Stable tumor vessel normalization with pO_{2} increase and endothelial PTEN activation by inositol trispyrophosphate brings novel tumor treatment

Tumor hypoxia is a characteristic of cancer cell growth and invasion, promoting angiogenesis, which facilitates metastasis. Oxygen delivery remains impaired because tumor vessels are anarchic and leaky, contributing to tumor cell dissemination. Counteracting hypoxia by normalizing tumor vessels in order to improve drug and radio therapy efficacy and avoid cancer stem-like cell selection is a highly challenging issue. We show here that inositol trispyrophosphate (ITPP) treatment stably increases oxygen tension and blood flow in melanoma and breast cancer syngeneic models. It suppresses hypoxia-inducible factors (HIFs) and proangiogenic/glycolysis genes and proteins cascade. It selectively activates the tumor suppressor phosphatase and tensin homolog (PTEN) in vitro and in vivo at the endothelial cell (EC) level thus inhibiting PI3K and reducing tumor AKT phosphorylation. These mechanisms normalize tumor vessels by EC reorganization, maturation, pericytes attraction, and lowering progenitor cells recruitment in the tumor. It strongly reduces vascular leakage, tumor growth, drug resistance, and metastasis. ITPP treatment avoids cancer stem-like cell selection, multidrug resistance (MDR) activation and efficiently enhances chemotherapeutic drugs activity. These data show that counteracting tumor hypoxia by stably restoring healthy vasculature is achieved by ITPP treatment, which opens new therapeutic options overcoming hypoxia-related limitations of antiangiogenesis-restricted therapies. By achieving long-term vessels normalization, ITPP should provide the adjuvant treatment required in order to overcome the subtle definition of therapeutic windows for in vivo treatments aimed by the current strategies against angiogenesis-dependent tumors

ORGANO-SPÉCIFICITÉ DE L'ENDOTHÉLIUM : MISE EN ÉVIDENCE ET CARACTÉRISATION D'UNE MOLÉCULE RÉGULATRICE DE L'ADHÉSION, NOMMEE ARM-1

JAFFREDO Thierry, Directeur de recherche, CNRS, Paris DIJK W.Jim van, Professeur, Université d'Amsterdam, Pays-Bas PILLER Friedrich, Chargé de Recherche, INSERM, Orléans DELMOTTE Francis, Professeur, Université d'Orléans KIEDA Claudine, Directeur de Recherche, CNRS, OrléansThe LTP1 extracted from leaves of Nicotiana tabacum, named LTP1_1, was produced in Pichia pastoris. We have determined its three-dimensional structure by 2D and 3D NMR and molecular modelling. Various interaction and dynamic studies have highlighted the LTP1_1 particular binding properties compared to other LTPs. This work was used as a basis for the structure determination of others tobacco LTP1 using comparative modelling and for molecular dynamic simulations at ambient temperature and high temperature. Moreover, we mapped the LTP1_1 hydrophobic cavity by using hyperpolarized xenon NMR. This work allowed us to identify the amino acids involved specifically in lipid binding. We have discovered that the remarkable binding properties of LTP1 are related not only on their original structure but also in their particular dynamic.Afin d'identifier de nouvelles cibles organo-spécifiques de l'endothélium, nous avons comparé l'expression de gènes entre deux lignées de hautes cellules endothéliales et mis en évidence la protéine ARM-1. Des expériences de RT-PCR ont montré une expression spécifique d'ARM-1 dans certaines lignées de cellules endothéliales et de lymphocytes. La surexpression d'ARM-1 dans des cellules endothéliales de peau, n'exprimant pas cette protéine, augmente de façon préférentielle l'adhésion de certaines lignées lymphocytaires sur ces cellules. Ceci renforce l'hypothèse d'un rôle particulier d'ARM-1 au sein des cellules endothéliales. Une étude de fractionnement cellulaire a montré qu'ARM-1 était une protéine sécrétée, pouvant être associée à la membrane. Des expériences d'immunolocalisation n'ont cependant démontré aucune expression d'ARM-1 à la surface cellulaire. Ces résultats suggèrent une action indirecte d'ARM-1 dans l'adhésion plutôt qu'un rôle direct en tant que molécule d'adhésion

Chemokine-glycosaminoglycan interactions participate to the endothelium organospecificity and cellular addressing

International audienc

Flow cytometric assay for quantitative and qualitative evaluation of adhesive interactions of tumor cells with endothelial cells

International audienceThe purpose of the study was to develop a flow cytometric assay for quantitative determination of adhesive interactions of human endothelial cells (ECs) with tumor cells. EC lines established from human lymph node, appendix, lung, skin and intestine microvessels, labeled with PKH26-GL fluorescent dye, were grown to confluency in 24-well TC plates. Human colon adenocarcinoma cell suspension was overlaid onto labeled ECs, and allowed to adhere for 20 min at 4 degrees C under static conditions. Non-adhering cells were collected first, and adhering tumor cells together with ECs were detached from the culture plate. Collected cell fractions were evaluated by flow cytometry. Results were re-calculated as a ratio (R) of adhering colon carcinoma cells per one EC. We demonstrated that immortalized human microvascular ECs preserved their organ specificity. Colon carcinoma cells adhere preferentially to ECs of intestine origin. The immunofluorescent staining of adhering and non-adhering cancer cell subpopulations has revealed an augmented level of Lewis' antigen on adhering cancer cells. The organ specificity of endothelial cell interactions with colon carcinoma cells demonstrated in static conditions was verified and confirmed with flow adhesion assay. The method elaborated is suitable for quantifying of tumor cells adhering to ECs, with simultaneous evaluation of cell surface phenotypic markers of both partner cells participating in adhesive interactions. Validated by comparison to dynamic shear stress adhesion assay in blood flow reconstituted conditions this assay greatly facilitates evaluation of tumor cell-endothelial cell mutual interactions taking place during metastatic process

News on microenvironmental physioxia to revisit skin cells targeting approaches.

International audienceThe skin is a multifunctional organ and a first line of defense actively protecting from environmental stress caused by injury, microbial treat, UV irradiation and environmental toxins. Diverse cutaneous cell types together with extracellular matrix elements and factors create a dynamic scene for cellular communication crucial in vital processes such as wound healing, inflammation, angiogenesis, immune response. Direct functional success of skin equilibrium depends on its microenvironment settings and particularly the local oxygen tension. Indeed, skin entire milieu is characterized by and highly dependent on its low oxygen tension called physioxia as emphasized in this review. In the context of skin physioxia, we review and propose here new approaches to minimize age-related changes in skin state and function. We particularly emphasize carbohydrate-mediated interactions and new 3D models of engineered skin substitutes. We highlight newly emerged tools and targets including stem cells, miRNAs, matrix metalloproteinases, mitochondria and natural antioxidants that are promising in prevention of skin ageing and disease restraint. In the era of advanced dermatology, new attempts are bringing us closer to 'well being' perception

Hypoxia control to normalize pathologic angiogenesis: potential role for endothelial precursor cells and miRNAs regulation.

International audienceTumor microenvironment is a complex and highly dynamic milieu that provides very important clues on tumor development and progression mechanisms. Tumor-associated endothelial cells play a key role in stroma organization. They achieve tumor angiogenesis, a formation of tumor-associated (angiogenic) vessels mainly through sprouting from locally preexisting vessels and/or recruitment of bone marrow-derived endothelial progenitor cells. This process participates to supply nutritional support and oxygen to the growing tumor. Endothelial cells constitute the interface between circulating blood cells, tumor cells and the extracellular matrix, thereby controlling leukocyte recruitment, tumor cell behavior and metastasis formation. Hypoxia, a critical parameter of the tumor microenvironment, controls endothelial/tumor cell interactions and is the key to tumor angiogenesis development. Under hypoxic stress, tumor cells produce factors that promote angiogenesis, vasculogenesis, tumor cell motility, metastasis and cancer stem cell selection. Targeting tumor vessels is a therapeutic strategy that has lately been fast evolving from antiangiogenesis to vessel normalization as discussed in this review. We shall focus on the pivotal role of endothelial cells within the tumor microenvironment, the specific features and the part played by circulating endothelial precursors cells. Attention is stressed on their recruitment to the tumor site and their role in tumor angiogenesis where they are submitted to miRNAs-mediated de/regulation. Here the compensation of the tumor deregulated angiogenic miRNAs - angiomiRs - is emphasized as a potential therapeutic approach. The strategy is to over express anti-angiomiRs in the tumor angiogenesis site upon selective delivery by precursor endothelial cells as miRs carriers

Tumor hypoxia modulates podoplanin/CCL21 interactions in CCR7+ NK cell recruitment and CCR7+ tumor cell mobilization

International audiencePodoplanin (PDPN), an O-glycosylated, transmembrane, mucin-type glycoprotein, is expressed by cancer associated fibroblasts (CAFs). In malignant transformation, PDPN is subjected to changes and its role is yet to be established. Here we show that it is involved in modulating the activity of the CCL21/CCR7 chemokine/receptor axis in a hypoxia-dependent manner. In the present model, breast cancer MDA-MB-231 cells and NKL3 cells express the surface CCR7 receptor for CCL21 chemokine which is a potent chemoattractant able to bind to PDPN. The impact of the CCL21/CCR7 axis in the molecular mechanism of the adhesion of NKL3 cells and of MDA-MB-231 breast ancer cells was reduced in a hypoxic tumor environment. In addition to its known effect on migration, CCL21/CCR7 interaction was shown to allow NK cell adhesion to endothelial cells (ECs) and its reduction by hypoxia. A PDPN expressing model of CAFs made it possible to demonstrate the same CCL21/CCR7 axis involvement in the tumor cells to CAFs recognition mechanism through PDPN binding of CCL21. PDPN was induced by hypoxia and its overexpression undergoes a reduction of adhesion, making it an anti-adhesion molecule in the absence of CCL21, in the tumor. CCL21/CCR7 odulated NK cells/ECs and MDA-MB-231 cells/CAF PDPN-dependent interactions were further shown to be linked to hypoxia-dependent microRNAs as miRs: miR-210 and specifically miR-21, miR-29b which influence PDPN expression

Alteration of cathepsin D trafficking induced by hypoxia and extracellular acidification in MCF-7 breast cancer cells

International audienceThe microenvironment that surrounds tumor cells is characterized by hypoxic conditions and extracellular acidity. These hostile conditions induce crucial changes in cell behavior and can promote the secretion of many soluble factors such as growth factors, cytokines and enzymes. The lysosomal aspartyl-endopeptidase cathepsin D (CD) is a marker of poor prognosis in breast cancer and is associated with a metastatic risk. In this study, the transport of CD was investigated in a model of breast cancer cells line (MCF-7) cultivated under hypoxia and acidification of media. CD secretion was assessed using Western blot analysis and protease activity was measured in conditioned culture media. We demonstrate that cultured MCF-7 cells secrete an active 52 kDa pCD precursor and report that under hypoxia there was an increased amount of pCD secreted. More surprisingly, extracellular acidification (pH 6 and 5.6) induced the secretion of the fully-mature and active (34 kDa + 14 kDa) double chain CD. Our findings reflect the fact that chemical anomalies influence the secretion path of CD in a breast cancer cell model, resulting in altered trafficking of the mature form. This important result may provide new arguments in favor of the role of extracellular CD in the degradation of the matrix proteins that constitute the breast tumor microenvironment