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Toll-like receptor signaling-deficient cells enhance antitumor activity of cell-based immunotherapy by increasing tumor homing

A. Morales-Molina, M.A. Rodríguez-Milla, S,. Gambera, T. Cejalvo, B. de Andrés M.L. Gaspar, J. Garcia-Castro. Cancer Res Commun 2023 Mar 1;3(3):347-360. eCollection 2023 Mar

PUBMED DOI

Immune stress suppresses innate immune signaling in preleukemic precursor B-cells to provoke leukemia in predisposed mice

Isidro-Hernández M, Casado-García A, Oak N, Alemán-Arteaga S, Ruiz-Corzo B, Martínez-Cano J, Mayado A, G. Sánchez E, Blanco O, Gaspar ML, Orfao A, Alonso-López D, De las Rivas J, Riesco S, Prieto-Matos P, González-Murilo A, García Criado FJ, García Cenador MB, Ramírez-Orellana M, De Andrés B, Vicente-Dueñas C, Cobaleda C, Nichols KE, Sánchez-García I. Nat Commun 2023 Aug 24;14(1):5159.

PUBMED DOI

Role of Toll-like receptor 4 in intravascular hemolisis-mediated injury

Vázquez-Carballo C, Herencia C, Guerrero-Hue M, García-Caballero C, Rayego-Mateos S, Morgado-Pascual JL, Opazo-Rios L, González-Guerrero C, Vallejo-Mudarra M, Cortegano I, Gaspar ML, de Andrés B, Egido J, Moreno JA. J Pathol. 2022 Nov; 258(3): 236–249.

PUBMED DOI

Age-dependent nasal immune responses in non-hospitalized bronchiolitis children

Cortegano I, Rodríguez M, Hernángómez S, Arrabal A, Garcia-Vao C, Rodríguez J, Sandra Fernández S, Díaz J, de la Rosa B, Solís B, Arribas C, Garrido F, Zaballos A, Roa S, López V, Gaspar ML, de Andrés B. Front Immunol 2022 Dec 6:13:1011607.

PUBMED DOI

TREM1 regulates antifungal immune responses in invasive pulmonary aspergillosis

Bernal-Martinez L, Gonçalves S, de Andres B, Cunha C, Gonzalez Jimenez I, Lagrou K, Mellado E, Gaspar ML, Maertens J, Carvalho A, and Alcazar-Fuoli L. Virulence 2021 Dec;12(1):570-583.

PUBMED DOI

Toll-like receptors in acute kidney injury

Vázquez-Carballo C, Guerrero-Hue M, García Caballero C, Rayego-Mateos S, Opazo-Rios L, Morgado-Pascual JL, Herencia-Bellido C, Vallejo-Mudarra M, Cortegano I, Gaspar ML, de Andrés B, Egido J, Moreno-Gutiérrez JA. Int J Mol Sci. 2021 Jan; 22(2): 816.

PUBMED DOI

Senescent accelerated prone 8 (SAMP8) mice as a model of age dependent neuroinflammation

Fernández A, Quintana E, Velasco P, Moreno-Jimenez B, de Andrés B, Gaspar ML, Liste I, Vilar M, Mira E, Cano E. J Neuroinflammation 2021 Mar 18;18(1):75.

PUBMED DOI

The TLR4-MyD88 Signaling Regulates Lung Monocyte Differentiation Pathways in Response to Streptococcus pneumoniae

Sánchez-Tarjuelo R, Cortegano I, Manosalva J, Rodríguez M, Ruiz C, Alía M, Prado MC, Cano EM, Ferrándiz MJ, de la Campa A, Gaspar ML, de Andrés B. Front Immunol 2020 Sep 16:11:2120.

PUBMED DOI

Nrf2 plays a protective role against intravascular hemolysis-mediated acute kidney injury.

Rubio-Navarro A, Vázquez-Carballo C, Guerrero-Hue M, García-Caballero C, Herencia C, Gutierrez E, Yuste C, Sevillano A, Praga M, Egea J, Cannata P, Cortegano I, de Andrés B, Gaspar ML, Cadenas S, Michalska P, León R, Ortiz, A, Egido J, Moreno JA. Front Pharmacol. 2019; 10: 740.

PUBMED DOI

ICOS deficiency hampers the homeostasis, development and activity of NK cell

Montes-Casado M, Ojeda G, Aragoneses-Fenoll L, López D, de Andrés B, Gaspar ML, Dianzani U, Rojo JM, Portolés P. PLoS One 2019 Jul 8;14(7):e0219449.

PUBMED DOI

Neutrophil derived CSF1 induces macrophage polarization and promotes transplantation tolerance

Braza MS, Conde P, García M, Cortegano I, Brahmachary M, Pothula V, Fay F, Boros P, Werner SA, Ginhoux F, Mulder WJM, Ochando J. Am J Transplant 2018 May;18(5):1247-1255.

PUBMED DOI

CD45 expression discriminates waves of embryonic megakaryocytes in the mouse.

Cortegano, I., Serrano, N., Ruiz, C., Rodríguez, M., Prado, C., Alía, M., Hidalgo, A., Cano, E., de Andrés B. and Gaspar, ML. 2018. Haematologica, 104(9):1853-1865

PUBMED DOI

Podocytes as new cellular targets of hemoglobin toxicity in massive intravascular hemolysis.

Rubio-Navarro A, Sanchez-Niño MD, Guerrero-Hue M, García-Caballero C, Gutiérrez E, Yuste C, Sevillano A, Praga M, Egea J, Román E, Cannata P, Ortega R, Cortegano I, de Andrés B, Gaspar ML, Cadenas S, Ortiz A, Egido J, Moreno JA. Podocytes as new cellular targets of hemoglobin toxicity in massive intravascular hemolysis. 2018. J.Pathol. 244(3):296-310.

PUBMED DOI

Spatially-restricted JAG1-Notch signaling in the human thymus provides permissive microenvironments for dendritic cell development.

Martín Gayo, E., González-García, S., García-León, M., Murcia-Ceballos, A., Alcain, J., García-Peydró, M., Allende, L., de Andrés, B., Gaspar, ML. and Toribio, ML. J.Exp.Med. (2017) 214:3361-3379

PUBMED DOI

Altered Marginal Zone and innate-like B cells in aged SAMP8 mice with defective IgG1 responses

Cortegano, I., Rodriguez, M., Martin, I., Prado, C., Ruiz, C., Hortigüela, R., Alia, M., Vilar, M., Mira, H., Cano, E., de Andrés, B., and Gaspar, ML. Cell death & disease (2017) 8, e3000

PUBMED DOI

The formation of titan cells in Cryptococcus neoformans depends on the mouse strain and correlates with induction of Th2-type responses

García-Barbazán, I., Trevijano-Contador, N., Rueda, C., de Andrés, B., Pérez-Tavárez, R., Herrero-Fernández, I., Gaspar ML., and Zaragoza, O. Cellular Microbiology (2015) 18:111-124

PUBMED DOI

DNGR-1+ dendritic cells are located in meningeal and choroid plexus membranes of the non-injured brain.

Quintana, E., Fernández. A, de Andrés, B., Liste, I., Sancho, D., Gaspar, ML. and Cano, E. Glia (2015) 62 (12):2231-2248

PUBMED DOI

Postnatal and adult immunoglobulin repertoires of innate-like CD19(+)CD45R(lo) B Cells.

Prado, C., Rodriguez, M., Cortegano I., Ruiz, C., Alía, M., de Andrés, B., Gaspar, ML. J Inn Inmmunol. (2014) 6: 499-514

PUBMED DOI

Notch1 regulates progenitor cell proliferation and differentiation during murine yolk sac hematopoiesis

Isabel Cortegano, Pedro Melgar-Rojas, Luis Luna-Zurita, Miguel Ángel Rodríguez-Marcos, MA., Gaspar ML., and José Luis de la Pompa, JL. Cell death and diff. (2014) 21: 1081-1094

PUBMED DOI

Timely Diagnosis of Histoplasmosis in Non-endemic Countries: A Laboratory Challenge

Buitrago MJ, Martín-Gómez T. Front Microbiol. 2020 Mar 24; 11:467

PUBMED DOI

Content with Investigacion Biología y Variabilidad del VIH .

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Additional Information

La inducción de la tolerancia al aloinjerto sigue siendo una meta por alcanzar en el trasplante de órganos. La mayoría de las estrategias terapéuticas se centran en la inhibición del sistema inmunológico adaptativo, pero datos recientes demuestran que el reconocimiento alogénico de las células mieloides inicia el rechazo al trasplante. Terapias dirigidas hacia las células mieloides “in vivo” representan un objetivo potencial para inducir tolerancia inmunológica, pero permanece inexplorado clínicamente.Nuestro laboratorio utiliza una nanoinmunoterapia revolucionaria de nanopartículas de lipoproteínas de alta densidad (HDL) cargadas con rapamicina (mTORi-HDL) que previenen las modificaciones epigenéticas asociadas con la inmunidad entrenada, un estado funcional de los macrófagos recientemente descubierto. Usando un modelo experimental de trasplante en ratón, nuestros resultados demuestran que la administración de esta inmunoterapia con mTORi-HDL previene la respuesta inmunológica y promueve la tolerancia al órgano trasplantado.Nuestro laboratorio muestra un enfoque de investigación multidisciplinar articulado en tres objetivos diferentes para evaluar la relevancia clínica y los efectos terapéuticos de la inmunoterapia como preparación para un ensayo clínico en trasplante de órganos. Los objetivos generales estarán orientados a confirmar la identificación de la inmunidad entrenada como biomarcador y valor analítico para predecir el riesgo de rechazo en pacientes trasplantados bajo tres condiciones: periodos prolongadas de reperfusión isquémica (IRI) (objetivo 1), alosensibilización (objetivo 2) e infección (objetivo 3).

Induction of allograft tolerance remains a goal to be achieved in organ transplantation. Most therapeutic strategies focus on inhibition of the adaptive immune system, but recent data demonstrate that allogeneic recognition of myeloid cells initiates transplant rejection. Therapies targeting myeloid cells “in vivo” represent a potential target to induce immunological tolerance, but remain clinically unexplored. 

Our laboratory uses a revolutionary nanoimmunotherapy of high-density lipoprotein (HDL) nanoparticles loaded with rapamycin (mTORi-HDL) that prevents epigenetic modifications associated with trained immunity, a recently discovered functional state of macrophages. Using an experimental mouse transplant model, our results demonstrate that the administration of this immunotherapy with mTORi-HDL prevents the immune response and promotes tolerance to the transplanted organ. 

Our laboratory shows a multidisciplinary research approach articulated in three different objectives to evaluate the clinical relevance and therapeutic effects of immunotherapy in preparation for a clinical trial in organ transplantation. The general objectives will be aimed at confirming the identification of trained immunity as a biomarker and analytical value to predict the risk of rejection in transplant patients under three conditions: prolonged periods of ischemic reperfusion (IRI) (objective 1), allosensitization (objective 2) and infection (objective 3).

Induction of allograft tolerance remains a goal to be achieved in organ transplantation. Most therapeutic strategies focus on inhibition of the adaptive immune system, but recent data demonstrate that allogeneic recognition of myeloid cells initiates transplant rejection. Therapies targeting myeloid cells “in vivo” represent a potential target to induce immunological tolerance, but remain clinically unexplored. 

Our laboratory uses a revolutionary nanoimmunotherapy of high-density lipoprotein (HDL) nanoparticles loaded with rapamycin (mTORi-HDL) that prevents epigenetic modifications associated with trained immunity, a recently discovered functional state of macrophages. Using an experimental mouse transplant model, our results demonstrate that the administration of this immunotherapy with mTORi-HDL prevents the immune response and promotes tolerance to the transplanted organ. 

Our laboratory shows a multidisciplinary research approach articulated in three different objectives to evaluate the clinical relevance and therapeutic effects of immunotherapy in preparation for a clinical trial in organ transplantation. The general objectives will be aimed at confirming the identification of trained immunity as a biomarker and analytical value to predict the risk of rejection in transplant patients under three conditions: prolonged periods of ischemic reperfusion (IRI) (objective 1), allosensitization (objective 2) and infection (objective 3).

Content with Investigacion Biología y Variabilidad del VIH .