Gennaro De Libero
University of Basel
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Publication
Featured researches published by Gennaro De Libero.
Journal of Experimental Medicine | 2003
Hans-Jürgen Gober; Magdalena Kistowska; Lena Angman; Paul Jenö; Lucia Mori; Gennaro De Libero
T lymphocytes expressing the T cell receptor (TCR)-γδ recognize unknown antigens on tumor cells. Here we identify metabolites of the mevalonate pathway as the tumor ligands that activate TCR-γδ cells. In tumor cells, blockade of hydroxy-methylglutaryl-CoA reductase (HMGR), the rate limiting enzyme of the mevalonate pathway, prevents both accumulation of mevalonate metabolites and recognition by TCR-γδ cells. When metabolite accumulation is induced by overexpressing HMGR or by treatment with nitrogen-containing bisphosphonate drugs, tumor cells derived from many tissues acquire the capacity to stimulate the same TCR-γδ population. Accumulation of mevalonate metabolites in tumor cells is a powerful danger signal that activates the immune response and may represent a novel target of tumor immunotherapy.
European Journal of Immunology | 1999
Abdijapar Shamshiev; Alena Donda; Ilaria Carena; Lucia Mori; Ludwig Kappos; Gennaro De Libero
Multiple sclerosis (MS) is a chronic inflammatory disease of the central nervous system characterized by discrete areas of demyelination. An autoimmune response against components of myelin is thought to contribute to disease pathogenesis. Here we identify glycolipids as new targets recognized by T cells in multiple sclerosis patients. Circulating T cells reactive with glycolipids are more frequent in MS patients than in control donors as shown by enzyme‐linked immunospot assay. They specifically recognize different types of glycolipids, such as gangliosides, sulfatide and galactosylceramide and release IFN‐γ and TNF‐α. T cells specific for gangliosides were found to be CD8+, TCR α β+, restricted by the MHC‐like CD1b molecule and specific for epitopes residing in the carbohydrate moiety of gangliosides. Our findings suggest that in addition to self proteins, self glycolipids may represent potential source of autoantigens recognized by T cells in autoimmune diseases.
Science | 2005
Sabrina Mariotti; Catherine Angénieux; Martine Gilleron; Luis-Fernando Garcia-Alles; Dag Malm; Thomas Berg; Samantha Paoletti; Blandine Maître; Lionel Mourey; Jean Salamero; Jean Pierre Cazenave; Daniel Hanau; Lucia Mori; Germain Puzo; Gennaro De Libero
Complexes between CD1 molecules and self or microbial glycolipids represent important immunogenic ligands for specific subsets of T cells. However, the function of one of the CD1 family members, CD1e, has yet to be determined. Here, we show that the mycobacterial antigens hexamannosylated phosphatidyl-myo-inositols (PIM6) stimulate CD1b-restricted T cells only after partial digestion of the oligomannose moiety by lysosomal α-mannosidase and that soluble CD1e is required for this processing. Furthermore, recombinant CD1e was able to bind glycolipids and assist in the digestion of PIM6. We propose that, through this form of glycolipid editing, CD1e helps expand the repertoire of glycolipidic T cell antigens to optimize antimicrobial immune responses.
Journal of Experimental Medicine | 2004
Martine Gilleron; Steffen Stenger; Zaima Mazorra; Frederick Wittke; Sabrina Mariotti; Gabriele Böhmer; Jacques Prandi; Lucia Mori; Germain Puzo; Gennaro De Libero
Mycobacterial lipids comprise a heterogeneous group of molecules capable of inducing T cell responses in humans. To identify novel antigenic lipids and increase our understanding of lipid-mediated immune responses, we established a panel of T cell clones with different lipid specificities. Using this approach we characterized a novel lipid antigen belonging to the group of diacylated sulfoglycolipids purified from Mycobacterium tuberculosis. The structure of this sulfoglycolipid was identified as 2-palmitoyl or 2-stearoyl-3-hydroxyphthioceranoyl-2′-sulfate-α-α′-d-trehalose (Ac2SGL). Its immunogenicity is dependent on the presence of the sulfate group and of the two fatty acids. Ac2SGL is mainly presented by CD1b molecules after internalization in a cellular compartment with low pH. Ac2SGL-specific T cells release interferon γ, efficiently recognize M. tuberculosis–infected cells, and kill intracellular bacteria. The presence of Ac2SGL-responsive T cells in vivo is strictly dependent on previous contact with M. tuberculosis, but independent from the development of clinically overt disease. These properties identify Ac2SGL as a promising candidate to be tested in novel vaccines against tuberculosis.
Nature Immunology | 2013
Stefano Vavassori; Anil Kumar; Gan Siok Wan; Gundimeda S Ramanjaneyulu; Marco Cavallari; Sary El Daker; Travis Beddoe; Alex Theodossis; Neal K. Williams; Emma Gostick; David A. Price; Dinish U. Soudamini; Kong Kien Voon; Malini Olivo; Jamie Rossjohn; Lucia Mori; Gennaro De Libero
Human T cells that express a T cell antigen receptor (TCR) containing γ-chain variable region 9 and δ-chain variable region 2 (Vγ9Vδ2) recognize phosphorylated prenyl metabolites as antigens in the presence of antigen-presenting cells but independently of major histocompatibility complex (MHC), the MHC class I–related molecule MR1 and antigen-presenting CD1 molecules. Here we used genetic approaches to identify the molecule that binds and presents phosphorylated antigens. We found that the butyrophilin BTN3A1 bound phosphorylated antigens with low affinity, at a stoichiometry of 1:1, and stimulated mouse T cells with transgenic expression of a human Vγ9Vδ2 TCR. The structures of the BTN3A1 distal domain in complex with host- or microbe-derived phosphorylated antigens had an immunoglobulin-like fold in which the antigens bound in a shallow pocket. Soluble Vγ9Vδ2 TCR interacted specifically with BTN3A1-antigen complexes. Accordingly, BTN3A1 represents an antigen-presenting molecule required for the activation of Vγ9Vδ2 T cells.
Journal of Experimental Medicine | 2005
Elisabetta Agea; Anna Russano; Onelia Bistoni; Roberta Mannucci; Ildo Nicoletti; Lanfranco Corazzi; Anthony D. Postle; Gennaro De Libero; Steven A. Porcelli; Fabrizio Spinozzi
Plant pollens are an important source of environmental antigens that stimulate allergic responses. In addition to acting as vehicles for foreign protein antigens, they contain lipids that incorporate saturated and unsaturated fatty acids, which are necessary in the reproduction of higher plants. The CD1 family of nonpolymorphic major histocompatibility complex–related molecules is highly conserved in mammals, and has been shown to present microbial and self lipids to T cells. Here, we provide evidence that pollen lipids may be recognized as antigens by human T cells through a CD1-dependent pathway. Among phospholipids extracted from cypress grains, phosphatidyl-choline and phosphatidyl-ethanolamine were able to stimulate the proliferation of T cells from cypress-sensitive subjects. Recognition of phospholipids involved multiple cell types, mostly CD4+ T cell receptor for antigen (TCR)αβ+, some CD4−CD8− TCRγδ+, but rarely Vα24i + natural killer–T cells, and required CD1a+ and CD1d+ antigen presenting cell. The responding T cells secreted both interleukin (IL)-4 and interferon-γ, in some cases IL-10 and transforming growth factor-β, and could provide help for immunoglobulin E (IgE) production. Responses to pollen phospholipids were maximally evident in blood samples obtained from allergic subjects during pollinating season, uniformly absent in Mycobacterium tuberculosis–exposed health care workers, but occasionally seen in nonallergic subjects. Finally, allergic, but not normal subjects, displayed circulating specific IgE and cutaneous weal and flare reactions to phospholipids.
Nature Reviews Immunology | 2005
Gennaro De Libero; Lucia Mori
Recent studies have shown that the recognition of lipid antigens by the immune system is important for defence against infection and other diseases, and that lipid-specific responses occur at higher frequencies than previously suspected. Thanks to several recent advances in this field, we now have a better appreciation of the molecular and cellular requirements of T-cell stimulation by lipids. These findings have raised new questions about the mechanisms of lipid presentation, the priming and clonal expansion of lipid-specific T cells, and their differentiation into memory cells. A greater understanding of lipid-specific T cells and the molecular mechanisms of lipid immunogenicity should facilitate the development of lipid-based vaccines.
Immunity | 2000
Abdijapar Shamshiev; Alena Donda; Theodore I. Prigozy; Lucia Mori; Vanna Chigorno; Chris A. Benedict; Ludwig Kappos; Sandro Sonnino; Mitchell Kronenberg; Gennaro De Libero
The structural basis for the T cell recognition of lipoglycans remains to be elucidated. We have described autoreactive T cells responsive to GM1 ganglioside presented by CD1b. We show that glycosphingolipids bind to CD1b on the cell surface at neutral pH and are recognized without internalization or processing. Furthermore, soluble GM-CD1b complexes stimulate specific T cells. Oligosaccharide groups containing five or more sugars are required to build a minimal epitope for TCR recognition. This suggests a mechanism for T cell recognition of glycosphingolipids in which much of the CD1b-bound ligand is exposed. Binding to CD1b is a highly reversible process and other ceramide-containing glycosphingolipids displace GM1. These nonantigenic compounds act as blockers and may prevent harmful autoreactivity in vivo.
Nature Immunology | 2012
Federica Facciotti; Gundimeda S Ramanjaneyulu; Marco Lepore; Sebastiano Sansano; Marco Cavallari; Magdalena Kistowska; Sonja Forss-Petter; Guanghui Ni; Alessia Colone; Amit Singhal; Johannes Berger; Chengfeng Xia; Lucia Mori; Gennaro De Libero
The development and maturation of semi-invariant natural killer T cells (iNKT cells) rely on the recognition of self antigens presented by CD1d restriction molecules in thymus. The nature of the stimulatory thymic self lipids remains elusive. We isolated lipids from thymocytes and found that ether-bonded mono-alkyl glycerophosphates and the precursors and degradation products of plasmalogens stimulated iNKT cells. Synthetic analogs showed high potency in activating thymic and peripheral iNKT cells. Mice deficient in the peroxisomal enzyme glyceronephosphate O-acyltransferase (GNPAT), essential for the synthesis of ether lipids, had significant alteration of the thymic maturation of iNKT cells and fewer iNKT cells in both thymus and peripheral organs, which confirmed the role of ether-bonded lipids as iNKT cell antigens. Thus, peroxisome-derived lipids are nonredundant self antigens required for the generation of a full iNKT cell repertoire.
European Journal of Immunology | 2011
Claudia de Lalla; Marco Lepore; Francesco Piccolo; Anna Rinaldi; Andrea Scelfo; Claudio Garavaglia; Lucia Mori; Gennaro De Libero; Paolo Dellabona; Giulia Casorati
CD1 molecules present lipid antigens to T cells. An intriguing subset of human T cells recognize CD1‐expressing cells without deliberately added lipids. Frequency, subset distribution, clonal composition, naïve‐to‐memory dynamic transition of these CD1 self‐reactive T cells remain largely unknown. By screening libraries of T‐cell clones, generated from CD4+ or CD4−CD8− double negative (DN) T cells sorted from the same donors, and by limiting dilution analysis, we find that the frequency of CD1 self‐reactive T cells is unexpectedly high in both T‐cell subsets, in the range of 1/10–1/300 circulating T cells. These T cells predominantly recognize CD1a and CD1c and express diverse TCRs. Frequency comparisons of T‐cell clones from sorted naïve and memory compartments of umbilical cord and adult blood show that CD1 self‐reactive T cells are naïve at birth and undergo an age‐dependent increase in the memory compartment, suggesting a naïve/memory adaptive‐like population dynamics. CD1 self‐reactive clones exhibit mostly Th1 and Th0 functional activities, depending on the subset and on the CD1 isotype restriction. These findings unveil the unanticipated relevance of self‐lipid T‐cell response in humans and clarify the basic parameters of the lipid‐specific T‐cell physiology.