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8 results on '"Le Balle, F"'

2. T Cells Promote Bronchial Epithelial Cell Secretion of Matrix Metalloproteinase‐9 via a C‐C Chemokine Receptor Type 2 Pathway: Implications for Chronic Lung Allograft Dysfunction

Author

Pain, M., Royer, P.‐J., Loy, J., Girardeau, A., Tissot, A., Lacoste, P., Roux, A., Reynaud‐Gaubert, M., Kessler, R., Mussot, S., Dromer, C., Brugière, O., Mornex, J.‐F., Guillemain, R., Dahan, M., Knoop, C., Botturi, K., Pison, C., Danger, R., Brouard, S., Magnan, A., Jougon, J., Velly, J.‐F., Rozé, H., Blanchard, E., Antoine, M., Cappello, M., Souilamas, R., Ruiz, M., Sokolow, Y., Vanden Eynden, F., Van Nooten, G., Barvais, L., Berré, J., Brimioulle, S., De Backer, D., Créteur, J., Engelman, E., Huybrechts, I., Ickx, B., Preiser, T.J.C., Tuna, T., Van Obberghe, L., Vancutsem, N., Vincent, J.‐L., De Vuyst, P., Etienne, I., Féry, F., Jacobs, F., Vachiéry, J.L., Van den Borne, P., Wellemans, I., Amand, G., Collignon, L., Giroux, M., Arnaud‐Crozat, E., Bach, V., Brichon, P.‐Y., Chaffanjon, P., Chavanon, O., de Lambert, A., Fleury, J.P., Guigard, S., Hireche, K., Pirvu, A., Porcu, P., Hacini, R., Albaladejo, P., Allègre, C., Bataillard, A., Bedague, D., Briot, E., Casez‐Brasseur, M., Colas, D., Dessertaine, G., Durand, M., Francony, G., Hebrard, A., Marino, M.R., Oummahan, B., Protar, D., Rehm, D., Robin, S., Rossi‐Blancher, M., Bedouch, P., Boignard, A., Bouvaist, H., Briault, A., Camara, B., Chanoine, S., Dubuc, M., Lantuéjoul, S., Quétant, S., Maurizi, J., Pavèse, P., Saint‐Raymond, C., Wion, N., Chérion, C., Grima, R., Jegaden, O., Maury, J.‐M., Tronc, F., Flamens, C., Paulus, S., Philit, F., Senechal, A., Glérant, J.‐C., Turquier, S., Gamondes, D., Chalabresse, L., Thivolet‐Bejui, F., Barnel, C., Dubois, C., Tiberghien, A., Le Pimpec‐Barthes, F., Bel, A., Mordant, P., Achouh, P., Boussaud, V., Méléard, D., Bricourt, M.O., Cholley, B., Pezella, V., Adda, M., Badier, M., Bregeon, F., Coltey, B., D'Journo, X.B., Dizier, S., Doddoli, C., Dufeu, N., Dutau, H., Forel, J.M., Gaubert, J.Y., Gomez, C., Leone, M., Nieves, A., Orsini, B., Papazian, L., Picard, C., Roch, A., Rolain, J.M., Sampol, E., Secq, V., Thomas, P., Trousse, D., Yahyaoui, M., Baron, O., Perigaud, C., Roussel, J.C., Danner, I., Haloun, A., Lepoivre, T., Treilhaud, M., Botturi‐Cavaillès, K., Morisset, M., Pares, S., Reboulleau, D., Dartevelle, P., Fabre, D., Fadel, E., Mercier, O., Stephan, F., Viard, P., Cerrina, J., Dorfmuller, P., Feuillet, S., Ghigna, M., Hervén, P., Le Roy Ladurie, F., Le Pavec, J., Thomas de Montpreville, V., Lamrani, L., Castier, Y., Cerceau, P., Francis, F., Lesèche, G., Allou, N., Augustin, P., Boudinet, S., Desmard, M., Dufour, G., Montravers, P., Dauriat, G., Jébrak, G., Mal, H., Marceau, A., Métivier, A.‐C., Thabut, G., Ait Ilalne, B., Falcoz, P., Massard, G., Santelmo, N., Ajob, G., Collange, O., Helms, O., Hentz, J., Roche, A., Bakouboula, B., Degot, T., Dory, A., Hirschi, S., Ohlmann‐Caillard, S., Kessler, L., Schuller, A., Bennedif, K., Vargas, S., Bonnette, P., Chapelier, A., Puyo, P., Sage, E., Bresson, J., Caille, V., Cerf, C., Devaquet, J., Dumans‐Nizard, V., Felten, M.L., Fischler, M., Si Larbi, A.G., Leguen, M., Ley, L., Liu, N., Trebbia, G., De Miranda, S., Douvry, B., Gonin, F., Grenet, D., Hamid, A.M., Neveu, H., Parquin, F., Picard, C., Stern, M., Bouillioud, F., Cahen, P., Colombat, M., Dautricourt, C., Delahousse, M., D'Urso, B., Gravisse, J., Guth, A., Hillaire, S., Honderlick, P., Lequintrec, M., Longchampt, E., Mellot, F., Scherrer, A., Temagoult, L., Tricot, L., Vasse, M., Veyrie, C., Zemoura, L., Berjaud, J., Brouchet, L., Le Balle, F, Mathe, O., Benahoua, H., Didier, A., Goin, A.L., Murris, M., Crognier, L., and Fourcade, O.

Abstract

Chronic lung allograft dysfunction (CLAD) is the major limitation of long‐term survival after lung transplantation. CLADmanifests as bronchiolitis obliterans syndrome (BOS) or restrictive allograft syndrome (RAS). Alloimmune reactions and epithelial‐to‐mesenchymal transition have been suggested in BOS. However, little is known regarding the role of allogenicity in epithelial cell differentiation. Primary human bronchial epithelial cells (BECs) were treated with activated T cells in the presence or absence of transforming growth factor (TGF)‐β. The expression of epithelial and mesenchymal markers was investigated. The secretion of inflammatory cytokines and matrix metalloproteinase (MMP)‐9 was measured in culture supernatants and in plasma from lung transplant recipients (LTRs): 49 stable, 29 with BOS,and 16 with RAS. We demonstrated that C‐C motif chemokine 2 secreted by T cells supports TGF‐β–induced MMP‐9 production by BECsafter binding to C‐C chemokine receptor type 2. Longitudinal investigation in LTRsrevealed a rise in plasma MMP‐9 before CLADonset. Multivariate analysis showed that plasma MMP‐9 was independently associated with BOS(odds ratio [OR] =6.19, p = 0.002) or RAS(OR= 3.9, p = 0.024) and predicted the occurrence of CLAD12 months before the functional diagnosis. Thus, immune cells support airway remodeling through the production of MMP‐9. Plasma MMP‐9 is a potential predictive biomarker of CLAD. The authors investigate the production of matrix metalloproteinase‐9 by primary bronchial epithelial cells after interaction with activated T cells and show that plasma matrix metalloproteinase‐9 can serve as a predictor of chronic lung allograft dysfunction 12 months before clinical diagnosis.

Published
2017
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4. Complete tracheal rupture after a failed suicide attempt.

Author

Costache VS, Renaud C, Brouchet L, Toma T, Le Balle F, Berjaud J, and Dahan M

Subjects
Adult, Humans, Male, Rupture, Trachea surgery, Suicide, Attempted, Trachea injuries
Abstract

Tracheal rupture is life-threatening and its management poses a considerable challenge to both anesthesiologists and surgeons. We report the case of a 44-year-old patient with a complete tracheal rupture after a failed suicide attempt by hanging. A rare bilateral injury of the laryngeal nerves was associated. An original tracheal intubation was performed using the video unit for thoracoscopy. The severity of the lesions required the placement of a tracheostomy cannula after the tracheal repair. The postoperative course was uneventful. The patient was discharged on the 12th day, with a remaining moderate dysphonia.

Published
2004
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5. New developments in phospholipase A2.

Author

Chaminade B, Le Balle F, Fourcade O, Nauze M, Delagebeaudeuf C, Gassama-Diagne A, Simon MF, Fauvel J, and Chap H

Subjects
Animals, Calcium metabolism, Cell Membrane enzymology, Cytosol enzymology, Humans, Lysophospholipase chemistry, Lysophospholipase genetics, Phospholipases A2, Recombinant Proteins metabolism, Phospholipases A chemistry, Phospholipases A metabolism
Abstract

Some of the most recent data concerning various phospholipases A2, with special emphasis on secretory, cytosolic, and calcium-independent phospholipases A2 are summarized. Besides their contribution to the production of proinflammatory lipid mediators, the involvement of these enzymes in key cell responses such as apoptosis or tumor cell metastatic potential is also discussed, taking advantage of transgenic models based on gene invalidation by homologous recombination. The possible role of secretory and cytosolic platelet-activating factor acetyl hydrolases is also briefly mentioned. Finally, the ectopic expression in epididymis of an intestinal phospholipase B opens some novel issues as to the possible function of phospholipases in reproduction.

Published
1999
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6. Membrane sidedness of biosynthetic pathways involved in the production of lysophosphatidic acid.

Author

le Balle F, Simon MF, Meijer S, Fourcade O, and Chap H

Subjects
Animals, Blood Platelets metabolism, Calcimycin pharmacology, Cell Membrane metabolism, Erythrocytes drug effects, Erythrocytes metabolism, Humans, In Vitro Techniques, Ionophores pharmacology, Lysophospholipids blood, Mice, Mice, Inbred Strains, Models, Biological, Phospholipases A blood, Phospholipases A2, Platelet Activation, Subcellular Fractions metabolism, Lysophospholipids biosynthesis
Abstract

Lysophosphatidic acid (LPA) is a novel phospholipid mediator with diverse biological activities such as smooth muscle contraction, and proliferative effects or modifications of cytoskeleton. Activated blood platelets are the best identified source, explaining accumulation of LPA in serum upon blood coagulation. However, the metabolic pathways responsible for LPA synthesis are still poorly known. Using a model of human erythrocytes treated with the calcium ionophore A23187, we have shown that type II secretory phospholipase A2 (sPLA2) is able to produce LPA by hydrolyzing phosphatidic acid exposed on the cell surface after phospholipid scrambling. A similar mechanism does not appear to occur in platelets, where inhibitors of sPLA2 or genetic lack of the enzyme do not modify LPA production. However, this does not definitely eliminate the possibility that LPA is also produced in platelets in the external leaflet of the membrane by other phospholipases, which have to be better characterized.

Published
1999
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7. Regulation of secretory type-II phospholipase A2 and of lysophosphatidic acid synthesis.

Author

Fourcade O, Le Balle F, Fauvel J, Simon MF, and Chap H

Subjects
Animals, Erythrocytes metabolism, Group II Phospholipases A2, Inflammation metabolism, Mammals, Membrane Lipids metabolism, Phospholipases A2, Phospholipids metabolism, Lysophospholipids biosynthesis, Phospholipases A metabolism
Abstract

Secretory non-pancreatic phospholipase A2 (sPLA2), also called type II-PLA2, is produced in large amounts under inflammatory conditions, thus accumulating in inflammatory fluids. Since the enzyme is virtually inactive on phospholipids from intact cells, we have searched for conditions allowing the action of sPLA2 on membrane phospholipids. Based on an in vitro model, our studies suggest that only those membranes where the transverse distribution of phospholipids has been disturbed offer a convenient surface able to interact with the enzyme, which then achieves significant degradation of all glycerophospholipids. This results in the accumulation of various lysophospholipids such as lysophosphatidylcholine, lysophosphatidylethanolamine and lysophosphatidylserine. However, lysophosphatidic acid (LPA) can also be generated under these conditions involving accumulation of phosphatidic acid in the cytoplasmic leaflet of the membrane, followed by its transfer to the outer monolayer. Since LPA is now considered as a novel phospholipid mediator, this pathway deserves further studies concerning mainly platelets, the main source of LPA identified so far.

Published
1998
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8. Lysophosphatidic acid as a phospholipid mediator: pathways of synthesis.

Author

Gaits F, Fourcade O, Le Balle F, Gueguen G, Gaigé B, Gassama-Diagne A, Fauvel J, Salles JP, Mauco G, Simon MF, and Chap H

Subjects
Animals, Blood Platelets metabolism, Cell Membrane metabolism, Group VI Phospholipases A2, Humans, Lysophospholipids metabolism, Phosphatidic Acids metabolism, Phospholipases A metabolism, Lysophospholipids biosynthesis, Phospholipids metabolism
Abstract

From very recent studies, including molecular cloning of cDNA coding for membrane receptors, lysophosphatidic acid (LPA) reached the status of a novel phospholipid mediator with various biological activities. Another strong argument supporting this view was the discovery that LPA is secreted from activated platelets, resulting in its appearance in serum upon blood coagulation. The metabolic pathways as well as the enzymes responsible for LPA production are poorly characterized. However, a survey of literature data indicates some interesting issues which might be used as the basis for further molecular characterization of phospholipases A able to degrade phosphatidic acid.

Published
1997
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