Project description:Exososmes, potent intercellular communicators, are supposed to contribute to metastasis formation, which we confirmed for exosomes of the metastatic rat pancreatic adenocarcinoma line BSp73ASML that promote metastatic settlement in lymph nodes and lung of poorly metastatic BSp73ASML cells with a selective CD44v4-v7 (BSp73ASML-CD44vkd) knockdown. To define the molecular pathway(s), whereby exosomes contribute to premetastatic niche preparation, we profiled mRNA miRNA of BSp73ASMLwt and BSp73ASML-CD44vkd- exosomes and evaluated the impact on potential target cells. BSp73ASML exosomes are recovered in the draining lymph node after subcutaneous injection. In vitro, they preferentially bind and are taken-up by lymph node stroma cells (LnStr) and lung fibroblasts (LuFb) that were chosen as exosome targets. BSp73ASMLwt and BSp73ASML-CD44kd exosomes contain a restricted repertoire of mRNA and miRNA, hwere the lattter differe significantly between the two lines and even more pronounced, exosomes derived thereof with a not yet explored dominance of tumor-suppressor miRNA in ASML-CD44kd cells and exosomes. Both, exosomal mRNA and miRNA are recovered in target cells and exosome-uptake is accompanied by significant changes in gene expression. We didn't observe a correlation between exosomal mRNA and changes in target cell mRNA or proteins. Instead transferred miRNA significantly affected target cell mRNA translation as demonstrated for selected, most abundant ASML exosomal miRNA besides others, miR-494 known target MAL (myelin and lymphocytes protein)/cadherin17, and miR-542-3p which targets TRAF/cadherin17. Furthermore, MMP transcription suggested to accompany cadherin17 dwon-regulation was upregulated in miR-494 or miR542-3p transfected or exosome co-cultured LnStr. Taken together, tumor exosomes target in vivo non-transformed cells in premetastatic organs. Exosome uptake induced altered target celll gene expression is strongly promoted by exosomal miRNA where we demonstrate for the first time that exosomes/exosomal miRNA from a metastasizing tumor line can modulate stroma cells from premetastatic organs. Endothelial cells lines were treated with pancreatic adenocarcinoma (AS) derived exosomes or pancreatic adenocarcinoma derived exosomes expressing tetraspanin 8. Total RNA was isolated and used to perform the Agilent gene expression microarrays. In this assay a replicate of endothelial cell lines treated with ASTspan8 were also included. Moreover, total RNA from both base line expression of endothelial cells and rat endothelial fibroblasts were also used to perfrom gene expression microarrays. RNA isolated from Rat endothelial fibroblasts treated with the exosomes derived from rat pancreatic adenocarcinoma and exosomes derived from rat pancreatic adenocarcinoma expressing tetraspanin8 were individually used to perfrom gene expression microarrays. RNA isolated from exosomes derived from rat pancreatic adenocarcinoma cell lines expressing tetraspanin were used to peform gene expresiion to see the base line expression. Another replicate were also used. RNA isolated from base line or control of rat pancreatic adenocarcinoma wild type cells and also base line RNA isolated from rat pancreatic adenocarcinoma cells lines where CD44 was knock-down.

Project description:Exososmes, potent intercellular communicators, are supposed to contribute to metastasis formation, which we confirmed for exosomes of the metastatic rat pancreatic adenocarcinoma line BSp73ASML that promote metastatic settlement in lymph nodes and lung of poorly metastatic BSp73ASML cells with a selective CD44v4-v7 (BSp73ASML-CD44vkd) knockdown. To define the molecular pathway(s), whereby exosomes contribute to premetastatic niche preparation, we profiled mRNA miRNA of BSp73ASMLwt and BSp73ASML-CD44vkd- exosomes and evaluated the impact on potential target cells. BSp73ASML exosomes are recovered in the draining lymph node after subcutaneous injection. In vitro, they preferentially bind and are taken-up by lymph node stroma cells (LnStr) and lung fibroblasts (LuFb) that were chosen as exosome targets. BSp73ASMLwt and BSp73ASML-CD44kd exosomes contain a restricted repertoire of mRNA and miRNA, hwere the lattter differe significantly between the two lines and even more pronounced, exosomes derived thereof with a not yet explored dominance of tumor-suppressor miRNA in ASML-CD44kd cells and exosomes. Both, exosomal mRNA and miRNA are recovered in target cells and exosome-uptake is accompanied by significant changes in gene expression. We didn't observe a correlation between exosomal mRNA and changes in target cell mRNA or proteins. Instead transferred miRNA significantly affected target cell mRNA translation as demonstrated for selected, most abundant ASML exosomal miRNA besides others, miR-494 known target MAL (myelin and lymphocytes protein)/cadherin17, and miR-542-3p which targets TRAF/cadherin17. Furthermore, MMP transcription suggested to accompany cadherin17 dwon-regulation was upregulated in miR-494 or miR542-3p transfected or exosome co-cultured LnStr. Taken together, tumor exosomes target in vivo non-transformed cells in premetastatic organs. Exosome uptake induced altered target celll gene expression is strongly promoted by exosomal miRNA where we demonstrate for the first time that exosomes/exosomal miRNA from a metastasizing tumor line can modulate stroma cells from premetastatic organs.

Project description:This SuperSeries is composed of the following subset Series: GSE34737: Comparative analysis of mRNA expression in untreated lymph node stroma cells and upon treatment with exosomes derived from ASMLwt, ASML cd44v knockdown cells. GSE34738: Characterization of exosomes from highly metastatic pancreatic adenocarcinoma line: ASML and a CD44v kd of ASML based on their miRNA content Refer to individual Series

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Tumor exosomes educate selected host tissues toward a prometastatic phenotype. We demonstrated this for exosomes of the metastatic rat adenocarcinoma BSp73ASML (ASML), which modulate draining lymph nodes and lung tissue to support settlement of poorly metastatic BSp73ASML-CD44v4-v7 knockdown (ASML-CD44v(kd)) cells. Now, we profiled mRNA and microRNA (miRNA) of ASML(wt) and ASML-CD44v(kd) exosomes to define the pathway(s), whereby exosomes prepare the premetastatic niche. ASML exosomes, recovered in draining lymph nodes after subcutaneous injection, preferentially are taken up by lymph node stroma cells (LnStr) and lung fibroblasts (LuFb) that were chosen as exosome targets. ASML(wt) and ASML-CD44v(kd) exosomes contain a restricted mRNA and miRNA repertoire that differs significantly between the two lines and exosomes thereof due to CD44v6 influencing gene and miRNA transcription/posttranscriptional regulation. Exosomal mRNA and miRNA are recovered in target cells, where transferred miRNA significantly affected mRNA translation. Besides others, this was exemplified for abundant ASML(wt)-exosomal miR-494 and miR-542-3p, which target cadherin-17 (cdh17). Concomitantly, matrix metalloproteinase transcription, accompanying cdh17 down-regulation, was upregulated in LnStr transfected with miR-494 or miR-542-3p or co-cultured with tumor exosomes. Thus, tumor exosomes target non-transformed cells in premetastatic organs and modulate premetastatic organ cells predominantly through transferred miRNA, where miRNA from a metastasizing tumor prepares premetastatic organ stroma cells for tumor cell hosting. Fitting the demands of metastasizing tumor cells, transferred exosomal miRNA mostly affected proteases, adhesion molecules, chemokine ligands, cell cycle- and angiogenesis-promoting genes, and genes engaged in oxidative stress response. The demonstration of function-competent exosomal miRNA in host target cells encourages exploiting exosomes as a therapeutic gene delivery system.

Project description:Fibroblast STAT3 activation drives organ-specific premetastatic niche formation

Project description:Exosomal tumor microRNA modulates premetastatic organ cells [Agilent]

Project description:Pancreatic cancer is associated with a high rate of metastasis and poor prognosis. The formation of a premetastatic niche (PMN) facilitates cancer cell spread and contributes to cancer mortality. Using murine pancreatic cancer models based on expression of oncogenic KRAS in the pancreas epithelium, we discovered that remodeling of the lung microenvironment occurred in mice bearing pancreatic precursor lesions prior to cancer formation. This early lesion premetastatic niche (EL-PMN) resembled the PMN in cancer-bearing mice, and both feature characteristics of overt metastasis, such as transcriptional reprogramming, activation of fibroblast STAT3 signaling, and infiltration of immunosuppressive ARG1+ macrophages. Both pancreatic cancer patients and mouse models demonstrated elevated serum IL6. Inactivating oncogenic KRAS reduced serum IL6 and reverted fibroblast STAT3 phosphorylation in mouse lungs; loss of lung fibroblast STAT3 phosphorylation was similarly observed when mice were treated with the pan-RAS inhibitor RMC7977. While ARG1+ macrophage infiltration was dispensable for fibroblast STAT3 activation, IL6 blockade inhibited lung fibroblast STAT3 activation. Functionally, fibroblast STAT3 activation was necessary for lung metastasis establishment and growth. Interestingly, activation of STAT3 in the PMN was present in the lungs but not in the liver, where fibroblast reprogramming occurred only in overt metastasis, pointing to organ-specific PMN formation. In human metastasis samples, phosphorylated STAT3 in fibroblasts was similarly more abundant in the lungs than liver. Together, these data point to organ-specific mechanisms driving formation of the PMN and indicate that reprogramming of the microenvironment prior to metastasis might support early dissemination of pancreatic cancer.

Project description:To identify and assess exosomal miRNA signatures with potential to predict individuals with persistent organ failure (POF) at early phase of acute pancreatitis. We analyzed serum collected from 790 AP patients. In discovery cohort, we profiled exosomal miRNAs in sera sampled from AP patients with or without POF (5 vs. 5) using microarrays and identified a list of miRNAs with increased expression pattern. Of notes, 10 AP samples with/without POF are collected within 24 hours after AP onset and later did/didn’t develop POF. We further constructed a miRNA classifier (Cmi) through logistic regression and identified certain individual miRNAs (OR>2) as candidate predictive markers in the training cohort of 227 AP samples. Predictive performance of these markers were validated in three independent cohorts (255, 226 and 78 AP samples respectively).

Project description:To investigate the exosomal miRNA changes under LPS treatment in RAW 264.7 cells, 2 μg/mL LPS were added into complete medium to incubate RAW 264.7 cells. And then The exosomes were isolated and tested the exosomal miRNAs change using microarray.