Project description:miR-100 maintains phenotype of tumor associated macrophages by targeting mTOR to promote tumor metastasis via Stat5a/IL-1ra pathway in mouse breast cancer

Project description:This study provides a novel mechanism that RAS activation of breast cancer cells induces osteolytic bone metastasis by stimulating the exosome-mediated transfer of osteoclastogenic miRNAs including miR-494-3p to bone cells

Project description:Metastasis is the primary cause of mortality in breast cancer patients. Tumor associated macrophages (TAMs) are active collaborators in mediating several steps of the tumor metastatic cascade, but the molecular details governing this collaboration remain ill-defined. Colony Stimulating Factor 1 (CSF1), a factor critical for macrophage differentiation and survival, functions to recruit TAMs to the primary tumor site, and anti-CSF1 therapies are in clinical trials.In this study, we tested the effect of inhibiting CSF1 signaling in macrophages on gene expression in metastatic tumor cells in mouse models of breast cancer metastasis. Tumor cells were sorted from lung metastases from control and CSF1R inhibitor treated mice. Several pro-tumor processes were significantly affected by CSF1R inhibitor treatment, including angiogenesis and tumor cell proliferation. In addition, a 29 gene signature derived from this data could retrospectively predict survival in a cohort of luminal B breast cancer patients. Collectievly, our results highlight the utility of employing CSF1R inhibitors for the treatment of metastatic breast cancer.

Project description:Metastasis is the primary cause of mortality in breast cancer patients. Tumor associated macrophages (TAMs) are active collaborators in mediating several steps of the tumor metastatic cascade, but the molecular details governing this collaboration remain ill-defined. Colony Stimulating Factor 1 (CSF1), a factor critical for macrophage differentiation and survival, functions to recruit TAMs to the primary tumor site, and anti-CSF1 therapies are in clinical trials.In this study, we tested the effect of inhibiting CSF1 signaling in macrophages on gene expression in metastatic tumor cells in mouse models of breast cancer metastasis. Tumor cells were sorted from lung metastases from control and CSF1R inhibitor treated mice. Several pro-tumor processes were significantly affected by CSF1R inhibitor treatment, including angiogenesis and tumor cell proliferation. In addition, a 29 gene signature derived from this data could retrospectively predict survival in a cohort of luminal B breast cancer patients. Collectievly, our results highlight the utility of employing CSF1R inhibitors for the treatment of metastatic breast cancer. GFP tagged MVT1 metastatic mammary tumor cells were injected intravenously into FVB/N mice. Mice were gavaged with the CSF1R inhibitor GW2580 or vehicle starting one week post injection. GFP tagged tumor cells were sorted from metastatic tumor bearing lungs 1 and 2 weeks post injection from 2 vehicle treated mice for each. These are denoted 1_week_WT and 2_week_WT respectively. GFP tagged tumor cells were simultaneously sorted from mice gavaged with GW2580. These samples are denoted 2_week_GW. RNA was extracted and gene expression profiling was performed using the Affymetrix Mouse Genome 430 2.0 Array platform.

Project description:MicroRNAs (miRNAs) are single-stranded noncoding RNAs that play important roles in many biological processes. Although the oncogenic and tumor suppressive functions of several miRNAs have been characterized, the role of miRNAs in mediating tumor metastasis was only recently addressed and still remain largely unexplored. To identify potential metastasis-promoting miRNAs, we set up a genetic screen using a non-metastatic human breast tumor cell line that was transduced with a miRNA expression library and subjected to a trans-well migration assay. We found human miR-373 and 520c to stimulate cancer cell migration as well as tumor cell invasion in vitro and in vivo, and that certain cancer cell lines depend on endogenous miR-373 activity to migrate efficiently. Mechanistically, the migration phenotype of miR-373 and miR-520c can be explained by their suppression of CD44 expression. Finally, we found significant up-regulation of miR-373 expression in clinical breast cancer primary and metastasis samples that inversely correlated with CD44 expression. Taken together, our study indicates that miRNAs are involved in tumor migration and invasion and implicates miR-373 and conceivably miR-520c as metastasis-promoting miRNAs. Keywords: human breast cancer cell MCF7 vs MCF7 expressing miR-373 vs MCF7 expressing miR-520c

Project description:Tumor microenvironment-targeted therapies are emerging as promising treatment options for different tumor types. Tumor-associated macrophages/microglia (TAMs) represent the most abundant non-malignant cell type in brain metastasis and are known to support metastatic colonization and outgrowth. We used the colony-stimulating factor 1 receptor (Csf1r) inhibitor BLZ945 to target TAMs at distinct stages of the metastatic cascade in experimental breast-to-brain metastasis and demonstrate that Csf1r inhibition leads to anti-tumor responses in prevention and intervention trails. However, compensatory Csf2-mediated pro-inflammatory TAM activation blunts long-term efficacy of Csf1r inhibition by inducing signatures associated with neuroinflammation followed by wound repair responses that foster tumor recurrence. Combined blockade of Csf1r and Csf2rb-Stat5 signaling leads to sustained tumor control and a normalization of microglial activation states.

Project description:Macrophages have been implicated in breast cancer progression and metastasis, but relatively little is known about the genes and pathways that are involved. Using a conditional allele of Ets2 in the mouse, we have identified Ets2 as a critical gene in tumor associated macrophages (TAMs) that specifically promotes mammary tumor metastasis. Loss of Ets2 in TAMs decreased the frequency and size of lung metastases without impacting primary tumor burden. Expression profiling of isolated tumor macrophages established that Ets2 deficiency resulted in the de-repression of a defined set of anti-angiogenic genes. Activation of this transcriptional program correlated with decreased angiogenesis in metastatic tumors and decreased metastatic growth. Comparison of this Ets2-specific TAM expression profile with human breast cancer profiles revealed a macrophage gene expression signature that could predict overall survival of estrogen receptor negative patients. In summary, we have identified a critical factor, Ets2, in TAMs that represses a transcriptional program to promote the growth of mammary tumor metastases in the lung. Breast TAMs were isolated from early-stage PyMT-induced mammary tumors expressing Ets2 and also from the tumors with Ets2-deficient TAMs. Since macrophages have also been implicated in normal mammary gland remodeling, normal remeodeling macrophages were also purified from females expressing Ets2 and the ones where Ets2 is deleted in the macrophages. One RNA sample was extracted from each genetic group for gene-expression profiling.

Project description:MicroRNAs (miRNAs) regulate many genes critical for tumorigenesis. We profiled miRNAs from 11 normal breast tissues, 17 non-invasive, 151 invasive breast carcinomas, and 6 cell lines by in-house-developed barcoded Solexa sequencing. miRNAs were organized in genomic clusters representing promoter-controlled miRNA expression and sequence families representing seed-sequence-dependent miRNA-target regulation. Unsupervised clustering of samples by miRNA sequence families best reflected the clustering based on mRNA expression available for this sample set. Clustering and comparative analysis of miRNA read frequencies showed that normal breast samples were separated from most non-invasive ductal carcinoma in situ and invasive carcinomas by increased miR-21 (the most abundant miRNA in carcinomas) and multiple decreased miRNA families (including mir-98/let-7), with most miRNA changes apparent already in the non-invasive carcinomas. In addition, patients that went on to develop metastasis demonstrated increased expression of mir-423, and triple negative breast carcinomas were most distinct from other tumor subtypes due to up-regulation of the mir-17~92 cluster. However, absolute miRNA levels between normal breast and carcinomas did not reveal any significant differences. We also discovered two polymorphic nucleotide variations among the more abundant miRNAs miR-181a (T19G) and miR-185 (T16G), but we did not identify nucleotide variations expected for classical tumor suppressor function associated with miRNAs. The differentiation of tumor subtypes and prediction of metastasis based on miRNA levels is statistically possible, but is not driven by deregulation of abundant miRNAs, implicating far fewer miRNAs in tumorigenic processes than previously suggested. mRNA profiles for 161 normal breast and invasive breast carcinomas using NKI Operon V3 arrays; These samples have matched entries for miRNA profiles also included in this GEO submission.

Project description:This SuperSeries is composed of the following subset Series: GSE29173: MicroRNA sequence and expression analysis in breast tumors by deep sequencing [miRNA sequence data] GSE29174: MicroRNA sequence and expression analysis in breast tumors by deep sequencing [mRNA expression array data] MicroRNAs (miRNAs) regulate many genes critical for tumorigenesis. We profiled miRNAs from 11 normal breast tissues, 17 non-invasive, 151 invasive breast carcinomas, and 6 cell lines by in-house-developed barcoded Solexa sequencing. miRNAs were organized in genomic clusters representing promoter-controlled miRNA expression and sequence families representing seed-sequence-dependent miRNA-target regulation. Unsupervised clustering of samples by miRNA sequence families best reflected the clustering based on mRNA expression available for this sample set. Clustering and comparative analysis of miRNA read frequencies showed that normal breast samples were separated from most non-invasive ductal carcinoma in situ and invasive carcinomas by increased miR-21 (the most abundant miRNA in carcinomas) and multiple decreased miRNA families (including mir-98/let-7), with most miRNA changes apparent already in the non-invasive carcinomas. In addition, patients that went on to develop metastasis demonstrated increased expression of mir-423, and triple negative breast carcinomas were most distinct from other tumor subtypes due to up-regulation of the mir-17~92 cluster. However, absolute miRNA levels between normal breast and carcinomas did not reveal any significant differences. We also discovered two polymorphic nucleotide variations among the more abundant miRNAs miR-181a (T19G) and miR-185 (T16G), but we did not identify nucleotide variations expected for classical tumor suppressor function associated with miRNAs. The differentiation of tumor subtypes and prediction of metastasis based on miRNA levels is statistically possible, but is not driven by deregulation of abundant miRNAs, implicating far fewer miRNAs in tumorigenic processes than previously suggested. Refer to individual Series

Project description:Molecular mechanisms underlying the cancer stroma in metastasis is largely unknown. Here we show that cancer-associated fibroblasts (CAFs) produce high levels of IL-33 that acted on tumor-associated macrophages (TAMs) to induce the M1 to M2 transition. Genome profiling of metastasis-related genes in the IL-33-stimulated TAMs showed a > 200-fold increase of metalloproteinase 9 (MMP9). Signaling analysis demonstrated the IL-33-ST2-NFkB-MMP9-laminin pathway that mediates cancer metastasis. In mouse and human fibroblast-rich pancreatic cancers, genetic deletion of IL-33, ST2 and MMP9 markedly blocked metastasis. Pharmacological inhibition of NFkB and MMP9 also blocked cancer metastasis. Deletion of IL-33, ST2 and MMP9 restored laminin, a key basement membrane component associated to tumor microvessels. Together, our data provide novel mechanistic insights on the IL-33-NFkB-MMP9-laminin axis that mediates the CAF-TAM-committed cancer metastasis. Thus, targeting the CAF-TAM-vessel interaction provides an outstanding therapeutic opportunity for cancer treatment.