Platelets, in addition to their function in hemostasis, play an important role in wound healing and tumor growth. Because platelets contain angiogenesis stimulators and inhibitors, the mechanisms by which platelets regulate angiogenesis remain unclear. As platelets adhere to activated endothelium, their action can enhance or inhibit local angiogenesis. We therefore suspected a higher organization of angiogenesis regulators in platelets. Using double immunofluorescence and immunoelectron microscopy, we show that pro-and antiangiogenic proteins are separated in distinct subpopulations of ␣-granules in platelets and megakaryocytes. Double immunofluorescence labeling of vascular endothelial growth factor (VEGF) (an angiogenesis stimulator) and endostatin (an angiogenesis inhibitor), or for thrombospondin-1 and basic fibroblast growth factor, confirms the segregation of stimulators and inhibitors into separate and distinct ␣-granules. These observations motivated the hypothesis that distinct populations of ␣-granules could undergo selective release. The treatment of human platelets with a selective PAR4 agonist (AYPGKF-NH 2 ) resulted in release of endostatin-containing granules, but not VEGF-containing granules, whereas the selective PAR1 agonist (TFLLR-NH 2 ) liberated VEGF, but not endostatin-containing granules. In conclusion, the separate packaging of angiogenesis regulators into pharmacologically and morphologically distinct populations of ␣-granules in megakaryocytes and platelets may provide a mechanism by which platelets can locally stimulate or inhibit angiogenesis. IntroductionAngiogenesis, the process of new vessel development, plays an essential role in embryogenesis, but postnatal angiogenesis is limited to sites of abnormal vascular surface. An activated vascular endothelium can be induced by tissue injury or wound healing, by hormonal cycling such as in pregnancy and ovulation, or by tumor-induced vessel growth. In all of these circumstances, platelets act as the initial responder to vascular change and provide a flexible delivery system for angiogenesis-related molecules. [1][2][3][4] The process of postnatal angiogenesis is regulated by a continuous interplay of stimulators and inhibitors of angiogenesis, and their imbalance contributes to numerous inflammatory, malignant, ischemic, and immune disorders. 5 There is a revived interest in the overlap between angiogenesis and platelets 6 because several clinical trials have now shown that anticoagulation can improve cancer survival 7,8 beyond the benefit derived from the treatment of deep vein thrombosis alone.It is known that platelets stimulate endothelial cells in culture and can promote the assembly of capillary-like structures in vitro. 9,10 Platelets may modulate angiogenesis by releasing promoters such as vascular endothelial growth factor (VEGF), basic fibroblast growth factor (bFGF), epidermal growth factor (EGF), platelet derived growth factor (PDGF), and matrix metalloproteinases (MMPs). 1,6,[11][12][13][14][15][16][17][18] The repertoire o...
SUMMARY Lung stem cells are instructed to produce lineage-specific progeny through unknown factors in their microenvironment. We used clonal three-dimensional (3D) co-cultures of endothelial cells and distal lung stem cells, bronchioalveolar stem cells (BASCs), to probe the instructive mechanisms. Single BASCs had bronchiolar and alveolar differentiation potential in lung endothelial cell co-cultures. Gain and loss of function experiments showed BMP4-Bmpr1a signaling triggers calcineurin/NFATc1-dependent expression of Thrombospondin-1 (Tsp1) in lung endothelial cells to drive alveolar lineage-specific BASC differentiation. Tsp1-null mice exhibited defective alveolar injury repair, confirming a crucial role for the BMP4-NFATc1-TSP1 axis in lung epithelial differentiation and regeneration in vivo. Discovery of this pathway points to methods to direct the derivation of specific lung epithelial lineages from multipotent cells. These findings elucidate a pathway that may be a critical target in lung diseases and provide new tools to understand the mechanisms of respiratory diseases at the single cell level.
Metastasis is responsible for the majority of prostate cancer-related deaths; however, little is known about the molecular mechanisms that underlie this process. Here we identify an oncogene-tumor suppressor cascade that promotes prostate cancer initiation and metastasis by coordinately activating Ras and NF-κB. Specifically, we show that loss of the RasGAP gene DAB2IP induces metastatic prostate cancer in a murine model. Notably, DAB2IP functions as a signaling scaffold that coordinately regulates Ras and NF-κB through distinct domains to promote tumor initiation and metastasis, respectively. DAB2IP is suppressed in human prostate cancer where expression inversely correlates with tumor grade and predicts prognosis. Moreover, we report that epigenetic silencing of DAB2IP is a key mechanism by which the polycomb-group protein EZH2 activates Ras, NF-κB, and triggers metastasis. These studies define the mechanism by which two major pathways can be simultaneously activated in metastatic prostate cancer and establish EZH2 as a driver of metastasis.
The incidence of many cancer types is significantly reduced in individuals with Down syndrome1–4 and it is proposed that this broad cancer protection is conferred by the elevated expression of one or more of the 231 supernumerary genes on the extra copy of chromosome 21. One such gene is the Down syndrome candidate region-1 (Dscr1, RCAN1), which encodes a protein that suppresses vascular endothelial growth factor (VEGF)-mediated angiogenic signalling via the calcineurin pathway5–10. Here we show that DSCR1 is elevated in Down syndrome individuals and a mouse model of Down syndrome. Further, we show that the modest elevation in expression afforded by a single extra transgenic copy of Dscr1 is sufficient to confer significant suppression of tumor growth in mice and that such resistance is a consequence of a deficit in tumor angiogenesis arising from suppression of the calcineurin pathway. We also provide evidence that attenuation of calcineurin activity by DSCR1 together with another chromosome 21 gene DYRK1A, may be sufficient to dramatically diminish angiogenesis. These data provide a mechanism for the reduced cancer incidence in Down syndrome and identifies the calcineurin signalling pathway and its regulators DSCR1 and DYRK1A as potential therapeutic targets in cancers arising in all individuals.
Summary Oncogene addiction is thought to occur cell autonomously. Immune effectors are implicated in the induction and restraint of tumorigenesis, but their role in oncogene inactivation mediated tumor regression is unclear. Here, we show that an intact immune system, specifically CD4+ T-cells, is required for the induction of cellular senescence, shut down of angiogenesis and chemokine expression resulting in sustained tumor regression upon inactivation of the MYC or BCR-ABL oncogenes in mouse models of T-cell acute lymphoblastic lymphoma and pro-B-cell leukemia, respectively. Moreover, immune effectors knocked out for thrombospondins failed to induce sustained tumor regression. Hence, CD4+ T-cells are required for the remodeling of the tumor microenvironment through the expression of chemokines, such as thrombospondins, in order to elicit oncogene addiction.
Inactivating mutations in NF1 underlie the prevalent familial cancer syndrome neurofibromatosis type 1 [1]. The NF1-encoded protein is a Ras GTPase-activating protein (RasGAP) [2]. Accordingly, Ras is aberrantly activated in NF1-deficient tumors; however, it is unknown which effector pathways critically function in tumor development. Here we provide in vivo evidence that TORC1/mTOR activity is essential for tumorigenesis. Specifically, we show that the mTOR inhibitor rapamycin potently suppresses the growth of aggressive NF1-associated malignancies in a genetically engineered murine model. However, in these tumors rapamycin does not function via mechanisms generally assumed to mediate tumor suppression, including inhibition of HIF-1alpha and indirect suppression of AKT, but does suppress the mTOR target Cyclin D1 [3]. These results demonstrate that mTOR inhibitors may be an effective targeted therapy for this commonly untreatable malignancy. Moreover, they indicate that mTOR inhibitors do not suppress all tumor types via the same mechanism, suggesting that current biomarkers that rely on HIF-1alpha suppression may not be informative for all cancers. Finally, our results reveal important differences between the effects of mTOR inhibition on the microvasculature in genetically engineered versus xenograft models and indicate that the former may be required for effective preclinical screening with this class of inhibitors.
Targeted therapies aimed at tumor vasculature are utilized in combination with chemotherapy to improve drug delivery and efficacy after tumor vascular normalization. Tumor vessels are highly disorganized with disrupted blood flow impeding drug delivery to cancer cells. Although pharmacologic anti-angiogenic therapy can remodel and normalize tumor vessels, there is a limited window of efficacy and these drugs are associated with severe side effects necessitating alternatives for vascular normalization. Recently, moderate aerobic exercise has been shown to induce vascular normalization in mouse models. Here, we provide a mechanistic explanation for the tumor vascular normalization induced by exercise. Shear stress, the mechanical stimuli exerted on endothelial cells by blood flow, modulates vascular integrity. Increasing vascular shear stress through aerobic exercise can alter and remodel blood vessels in normal tissues. Our data in mouse models indicate that activation of calcineurin-NFAT-TSP1 signaling in endothelial cells plays a critical role in exercise-induced shear stress mediated tumor vessel remodeling. We show that moderate aerobic exercise with chemotherapy caused a significantly greater decrease in tumor growth than chemotherapy alone through improved chemotherapy delivery after tumor vascular normalization. Our work suggests that the vascular normalizing effects of aerobic exercise can be an effective chemotherapy adjuvant.
SummaryLow-dose exposures to common environmental chemicals that are deemed safe individually may be combining to instigate carcinogenesis, thereby contributing to the incidence of cancer. This risk may be overlooked by current regulatory practices and needs to be vigorously investigated.
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