FAS (Fas cell surface death receptor)

CD95 (also known as Fas) is a death receptor that belongs to the TNF-receptor superfamily. Expressed at the cell surface as a homotrimer, this receptor implements both apoptotic and non-apoptotic signalling pathways. While the apoptotic signalling pathway is involved in tumor surveillance, peripheral tolerance and immune homeostasis (Strasser et al., 2009), its non-apoptotic cues seem to promote oncogenesis (Chen et al., 2010; Hoogwater et al., 2010; Kleber et al., 2010; Malleter et al., 2013; Steller et al., 2011)

CD95-mediated calcium signaling promotes T helper 17 trafficking to inflamed organs in lupus-prone mice

CD95 ligand (CD95L) is expressed by immune cells and triggers apoptotic death. Metalloprotease-cleaved CD95L (cl-CD95L) is released into the bloodstream but does not trigger apoptotic signaling. Hence, the pathophysiological role of cl-CD95L remains unclear. We observed that skin-derived endothelial cells from systemic lupus erythematosus (SLE) patients expressed CD95L and that after cleavage, cl-CD95L promoted T helper 17 (Th17) lymphocyte transmigration across the endothelial barrier at the expense of T regulatory cells. T cell migration relied on a direct interaction between the CD95 domain called calcium-inducing domain (CID) and the Src homology 3 domain of phospholipase Cγ1. Th17 cells stimulated with cl-CD95L produced sphingosine-1-phosphate (S1P), which promoted endothelial transmigration by activating the S1P receptor 3. We generated a cell-penetrating CID peptide that prevented Th17 cell transmigration and alleviated clinical symptoms in lupus mice. Therefore, neutralizing the CD95 non-apoptotic signaling pathway could be an attractive therapeutic approach for SLE treatment

Study of the CD95 receptor and its proinflammatory role in lupus

Le récepteur de mort CD95 participe à de nombreuses fonctions physiologiques en transmettant des signaux apoptotiques. Son ligand membranaire, CD95L, est principalement exprimé à la surface des lymphocytes et contrôle ainsi l’homéostasie cellulaire et l’élimination des cellules infectées ou transformées. Certaines situations pathologiques conduisent à une expression ectopique du CD95L par d’autres types cellulaires,associé à son clivage par des métalloprotéases (cl-CD95L). La forme soluble ainsi libérée perd sa capacité à transmettre l’apoptose mais déclenche l’activation de voies non-apoptotiques induisant l’inflammation dans des maladies inflammatoires chroniques comme le lupus érythémateux systémique (LES) ou encore les formes métastatiques du cancer du sein. Dans ces deux pathologies, de fortes quantités de cl-CD95L sont détectées dans le sérum de ces patients et ont été associés à la progression des pathologies. Dans le LES, nous établissons que cl-CD95L contribue au processus inflammatoireen favorisant la transmigration endothéliale des lymphocytes Th17. Cette migration cellulaire dépendante de CD95 nécessitele recrutement de la PLCγ1 sur le domaine juxta-membranaire de CD95 qui induitl’activation du signal calcique. Pour identifier d’autres partenaires moléculaires de CD95, une analyse protéomique a été réalisée et a permis d’identifier une association entre CD95 et la machinerie traductionnelle. Cette interaction nécessite le recrutement d’eIF4A1 au niveau du domaine juxta-membranaire de CD95. Nous avons par ailleurs montré que dans des lignées cancéreuses mammaires, eIF4A1 participe à la traduction de certaines protéines comme la sérine-thréonine kinase Akt pour faciliter l’activation de la voie de signalisation PI3K et la migration cellulaire induite par CD95. Cette étude a donc mis en évidence l’implication d’un nouveau domaine de CD95 dans l’induction des signaux non-apoptotiques. Ce domaine juxta-membranaire a été nommé CID pour « calcium inducing domain ». De plus, ce domaine fusionné à un peptide perméant provenant de la protéine TAT appelé TAT-CIDa montré son efficacité pour inhiber la migration lymphocytaire chez les souris lupiques et offre de nouvelles perspectives pour le développement de traitements améliorants les symptômes inflammatoires du LES.The death ligand CD95L, mainly expressed by immune cells, contributes to the elimination ofinfected and transformed cells. In pathological contexts, CD95L can be expressed by others cell types such as endothelial cells.CD95L can be cleaved by metalloproteases to generate a soluble CD95L (cl-CD95L) failing to trigger the apoptotic signaling pathwaybutinducing non-pro-apoptotic signaling pathways. cl-CD95L promotes inflammation in chronic inflammatory disorders such as systemic lupus erythematosus (SLE) and increases risks of metastatic dissemination in breast cancer patients. In SLE patients, we established that high amounts of cl-CD95L fuels inflammation by promoting endothelial transmigration of activated Th17 cells. This CD95-drivencell migration requires PLCγ1 recruitment by CD95 and the subsequentimplementation of the calcium signal. To identify in an exhaustive fashion, all molecular partners of CD95, a global proteomic analysis was undertaken. This TAP-Tag approach highlighted a strong association between the translational machinery and CD95. This analysis was confirmed by a two-hybrid approach revealingthat the translation initiation factor eIF4A1 directly interactedwith CD95.In breast cancer cells, we established that eIF4A1 was instrumental in the translation of certain genes such as Akt contributing to the implementation of the CD95-mediated PI3K signaling pathway and cell migration. In this study, we identifiedthe CD95 domaininvolved in the induction of the non-apoptotic signaling pathway. This domain was named CID for “calcium inducing domain”.Moreover, wegenerated a therapeutic molecule consisting of theCID fused to the cationic cell-penetrating HIV TAT domain. TAT-CID prevented the accumulation of Th17 cells in inflamed organs of lupus-prone mice and could turn out to be an original therapeutic molecule to alleviate clinical symptoms in SLE patients

Study of the CD95 receptor and its proinflammatory role in lupus

Le récepteur de mort CD95 participe à de nombreuses fonctions physiologiques en transmettant des signaux apoptotiques. Son ligand membranaire, CD95L, est principalement exprimé à la surface des lymphocytes et contrôle ainsi l’homéostasie cellulaire et l’élimination des cellules infectées ou transformées. Certaines situations pathologiques conduisent à une expression ectopique du CD95L par d’autres types cellulaires,associé à son clivage par des métalloprotéases (cl-CD95L). La forme soluble ainsi libérée perd sa capacité à transmettre l’apoptose mais déclenche l’activation de voies non-apoptotiques induisant l’inflammation dans des maladies inflammatoires chroniques comme le lupus érythémateux systémique (LES) ou encore les formes métastatiques du cancer du sein. Dans ces deux pathologies, de fortes quantités de cl-CD95L sont détectées dans le sérum de ces patients et ont été associés à la progression des pathologies. Dans le LES, nous établissons que cl-CD95L contribue au processus inflammatoireen favorisant la transmigration endothéliale des lymphocytes Th17. Cette migration cellulaire dépendante de CD95 nécessitele recrutement de la PLCγ1 sur le domaine juxta-membranaire de CD95 qui induitl’activation du signal calcique. Pour identifier d’autres partenaires moléculaires de CD95, une analyse protéomique a été réalisée et a permis d’identifier une association entre CD95 et la machinerie traductionnelle. Cette interaction nécessite le recrutement d’eIF4A1 au niveau du domaine juxta-membranaire de CD95. Nous avons par ailleurs montré que dans des lignées cancéreuses mammaires, eIF4A1 participe à la traduction de certaines protéines comme la sérine-thréonine kinase Akt pour faciliter l’activation de la voie de signalisation PI3K et la migration cellulaire induite par CD95. Cette étude a donc mis en évidence l’implication d’un nouveau domaine de CD95 dans l’induction des signaux non-apoptotiques. Ce domaine juxta-membranaire a été nommé CID pour « calcium inducing domain ». De plus, ce domaine fusionné à un peptide perméant provenant de la protéine TAT appelé TAT-CIDa montré son efficacité pour inhiber la migration lymphocytaire chez les souris lupiques et offre de nouvelles perspectives pour le développement de traitements améliorants les symptômes inflammatoires du LES.The death ligand CD95L, mainly expressed by immune cells, contributes to the elimination ofinfected and transformed cells. In pathological contexts, CD95L can be expressed by others cell types such as endothelial cells.CD95L can be cleaved by metalloproteases to generate a soluble CD95L (cl-CD95L) failing to trigger the apoptotic signaling pathwaybutinducing non-pro-apoptotic signaling pathways. cl-CD95L promotes inflammation in chronic inflammatory disorders such as systemic lupus erythematosus (SLE) and increases risks of metastatic dissemination in breast cancer patients. In SLE patients, we established that high amounts of cl-CD95L fuels inflammation by promoting endothelial transmigration of activated Th17 cells. This CD95-drivencell migration requires PLCγ1 recruitment by CD95 and the subsequentimplementation of the calcium signal. To identify in an exhaustive fashion, all molecular partners of CD95, a global proteomic analysis was undertaken. This TAP-Tag approach highlighted a strong association between the translational machinery and CD95. This analysis was confirmed by a two-hybrid approach revealingthat the translation initiation factor eIF4A1 directly interactedwith CD95.In breast cancer cells, we established that eIF4A1 was instrumental in the translation of certain genes such as Akt contributing to the implementation of the CD95-mediated PI3K signaling pathway and cell migration. In this study, we identifiedthe CD95 domaininvolved in the induction of the non-apoptotic signaling pathway. This domain was named CID for “calcium inducing domain”.Moreover, wegenerated a therapeutic molecule consisting of theCID fused to the cationic cell-penetrating HIV TAT domain. TAT-CID prevented the accumulation of Th17 cells in inflamed organs of lupus-prone mice and could turn out to be an original therapeutic molecule to alleviate clinical symptoms in SLE patients

Lysosome signaling controls the migration of dendritic cells

Dendritic cells (DCs) patrol their environment by linking antigen acquisition by macropinocytosis to cell locomotion. DC activation upon bacterial sensing inhibits macropinocytosis and increases DC migration, thus promoting the arrival of DCs to lymph nodes for antigen presentation to T cells. The signaling events that trigger such changes are not fully understood. We show that lysosome signaling plays a critical role in this process. Upon bacterial sensing, lysosomal calcium is released by the ionic channel TRPML1 (transient receptor potential cation channel, mucolipin subfamily, member 1), which activates the actin-based motor protein myosin II at the cell rear, promoting fast and directional migration. Lysosomal calcium further induces the activation of the transcription factor EB (TFEB), which translocates to the nucleus to maintain TRPML1 expression. We found that the TRPML1-TFEB axis results from the down-regulation of macropinocytosis after bacterial sensing by DCs. Lysosomal signaling therefore emerges as a hitherto unexpected link between macropinocytosis, actomyosin cytoskeleton organization, and DC migration

A Shape Sensing Mechanism driven by Arp2/3 and cPLA 2 licenses Dendritic Cells for Migration to Lymph Nodes in Homeostasis

Motile cells such as immune and cancer cells experience large deformation events that result from the physical constraints they encounter while migrating within tissues or circulating between organs. It has become increasingly clear that these cells can survive and adapt to these changes in cell shape using dedicated shape sensing pathways. However, how shape sensing impacts their function and fate remains largely unknown. Here we identify a shape sensing mechanism that couples cell motility to expression of CCR7, the chemokine receptor that guides immune cells to lymph nodes. We found that this mechanism is controlled by the lipid metabolism enzyme cPLA 2 , requires an intact nuclear envelop and exhibits an exquisitely sensitive activation threshold tuned by ARP2/3 and its inhibitor Arpin. We further show that shape sensing through the ARP2/3-cPLA 2 axis controls Ikkβ-NFκB-dependent transcriptional reprogramming of dendritic cells, which instructs them to migrate to lymph nodes in an immunoregulatory state compatible with their homeostatic tolerogenic function. These results highlight that the cell shape changes experienced by motile cells evolving within the complex environment of tissues can dictate their behavior and fate