Project description:Development of effective therapies against brain metastasis is currently hindered by limitations in our understanding of the molecular mechanisms driving it. Here we define the contributions of tumour-secreted exosomes to brain metastatic colonization and demonstrate that pre-conditioning the brain microenvironment with exosomes from brain metastatic cells enhances cancer cell outgrowth. Proteomic analysis identified cell migration-inducing and hyaluronan-binding protein (CEMIP) as elevated in exosomes from brain metastatic, but not lung or bone metastatic cells. CEMIP depletion in tumour cells impaired brain metastasis, disrupting invasion and tumour cell association with the brain vasculature, phenotypes rescued by pre-conditioning the brain microenvironment with CEMIP+ exosomes. Moreover, uptake of CEMIP+ exosomes by brain endothelial and microglial cells induced endothelial cell branching and inflammation in the perivascular niche by upregulating Ptgs2, Tnf, and Ccl/Cxcl cytokines, known to promote brain vascular remodeling and metastasis. CEMIP was elevated in tumour tissues and exosomes from patients with brain metastasis and predicted brain metastasis progression and patient survival. Collectively, our findings suggest that targeting of exosomal CEMIP could constitute a future avenue for the prevention and treatment of brain metastasis.

Project description:Development of melanoma brain metastasis is caused by an interaction between tumor cells and normal cells in the brain microenvironment. miRNAs delivered by exosomes derived from the tumor cells seem to prime the brain microenvironment, prior to extravasation of tumor cells into the brain. We investigated miRNA in exosomes extracted from normal (astrocytes, melanocytes) and metastatic melanoma cells (brain, skin and lymph node metastasis). We have discovered that miR-146a-5p is an important player in brain metastatic development: this miRNA was highly upregulated in exosomes from melanoma brain metastasis cells, compared to normal cells.

Project description:Stephen Paget first proposed, in 1889, that organ distribution of metastases is a non-random event, yet metastatic organotropism remains one of the greatest mysteries in cancer biology. Here, we demonstrate that exosomes released by lung-, liver- and brain-tropic tumor cells fuse preferentially with resident cells at their predicted destination, such as fibroblasts and epithelial cells in the lung, Kupffer cells in the liver, and endothelial cells in the brain. We found that exosome homing to organ-specific cell types prepares the pre-metastatic niche and that treatment with exosomes derived from lung tropic models can redirect metastasis to the lung. Proteomic profiling of exosomes revealed distinct integrin expression patterns associated with each organ-specific metastasis. Whereas exosomal integrins α6β4 and α6β1 were associated with lung metastasis, exosomal integrins αvβ5 and αvβ3 were linked with liver and brain metastases, respectively. Targeting α6β4 and αvβ5 integrins decreased exosome uptake and metastasis in the lung and liver, respectively. Importantly, we demonstrate that exosome uptake activates a cell-specific subset of S100 family genes, known to support cell migration and niche formation. Finally, our clinical data indicate that integrin-expression profiles in circulating plasma exosomes from cancer patients could be used to predict organ-specific metastasis. Education of human von Kupffer cells in vitro with human pancreatic cancer exosomes

Project description:Stephen Paget first proposed, in 1889, that organ distribution of metastases is a non-random event, yet metastatic organotropism remains one of the greatest mysteries in cancer biology. Here, we demonstrate that exosomes released by lung-, liver- and brain-tropic tumor cells fuse preferentially with resident cells at their predicted destination, such as fibroblasts and epithelial cells in the lung, Kupffer cells in the liver, and endothelial cells in the brain. We found that exosome homing to organ-specific cell types prepares the pre-metastatic niche and that treatment with exosomes derived from lung tropic models can redirect metastasis to the lung. Proteomic profiling of exosomes revealed distinct integrin expression patterns associated with each organ-specific metastasis. Whereas exosomal integrins α6β4 and α6β1 were associated with lung metastasis, exosomal integrins αvβ5 and αvβ3 were linked with liver and brain metastases, respectively. Targeting α6β4 and αvβ5 integrins decreased exosome uptake and metastasis in the lung and liver, respectively. Importantly, we demonstrate that exosome uptake activates a cell-specific subset of S100 family genes, known to support cell migration and niche formation. Finally, our clinical data indicate that integrin-expression profiles in circulating plasma exosomes from cancer patients could be used to predict organ-specific metastasis.

Project description:Exosomes in the microenvironment play key roles in cellular signal transduction. The biological function of exosomes in cancer metastasis and progression, however, is still unknown.We used quantitative proteomics in this study to decipher the proteome of cellular exosomes derived from highly/lowly metastatic lung cancer cells and bioinformatics analysis showed that the differential proteins were associated with metastasis.

Project description:Pancreatic cancers (PCs) are highly metastatic with poor prognosis, mainly due to delayed detection. We hypothesized that intercellular communication is critical for metastatic progression. Here, we show that PC-derived exosomes induce liver pre-metastatic niche formation in naïve mice and consequently increase liver metastatic burden. Uptake of PC-derived exosomes by Kupffer cells caused transforming growth factor β secretion and upregulation of fibronectin production by hepatic stellate cells. This fibrotic microenvironment enhanced recruitment of bone marrow-derived macrophages. We found that macrophage migration inhibitory factor (MIF) was highly expressed in PC-derived exosomes, and its blockade prevented liver pre-metastatic niche formation and metastasis. Compared to patients whose pancreatic tumors did not progress, MIF was markedly higher in exosomes from stage I PC patients who later developed liver metastasis. These findings suggest that exosomal MIF primes the liver for metastasis and may be a prognostic marker for the development of PC liver metastasis.

Project description:The brain microenvironment imposes a particularly intense selective pressure on metastasis initiating cells, but successful metastasis bypass this control through mechanisms that are poorly understood. Reactive astrocytes are key components of this microenvironment, as they have been observed to confine brain metastasis without infiltrating the lesion. We describe a subpopulation of reactive astrocytes surrounding metastatic lesions that are characterized by the activation of STAT3 pathway. Blocking STAT3 signaling in this subpopulation of reactive astrocytes reduces experimental brain metastasis from different primary tumor sources, even at advanced stages of colonization. We conclude that brain metastatic cells induce and maintain the co-option of a pro-metastatic program driven by STAT3 in a subpopulation of reactive astrocytes. We also show that a safe and orally bioavailable treatment that inhibits STAT3 in patients with established brain metastasis and extracranial disease exhibits significant antitumor effects, especially in the CNS where several complete responses were achieved. Given that brain metastasis imposes significant morbidity and mortality, our experimental results suggest a novel treatment for increasing survival in patients with secondary brain tumors.

Project description:Pancreatic ductal adenocarcinoma (PDAC) shows a remarkable predilection for liver metastasis. Prooncogenic secretome delivering and trafficking via exosomes is crucial for pre-metastatic microenvironment formation and metastasis. This study aims to explore the underlying molecular mechanisms of how PDAC derived exosomes (Pex) modulate the microenvironments of future sites of metastasis.So we dicided using Hepatic Stellate Cells to see their transcriptomes changing after Pex addition.

Project description:Neuroblastoma (NB) is the most common extracranial pediatric solid tumor. At diagnosis, around 70% of patients with metastatic disease present bone-marrow (BM) infiltration; however, the mechanism underlying this specific tropism has to be elucidated. Tumor-derived exosomes may support metastatic progression in several tumors by interacting with the microenvironment, and may serve as tumor biomarkers. The main objective of this study was to identify an exosomal signature associated with NB metastatic BM dissemination. Therefore, we characterized the proteomic cargo of exosomes isolated from NB cell lines derived from primary tumor (PT) and BM metastasis. The comparison among all exosomal proteins showed 15 proteins exclusively present in PT, mainly involved in neuronal development, and 6 proteins in BM metastasis-derived exosomes related to cancer progression. Significant proteins obtained with t-test analysis, performed between the 2 groups (PT and BM metastasis), revealed that PT exosomes contain a higher level of proteins involved in extra-cellular matrix (ECM) assembly and adhesion, as well as in neuronal development. Exosomes isolated from BM metastasis showed proteins involved in ameboidal cell migration and mitochondrial activity. This work shows that proteomic profiling of NB-derived exosomes reflects the advanced tumor stage and may be considered as potential tumor biomarker

Project description:Keratinocyte carcinomas (KC) are the most common malignancy worldwide. This category of tumours groups both basal (BCC) and squamous (SCC) cell carcinomas. While the former rarely metastasizes (0.03-0.55%), the latter is more associated to a substantial risk of local recurrence, metastasis and death (1.5-4%). In addition, it is well known that the extracellular signals from tumour cells are involved in most of the steps triggering metastasis. This pro-metastatic signalling is mediated by proteins secreted by cancer cells, which constitute the tumour secretome and can be obtained from tumour interstitial fluid (TIF). The TIF baths the tumour and stromal cells and characterizes the tumour microenvironment. The proteomic study of TIF is of particular interest for explaining the metastatic potential of a tumour. In this work, we have analysed the proteomic composition of the TIF from BCC and SCC tumour biopsies and discovered a new set of extracellular proteins that could be useful as differential biomarkers. In addition, these proteins may help to understand the distinct invasive and metastatic abilities of the KC.