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Investigation
Viral Biology
Publications
Heterodimers as the structural unit of the T=1 capsid of the fungal dsRNA Rosellinia necatrix quadrivirus 1
Luque D., Mata C.P., González-Camacho F., González J.M., Gómez-Blanco J., Alfonso C., Rivas G., Havens W.M., Kanematsu S., Suzuki N., Ghabrial S.A., Trus B.L., Castón J.R. 2016. Heterodimers as the structural unit of the T=1 capsid of the fungal dsRNA Rosellinia necatrix quadrivirus 1. J Virol. 90(24):11220-11230. IF: 4.666, Q1.
PUBMED DOISelf-assembly and characterization of small and monodisperse dye nanospheres in a protein cage
Luque D., de la Escosura A., Snijder J., Brasch M., Burnley R.J, Koay M.S.T., Carrascosa J.L., Wuite G.J.L., Roos W.H., Heck A.J.R., J.J.L.M Cornelissen, Torres T., Castón J.R. 2014. Self-assembly and characterization of small and monodisperse dye nanospheres in a protein cage. Chem. Sci.,5, 575-581. IF: 9.211, D1.
DOICryo-EM near-atomic structure of a dsRNA fungal virus shows ancient structural motifs preserved in the dsRNA viral lineage.
Luque D., Gómez-Blanco J., Garriga D., Brilot A.F., González J.M., Havens W.M., Carrascosa J.L., Trus B.L., Verdaguer N., Ghabrial S.A., Castón J.R. 2014. Cryo-EM near-atomic structure of a dsRNA fungal virus shows ancient structural motifs preserved in the dsRNA viral lineage. Proc Natl Acad Sci U S A 111(21):7641-7646. IF: 9.674, D1
PUBMED DOINew insights into rotavirus entry machinery: stabilization of rotavirus spike conformation is independent of trypsin cleavage
Rodríguez J.M., Chichón F.J., Martín-Forero E., González-Camacho F., Carrascosa J.L., Castón J.R., Luque D*. 2014. New insights into rotavirus entry machinery: stabilization of rotavirus spike conformation is independent of trypsin cleavage. PLoS Pathog. 10(5):e1004157. IF: 7.562, D1. * Corresponding autor.
PUBMED DOIEfficacy and safety assessment of a TRAF6-targeted nanoimmunotherapy in atherosclerotic mice and non-human primates.
3. Lameijer M, Binderup T, van Leent M, Senders M, Fay F. Seijkens T, Kroon J, Stroes E, Kjaer A, Ochando J, Reiner T, Pérez-Medina C, Calcagno C, Fischer E, Zhang B, Temel R, Swirski F, Nahrendorf M, Fayad Z, Lutgens E, Mulder W and Duivenvoorden R. Efficacy and safety assessment of a TRAF6-targeted nanoimmunotherapy in atherosclerotic mice and non-human primates. Nature Biomedical Engineering. 2018. 2: 279–292.
PUBMED DOINeutrophil derived CSF1 induces macrophage polarization and promotes transplantation tolerance.
4. Braza MS, Conde P, Garcia MR, Cortegano I, Brahmachary M, Pothula V, Fay F, Boros P, Werner SW, Ginhoux F, Mulder WJ, and Ochando J. Neutrophil derived CSF1 induces macrophage polarization and promotes transplantation tolerance. Am J Transplant. 2018.
PUBMED DOIContent with Investigacion .
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Isabel de Fuentes Corripio
Jefa de Unidad, Investigador Titular OPIS
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David Carmena Jiménez
Investigador Doctor distinguido
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Aly Salimo Omar Muadica
Becario pre-doctoral
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Marta Hernández de Mingo
Colaborador I+D+I
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Begoña Bailo Cardoso
Técnico de Laboratorio
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María Aguilera
Técnico de laboratorio
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David González Barrio
Investigador contratado
List of staff
Additional Information
The research activity of the Viral Biology group since its beginnings in the 1980s has focused on respiratory viruses, especially on the study of the mechanisms of virus entry into the cell, evolutionary aspects, antigenic properties and vaccine development.
Currently, the group's objectives are focused on the characterisation of the immune response and the development of vaccines against human pneumoviruses: human respiratory syncytial virus (hRSV) and human metapneumovirus (hMPV).
Both viruses are considered to be important respiratory pathogens of high clinical relevance, especially in the paediatric population.
Safe and effective vaccines against these viruses are currently not available. Soluble protein subunits based on the fusion protein (F-protein) of hRSV and hMPV are being developed in the laboratory by protein engineering for use as vaccines against human pneumoviruses.
On the other hand, and thanks to the characterisation of the type of humoral response induced by the F proteins of these viruses, the laboratory is also involved in the isolation of monoclonal antibodies and nanoantibodies for use as treatments against these viruses.
The research activity of the Viral Biology group since its beginnings in the 1980s has focused on respiratory viruses, especially on the study of the mechanisms of virus entry into the cell, evolutionary aspects, antigenic properties and vaccine development.
Currently, the group's objectives are focused on the characterisation of the immune response and the development of vaccines against human pneumoviruses: human respiratory syncytial virus (hRSV) and human metapneumovirus (hMPV).
Both viruses are considered to be important respiratory pathogens of high clinical relevance, especially in the paediatric population.
Safe and effective vaccines against these viruses are currently not available. Soluble protein subunits based on the fusion protein (F-protein) of hRSV and hMPV are being developed in the laboratory by protein engineering for use as vaccines against human pneumoviruses.
On the other hand, and thanks to the characterisation of the type of humoral response induced by the F proteins of these viruses, the laboratory is also involved in the isolation of monoclonal antibodies and nanoantibodies for use as treatments against these viruses.