Rôle de la Protéine C, un anticoagulant naturel, dans l’association thrombose et cancer

It is now recognized that the invasiveness of tumor cells is not only related to the genotype of these cells but also to their interaction with tumor microenvironment (TM). Within the TM, stromal matrix destabilization promotes tumor progression and metastatic dissemination. The extracellular matrix remodeling is often driven by proteolytic enzymes. However, few studies have investigated the effects of an impairment of the matrix formation. Given these facts and circumstances, we were interested in protein C (PC) and its endothelial receptor (EPCR), as well as in their role in tumorigenesis in leukemia and solid cancers.EPCR is expressed by a wide range of cancer cell lines. It is also detected within the tumor compartment in patients with malignant diseases. EPCR gene is highly conserved but nevertheless contains polymorphisms. One of these SNPs (single nucleotide polymorphism) - 6936A/G – reflects – in the release of a soluble circulating form (EPCRs) resulting from the proteolysis of membrane-associated form. In leukemic patients a high incidence of 6936A/G SNP is observed and associated with thrombosis events. Moreover, EPCR is detected in the majority of tumor biopsies and is abundantly secreted in ascitic fluid. The PC attachment to EPCR and its activation promotes cell survival and migratory potential of tumor cells. Also, APC is able to modulate, by a paracrine manner, interleukins and cytokines secretion. Thus, ovarian cancer cells stimulation by APC induces the synthesis of a functional ovarian thrombopoietin. As this cytokine has a regulatory effect on platelet production, APC may be once again at the interface between hemostasis disorders and coagulation. The elucidation of the intricate role of APC and its endothelial receptor could permit not only to identify new therapeutic approaches but also to prevent cancer-associated thrombosis risk and to decrease morbidity in cancer patients.Il est désormais admis que le caractère invasif d'une tumeur est lié, non seulement, au génotype des cellules cancéreuses, mais aussi à leurs interactions avec le microenvironnement tumoral (MT). Au sein du MT, une déstabilisation de la matrice stromale favorise la progression tumorale et la dissémination métastatique. Le remaniement de la matrice extracellulaire est souvent piloté par des enzymes protéolytiques. En revanche, les effets de l'inhibition de la formation de cette matrice sont peu étudiés. C’est dans cette optique que nous nous sommes intéressés à la protéine C (PC) et son récepteur endothélial (EPCR) et à leur rôle dans la tumorigenèse des leucémies et des cancers solides.L’EPCR est exprimé par un grand nombre de lignées cellulaires cancéreuses. Il est aussi détecté dans le compartiment tumoral chez des patients atteints de pathologie tumorale. Son gène est hautement conservé. Il possède cependant plusieurs polymorphismes. Un de ces SNPs (single nucleotide polymorphism) - 6936A/G - se traduit par la libération d'une forme soluble circulante de l'EPCR (EPCRs) résultant de la protéolyse de la forme membranaire. Chez des patients leucémiques, une fréquence élevée du SNP 6936A/G est observée et associée à la survenue de thrombose. D'autre part, l’EPCR est détecté in situ dans la majorité des biopsies tumorales testées et sécrété en grande quantité dans les ascites. La fixation de la PC sur l’EPCR et son activation augmentent la survie et le potentiel migratoire des cellules cancéreuses. Aussi, la PCA est capable de moduler, par communication paracrine, la sécrétion de plusieurs interleukines et cytokines. Ainsi, la stimulation de cellules du cancer de l'ovaire par la PCA induit la synthèse d'une thrombopoéïtine ovarienne fonctionnelle. Cette cytokine étant régulatrice de la production de plaquettes, la PCA semble être de nouveau à l'interface entre troubles de l'hémostase et pathologie cancéreuse.L’élucidation du rôle complexe de la PCA et de son récepteur endothélial dans la carcinogenèse permettrait non seulement de dégager de nouvelles approches thérapeutiques, mais aussi de prévenir le risque de thrombose associée au cancer et d’en réduire la morbidité

Thrombopoietin Secretion by Human Ovarian Cancer Cells

The thrombopoietin (TPO) gene expression in human ovary and cancer cells from patients with ovarian carcinomatosis, as well as several cancer cell lines including MDA-MB231 (breast cancer), K562 and HL60 (Leukemic cells), OVCAR-3NIH and SKOV-3 (ovarian cancer), was performed using RT PCR, real-time PCR, and gene sequencing. Human liver tissues are used as controls. The presence of TPO in the cells and its regulation by activated protein C were explored by flow cytometry. TPO content of cell extract as well as plasma of a patient with ovarian cancer was evaluated by ELISA. The functionality of TPO was performed in coculture on the basis of the viability of a TPO-dependent cell line (Ba/F3), MTT assay, and Annexin-V labeling. As in liver, ovarian tissues and all cancer cells lines except the MDA-MB231 express the three TPO-1 (full length TPO), TPO-2 (12 bp deletion), and TPO-3 (116 pb deletion) variants. Primary ovarian cancer cells as well as cancer cell lines produce TPO. The thrombopoietin production by OVCAR-3 increased when cells are stimulated by aPC. OVCAR-3 cell’s supernatant can replace exogenous TPO and inhibited TPO-dependent cell line (Ba/F3) apoptosis. The thrombopoietin produced by tumor may have a direct effect on thrombocytosis/thrombosis occurrence in patients with ovarian cancer

Role of Protein C, a Natural Anticoagulant, in Thrombosis and Cancer Association

Il est désormais admis que le caractère invasif d'une tumeur est lié, non seulement, au génotype des cellules cancéreuses, mais aussi à leurs interactions avec le microenvironnement tumoral (MT). Au sein du MT, une déstabilisation de la matrice stromale favorise la progression tumorale et la dissémination métastatique. Le remaniement de la matrice extracellulaire est souvent piloté par des enzymes protéolytiques. En revanche, les effets de l'inhibition de la formation de cette matrice sont peu étudiés. C’est dans cette optique que nous nous sommes intéressés à la protéine C (PC) et son récepteur endothélial (EPCR) et à leur rôle dans la tumorigenèse des leucémies et des cancers solides.L’EPCR est exprimé par un grand nombre de lignées cellulaires cancéreuses. Il est aussi détecté dans le compartiment tumoral chez des patients atteints de pathologie tumorale. Son gène est hautement conservé. Il possède cependant plusieurs polymorphismes. Un de ces SNPs (single nucleotide polymorphism) - 6936A/G - se traduit par la libération d'une forme soluble circulante de l'EPCR (EPCRs) résultant de la protéolyse de la forme membranaire. Chez des patients leucémiques, une fréquence élevée du SNP 6936A/G est observée et associée à la survenue de thrombose. D'autre part, l’EPCR est détecté in situ dans la majorité des biopsies tumorales testées et sécrété en grande quantité dans les ascites. La fixation de la PC sur l’EPCR et son activation augmentent la survie et le potentiel migratoire des cellules cancéreuses. Aussi, la PCA est capable de moduler, par communication paracrine, la sécrétion de plusieurs interleukines et cytokines. Ainsi, la stimulation de cellules du cancer de l'ovaire par la PCA induit la synthèse d'une thrombopoéïtine ovarienne fonctionnelle. Cette cytokine étant régulatrice de la production de plaquettes, la PCA semble être de nouveau à l'interface entre troubles de l'hémostase et pathologie cancéreuse. L’élucidation du rôle complexe de la PCA et de son récepteur endothélial dans la carcinogenèse permettrait non seulement de dégager de nouvelles approches thérapeutiques, mais aussi de prévenir le risque de thrombose associée au cancer et d’en réduire la morbidité.It is now recognized that the invasiveness of tumor cells is not only related to the genotype of these cells but also to their interaction with tumor microenvironment (TM). Within the TM, stromal matrix destabilization promotes tumor progression and metastatic dissemination. The extracellular matrix remodeling is often driven by proteolytic enzymes. However, few studies have investigated the effects of an impairment of the matrix formation. Given these facts and circumstances, we were interested in protein C (PC) and its endothelial receptor (EPCR), as well as in their role in tumorigenesis in leukemia and solid cancers. EPCR is expressed by a wide range of cancer cell lines. It is also detected within the tumor compartment in patients with malignant diseases. EPCR gene is highly conserved but nevertheless contains polymorphisms. One of these SNPs (single nucleotide polymorphism) - 6936A/G – reflects – in the release of a soluble circulating form (EPCRs) resulting from the proteolysis of membrane-associated form. In leukemic patients a high incidence of 6936A/G SNP is observed and associated with thrombosis events. Moreover, EPCR is detected in the majority of tumor biopsies and is abundantly secreted in ascitic fluid. The PC attachment to EPCR and its activation promotes cell survival and migratory potential of tumor cells. Also, APC is able to modulate, by a paracrine manner, interleukins and cytokines secretion. Thus, ovarian cancer cells stimulation by APC induces the synthesis of a functional ovarian thrombopoietin. As this cytokine has a regulatory effect on platelet production, APC may be once again at the interface between hemostasis disorders and coagulation. The elucidation of the intricate role of APC and its endothelial receptor could permit not only to identify new therapeutic approaches but also to prevent cancer-associated thrombosis risk and to decrease morbidity in cancer patients

Activated protein C upregulates ovarian cancer cell migration and promotes unclottability of the cancer cell microenvironment

International audienceThe objective of this study was to evaluate the role of activated protein C (aPC), known to be a physiological anticoagulant, in ovarian cancer cell activation as well as in loss of clotting of cancer ascitic fluid. The effect of aPC on an ovarian cancer cell line (OVCAR-3) was tested in regards to i) cell migration and adhesion with the use of adhesion and wound healing assays as well as a droplet test; ii) protein phosphorylation, evaluated by cyto-ELISA; iii) cell cycle modification assessed by flow cytometric DNA quantification; and iv) anticoagulant activity evaluated by the prolongation of partial thromboplastin time (aPTT) of normal plasma in the presence or absence of aPC-treated ovarian cancer cells. In addition, the soluble endothelial protein C receptor (sEPCR) was quantified by ELISA in ascitic fluid of patients with ovarian cancer. Our results showed that in the OVCAR-3 aPC-induced cells i) an increase in cell migration was noted, which was inhibited when anti-endothelial protein C receptor (EPCR) was added to the culture medium and which may act via MEK-ERK and Rho-GTPase pathways; ii) an increase in threonine, and to a lesser extent tyrosine phosphorylation; iii) cell cycle activation (G1 to S/G2); and iv) a 2-3-fold prolongation of aPTT of normal plasma. In the peritoneal fluid, the sEPCR concentration was 71 ± 23 ng/ml. In conclusion, free aPC binds to membrane EPCR in ovarian cancer cells and induces cell migration via MEK-ERK and Rho-GTPase pathways. This binding could also explain the loss of clotting of peritoneal fluids

Angiopoietin-like 4-Induced 3D Capillary Morphogenesis Correlates to Stabilization of Endothelial Adherens Junctions and Restriction of VEGF-Induced Sprouting

Angiopoietin-like 4 (ANGPTL4) is a target of hypoxia that accumulates in the endothelial extracellular matrix. While ANGPTL4 is known to regulate angiogenesis and vascular permeability, its context-dependent role related to vascular endothelial growth factor (VEGF) has been suggested in capillary morphogenesis. We here thus develop in vitro 3D models coupled to imaging and morphometric analysis of capillaries to decipher ANGPTL4 functions either alone or in the presence of VEGF. ANGPTL4 induces the formation of barely branched and thin endothelial capillaries that display linear adherens junctions. However, ANGPTL4 counteracts VEGF-induced formation of abundant ramified capillaries presenting cell–cell junctions characterized by VE-cadherin containing reticular plaques and serrated structures. We further deciphered the early angiogenesis steps regulated by ANGPTL4. During the initial activation of endothelial cells, ANGPTL4 alone induces cell shape changes but limits the VEGF-induced cell elongation and unjamming. In the growing sprout, ANGPTL4 maintains cohesive VE-cadherin pattern and sustains moderate 3D cell migration but restricts VEGF-induced endothelium remodeling and cell migration. This effect is mediated by differential short- and long-term regulation of P-Y1175-VEGFR2 and ERK1-2 signaling by ANGPTL4. Our in vitro 3D models thus provide the first evidence that ANGPTL4 induces a specific capillary morphogenesis but also overcomes VEGF effect

Glucagon-like Peptide 1 Receptor Agonists, Diabetic Retinopathy and Angiogenesis: The AngioSafe Type 2 Diabetes Study

International audienceAims: Recent trials provide conflicting results on the association between glucagon-like peptide 1 receptor agonists (GLP-1RA) and diabetic retinopathy (DR). The aim of the AngioSafe type 2 diabetes (T2D) study was to determine the role of GLP-1RA in angiogenesis using clinical and preclinical models.Methods: We performed two studies in humans. In study 1, we investigated the effect of GLP-1RA exposure from T2D diagnosis on the severity of DR, as diagnosed with retinal imaging (fundus photography). In study 2, a randomized 4-week trial, we assessed the effect of liraglutide on circulating hematopoietic progenitor cells (HPCs), and angio-miRNAs. We then studied the experimental effect of Exendin-4, on key steps of angiogenesis: in vitro on human endothelial cell proliferation, survival and three-dimensional vascular morphogenesis; and in vivo on ischemia-induced neovascularization of the retina in mice.Results: In the cohort of 3154 T2D patients, 10% displayed severe DR. In multivariate analysis, sex, disease duration, glycated hemoglobin (HbA1c), micro- and macroangiopathy, insulin therapy and hypertension remained strongly associated with severe DR, while no association was found with GLP-1RA exposure (o 1.139 [0.800-1.622], P = .47). We further showed no effect of liraglutide on HPCs, and angio-miRNAs. In vitro, we demonstrated that exendin-4 had no effect on proliferation and survival of human endothelial cells, no effect on total length and number of capillaries. Finally, in vivo, we showed that exendin-4 did not exert any negative effect on retinal neovascularization.Conclusions: The AngioSafe T2D studies provide experimental and clinical data confirming no effect of GLP-1RA on angiogenesis and no association between GLP-1 exposure and severe DR