Your search keyword '"Thoreau M"' showing total 14 results

1. AUNT MARIA LOOKS AT JAPP'S BIOGRAPHY

Author

Thoreau, M[aria]

Published

1990

2. Abstracts from the 4th ImmunoTherapy of Cancer Conference

Author

Ženka, J., primary, Caisová, V., additional, Uher, O., additional, Nedbalová, P., additional, Kvardová, K., additional, Masáková, K., additional, Krejčová, G., additional, Paďouková, L., additional, Jochmanová, I., additional, Wolf, K. I., additional, Chmelař, J., additional, Kopecký, J., additional, Loumagne, L., additional, Mestadier, J., additional, D’agostino, S., additional, Rohaut, A., additional, Ruffin, Y., additional, Croize, V., additional, Lemaître, O., additional, Sidhu, S. S., additional, Althammer, S., additional, Steele, K., additional, Rebelatto, M., additional, Tan, T., additional, Wiestler, T., additional, Spitzmueller, A., additional, Korn, R., additional, Schmidt, G., additional, Higgs, B., additional, Li, X., additional, Shi, L., additional, Jin, X., additional, Ranade, K., additional, Koeck, S., additional, Amann, A., additional, Gamerith, G., additional, Zwierzina, M., additional, Lorenz, E., additional, Zwierzina, H., additional, Kern, J., additional, Riva, M., additional, Baert, T., additional, Coosemans, A., additional, Giovannoni, R., additional, Radaelli, E., additional, Gsell, W., additional, Himmelreich, U., additional, Van Ranst, M., additional, Xing, F., additional, Qian, W., additional, Dong, C., additional, Xu, X., additional, Guo, S., additional, Shi, Q., additional, Quandt, D., additional, Seliger, B., additional, Plett, C., additional, Amberger, D. C., additional, Rabe, A., additional, Deen, D., additional, Stankova, Z., additional, Hirn, A., additional, Vokac, Y., additional, Werner, J., additional, Krämer, D., additional, Rank, A., additional, Schmid, C., additional, Schmetzer, H., additional, Guerin, M., additional, Weiss, J. M., additional, Regnier, F., additional, Renault, G., additional, Vimeux, L., additional, Peranzoni, E., additional, Feuillet, V., additional, Thoreau, M., additional, Guilbert, T., additional, Trautmann, A., additional, Bercovici, N., additional, Doraneh-Gard, F., additional, Boeck, C. L., additional, Gunsilius, C., additional, Kugler, C., additional, Schmohl, J., additional, Kraemer, D., additional, Ismann, B., additional, Schmetzer, H. M., additional, Markota, A., additional, Ochs, C., additional, May, P., additional, Gottschlich, A., additional, Gosálvez, J. Suárez, additional, Karches, C., additional, Wenk, D., additional, Endres, S., additional, Kobold, S., additional, Hilmenyuk, T., additional, Klar, R., additional, Jaschinski, F., additional, Augustin, F., additional, Manzl, C., additional, Hoflehner, E., additional, Moser, P., additional, Zelger, B., additional, Köck, S., additional, Schäfer, G., additional, Öfner, D., additional, Maier, H., additional, Sopper, S., additional, Prado-Garcia, H., additional, Romero-Garcia, S., additional, Sandoval-Martínez, R., additional, Puerto-Aquino, A., additional, Lopez-Gonzalez, J., additional, Rumbo-Nava, U., additional, Van Hoylandt, A., additional, Busschaert, P., additional, Vergote, I., additional, Laengle, J., additional, Pilatova, K., additional, Budinska, E., additional, Bencsikova, B., additional, Sefr, R., additional, Nenutil, R., additional, Brychtova, V., additional, Fedorova, L., additional, Hanakova, B., additional, Zdrazilova-Dubska, L., additional, Allen, Chris, additional, Ku, Yuan-Chieh, additional, Tom, Warren, additional, Sun, Yongming, additional, Pankov, Alex, additional, Looney, Tim, additional, Hyland, Fiona, additional, Au-Young, Janice, additional, Mongan, Ann, additional, Becker, A., additional, Tan, J. B. L., additional, Chen, A., additional, Lawson, K., additional, Lindsey, E., additional, Powers, J. P., additional, Walters, M., additional, Schindler, U., additional, Young, S., additional, Jaen, J. C., additional, Yin, S., additional, Chen, Y., additional, Gullo, I., additional, Gonçalves, G., additional, Pinto, M. L., additional, Athelogou, M., additional, Almeida, G., additional, Huss, R., additional, Oliveira, C., additional, Carneiro, F., additional, Merz, C., additional, Sykora, J., additional, Hermann, K., additional, Hussong, R., additional, Richards, D. M., additional, Fricke, H., additional, Hill, O., additional, Gieffers, C., additional, Pinho, M. P., additional, Barbuto, J. A. M., additional, McArdle, S. E., additional, Foulds, G., additional, Vadakekolathu, J. N., additional, Abdel-Fatah, T. M. A., additional, Johnson, C., additional, Hood, S., additional, Moseley, P., additional, Rees, R. C., additional, Chan, S. Y. T., additional, Pockley, A. G., additional, Rutella, S., additional, Geppert, C., additional, Hartmann, A., additional, Kumar, K. Senthil, additional, Gokilavani, M., additional, Wang, S., additional, Redondo-Müller, M., additional, Heinonen, K., additional, Marschall, V., additional, Thiemann, M., additional, Zhang, L., additional, Mao, B., additional, Jin, Y., additional, Zhai, G., additional, Li, Z., additional, Wang, Z., additional, An, X., additional, Qiao, M., additional, Zhang, J., additional, Weber, J., additional, Kluger, H., additional, Halaban, R., additional, Sznol, M., additional, Roder, H., additional, Roder, J., additional, Grigorieva, J., additional, Asmellash, S., additional, Meyer, K., additional, Steingrimsson, A., additional, Blackmon, S., additional, Sullivan, R., additional, Sutanto, W., additional, Guenther, T., additional, Schuster, F., additional, Salih, H., additional, Babor, F., additional, Borkhardt, A., additional, Kim, Y., additional, Oh, I., additional, Park, C., additional, Ahn, S., additional, Na, K., additional, Song, S., additional, Choi, Y., additional, Poprach, A., additional, Lakomy, R., additional, Selingerova, I., additional, Demlova, R., additional, Kozakova, S., additional, Valik, D., additional, Petrakova, K., additional, Vyzula, R., additional, Aguilar-Cazares, D., additional, Galicia-Velasco, M., additional, Camacho-Mendoza, C., additional, Islas-Vazquez, L., additional, Chavez-Dominguez, R., additional, Gonzalez-Gonzalez, C., additional, Lopez-Gonzalez, J. S., additional, Yang, S., additional, Moynihan, K. D., additional, Noh, M., additional, Bekdemir, A., additional, Stellacci, F., additional, Irvine, D. J., additional, Volz, B., additional, Kapp, K., additional, Oswald, D., additional, Wittig, B., additional, Schmidt, M., additional, Kleef, R., additional, Bohdjalian, A., additional, McKee, D., additional, Moss, R. W., additional, Saeed, Mesha, additional, Zalba, Sara, additional, Debets, Reno, additional, ten Hagen, Timo L. M., additional, Javed, S., additional, Becher, J., additional, Koch-Nolte, F., additional, Haag, F., additional, Gordon, E. M., additional, Sankhala, K. K., additional, Stumpf, N., additional, Tseng, W., additional, Chawla, S. P., additional, Suárez, N. González, additional, Báez, G. Bergado, additional, Rodríguez, M. Cruz, additional, Pérez, A. Gutierrez, additional, García, L. Chao, additional, Fernández, D. Hernández, additional, Pous, J. Raymond, additional, Ramírez, B. Sánchez, additional, Jacoberger-Foissac, C., additional, Saliba, H., additional, Seguin, C., additional, Brion, A., additional, Frisch, B., additional, Fournel, S., additional, Heurtault, B., additional, Otterhaug, T., additional, Håkerud, M., additional, Nedberg, A., additional, Edwards, V., additional, Selbo, P., additional, Høgset, A., additional, Jaitly, T., additional, Dörrie, J., additional, Schaft, N., additional, Gross, S., additional, Schuler-Thurner, B., additional, Gupta, S., additional, Taher, L., additional, Schuler, G., additional, Vera, J., additional, Rataj, F., additional, Kraus, F., additional, Grassmann, S., additional, Chaloupka, M., additional, Lesch, S., additional, Heise, C., additional, Cadilha, B. M. Loureiro, additional, and Dorman, K., additional

Published

2017

3. Abstracts from the 4th ImmunoTherapy of Cancer Conference

Author

Ženka, J., Caisová, V., Uher, O., Nedbalová, P., Kvardová, K., Masáková, K., Krejčová, G., Paďouková, L., Jochmanová, I., Wolf, K. I., Chmelař, J., Kopecký, J., Loumagne, L., Mestadier, J., D’agostino, S., Rohaut, A., Ruffin, Y., Croize, V., Lemaître, O., Sidhu, S. S., Althammer, S., Steele, K., Rebelatto, M., Tan, T., Wiestler, T., Spitzmueller, A., Korn, R., Schmidt, G., Higgs, B., Li, X., Shi, L., Jin, X., Ranade, K., Koeck, S., Amann, A., Gamerith, G., Zwierzina, M., Lorenz, E., Zwierzina, H., Kern, J., Riva, M., Baert, T., Coosemans, A., Giovannoni, R., Radaelli, E., Gsell, W., Himmelreich, U., Van Ranst, M., Xing, F., Qian, W., Dong, C., Xu, X., Guo, S., Shi, Q., Quandt, D., Seliger, B., Plett, C., Amberger, D. C., Rabe, A., Deen, D., Stankova, Z., Hirn, A., Vokac, Y., Werner, J., Krämer, D., Rank, A., Schmid, C., Schmetzer, H., Guerin, M., Weiss, J. M., Regnier, F., Renault, G., Vimeux, L., Peranzoni, E., Feuillet, V., Thoreau, M., Guilbert, T., Trautmann, A., Bercovici, N., Doraneh-Gard, F., Boeck, C. L., Gunsilius, C., Kugler, C., Schmohl, J., Kraemer, D., Ismann, B., Schmetzer, H. M., Markota, A., Ochs, C., May, P., Gottschlich, A., Gosálvez, J. Suárez, Karches, C., Wenk, D., Endres, S., Kobold, S., Hilmenyuk, T., Klar, R., Jaschinski, F., Augustin, F., Manzl, C., Hoflehner, E., Moser, P., Zelger, B., Köck, S., Schäfer, G., Öfner, D., Maier, H., Sopper, S., Prado-Garcia, H., Romero-Garcia, S., Sandoval-Martínez, R., Puerto-Aquino, A., Lopez-Gonzalez, J., Rumbo-Nava, U., Van Hoylandt, A., Busschaert, P., Vergote, I., Laengle, J., Pilatova, K., Budinska, E., Bencsikova, B., Sefr, R., Nenutil, R., Brychtova, V., Fedorova, L., Hanakova, B., Zdrazilova-Dubska, L., Allen, Chris, Ku, Yuan-Chieh, Tom, Warren, Sun, Yongming, Pankov, Alex, Looney, Tim, Hyland, Fiona, Au-Young, Janice, Mongan, Ann, Becker, A., Tan, J. B. L., Chen, A., Lawson, K., Lindsey, E., Powers, J. P., Walters, M., Schindler, U., Young, S., Jaen, J. C., Yin, S., Chen, Y., Gullo, I., Gonçalves, G., Pinto, M. L., Athelogou, M., Almeida, G., Huss, R., Oliveira, C., Carneiro, F., Merz, C., Sykora, J., Hermann, K., Hussong, R., Richards, D. M., Fricke, H., Hill, O., Gieffers, C., Pinho, M. P., Barbuto, J. A. M., McArdle, S. E., Foulds, G., Vadakekolathu, J. N., Abdel-Fatah, T. M. A., Johnson, C., Hood, S., Moseley, P., Rees, R. C., Chan, S. Y. T., Pockley, A. G., Rutella, S., Geppert, C., Hartmann, A., Kumar, K. Senthil, Gokilavani, M., Wang, S., Redondo-Müller, M., Heinonen, K., Marschall, V., Thiemann, M., Zhang, L., Mao, B., Jin, Y., Zhai, G., Li, Z., Wang, Z., An, X., Qiao, M., Zhang, J., Weber, J., Kluger, H., Halaban, R., Sznol, M., Roder, H., Roder, J., Grigorieva, J., Asmellash, S., Meyer, K., Steingrimsson, A., Blackmon, S., Sullivan, R., Sutanto, W., Guenther, T., Schuster, F., Salih, H., Babor, F., Borkhardt, A., Kim, Y., Oh, I., Park, C., Ahn, S., Na, K., Song, S., Choi, Y., Poprach, A., Lakomy, R., Selingerova, I., Demlova, R., Kozakova, S., Valik, D., Petrakova, K., Vyzula, R., Aguilar-Cazares, D., Galicia-Velasco, M., Camacho-Mendoza, C., Islas-Vazquez, L., Chavez-Dominguez, R., Gonzalez-Gonzalez, C., Lopez-Gonzalez, J. S., Yang, S., Moynihan, K. D., Noh, M., Bekdemir, A., Stellacci, F., Irvine, D. J., Volz, B., Kapp, K., Oswald, D., Wittig, B., Schmidt, M., Kleef, R., Bohdjalian, A., McKee, D., Moss, R. W., Saeed, Mesha, Zalba, Sara, Debets, Reno, ten Hagen, Timo L. M., Javed, S., Becher, J., Koch-Nolte, F., Haag, F., Gordon, E. M., Sankhala, K. K., Stumpf, N., Tseng, W., Chawla, S. P., Suárez, N. González, Báez, G. Bergado, Rodríguez, M. Cruz, Pérez, A. Gutierrez, García, L. Chao, Fernández, D. Hernández, Pous, J. Raymond, Ramírez, B. Sánchez, Jacoberger-Foissac, C., Saliba, H., Seguin, C., Brion, A., Frisch, B., Fournel, S., Heurtault, B., Otterhaug, T., Håkerud, M., Nedberg, A., Edwards, V., Selbo, P., Høgset, A., Jaitly, T., Dörrie, J., Schaft, N., Gross, S., Schuler-Thurner, B., Gupta, S., Taher, L., Schuler, G., Vera, J., Rataj, F., Kraus, F., Grassmann, S., Chaloupka, M., Lesch, S., Heise, C., Cadilha, B. M. Loureiro, and Dorman, K.

Subjects

Meeting Abstracts

4. Correction to "Nanoprobe Synthesized by Magnetotactic Bacteria, Detecting Fluorescence Variations under Dissociation of Rhodamine B from Magnetosomes following Temperature, pH Changes, or the Application of Radiation".

Author

Alphandéry E, Abi Haidar D, Seksek O, Thoreau M, Trautmann A, Bercovici N, Gazeau F, Guyot F, and Chebbi I

Published

2020

5. Local IFNα enhances the anti-tumoral efficacy of systemic anti-PD1 to prevent tumor relapse.

Author

Guerin MV, Regnier F, Thoreau M, Vimeux L, Benard M, Dransart E, Penny HL, Johannes L, Trautmann A, and Bercovici N

Subjects

Animals, Disease Models, Animal, Humans, Immunotherapy, Mice, Interferon-alpha metabolism, Neoplasms drug therapy, Programmed Cell Death 1 Receptor antagonists & inhibitors

Abstract

Background: Tumor relapse constitutes a major challenge for anti-tumoral treatments, including immunotherapies. Indeed, most cancer-related deaths occur during the tumor relapse phase., Methods: We designed a mouse model of tumor relapse in which mice transplanted with E7 + TC1 tumor cells received a single therapeutic vaccination of STxB-E7+IFNα. Unlike the complete regression observed after two vaccinations, such a treatment induced a transient shrinkage of the tumor mass, followed by a rapid tumor outgrowth. To prevent this relapse, we tested the efficacy of a local administration of IFNα together with a systemic therapy with anti-PD1 Ab. The immune response was analyzed during both the tumor regression and relapse phases., Results: We show that, during the regression phase, tumors of mice treated with a single vaccination of STxB-E7 + IFNα harbor fewer activated CD8 T cells and monocytes than tumors doomed to fully regress after two vaccinations. In contrast, the systemic injection of an anti-PD1 Ab combined with the peri-tumoral injection of IFNα in this time frame promotes infiltration of activated CD8 T cells and myeloid cells, which, together, exert a high cytotoxicity in vitro against TC1 cells. Moreover, the IFNα and anti-PD1 Ab combination was found to be more efficient than IFNα or anti-PD1 used alone in preventing tumor relapse and was better able to prolong mice survival., Conclusions: Together, these results indicate that the local increase of IFNα in combination with an anti-PD1 therapy is an effective way to promote efficient and durable innate and adaptive immune responses preventing tumor relapse., Competing Interests: Competing interests: None declared., (© Author(s) (or their employer(s)) 2020. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.)

Published

2020

6. HIV-1 Envelope Overcomes NLRP3-Mediated Inhibition of F-Actin Polymerization for Viral Entry.

Author

Paoletti A, Allouch A, Caillet M, Saïdi H, Subra F, Nardacci R, Wu Q, Muradova Z, Voisin L, Raza SQ, Law F, Thoreau M, Dakhli H, Delelis O, Poirier-Beaudouin B, Dereuddre-Bosquet N, Le Grand R, Lambotte O, Saez-Cirion A, Pancino G, Ojcius DM, Solary E, Deutsch E, Piacentini M, Gougeon ML, Kroemer G, and Perfettini JL

Subjects

Humans, Polymerization, Signal Transduction, Virus Internalization, Actins metabolism, HIV-1 metabolism, NLR Family, Pyrin Domain-Containing 3 Protein metabolism

Abstract

Purinergic receptors and nucleotide-binding domain leucine-rich repeat containing (NLR) proteins have been shown to control viral infection. Here, we show that the NLR family member NLRP3 and the purinergic receptor P2Y2 constitutively interact and regulate susceptibility to HIV-1 infection. We found that NLRP3 acts as an inhibitory factor of viral entry that represses F-actin remodeling. The binding of the HIV-1 envelope to its host cell receptors (CD4, CXCR4, and/or CCR5) overcomes this restriction by stimulating P2Y2. Once activated, P2Y2 enhances its interaction with NLRP3 and stimulates the recruitment of the E3 ubiquitin ligase CBL to NLRP3, ultimately leading to NLRP3 degradation. NLRP3 degradation is permissive for PYK2 phosphorylation (PYK2Y402 ∗ ) and subsequent F-actin polymerization, which is required for the entry of HIV-1 into host cells. Taken together, our results uncover a mechanism by which HIV-1 overcomes NLRP3 restriction that appears essential for the accomplishment of the early steps of HIV-1 entry., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2019

7. TGFβ blocks IFNα/β release and tumor rejection in spontaneous mammary tumors.

Author

Guerin MV, Regnier F, Feuillet V, Vimeux L, Weiss JM, Bismuth G, Altan-Bonnet G, Guilbert T, Thoreau M, Finisguerra V, Donnadieu E, Trautmann A, and Bercovici N

Subjects

Animals, Female, Interferon Regulatory Factor-3 metabolism, Macrophages drug effects, Macrophages metabolism, Mammary Tumor Virus, Mouse metabolism, Mice, Phosphorylation drug effects, Xanthones pharmacology, Interferon-alpha metabolism, Interferon-beta metabolism, Mammary Neoplasms, Animal metabolism, Transforming Growth Factor beta metabolism

Abstract

Type I interferons (IFN) are being rediscovered as potent anti-tumoral agents. Activation of the STimulator of INterferon Genes (STING) by DMXAA (5,6-dimethylxanthenone-4-acetic acid) can induce strong production of IFNα/β and rejection of transplanted primary tumors. In the present study, we address whether targeting STING with DMXAA also leads to the regression of spontaneous MMTV-PyMT mammary tumors. We show that these tumors are refractory to DMXAA-induced regression. This is due to a blockade in the phosphorylation of IRF3 and the ensuing IFNα/β production. Mechanistically, we identify TGFβ, which is abundant in spontaneous tumors, as a key molecule limiting this IFN-induced tumor regression by DMXAA. Finally, blocking TGFβ restores the production of IFNα by activated MHCII + tumor-associated macrophages, and enables tumor regression induced by STING activation. On the basis of these findings, we propose that type I IFN-dependent cancer therapies could be greatly improved by combinations including the blockade of TGFβ.

Published

2019

8. Anticancer chemotherapy and radiotherapy trigger both non-cell-autonomous and cell-autonomous death.

Author

Martins I, Raza SQ, Voisin L, Dakhli H, Allouch A, Law F, Sabino D, De Jong D, Thoreau M, Mintet E, Dugué D, Piacentini M, Gougeon ML, Jaulin F, Bertrand P, Brenner C, Ojcius DM, Kroemer G, Modjtahedi N, Deutsch E, and Perfettini JL

Subjects

Animals, Antineoplastic Agents therapeutic use, Cell Death drug effects, Cell Death radiation effects, Cell Line, Tumor, Cisplatin pharmacology, HCT116 Cells, Humans, Jurkat Cells, MCF-7 Cells, Mice, Neoplasms drug therapy, Neoplasms pathology, Neoplasms radiotherapy, Oxaliplatin pharmacology, Paclitaxel pharmacology, Radiotherapy, Antineoplastic Agents pharmacology, Apoptosis drug effects, Apoptosis radiation effects, Bystander Effect drug effects, Bystander Effect radiation effects, Gamma Rays therapeutic use

Abstract

Even though cell death modalities elicited by anticancer chemotherapy and radiotherapy have been extensively studied, the ability of anticancer treatments to induce non-cell-autonomous death has never been investigated. By means of multispectral imaging flow-cytometry-based technology, we analyzed the lethal fate of cancer cells that were treated with conventional anticancer agents and co-cultured with untreated cells, observing that anticancer agents can simultaneously trigger cell-autonomous and non-cell-autonomous death in treated and untreated cells. After ionizing radiation, oxaliplatin, or cisplatin treatment, fractions of treated cancer cell populations were eliminated through cell-autonomous death mechanisms, while other fractions of the treated cancer cells engulfed and killed neighboring cells through non-cell-autonomous processes, including cellular cannibalism. Under conditions of treatment with paclitaxel, non-cell-autonomous and cell-autonomous death were both detected in the treated cell population, while untreated neighboring cells exhibited features of apoptotic demise. The transcriptional activity of p53 tumor-suppressor protein contributed to the execution of cell-autonomous death, yet failed to affect the non-cell-autonomous death by cannibalism for the majority of tested anticancer agents, indicating that the induction of non-cell-autonomous death can occur under conditions in which cell-autonomous death was impaired. Altogether, these results reveal that chemotherapy and radiotherapy can induce both non-cell-autonomous and cell-autonomous death of cancer cells, highlighting the heterogeneity of cell death responses to anticancer treatments and the unsuspected potential contribution of non-cell-autonomous death to the global effects of anticancer treatment.

Published

2018

9. Nanoprobe Synthesized by Magnetotactic Bacteria, Detecting Fluorescence Variations under Dissociation of Rhodamine B from Magnetosomes following Temperature, pH Changes, or the Application of Radiation.

Author

Alphandéry E, Abi Haidar D, Seksek O, Thoreau M, Trautmann A, Bercovici N, Gazeau F, Guyot F, and Chebbi I

Abstract

We report a method of fabrication of fluorescent magnetosomes, designated as MCR400, in which 400 μM of rhodamine B are introduced in the growth medium of AMB-1 magnetotactic bacteria and fluorescent magnetosomes are then extracted from these bacteria. These fluorescent magnetosomes behave differently from most fluorescent nanoprobes, which often lead to fluorescence losses over time due to photobleaching. Indeed, when MCR400 are heated to 30-90 °C, brought to an acidic pH, or exposed to radiations, we observed that their fluorescence intensity increased. We attributed this behavior to the dissociation of rhodamine B from the magnetosomes. Interestingly, enhanced fluorescence was also observed in vitro when MCR400 were mixed with either primary macrophages or tumor cells (TC1-GFP or RG2-Cells) or in vivo when MCR400 were introduced in rat glioblastoma. We showed that MCR400 internalize in tumor and immune cells (macrophages) leading to enhanced fluorescence, suggesting that fluorescent magnetosomes could be used during cancer treatments such as magnetic hyperthermia to image cells of interest such as immune or tumor cells.

Published

2017

10. NOX2-dependent ATM kinase activation dictates pro-inflammatory macrophage phenotype and improves effectiveness to radiation therapy.

Author

Wu Q, Allouch A, Paoletti A, Leteur C, Mirjolet C, Martins I, Voisin L, Law F, Dakhli H, Mintet E, Thoreau M, Muradova Z, Gauthier M, Caron O, Milliat F, Ojcius DM, Rosselli F, Solary E, Modjtahedi N, Deutsch E, and Perfettini JL

Subjects

Animals, Cell Line, Flow Cytometry, Humans, Interferon-gamma metabolism, Mice, Microscopy, Fluorescence, Phosphorylation radiation effects, Protein Processing, Post-Translational, RAW 264.7 Cells, Signal Transduction, Ataxia Telangiectasia Mutated Proteins metabolism, Macrophage Activation radiation effects, Macrophages metabolism

Abstract

Although tumor-associated macrophages have been extensively studied in the control of response to radiotherapy, the molecular mechanisms involved in the ionizing radiation-mediated activation of macrophages remain elusive. Here we show that ionizing radiation induces the expression of interferon regulatory factor 5 (IRF5) promoting thus macrophage activation toward a pro-inflammatory phenotype. We reveal that the activation of the ataxia telangiectasia mutated (ATM) kinase is required for ionizing radiation-elicited macrophage activation, but also for macrophage reprogramming after treatments with γ-interferon, lipopolysaccharide or chemotherapeutic agent (such as cisplatin), underscoring the fact that the kinase ATM plays a central role during macrophage phenotypic switching toward a pro-inflammatory phenotype through the regulation of mRNA level and post-translational modifications of IRF5. We further demonstrate that NADPH oxidase 2 (NOX2)-dependent ROS production is upstream to ATM activation and is essential during this process. We also report that the inhibition of any component of this signaling pathway (NOX2, ROS and ATM) impairs pro-inflammatory activation of macrophages and predicts a poor tumor response to preoperative radiotherapy in locally advanced rectal cancer. Altogether, our results identify a novel signaling pathway involved in macrophage activation that may enhance the effectiveness of radiotherapy through the reprogramming of tumor-infiltrating macrophages.

Published

2017

11. The STING agonist DMXAA triggers a cooperation between T lymphocytes and myeloid cells that leads to tumor regression.

Author

Weiss JM, Guérin MV, Regnier F, Renault G, Galy-Fauroux I, Vimeux L, Feuillet V, Peranzoni E, Thoreau M, Trautmann A, and Bercovici N

Abstract

Regressing tumors are usually associated with a large immune infiltrate, but the molecular and cellular interactions that govern a successful anti-tumor immunity remain elusive. Here, we have triggered type I Interferon (IFN) signaling in a breast tumor model (MMTV-PyMT) using 5,6-dimethylxanthenone-4-acetic acid (DMXAA), a ligand of the STimulator of Interferon Genes, STING. The 2 main events rapidly triggered by DMXAA in transplanted PyMT tumors are 1) the disruption of the tumor vasculature, followed by hypoxia and cell death; 2) the release of chemokines. Both events converged to trigger the recruitment of 2 waves of immune cells: a swift, massive recruitment of neutrophils, followed by a delayed rise in monocytes and CD8 T cells in the tumor mass. Depletion experiments in vivo revealed that myeloid cell subsets and T cells need to cooperate to achieve full-blown recruitment and activation at the tumor site and to induce effective secondary cell death leading to tumor regression (Illustration 1). Altogether, our study highlights that the tumor regression induced by the STING agonist DMXAA results from a cascade of events, with an initial vessel destruction followed by several infiltration waves of immune cells which have to cooperate to amplify and sustain the initial effect. We thus provide the first global and detailed kinetic analysis of the anti-tumoral effect of DMXAA and of its different articulated steps.

Published

2017

12. Entosis: The emerging face of non-cell-autonomous type IV programmed death.

Author

Martins I, Raza SQ, Voisin L, Dakhli H, Law F, De Jong D, Allouch A, Thoreau M, Brenner C, Deutsch E, and Perfettini JL

Subjects

Humans, Phagosomes physiology, Signal Transduction physiology, Apoptosis physiology, Autophagosomes pathology, Autophagy physiology, Entosis physiology

Abstract

The present review summarizes recent experimental evidences about the existence of the non-cell-autonomous death entosis in physiological and pathophysiological contexts, discusses some aspects of this form of cell death, including morphological, biochemical and signaling pathways that distinguish non-cell-autonomous demises from other death modalities and propose to define this new modality of death as type IV programmed cell death., (Copyright © 2017 Chang Gung University. Published by Elsevier B.V. All rights reserved.)

Published

2017

13. [The vaccination-induced cooperation of T cells and myeloid cells leads to an anti-tumoral effect].

Author

Thoreau M, Bercovici N, and Trautmann A

Subjects

Animals, CD8-Positive T-Lymphocytes physiology, Cancer Vaccines immunology, Humans, Mice, Molecular Mimicry, Viral Vaccines immunology, Cell Communication immunology, Myeloid Cells physiology, Neoplasms immunology, T-Lymphocytes physiology, Vaccination

Published

2016

14. Vaccine-induced tumor regression requires a dynamic cooperation between T cells and myeloid cells at the tumor site.

Author

Thoreau M, Penny HL, Tan K, Regnier F, Weiss JM, Lee B, Johannes L, Dransart E, Le Bon A, Abastado JP, Tartour E, Trautmann A, and Bercovici N

Subjects

Animals, Cell Communication immunology, Flow Cytometry, Fluorescent Antibody Technique, Mice, Mice, Inbred C57BL, Mice, Knockout, Transcriptome, CD8-Positive T-Lymphocytes immunology, Cancer Vaccines immunology, Lymphocytes, Tumor-Infiltrating immunology, Myeloid Cells immunology, Neoplasms, Experimental immunology

Abstract

Most cancer immunotherapies under present investigation are based on the belief that cytotoxic T cells are the most important anti-tumoral immune cells, whereas intra-tumoral macrophages would rather play a pro-tumoral role. We have challenged this antagonistic point of view and searched for collaborative contributions by tumor-infiltrating T cells and macrophages, reminiscent of those observed in anti-infectious responses. We demonstrate that, in a model of therapeutic vaccination, cooperation between myeloid cells and T cells is indeed required for tumor rejection. Vaccination elicited an early rise of CD11b+ myeloid cells that preceded and conditioned the intra-tumoral accumulation of CD8+ T cells. Conversely, CD8+ T cells and IFNγ production activated myeloid cells were required for tumor regression. A 4-fold reduction of CD8+ T cell infiltrate in CXCR3KO mice did not prevent tumor regression, whereas a reduction of tumor-infiltrating myeloid cells significantly interfered with vaccine efficiency. We show that macrophages from regressing tumors can kill tumor cells in two ways: phagocytosis and TNFα release. Altogether, our data suggest new strategies to improve the efficiency of cancer immunotherapies, by promoting intra-tumoral cooperation between macrophages and T cells.

Published

2015