Project description:Tumor-derived extracellular vesicles (EVs) play critical roles in premetastatic niche (PMN) formation. Here, we demonstrated that EVs from highly metastatic osteosarcoma cell lines preferentially localized to lung fibroblasts and induce inflammatory PMN formation. High-throughput profiling of EVs-derived long noncoding RNAs (lncRNAs) identified lncOSLMT as a candidate enriched in EVs and markedly upregulated in patient tumor and serum, with elevated levels correlating with poor prognosis. Mechanistically, in EVs, lncOSLMT directly bound the RNA-binding protein hnRNPA2B1. Following internalization by recipient lung fibroblasts, hnRNPA2B1 bound to N⁶-methyladenosine (m⁶A) -modified sites in the 3’UTR of PTGS2 mRNA, leading to transcript stabilization and increased COX-2 expression. For therapeutic intervention, we developed lactoferrin-resveratrol (LF-RES) nanoparticles, which loaded siRNA against lncOSLMT. Intravenous administration of LF-RES-siRNA in mice reduced EVs-induced lung inflammation and suppressed lung metastasis. Combination with EP2/EP4 antagonists produced enhanced anti-metastatic effects. These findings establish EVs-derived lncOSLMT as a key regulator of inflammatory PMN formation in the lung and highlight the potential of LF-RES-siRNA nanoparticles as a targeted anti-metastatic therapy in osteosarcoma.

Project description:Tumor-derived extracellular vesicles (EVs) play critical roles in premetastatic niche (PMN) formation. Here, we demonstrated that EVs from highly metastatic osteosarcoma cell lines preferentially localized to lung fibroblasts and induce inflammatory PMN formation. High-throughput profiling of EVs-derived long noncoding RNAs (lncRNAs) identified lncOSLMT as a candidate enriched in EVs and markedly upregulated in patient tumor and serum, with elevated levels correlating with poor prognosis. Mechanistically, in EVs, lncOSLMT directly bound the RNA-binding protein hnRNPA2B1. Following internalization by recipient lung fibroblasts, hnRNPA2B1 bound to N⁶-methyladenosine (m⁶A) -modified sites in the 3’UTR of PTGS2 mRNA, leading to transcript stabilization and increased COX-2 expression. For therapeutic intervention, we developed lactoferrin-resveratrol (LF-RES) nanoparticles, which loaded siRNA against lncOSLMT. Intravenous administration of LF-RES-siRNA in mice reduced EVs-induced lung inflammation and suppressed lung metastasis. Combination with EP2/EP4 antagonists produced enhanced anti-metastatic effects. These findings establish EVs-derived lncOSLMT as a key regulator of inflammatory PMN formation in the lung and highlight the potential of LF-RES-siRNA nanoparticles as a targeted anti-metastatic therapy in osteosarcoma.

Project description:Pre-metastatic niche (PMN) formation is a critical step in metastatic progression, yet the biological effect of subtherapeutic-dose of ionizing radiation (SDIR) following radiotherapy on this process remains unclear. Using a 4T1 breast cancer mouse model, we investigated the effects of SDIR (3×0.3 Gy) on lung PMN development and metastasis formation. Lung PMNs were exposed to SDIR on days 8–10 post-tumor induction, followed by mastectomy on day 18, and analyzed on day 24. SDIR significantly increased total metastatic volume (TMV) in lungs, suggesting an accelerated PMN formation. Mechanistically, SDIR upregulated Bv8 expression, enhanced neutrophil recruitment, and increased MMP9, S100A8, and IL-6 production in the PMN by day 11, though differences between irradiated and non-irradiated PMN were no longer evident by day 14. Notably, Bv8 inhibition prevented SDIR-induced neutrophil recruitment but did not reduce TMV, indicating additional mechanisms in SDIR-driven metastasis. Proteomic analysis revealed SDIR-induced metabolic reprogramming, extracellular matrix (ECM) remodeling, and upregulation of adhesion-related pathways, driving a microenvironment that accelerates tumor invasion and metastatic outgrowth. By demonstrating that SDIR reprograms the pre-metastatic lung microenvironment, this study highlights the need to integrate organ-specific radiation exposure into predictive models of metastasis and identifies metabolic and immune-stromal pathways as potential targets for therapeutic intervention.

Project description:Accelerated senescence in lung epithelial cells is known to play a key role in the pathogenesis of idiopathic pulmonary fibrosis (IPF). However, the exact mechanisms underlying the IPF-related epithelial cell phenotype have yet to be elucidated. Increasing evidence supports the concept that extracellular vesicles (EVs), including exosomes and microvesicles, mediate intercellular communication that contributes to diverse aspects of physiology and pathogenesis. Here, we demonstrate that lung fibroblasts (LFs) from IPF patients accelerate epithelial cell senescence via EV-mediated transfer of LF-derived pathogenic cargo to lung epithelial cells. Mechanistically, IPF LF-derived EVs increase mitochondrial reactive oxygen species (mtROS) and associated mitochondrial damage in lung epithelial cells, leading to mtROS-mediated activation of the DNA damage response and subsequent epithelial cell senescence. We show that IPF LF-derived EVs contain elevated levels of miR-23b-3p and miR-494-3p that are responsible for suppressing SIRT3, resulting in the EV-induced phenotypic changes of lung epithelial cells. Furthermore, we observe that miR-23b-3p and miR-494-3p expression increases in lung epithelial cells from IPF patients’ lungs. Finally, the levels of miR-23b-3p and 494-3p found in IPF LF-derived EVs correlate positively with IPF disease severity. These findings reveal that the accelerated epithelial cell mitochondrial damage and senescence observed during IPF pathogenesis are caused by a novel mechanism in which SIRT3 is suppressed by miR-containing EVs derived from IPF fibroblasts.

Project description:Accelerated senescence in lung epithelial cells is known to play a key role in the pathogenesis of idiopathic pulmonary fibrosis (IPF). However, the exact mechanisms underlying the IPF-related epithelial cell phenotype have yet to be elucidated. Increasing evidence supports the concept that extracellular vesicles (EVs), including exosomes and microvesicles, mediate intercellular communication that contributes to diverse aspects of physiology and pathogenesis. Here, we demonstrate that lung fibroblasts (LFs) from IPF patients accelerate epithelial cell senescence via EV-mediated transfer of LF-derived pathogenic cargo to lung epithelial cells. Mechanistically, IPF LF-derived EVs increase mitochondrial reactive oxygen species (mtROS) and associated mitochondrial damage in lung epithelial cells, leading to mtROS-mediated activation of the DNA damage response and subsequent epithelial cell senescence. We show that IPF LF-derived EVs contain elevated levels of miR-23b-3p and miR-494-3p that are responsible for suppressing SIRT3, resulting in the EV-induced phenotypic changes of lung epithelial cells. Furthermore, we observe that miR-23b-3p and miR-494-3p expression increases in lung epithelial cells from IPF patients’ lungs. Finally, the levels of miR-23b-3p and 494-3p found in IPF LF-derived EVs correlate positively with IPF disease severity. These findings reveal that the accelerated epithelial cell mitochondrial damage and senescence observed during IPF pathogenesis are caused by a novel mechanism in which SIRT3 is suppressed by miR-containing EVs derived from IPF fibroblasts.

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: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:Our research aims to chart the circRNA expression profile and assess their impact on the lung PMN. We developed a lung PMN model and employed comprehensive RNA sequencing to analyze the differences in circRNA expression between normal and pre-metastatic lungs.Overall, our study highlights the crucial role of circRNAs in the formation of lung PMNs, supporting their potential as diagnostic or therapeutic targets for lung metastasis.

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:Mice were intravenously injected with extracellular vesicles (EVs) isolated from B16V wt (n=3) or BAG6KO (n=3) cells or with PBS (n=3) as a control for 4 weeks on a weekly basis. Since B-16V melanoma cells colonise the lung upon intravenous injection and referring to current literature, we hypothesise that melanoma EVs alter the (immune-) microenvironment of the lung to prepare a pre-metastatic niche. Based on current literature and own previous experiments identifying BAG6 as an immunoregulatory protein that is also involved in the biogenesis of EVs, we are particularly interested in differences between the immune signature upon wt EV treatment compared to BAG6KO EV treatment.