. The ability to model initial density, metastatic seeding into the bone marrow and growth once the cells are present, and movement of cells out of the bone marrow niche and apoptosis of cells are all aspects of the adapted equations. These equations are currently being applied to clinical data sets for verification and further refinement of the models. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:The main cause of death in medulloblastoma is recurrence associated with leptomeningeal dissemination. Although the molecular basis of medulloblastoma has received considerable attention over the past decade, the role of microRNAs (miRNAs) in the acquisition of metastatic phenotype remains poorly understood. This study aimed to identify miRNA involved in leptomeningeal dissemination and to elucidate its target mechanisms. We analyzed miRNA expression profiles of 29 medulloblastomas according to the presence of cerebrospinal fluid (CSF) seeding. The differential expressed miRNAs (DEmiRNAs) were validated on 29 medulloblastoma tissues and three medulloblastoma cells. The biological function of the selected miRNA was evaluated using in vitro studies. A total of 12 DEmiRNAs were identified including miRNA-192 in medulloblastoma with seeding. The reduced expression of miRNA-192 was confirmed in tumor seeding group and the medulloblastoma cells. Overexpression of miRNA-192 inhibited cellular proliferation targeting dihydrofolate reductase (DHFR). MiRNA-192 decreased cellular anchoring via repression of integrin subunits (αV, β1, and β3) and CD47. Medulloblastoma with seeding showed specific DEmiRNAs compared with those without seeding. MicroRNA-192 suppresses leptomeningeal dissemination of medulloblastoma through modulating cell proliferation and anchoring ability. leptomeningeal dissemination in 29 pediatric medulloblastoma patients

Project description:Bone invigorates metastatic seeding [RNA-seq]

Project description:Tumor heterogeneity resulting from clonal evolution is a frequent feature in clear cell renal cell carcinoma (ccRCC) and could play a role in metastatic dissemination. However, the dynamics of metastatic evolution is not completely elucidated and could follow a complex seeding process. Using a unique experimental design with a rare matched primary-metastatic case prior to any medical treatment, we retraced the lineage of metastatic clones that showed a complex, multiple, polyphyletic seeding of two functionally interdependent subclonal populations originating from the primary tumor, in the direction of all metastatic sites.

Project description:Tumor heterogeneity resulting from clonal evolution is a frequent feature in clear cell renal cell carcinoma (ccRCC) and could play a role in metastatic dissemination. However, the dynamics of metastatic evolution is not completely elucidated and could follow a complex seeding process. Using a unique experimental design with a rare matched primary-metastatic case prior to any medical treatment, we retraced the lineage of metastatic clones that showed a complex, multiple, polyphyletic seeding of two functionally interdependent subclonal populations originating from the primary tumor, in the direction of all metastatic sites.

Project description:Breast cancer cells display preferences for specific metastatic sites including the bone, lung and liver. Metastasis is a complex process that relies, in part, on interactions between disseminated cancer cells and resident/infiltrating stromal cells that constitute the metastatic microenvironment. Distinct immune infiltrates can either impair the metastatic process or conversely, assist in the seeding, colonization and growth of disseminated cancer cells. Using in vivo selection approaches, we previously isolated 4T1-derived breast cancer cells that preferentially metastasize to these organs and tissues. In this study, we examined whether the propensity of breast cancer cells to metastasize to the lung, liver or bone is associated with and dependent on distinct patterns of immune cell infiltration. Immunohistocytochemistry and immunohistofluorescence approaches were used to quantify granulocytic infiltrates within distinct metastases and depletion of Gr1+ cells was performed to functionally interrogate the role of myeloid/granulocytic infiltrates in promoting metastasis to these organs. We show that T lymphocytes (CD3+), myeloid-derived/granulocytic cells (Gr-1+) cells and neutrophils (NE+) exhibit the most pronounced recruitment in lung and liver metastases, with markedly less recruitment within bone metastatic lesions. Interestingly, these infiltrating cell populations display different patterns of localization within soft tissue metastases. T lymphocytes and neutrophils are localized around the periphery of liver metastases whereas they were dispersed throughout the lung metastases. Furthermore, Gr-1+ cell-depletion studies demonstrate that infiltrating myeloid-derived/granulocytic cells, including neutrophils, are essential for the formation of breast cancer liver metastases but dispensable for metastasis to the lung and bone. Finally, we demonstrate that neutrophils that infiltrate and surround the liver metastases are polarized towards an N2 phenotype, which have previously been shown to enhance tumor growth and metastasis. Our results demonstrate that the liver metastatic potential of breast cancer cells is heavily reliant on interactions with infiltrating myeloid/granulocytic cells in the liver microenvironment.

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.