Your search keyword '"De Arcangelis, Adele"' showing total 6 results

1. Rfx6 promotes the differentiation of peptide-secreting enteroendocrine cells while repressing genetic programs controlling serotonin production

Author

Piccand, Julie, Vagne, Constance, Blot, Florence, Meunier, Aline, Beucher, Anthony, Strasser, Perrine, Lund, Mari L., Ghimire, Sabitri, Nivlet, Laure, Lapp, Celine, Petersen, Natalia, Engelstoft, Maja S., Thibault-Carpentier, Christelle, Keime, Celine, Correa, Sara Jimenez, Schreiber, Valerie, Molina, Nacho, Schwartz, Thue W., De Arcangelis, Adele, Gradwohl, Gerard, Piccand, Julie, Vagne, Constance, Blot, Florence, Meunier, Aline, Beucher, Anthony, Strasser, Perrine, Lund, Mari L., Ghimire, Sabitri, Nivlet, Laure, Lapp, Celine, Petersen, Natalia, Engelstoft, Maja S., Thibault-Carpentier, Christelle, Keime, Celine, Correa, Sara Jimenez, Schreiber, Valerie, Molina, Nacho, Schwartz, Thue W., De Arcangelis, Adele, and Gradwohl, Gerard

Published

2019

2. Rfx6 promotes the differentiation of peptide-secreting enteroendocrine cells while repressing genetic programs controlling serotonin production

Author

Piccand, Julie, Vagne, Constance, Blot, Florence, Meunier, Aline, Beucher, Anthony, Strasser, Perrine, Lund, Mari L., Ghimire, Sabitri, Nivlet, Laure, Lapp, Celine, Petersen, Natalia, Engelstoft, Maja S., Thibault-Carpentier, Christelle, Keime, Celine, Correa, Sara Jimenez, Schreiber, Valerie, Molina, Nacho, Schwartz, Thue W., De Arcangelis, Adele, Gradwohl, Gerard, Piccand, Julie, Vagne, Constance, Blot, Florence, Meunier, Aline, Beucher, Anthony, Strasser, Perrine, Lund, Mari L., Ghimire, Sabitri, Nivlet, Laure, Lapp, Celine, Petersen, Natalia, Engelstoft, Maja S., Thibault-Carpentier, Christelle, Keime, Celine, Correa, Sara Jimenez, Schreiber, Valerie, Molina, Nacho, Schwartz, Thue W., De Arcangelis, Adele, and Gradwohl, Gerard

Published

2019

3. Platelet integrin alpha 6 beta 1 controls lung metastasis through direct binding to cancer cell-derived ADAM9

Author

Mammadova-Bach, Elmina, Zigrino, Paola, Brucker, Camille, Bourdon, Catherine, Freund, Monique, De Arcangelis, Adele, Abrams, Scott I., Orend, Gertaud, Gachet, Christian, Mangin, Pierre Henri, Mammadova-Bach, Elmina, Zigrino, Paola, Brucker, Camille, Bourdon, Catherine, Freund, Monique, De Arcangelis, Adele, Abrams, Scott I., Orend, Gertaud, Gachet, Christian, and Mangin, Pierre Henri

Abstract

Metastatic dissemination of cancer cells, which accounts for 90% of cancer mortality, is the ultimate hallmark of malignancy. Growing evidence suggests that blood platelets have a predominant role in tumor metastasis; however, the molecular mechanisms involved remain elusive. Here, we demonstrate that genetic deficiency of integrin alpha 6 beta 1 on platelets markedly decreases experimental and spontaneous lung metastasis. In vitro and in vivo assays reveal that human and mouse platelet alpha 6 beta 1 supports platelet adhesion to various types of cancer cells. Using a knockdown approach, we identified ADAM9 as the major counter receptor of alpha 6 beta 1 on both human and mouse tumor cells. Static and flow-based adhesion assays of platelets binding to DC-9, a recombinant protein covering the disintegrin-cysteine domain of ADAM9, demonstrated that this receptor directly binds to platelet alpha 6 beta 1. In vivo studies showed that the interplay between platelet alpha 6 beta 1 and tumor cell-expressed ADAM9 promotes efficient lung metastasis. The integrin alpha 6 beta 1-dependent platelet-tumor cell interaction induces platelet activation and favors the extravasation process of tumor cells. Finally, we demonstrate that a pharmacological approach targeting alpha 6 beta 1 efficiently impairs tumor metastasis through a platelet-dependent mechanism. Our study reveals a mechanism by which platelets promote tumor metastasis and suggests that integrin alpha 6 beta 1 represents a promising target for antimetastatic therapies.

Published

2016

4. Platelet integrin alpha 6 beta 1 controls lung metastasis through direct binding to cancer cell-derived ADAM9

Author

Mammadova-Bach, Elmina, Zigrino, Paola, Brucker, Camille, Bourdon, Catherine, Freund, Monique, De Arcangelis, Adele, Abrams, Scott I., Orend, Gertaud, Gachet, Christian, Mangin, Pierre Henri, Mammadova-Bach, Elmina, Zigrino, Paola, Brucker, Camille, Bourdon, Catherine, Freund, Monique, De Arcangelis, Adele, Abrams, Scott I., Orend, Gertaud, Gachet, Christian, and Mangin, Pierre Henri

Abstract

Metastatic dissemination of cancer cells, which accounts for 90% of cancer mortality, is the ultimate hallmark of malignancy. Growing evidence suggests that blood platelets have a predominant role in tumor metastasis; however, the molecular mechanisms involved remain elusive. Here, we demonstrate that genetic deficiency of integrin alpha 6 beta 1 on platelets markedly decreases experimental and spontaneous lung metastasis. In vitro and in vivo assays reveal that human and mouse platelet alpha 6 beta 1 supports platelet adhesion to various types of cancer cells. Using a knockdown approach, we identified ADAM9 as the major counter receptor of alpha 6 beta 1 on both human and mouse tumor cells. Static and flow-based adhesion assays of platelets binding to DC-9, a recombinant protein covering the disintegrin-cysteine domain of ADAM9, demonstrated that this receptor directly binds to platelet alpha 6 beta 1. In vivo studies showed that the interplay between platelet alpha 6 beta 1 and tumor cell-expressed ADAM9 promotes efficient lung metastasis. The integrin alpha 6 beta 1-dependent platelet-tumor cell interaction induces platelet activation and favors the extravasation process of tumor cells. Finally, we demonstrate that a pharmacological approach targeting alpha 6 beta 1 efficiently impairs tumor metastasis through a platelet-dependent mechanism. Our study reveals a mechanism by which platelets promote tumor metastasis and suggests that integrin alpha 6 beta 1 represents a promising target for antimetastatic therapies.

Published

2016

5. Neuronal expression of muskelin in the rodent central nervous system

Author

Picower Institute for Learning and Memory, Loebrich, Sven, Tagnaouti, Nadia, Heisler, Frank F, Pechmann, Yvonne, Fehr, Susanne, De Arcangelis, Adele, Georges-Labouesse, Elisabeth, Adams, Josephine C, Kneussel, Matthias, Picower Institute for Learning and Memory, Loebrich, Sven, Tagnaouti, Nadia, Heisler, Frank F, Pechmann, Yvonne, Fehr, Susanne, De Arcangelis, Adele, Georges-Labouesse, Elisabeth, Adams, Josephine C, and Kneussel, Matthias

Abstract

Background: The kelch repeat protein muskelin mediates cytoskeletal responses to the extracellular matrix protein thrombospondin 1, (TSP1), that is known to promote synaptogenesis in the central nervous system (CNS). Muskelin displays intracellular localization and affects cytoskeletal organization in adherent cells. Muskelin is expressed in adult brain and has been reported to bind the Cdk5 activator p39, which also facilitates the formation of functional synapses. Since little is known about muskelin in neuronal tissues, we here analysed the tissue distribution of muskelin in rodent brain and analysed its subcellular localization using cultured neurons from multiple life stages. Results: Our data show that muskelin transcripts and polypeptides are expressed throughout the central nervous system with significantly high levels in hippocampus and cerebellum, a finding that resembles the tissue distribution of p39. At the subcellular level, muskelin is found in the soma, in neurite projections and the nucleus with a punctate distribution in both axons and dendrites. Immunostaining and synaptosome preparations identify partial localization of muskelin at synaptic sites. Differential centrifugation further reveals muskelin in membrane-enriched, rather than cytosolic fractions. Conclusion: Our results suggest that muskelin represents a multifunctional protein associated with membranes and/or large protein complexes in most neurons of the central nervous system. These data are in conclusion with distinct roles of muskelin's functional interaction partners., University of Hamburg, Deutsche Forschungsgemeinschaft (KN-556/1-3), Wellcome Trust (SFBBR 038284), Cleveland Clinic Foundation, Association pour le développement de la recherche sur le cancer (France)

Published

2010

6. Neuronal expression of muskelin in the rodent central nervous system

Author

Picower Institute for Learning and Memory, Loebrich, Sven, Tagnaouti, Nadia, Heisler, Frank F, Pechmann, Yvonne, Fehr, Susanne, De Arcangelis, Adele, Georges-Labouesse, Elisabeth, Adams, Josephine C, Kneussel, Matthias, Picower Institute for Learning and Memory, Loebrich, Sven, Tagnaouti, Nadia, Heisler, Frank F, Pechmann, Yvonne, Fehr, Susanne, De Arcangelis, Adele, Georges-Labouesse, Elisabeth, Adams, Josephine C, and Kneussel, Matthias

Abstract

Background: The kelch repeat protein muskelin mediates cytoskeletal responses to the extracellular matrix protein thrombospondin 1, (TSP1), that is known to promote synaptogenesis in the central nervous system (CNS). Muskelin displays intracellular localization and affects cytoskeletal organization in adherent cells. Muskelin is expressed in adult brain and has been reported to bind the Cdk5 activator p39, which also facilitates the formation of functional synapses. Since little is known about muskelin in neuronal tissues, we here analysed the tissue distribution of muskelin in rodent brain and analysed its subcellular localization using cultured neurons from multiple life stages. Results: Our data show that muskelin transcripts and polypeptides are expressed throughout the central nervous system with significantly high levels in hippocampus and cerebellum, a finding that resembles the tissue distribution of p39. At the subcellular level, muskelin is found in the soma, in neurite projections and the nucleus with a punctate distribution in both axons and dendrites. Immunostaining and synaptosome preparations identify partial localization of muskelin at synaptic sites. Differential centrifugation further reveals muskelin in membrane-enriched, rather than cytosolic fractions. Conclusion: Our results suggest that muskelin represents a multifunctional protein associated with membranes and/or large protein complexes in most neurons of the central nervous system. These data are in conclusion with distinct roles of muskelin's functional interaction partners., University of Hamburg, Deutsche Forschungsgemeinschaft (KN-556/1-3), Wellcome Trust (SFBBR 038284), Cleveland Clinic Foundation, Association pour le développement de la recherche sur le cancer (France)

Published

2010