Your search keyword '"Romagne, Francois"' showing total 3 results

1. Genetic and antibody-mediated reprogramming of natural killer cell missing-self recognition in vivo

Author

Sola, Caroline, Andre, Pascale, Lemmers, Celine, Fuseri, Nicolas, Bonnafous, Cecile, Blery, Mathieu, Wagtmann, Nicolai R., Romagne, Francois, Vivier, Eric, and Ugolini, Sophie

Subjects

Killer cells -- Research, MHC antibodies -- Research, Cancer -- Prevention, Cancer -- Genetic aspects, Cancer -- Research, Science and technology

Abstract

Natural killer (NK) cells are lymphocytes of the innate immune system able to recognize and kill tumors lacking self-MHC class I molecules. This 'missing-self' recognition is mediated by the lack of engagement of MHC class I-specific inhibitory NK cell receptors that include the killer cell Ig-like receptors (KIR) in humans and Ly49 molecules in mice. A promising immunotherapeutic strategy against MHC class [I.sup.+] cancer cells is to block NK cell inhibitory receptors using monoclonal antibodies (mAb). However, interactions between MHC class I molecules and their inhibitory receptors are also required for the acquisition of NK cell functional competence, a process referred as to ''education.' In addition, inhibitory receptors are involved in self-tolerance on educated NK cells. Here, we developed a preclinical mouse model in which all NK cells are educated by a single transgenic inhibitory receptor, human KIR2DL3, through the engagement with its HLA-Cw3 ligand. This approach revealed that NK cells could be reprogrammed to control the development of mouse syngenic tumors in vivo. Moreover, in vivo anti-KIR mAb treatment induced the killing of [HLA.sup.+] target cells without breaking self-tolerance. Finally, the long-term infusion of anti-KIR mAb neither abolished NK cell education nor tumor cell recognition. Therefore, these results strongly support the use of inhibitory receptor blockade in cancer patients. anti-tumor therapy | innate immunity | pre-clinical model | tolerance

Published

2009

2. Identification, activation, and selective in vivo ablation of mouse NK cells via NKp46

Author

Walzer, Thierry, Blery, Mathieu, Chaix, Julie, Fuseri, Nicolas, Chasson, Lionel, Robbins, Scott H., Jaeger, Sebastien, Andre, Pascale, Gauthier, Laurent, Daniel, Laurent, Chemin, Karine, Morel, Yannis, Dalod, Marc, Imbert, Jean, Pierres, Michel, Moretta, Alessandro, Romagne, Francois, and Vivier, Eric

Subjects

Killer cells -- Research, Killer cells -- Identification and classification, Immune response -- Research, Mice -- Genetic aspects, Mice -- Research, Cell transformation -- Research, Science and technology

Abstract

Natural killer (NK) cells contribute to a variety of innate immune responses to viruses, tumors and allogeneic cells. However, our understanding of NK cell biology is severely limited by the lack of consensus phenotypic definition of these cells across species, by the lack of specific marker to visualize them in situ, and by the lack of a genetic model where NK cells may be selectively ablated. NKp46/CD335 is an Ig-like superfamily cell surface receptor involved in human NK cell activation. In addition to human, we show here that NKp46 is expressed by NK cells in all mouse strains analyzed, as well as in three common monkey species, prompting a unifying phenotypic definition of NK cells across species based on NKp46 cell surface expression. Mouse NKp46 triggers NK cell effector function and allows the detection of NK cells in situ. NKp46 expression parallels cell engagement into NK differentiation programs because it is detected on all NK cells from the immature CD[122.sup.+]NK[1.1.sup.+]DX[5.sup.-] stage and on a minute fraction of NK-like T cells, but not on CDld-restricted NKT cells. Moreover, human NKp46 promoter drives NK cell selective expression both in vitro and in vivo. Using NKp46 promoter, we generated transgenic mice expressing EGFP and the diphtheria toxin (DT) receptor in NK cells. DT injection in these mice leads to a complete and selective NK cell ablation. This model paves a way for the in vivo characterization and preclinical assessment of NK cell biological function. genetic models | innate immunity

Published

2007

3. Recognition of peptide-MHC class I complexes by activating killer immunoglobulin-like receptors

Author

Stewart, C. Andrew, Laugier-Anfossi, Fanny, Vely, Frederic, Saulquin, Xavier, Riedmuller, Jenifer, Tisserant, Agnes, Gauthier, Laurent, Romagne, Francois, Ferracci, Geraldine, Arosa, Fernando A., Moretta, Alessandro, Sun, Peter D., Ugolini, Sophie, and Vivier, Eric

Subjects

Killer cells -- Research, Peptides -- Research, Science and technology

Abstract

Inhibitory receptors for MHC class I molecules increase the threshold of lymphocyte activation. Natural Killer (NK) cells express a large number of such inhibitory receptors, including the human killer Ig-like receptors (KIR). However, activating members of the KIR family have poorly defined ligands and functions. Here we describe the use of activating KIR tetramer reagents as probes to detect their ligands. Infection of cells with Epstein-Barr virus leads to expression of a detectable ligand for the activating receptor KIR2DS1. In this case, KIR2DS1 interacts with up-regulated peptide-MHC class I complexes on Epstein-Barr virus-infected cells in a transporter associated with antigen processing (TAP)-dependent manner. In tetramer-based cellular assays and direct affinity measurements, this interaction with MHC class I is facilitated by a broad spectrum of peptides. KIR2DS1 and its inhibitory homologue, KIR2DL1, share sensitivity to peptide sequence alterations at positions 7 and 8. These results fit a model in which activating and inhibitory receptors recognize the same sets of self-MHC class I molecules, differing only in their binding affinities. Importantly, KIR2DS1 is not always sufficient to trigger NK effector responses when faced with cognate ligand, consistent with fine control during NK cell activation. We discuss how our results for KIR2DS1 and parallel studies on KIR2DS2 relate to the association between activating KIR genes and susceptibility to autoimmune disorders. natural killer cell

Published

2005