Acquisition de la tolérance au soi des cellules tueuses naturelles (NK) KIR2DS1 chez des sujets exprimant des antigènes HLA-C2

Les cellules tueuses naturelles (NK) sont régulées par des récepteurs activateurs et inhibiteurs. La plupart des récepteurs inhibiteurs reconnaisse des molécules du complexe majeur d'histocompatibilité (CMH) de classe I, et protège les cellules saines des phénomènes d'auto-immunité médiés par les cellules NK. Cependant, certains récepteurs activateurs, incluant le récepteur killer cell Ig-like receptor (KIR) 2DS1, reconnaissent aussi des ligands CMH de classe I. Cela pose la question de savoir comment les cellules NK qui expriment des récepteurs activateurs deviennent tolérantes au soi. Nous avons cherché à déterminer si la présence de HLA-C2, le ligand du récepteurs 2DS1, peut induire les cellules NK qui expriment le 2DS1 à développer un état de tolérance au soi. Indépendamment de la présence ou de l'absence du ligand HLA-C2 dans le donneur, une activité anti-HLA-C2 a été identifiée in vitro dans certains clones NK 2DS1-positifs. La fréquence des clones NK avec réactivité anti-HLA-C2 était élevée parmi les donneurs homozygotes pour HLA-C1. De façon étonnante, nous n'avons pas constaté de différence statistiquement significative dans la fréquence de cytotoxicité anti-HLA-C2 entre les donneurs HLA-C2 hétérozygotes et les donneurs sans ligand HLA-C2. Par contre, les donneurs HLA-C2 homozygotes montrent une fréquence réduite de clones NK avec réactivité anti-HLA-C2 par rapport aux autres donneurs. Clones 2DS1-positifs qui co-expriment des KIR inhibiteurs spécifiques des molécules HLA de classe I du soi n’étaient pas communément cytotoxiques, et la cytotoxicité anti-HLA-C2 était limité presque exclusivement à des clones positifs seulement pour 2DS1 (« single positive » 2DS1 clones). Nous avons aussi identifié des clones 2DS1 « single positive » avec réactivité anti-HLA-C2 dans des patients recevant une greffe de cellules souches hématopoïétiques à partir de donneurs 2DS1. Ces résultats montrent que plusieurs cellules NK avec réactivité anti-HLA-C2 sont présentes dans des donneurs 2DS1 soit hétérozygotes soit homozygotes pour HLA-C1. En revanche, les clones 2DS1-positifs obtenus par des donneurs homozygotes pour HLA-C2 sont fréquemment tolérants aux antigènes HLA-C2.NK cells are regulated by inhibiting and activating cell surface receptors. Most inhibitory receptors recognize MHC-class I antigens, and protect healthy cells from NK cell-mediated auto-aggression. However, certain activating receptors, including the human killer cell Ig-like receptor (KIR) 2DS1, also recognize MHC-class I. This raises the question of how NK cells expressing such activating receptors are tolerized to host tissues. We investigated whether the presence of HLA-C2, the cognate ligand for 2DS1, induces tolerance in 2DS1-expressing NK cells. Anti-HLA-C2 activity could be detected in vitro in some 2DS1 positive NK clones irrespective of presence or absence of HLA-C2 ligand in the donor. The frequency of anti-HLA-C2 reactivity was high in donors homozygous for HLA-C1. Surprisingly, there was no significant difference in frequency of anti-HLA-C2 cytotoxicity in donors heterozygous for HLA-C2 and donors without HLA-C2 ligand. However, donors homozygous for HLA-C2 had significantly reduced frequency of anti-HLA-C2 reactive clones as compared to all other donors. 2DS1 positive clones that express inhibitory KIR for self-HLA class I were commonly non-cytotoxic, and anti-HLA-C2 cytotoxicity was nearly exclusively restricted to 2DS1 single positive clones lacking inhibitory KIR. 2DS1 single positive NK clones with anti-HLA-C2 reactivity were also present post-transplantation in HLA-C2 positive recipients of hematopoietic stem cell transplants from 2DS1 positive donors. These results demonstrate that many NK cells with anti-HLA-C2 reactivity are present in HLA-C1 homozygous and heterozygous donors with 2DS1. In contrast, 2DS1 positive clones from HLA-C2 homozygous donors are frequently tolerant to HLA-C2

Tailoring NK Cell Receptor-Ligand Interactions: An Art in Evolution

Recognition and killing of aberrant, infected or tumor targets by Natural Killer (NK) cells is mediated by positive signals transduced by activating receptors upon engagement of ligands on target surface. These stimulatory pathways are counterbalanced by inhibitory receptors that raise NK cell activation threshold through negative antagonist signals. While regulatory effects are necessary for physiologic control of autoimmune aggression, they may restrain the ability of NK cells to activate against disease. Overcoming this barrier to immune surveillance, multiple approaches to enhance NK-mediated responses are being investigated since two decades. Propelled by considerable advances in the understanding of NK cell biology, these studies are critical for effective translation of NK-based immunotherapy principles into the clinic. In humans, dominant inhibitory signals are transduced by Killer Immunoglobulin Like Receptors (KIR) recognizing cognate HLA class I on target cells. Conversely, KIR recognition of “missing self-HLA” - due to HLA loss or HLA/ KIR mismatch - triggers NK-mediated tumor rejection. Initially observed in murine transplant models, these antitumor effects were later found to have important implications for the clinical outcome of haplotype-mismatched stemcell transplantation. Here, donor NK subsets protect against acute myeloid leukemia (AML) relapse through missing self recognition of donor HLA-C allele groups (C1 or C2) and/or Bw4 epitope. These studies were subsequently extended by trials investigating the antileukemia effects of adoptively transferred haplotype-mismatched NK cells in non-transplant settings. Other mechanisms have been found to induce clinically relevant NK cell alloreactivity in transplantation, e.g., post-reconstitution functional reversal of anergic NK cells. More recently, activating KIR came into the spotlight for their potential ability to directly activate donor NK cells through in vivo recognition of HLA or other ligands. Novel therapeutic monoclonal antibodies (mAb) may optimize NK-mediated effects. Examples include obinutuzumab (GA101), a glyco-engineered anti-CD20 mAb with increased affinity for the FcγRIIIA receptor, enhancing antibody-dependent cellular cytotoxicity; lirilumab (IPH2102), a first-in-class NK-specific checkpoint inhibitor, blocking the interaction between the major KIR and cognate HLA-C antigens; and elotuzumab (HuLuc63), a humanized monoclonal antibody specific for SLAMF7, whose anti-myeloma therapeutic effects are partly due to direct activation of SLAMF7-expressing NK cells. In addition to conventional antibodies, NK cell-targeted bispecific (BiKEs) and trispecific (TriKEs) killer engagers have also been developed. These proteins elicit potent effector functions by binding target ligands (e.g., CD19, CD22, CD30, CD133, HLA class II, EGFR) on one arm and NK receptors on the other. An additional innovative approach to direct NK cell activity is genetic reprogramming with chimeric antigen receptors (CAR). To date, primary NK cells and the NK92 cell line have been engineered with CAR specific for antigens expressed on multiple tumors. Encouraging preclinical results warrant further development of this approach. This Research Topic welcomes contributions addressing mechanisms of NK-mediated activation in response to disease as well as past and contemporary strategies to enhance NK mediated reactivity through control of the interactions between NK receptors and their ligands

NK Cell Tolerance of Self-Specific Apecific Activating Receptor KIR2DS1 in Individuals with Cognate HLA-C2 Ligand.

Les cellules tueuses naturelles (NK) sont régulées par des récepteurs activateurs et inhibiteurs. La plupart des récepteurs inhibiteurs reconnaisse des molécules du complexe majeur d'histocompatibilité (CMH) de classe I, et protège les cellules saines des phénomènes d'auto-immunité médiés par les cellules NK. Cependant, certains récepteurs activateurs, incluant le récepteur killer cell Ig-like receptor (KIR) 2DS1, reconnaissent aussi des ligands CMH de classe I. Cela pose la question de savoir comment les cellules NK qui expriment des récepteurs activateurs deviennent tolérantes au soi. Nous avons cherché à déterminer si la présence de HLA-C2, le ligand du récepteurs 2DS1, peut induire les cellules NK qui expriment le 2DS1 à développer un état de tolérance au soi. Indépendamment de la présence ou de l'absence du ligand HLA-C2 dans le donneur, une activité anti-HLA-C2 a été identifiée in vitro dans certains clones NK 2DS1-positifs. La fréquence des clones NK avec réactivité anti-HLA-C2 était élevée parmi les donneurs homozygotes pour HLA-C1. De façon étonnante, nous n'avons pas constaté de différence statistiquement significative dans la fréquence de cytotoxicité anti-HLA-C2 entre les donneurs HLA-C2 hétérozygotes et les donneurs sans ligand HLA-C2. Par contre, les donneurs HLA-C2 homozygotes montrent une fréquence réduite de clones NK avec réactivité anti-HLA-C2 par rapport aux autres donneurs. Clones 2DS1-positifs qui co-expriment des KIR inhibiteurs spécifiques des molécules HLA de classe I du soi n étaient pas communément cytotoxiques, et la cytotoxicité anti-HLA-C2 était limité presque exclusivement à des clones positifs seulement pour 2DS1 ( single positive 2DS1 clones). Nous avons aussi identifié des clones 2DS1 single positive avec réactivité anti-HLA-C2 dans des patients recevant une greffe de cellules souches hématopoïétiques à partir de donneurs 2DS1. Ces résultats montrent que plusieurs cellules NK avec réactivité anti-HLA-C2 sont présentes dans des donneurs 2DS1 soit hétérozygotes soit homozygotes pour HLA-C1. En revanche, les clones 2DS1-positifs obtenus par des donneurs homozygotes pour HLA-C2 sont fréquemment tolérants aux antigènes HLA-C2.NK cells are regulated by inhibiting and activating cell surface receptors. Most inhibitory receptors recognize MHC-class I antigens, and protect healthy cells from NK cell-mediated auto-aggression. However, certain activating receptors, including the human killer cell Ig-like receptor (KIR) 2DS1, also recognize MHC-class I. This raises the question of how NK cells expressing such activating receptors are tolerized to host tissues. We investigated whether the presence of HLA-C2, the cognate ligand for 2DS1, induces tolerance in 2DS1-expressing NK cells. Anti-HLA-C2 activity could be detected in vitro in some 2DS1 positive NK clones irrespective of presence or absence of HLA-C2 ligand in the donor. The frequency of anti-HLA-C2 reactivity was high in donors homozygous for HLA-C1. Surprisingly, there was no significant difference in frequency of anti-HLA-C2 cytotoxicity in donors heterozygous for HLA-C2 and donors without HLA-C2 ligand. However, donors homozygous for HLA-C2 had significantly reduced frequency of anti-HLA-C2 reactive clones as compared to all other donors. 2DS1 positive clones that express inhibitory KIR for self-HLA class I were commonly non-cytotoxic, and anti-HLA-C2 cytotoxicity was nearly exclusively restricted to 2DS1 single positive clones lacking inhibitory KIR. 2DS1 single positive NK clones with anti-HLA-C2 reactivity were also present post-transplantation in HLA-C2 positive recipients of hematopoietic stem cell transplants from 2DS1 positive donors. These results demonstrate that many NK cells with anti-HLA-C2 reactivity are present in HLA-C1 homozygous and heterozygous donors with 2DS1. In contrast, 2DS1 positive clones from HLA-C2 homozygous donors are frequently tolerant to HLA-C2.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Tailoring NK Cell Receptor-Ligand Interactions: an Art in Evolution. 2nd Edition

Recognition and killing of aberrant, infected or tumor targets by Natural Killer (NK) cells is mediated by positive signals transduced by activating receptors upon engagement of ligands on target surface. These stimulatory pathways are counterbalanced by inhibitory receptors that raise NK cell activation threshold through negative antagonist signals. While regulatory effects are necessary for physiologic control of autoimmune aggression, they may restrain the ability of NK cells to activate against disease. Overcoming this barrier to immune surveillance, multiple approaches to enhance NK-mediated responses are being investigated since two decades. Propelled by considerable advances in the understanding of NK cell biology, these studies are critical for effective translation of NK-based immunotherapy principles into the clinic. In humans, dominant inhibitory signals are transduced by Killer Immunoglobulin Like Receptors (KIR) recognizing cognate HLA class I on target cells. Conversely, KIR recognition of “missing self-HLA” - due to HLA loss or HLA/ KIR mismatch - triggers NK-mediated tumor rejection. Initially observed in murine transplant models, these antitumor effects were later found to have important implications for the clinical outcome of haplotype-mismatched stemcell transplantation. Here, donor NK subsets protect against acute myeloid leukemia (AML) relapse through missing self recognition of donor HLA-C allele groups (C1 or C2) and/or Bw4 epitope. These studies were subsequently extended by trials investigating the antileukemia effects of adoptively transferred haplotype-mismatched NK cells in non-transplant settings. Other mechanisms have been found to induce clinically relevant NK cell alloreactivity in transplantation, e.g., post-reconstitution functional reversal of anergic NK cells. More recently, activating KIR came into the spotlight for their potential ability to directly activate donor NK cells through in vivo recognition of HLA or other ligands. Novel therapeutic monoclonal antibodies (mAb) may optimize NK-mediated effects. Examples include obinutuzumab (GA101), a glyco-engineered anti-CD20 mAb with increased affinity for the FcγRIIIA receptor, enhancing antibody-dependent cellular cytotoxicity; lirilumab (IPH2102), a first-in-class NK-specific checkpoint inhibitor, blocking the interaction between the major KIR and cognate HLA-C antigens; and elotuzumab (HuLuc63), a humanized monoclonal antibody specific for SLAMF7, whose anti-myeloma therapeutic effects are partly due to direct activation of SLAMF7-expressing NK cells. In addition to conventional antibodies, NK cell-targeted bispecific (BiKEs) and trispecific (TriKEs) killer engagers have also been developed. These proteins elicit potent effector functions by binding target ligands (e.g., CD19, CD22, CD30, CD133, HLA class II, EGFR) on one arm and NK receptors on the other. An additional innovative approach to direct NK cell activity is genetic reprogramming with chimeric antigen receptors (CAR). To date, primary NK cells and the NK92 cell line have been engineered with CAR specific for antigens expressed on multiple tumors. Encouraging preclinical results warrant further development of this approach. This Research Topic welcomes contributions addressing mechanisms of NK-mediated activation in response to disease as well as past and contemporary strategies to enhance NK mediated reactivity through control of the interactions between NK receptors and their ligands

Enhanced Cytotoxic Activity of Ex Vivo-differentiated Human Natural Killer Cells in the Presence of HOXB4

International audienceWe have previously shown that human umbilical cord blood CD34 progenitor cells undergo in vitro differentiation into functional natural killer (NK) cells and that their coculture in the presence of HOXB4-transduced stromal MS-5 cells resulted in an increase in differentiated NK number. The present study was conducted to compare the stromal effect on NK lytic potential in the presence and absence of HOXB4. Our results provide evidence that HOXB4-transduced MS-5 cells as compared with transduced GFP (+) MS-5 cells induced highly differentiated cytotoxic NK cells. Importantly, this difference was not because of the expression of activating NK receptors but was associated with an increased induction of granzyme B degranulation in response to stimulation with NK cell susceptible targets. DNA microarray-based global transcriptional profiling confirmed the upregulation of granzyme B. These findings provide further evidence that HOXB4 is a crucial regulator of NK function and that its use in generating functional NK cells with increased lytic potential may be significant for cancer immunotherapy