Cellular Immunology

Líneas de investigación

Content with Investigacion Inmunobiología .

The Immunobiology group has been working for years on the following lines of research:
1) The mechanisms of haematopoietic cell generation throughout ontogeny and the influence that the first haematopoietic cells exert on the innate and adaptive immune system present in the adults. We have identified and characterised a new population of B lymphocytes called B1-Rel (B220lo), which produce high levels of natural IgG/IgA antibodies. We sought to understand their role in the immune response in animal models of infection, analysing their impact on immune cell populations and on the production of soluble mediators (cytokines and immunoglobulins). In this regard, we have evaluated the generation of embryonic megakaryocytes (and their differentiation niches), their functionality and that of platelets, and their influence on haematopoietic development. For lymphoid populations, we have carried out extensive characterisation by flow cytometry and single cell RNA sequencing (scRNAseq) methodology. To carry out these cellomic studies, we have designed complex panels for use in multiparametric phenotypic analysis, and single cell cytometry and RNAseq omics technologies on purified cell populations.

In parallel, we are interested in understanding local immune responses in respiratory infections at times of particular susceptibility due to the fragility of the immune system (childhood and old age), both in mouse animal models, which allow their manipulation, and in humans.

2) Mouse models studied during neonatal life, in which we evaluated the effect of antibiotic (AB) treatment and addressed the role of TLR receptors in innate, pseudo-innate and adaptive immune cell populations. In these models, we observed that AB administration was able to modulate B-lymphoid populations, as well as their ability to secrete proinflammatory cytokines in culture and their differentiation into plasma cells, with differentiated immunoglobulin repertoires. Furthermore. These effects were mediated through the Toll-like receptor-2 (TLR2).

3) Mouse models with accelerated senescence (SAMP8) and senescent animals (over 20 months of age) to map lymphoid populations and soluble mediators of the immune response (immunoglobulins and cytokines). In these models, the B lymphoid populations (B1Rel and marginal zone B lymphocytes) are observed to be altered, accompanied by an increase in IgG1 with great restriction of their VDJ repertoires.

4) Role of the B1Rel population in animal models of local or systemic infection. We analysed the response to Streptoccoccus pneumoniae (SPN) locally in the lung and systemically in the spleen, as well as the role of TLR4 in these responses.

5) In humans, we are studying immune responses in children with respiratory syncytial virus (RSV) viral primo-infection. In this case we studied the immune response that occurs locally in the nasal mucosa (by analysis of nasal washings, NW) in a cohort of infected children versus healthy controls, stratified by age. We found that lymphomyeloid cells accumulate in these nasal washings in patients with diverse lymphocyte populations, as well as cytokines and immunoglobulins.

6) Analysis and characterisation of extracellular vesicles produced during respiratory infection both in lung supernatants from models of SPN infection and in LN in the case of children with RSV infection.

7) In parallel, we carry out studies of the genetic rearrangements of immunoglobulins and their use in the generation of chimeric receptors for possible use in immunotherapy.

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Publicaciones destacadas

Immunoinformatics lessons on the current COVID-19 pandemic and future coronavirus zoonoses

López D, García-Peydró M. “Immunoinformatics lessons on the current COVID-19 pandemic and future coronavirus zoonoses”. Frontiers in Immunology 14:1118267 (2023).

PUBMED DOI

Predicted HLA Class I and Class II Epitopes From Licensed Vaccines Are Largely Conserved in New SARS-CoV-2 Omicron Variant of Concern.

López, D. 2022. Predicted HLA Class I and Class II Epitopes From Licensed Vaccines Are Largely Conserved in New SARS-CoV-2 Omicron Variant of Concern. Front Immunol. 13:832889.

PUBMED

Garcia-Arriaza, J., M. Esteban, and D. López. 2021

Garcia-Arriaza, J., M. Esteban, and D. López. 2021. Modified Vaccinia Virus Ankara as a Viral Vector for Vaccine Candidates against Chikungunya Virus. Biomedicines. 9.

PUBMED

Cross-Recognition of SARS-CoV-2 B-Cell Epitopes with Other Betacoronavirus Nucleoproteins

Tajuelo, A., M. López-Siles, V. Mas, P. Perez-Romero, J. M. Aguado, V. Briz, M. J. McConnell, A. J. Martín-Galiano, and D. López. 2022. Cross-Recognition of SARS-CoV-2 B-Cell Epitopes with Other Betacoronavirus Nucleoproteins. Int.J.Mol.Sci. 23.

PUBMED

Abundance, Betweenness Centrality, Hydrophobicity, and Isoelectric Points Are Relevant Factors in the Processing of Parental Proteins of the HLA Class II Ligandome.

Lorente, E., A. J. Martín-Galiano, D. M. Kadosh, A. Barriga, J. Garcia-Arriaza, C. Mir, M. Esteban, A. Admon, and D. López. 2022. Abundance, Betweenness Centrality, Hydrophobicity, and Isoelectric Points Are Relevant Factors in the Processing of Parental Proteins of the HLA Class II Ligandome. J.Proteome.Res. 21:164-171.

DOI

Prediction of Conserved HLA Class I and Class II Epitopes from SARS-CoV-2 Licensed Vaccines Supports T-Cell Cross-Protection against SARS-CoV-1.

López, D. 2022. Prediction of Conserved HLA Class I and Class II Epitopes from SARS-CoV-2 Licensed Vaccines Supports T-Cell Cross-Protection against SARS-CoV-1. Biomedicines. 10.

PUBMED DOI

Predicted Epitope Abundance Supports Vaccine-Induced Cytotoxic Protection Against SARS-CoV-2 Variants of Concern.

Martín-Galiano, A. J., F. Diez-Fuertes, M. J. McConnell, and D. López. 2021. Predicted Epitope Abundance Supports Vaccine-Induced Cytotoxic Protection Against SARS-CoV-2 Variants of Concern. Front Immunol. 12:732693.

PUBMED DOI

de la Sota, P. G., E. Lorente, L. Notario, C. Mir, O. Zaragoza, and D. López. 2021. Mitoxantrone Shows In Vitro, but Not In Vivo Antiviral Activity against Human Respiratory Syncytial Virus. Biomedicines. 9.

de la Sota, P. G., E. Lorente, L. Notario, C. Mir, O. Zaragoza, and D. López. 2021. Mitoxantrone Shows In Vitro, but Not In Vivo Antiviral Activity against Human Respiratory Syncytial Virus. Biomedicines. 9.

PUBMED DOI

Lorente, E., M. Marcilla, P. G. de la Sota, A. Quijada-Freire, C. Mir, and D. López. 2021. Acid Stripping after Infection Improves the Detection of Viral HLA Class I Natural Ligands Identified by Mass Spectrometry. Int.J.Mol.Sci. 22.

Lorente, E., M. Marcilla, P. G. de la Sota, A. Quijada-Freire, C. Mir, and D. López. 2021. Acid Stripping after Infection Improves the Detection of Viral HLA Class I Natural Ligands Identified by Mass Spectrometry. Int.J.Mol.Sci. 22.

PUBMED DOI

Redondo-Anton, J., M. G. Fontela, L. Notario, R. Torres-Ruiz, S. Rodriguez-Perales, E. Lorente, and P. Lauzurica. 2020. Functional Characterization of a Dual Enhancer/Promoter Regulatory Element Leading Human CD69 Expression. Front Genet. 11:552949.

Redondo-Anton, J., M. G. Fontela, L. Notario, R. Torres-Ruiz, S. Rodriguez-Perales, E. Lorente, and P. Lauzurica. 2020. Functional Characterization of a Dual Enhancer/Promoter Regulatory Element Leading Human CD69 Expression. Front Genet. 11:552949.

PUBMED DOI

Lorente, E., E. Barnea, C. Mir, A. Admon, and D. López. 2020. The HLA-DP peptide repertoire from human respiratory syncytial virus is focused on major structural proteins with the exception of the viral polymerase. J Proteomics. 221:103759.

Lorente, E., E. Barnea, C. Mir, A. Admon, and D. López. 2020. The HLA-DP peptide repertoire from human respiratory syncytial virus is focused on major structural proteins with the exception of the viral polymerase. J Proteomics. 221:103759.

PUBMED DOI

Lorente, E., M. G. Fontela, E. Barnea, A. J. Martín-Galiano, C. Mir, B. Galocha, A. Admon, P. Lauzurica, and D. López. 2020. Modulation of Natural HLA-B*27:05 Ligandome by Ankylosing Spondylitis-associated Endoplasmic Reticulum Aminopeptidase 2 (ERAP2). Mol.Cell Proteomics. 19:994-1004.

Lorente, E., M. G. Fontela, E. Barnea, A. J. Martín-Galiano, C. Mir, B. Galocha, A. Admon, P. Lauzurica, and D. López. 2020. Modulation of Natural HLA-B*27:05 Ligandome by Ankylosing Spondylitis-associated Endoplasmic Reticulum Aminopeptidase 2 (ERAP2). Mol.Cell Proteomics. 19:994-1004.

PUBMED DOI

Marquez, A., M. Gomez-Fontela, S. Lauzurica, R. Candorcio-Simon, D. Munoz-Martín, M. Morales, M. Ubago, C. Toledo, P. Lauzurica, and C. Molpeceres. 2020. Fluorescence enhanced BA-LIFT for single cell detection and isolation. Biofabrication. 12:025019.

Marquez, A., M. Gomez-Fontela, S. Lauzurica, R. Candorcio-Simon, D. Munoz-Martín, M. Morales, M. Ubago, C. Toledo, P. Lauzurica, and C. Molpeceres. 2020. Fluorescence enhanced BA-LIFT for single cell detection and isolation. Biofabrication. 12:025019.

PUBMED DOI

Lorente, E., C. Palomo, E. Barnea, C. Mir, V. M. Del, A. Admon, and D. López. 2019a. Natural Spleen Cell Ligandome in Transporter Antigen Processing-Deficient Mice. J.Proteome.Res. 18:3512-3520.

PUBMED

Lorente, E., J. Redondo-Anton, A. Martín-Esteban, P. Guasp, E. Barnea, P. Lauzurica, A. Admon, and J. A. López de Castro. 2019. Substantial Influence of ERAP2 on the HLA-B40:02 Peptidome: Implications for HLA-B27-Negative Ankylosing Spondylitis. Mol.Cell Proteomics. 18:2298-2309.

Lorente, E., J. Redondo-Anton, A. Martín-Esteban, P. Guasp, E. Barnea, P. Lauzurica, A. Admon, and J. A. López de Castro. 2019. Substantial Influence of ERAP2 on the HLA-B*40:02 Peptidome: Implications for HLA-B*27-Negative Ankylosing Spondylitis. Mol.Cell Proteomics. 18:2298-2309.

PUBMED DOI

Brait, V. H., F. Miro-Mur, I. Perez-de-Puig, L. Notario, B. Hurtado, J. Pedragosa, M. Gallizioli, F. Jimenez-Altayo, M. Arbaizar-Rovirosa, A. Otxoa-de-Amezaga, J. Monteagudo, M. Ferrer-Ferrer, l. R. de, X, E. Bonfill-Teixidor, A. Salas-Perdomo, A. Hernandez-Vidal, P. Garcia-de-Frutos, P. Lauzurica, and A. M. Planas. 2019. CD69 Plays a Beneficial Role in Ischemic Stroke by Dampening Endothelial Activation. Circ.Res. 124:279-291.

Brait, V. H., F. Miro-Mur, I. Perez-de-Puig, L. Notario, B. Hurtado, J. Pedragosa, M. Gallizioli, F. Jimenez-Altayo, M. Arbaizar-Rovirosa, A. Otxoa-de-Amezaga, J. Monteagudo, M. Ferrer-Ferrer, l. R. de, X, E. Bonfill-Teixidor, A. Salas-Perdomo, A. Hernandez-Vidal, P. Garcia-de-Frutos, P. Lauzurica, and A. M. Planas. 2019. CD69 Plays a Beneficial Role in Ischemic Stroke by Dampening Endothelial Activation. Circ.Res. 124:279-291.

DOI

López, D., A. Barriga, E. Lorente, and C. Mir. 2019. Immunoproteomic Lessons for Human Respiratory Syncytial Virus Vaccine Design. J.Clin.Med. 8.

PUBMED DOI

Lorente, E., A. Barriga, E. Barnea, C. Palomo, J. Garcia-Arriaza, C. Mir, M. Esteban, A. Admon, and D. López. 2019. Immunoproteomic analysis of a Chikungunya poxvirus-based vaccine reveals high HLA class II immunoprevalence. PLoS.Negl.Trop.Dis. 13:e0007547.

Lorente, E., A. Barriga, E. Barnea, C. Palomo, J. Garcia-Arriaza, C. Mir, M. Esteban, A. Admon, and D. López. 2019. Immunoproteomic analysis of a Chikungunya poxvirus-based vaccine reveals high HLA class II immunoprevalence. PLoS.Negl.Trop.Dis. 13:e0007547.

PUBMED DOI

Computational characterization of the peptidome in transporter associated with antigen processing (TAP)-deficient cells.

Martin-Galiano, A. J. and Lopez, D. (2019) Computational characterization of the peptidome in transporter associated with antigen processing (TAP)-deficient cells. PLoS.ONE. 14, e0210583.

PUBMED DOI

Proteomics analysis reveals that structural proteins of the virion core and involved in gene expression are the main source for HLA class II ligands in vaccinia virus-infected cells.

Lorente, E., Martin-Galiano, A. J., Barnea, E., Barriga, A., Palomo, C., Garcia-Arriaza, J., Mir, C., Lauzurica, P., Esteban, M., Admon, A., and Lopez, D. (2019) Proteomics analysis reveals that structural proteins of the virion core and involved in gene expression are the main source for HLA class II ligands in vaccinia virus-infected cells. J.Proteome.Res. 18(9):3512-3520

PUBMED DOI

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Content with Investigacion Inmunobiología .

Belén de Andrés Muguruza

Research Scientist

ORCID code: 0000-0002-7391-2823

Graduated in Biology in 1987 and PhD in 1992 from the Autonomous University of Madrid. He completed his doctoral thesis in the laboratory of Dr. Carlos Lahoz in the Immunology department of the Jiménez Díaz Foundation with a pre-doctoral stay at the Institute Curie in Paris, in the laboratory of Dr. Wolf H. Fridman. Subsequently, he completed a two-year postdoctoral stay in the Department of Pathology of the College of Medicine at the University of Iowa, USA, in the laboratory of Dr. Richard G. Lynch. After a year as an Adjunct in the Immunology department of the Jiménez Diaz Foundation, she worked for 2 years with a reinstatement contract from the Ministry of Science in the Immunobiology department of the CNM/ISCIII in the laboratory of Dr. Mª Luisa Gaspar and later with a Ramón y Cajal contract. In 2006 she obtained a position as Staff Senior Scientist.
Isabel Cortegano Jimeno

Research Scientist

ORCID code: 0000-0002-6504-6347

Graduated in Biology in 1995 (Specialty in Biochemistry and Molecular Biology) and PhD in 1999 from the Autonomous University of Madrid. He completed his doctoral thesis at the Jiménez Díaz Foundation in the Immunology laboratory directed by Dr. Carlos Lahoz. Later he obtained a postdoctoral fellowship in the Immunobiology laboratory of Dr. Mª Luisa Gaspar at the National Center of Microbiology (CNM) of the Carlos IIII Health Institute (ISCIII) (2002-2006). He then enjoyed an I3P contract from the CSIC in the laboratory of Professor Miguel Ángel Rodríguez-Marcos (2007-2009). She has been a researcher associated with research projects in the ISCIII Immunobiology laboratory during the years 2010-2018. Since 2018 she has been an associate professor in the Department of Cell Biology of the UCM Faculty of Medicine. He coordinates the scientific dissemination group of the Spanish Society of Immunology (GESEI), is part of the editorial committee of the SEI magazine and is a member of the board of the CAM Immunology Society. She is a Senior Scientist of the ISCIII at the National Center for Microbiology since 2020.
María Luisa Gaspar Alonso-Vega

Research Professor

ORCID code: 0000-0001-9858-3862

Dr. María Luis Gaspar Alons-Vega graduated in 1980 and obtained her PhD in 1985 in Medicine and Surgery from the Autonomous University of Madrid. She completed the specialty of Immunology (1981-1985), and her doctoral thesis under the direction of Dr. Carmen Gutierrez, in the Immunology laboratory of the Puerta de Hierro Clinic directed by Dr. Miguel Kreisler. She completed a predoctoral stay in the Cytogenetics Laboratory of the National Institute of Autoimmune, Diabetes, Digestive and Kidney Diseases (NIDDK, NIH), under the supervision of Dr. JH Tjio and Dr. E. Raveché. She joined the Immunology Service of the National Center for Health Microbiology, Virology and Immunology (CNMVIS, AISNA and later ISCIII) as a Physician-Specialist in 1986, in the Immunology Laboratory directed by Dr. Alfredo Toraño. She completed a postdoctoral stay (1989-1991) at the Immunogenetics Unit of the Pasteur Institute (Paris) directed by Dr. T. Meo. From 1991 to 2006 she was Head of the Immunology Section successively at the CNMVIS, at the National Center for Fundamental Biology (CNBF-ISCIII) and at the National Center for Microbiology (CNM-ISCIII). From 2006 to 2016 she has been a Senior Researcher and Senior Scientist of OPIs, in the Immunobiology laboratory of the CNM-ISCIII. From 2016 to 2018 she was a Scientific Researcher at OPIs and since 2018, she is a Research Professor at OPIs at the CNM.
Carolina Ruiz Sánchez

Specialized Technician

ORCID code: 0000-0002-2177-8132

Graduated in Chemical Sciences (biochemistry specialty) in 1998 and PhD in 2022 from the Complutense University of Madrid. In 2008 he joined the OPIS Assistant in the Immunobiology laboratory of the National Center for Microbiology of the ISCIII, specializing in flow cytometry the first year and subsequently becoming part of the laboratory's technical team. In 2012 he was promoted to Intermediate Level Technician and in 2018 to Higher Specialized Technician of the OPIS, currently occupying this position in the same laboratory.
Mercedes Rodríguez García

Specialized Higher Technician

Graduated in Biology from the Complutense University of Madrid in 2003, she began her doctoral studies in the Bone Metabolism laboratory of the La Paz University Hospital.
In 2007 he joined as a Research Assistant at the Carlos III Health Institute, at the CNM, in the Transplant Immunology laboratory. After 5 years, he began working in the Immunobilology laboratory where he was promoted in 2018 to Specialized Technician, in 2024 to Senior Specialized Technician and where he currently continues to develop his professional career.
Alejandro Arrabal Sierra

Predoctoral Contract (Industrial Doctorate from CAM / Inmunotek).

ORCID code: 0000-0002-9354-9224

Graduated in Biotechnology in 2021 from the Polytechnic University of Madrid, carrying out his final degree project in the Immunobiology laboratory of the National Microbiology Center of the ISCIII. In 2021, he completed a Master's Degree in Research in Immunology at the Complutense University of Madrid and completed his master's thesis in the same CNM laboratory. Subsequently, he worked for a year as a Research Assistant in the laboratory of Dr. Elena Fernández Ruiz at the Hospital Universitario de la Princesa. Since the end of 2023, he has been a predoctoral fellow in the CNM Immunobiology laboratory with an Industrial Doctorate scholarship from the Community of Madrid in collaboration with the company Inmunotek.

List of staff

Información adicional

Our current objective is the analysis of costimulatory molecules that modulate lymphocyte activation and the adaptive and innate immune response; specifically the inducible costimulator ICOS and its association with the enzyme phosphatidylinositol-3-kinase (PI3K). ICOS is induced in T lymphocytes and some innate immune cells; It is involved in normal and pathological immune responses and in inflammation regulatory circuits. Its signals are mediated by the association of PI3K, enzymes that regulate many aspects of the response to antigen, lymphoproliferative syndromes, lupus and cancer.

We analyzed the usefulness of ICOS, its ligand (ICOS-L) and the PI3K associated with ICOS as therapeutic targets in immune response to infections and tumors and in autoimmune diseases. We used two different approaches: i) pharmacological (effect of PI3K p110 isoform inhibitors on immune response) and ii) genetic (analysis of mouse models with tissue-specific conditioned modification of PI3K p110α). We study; 1) The role of PI3K-p110α in the activation and differentiation of cells involved in innate and adaptive immune response to infection, tumors and autoimmunity, seeking new therapies. 2) The functional consequences of costimulation by ICOS/ICOS-L and its mediators, in innate immune cells that simultaneously express ICOS and its ligand.

Investigación