Les protéines de stress HSP90 et Gp96 dans la maladie du greffon contre l'hôte : implication physiopathologique, diagnostique et thérapeutique / Stress proteins HSP90 and Gp96 in graft-versus-host disease : pathophysiological, diagnostic and therapeutic implication

Seignez, Antoine

13 November 2015

L’allogreffe de cellules hématopoïétiques est une stratégie thérapeutique importante dans les hémopathies malignes. La maladie du greffon contre l’hôte (GvH) en est une complication majeure menaçant le pronostic vital. Elle est due à la reconnaissance des antigènes du receveur par les lymphocytes T du donneur et à l’activation de ceux-ci, à l’origine de dommages tissulaires. L’altération de la barrière intestinale joue un rôle critique dans la GvH. La famille des protéines de choc thermique (HSP)90 comporte cinq membres dont trois cytosoliques dénommés HSP90, et un localisé dans le réticulum endoplasmique (RE), Gp96, qui peut être sécrété en cas de stress. Nous montrons dans nos travaux de thèse que la 17AAG, un inhibiteur des HSP90, réduit la mortalité liée à la GvH dans un modèle murin. Cet effet est associé à une augmentation de la réponse au stress du RE dans les cellules épithéliales intestinales comme en atteste l’augmentation de l’épissage du facteur de transcription XBP-1, corrélée à une diminution du dommage tissulaire intestinal. Ces résultats permettent d’envisager une place pour la 17AAG ou d’autres inhibiteurs de HSP90 dans la prévention de la GvH chez l’homme. D’autre part, nous montrons que Gp96 est sécrétée dans le sérum de patients développant une GvH aiguë sévère avec atteinte intestinale. Nous suggérons de valider la pertinence de Gp96 comme biomarqueur de GvH intestinale dans une étude de plus grande ampleur. Enfin, nous trouvons que Gp96 s’associe avec le composant 3 du complément, une protéine impliquée dans l’immunité innée et adaptative, et inhibe certaines de ses fonctions. Les conséquences fonctionnelles de cette association sont discutées. / Allogeneic hematopoietic cell transplantation is a treatment for certain disorders including hematologic malignancies. Graft-versus-host-disease (GvHD) is a major, life-threatening complication. It is due to the recognition of recipient antigens by donor T cells, which activate and damage tissues. Intestinal barrier alteration plays a critical role in GvHD. Heat shock proteins (HSP)90 include five members, three cytosolic members named HSP90, and one member localized in endoplasmic reticulum (ER) called Gp96 and able to gain extracellular level in case of stress. We show in our thesis that 17AAG, a HSP90 inhibitor, reduces GvHD mortality in a mouse model. This effect is associated with an increase in ER stress pathway in intestinal epithelial cells as figured by transcription factor XBP-1 splicing, correlated to a decrease in intestinal tissue damage. These results suggest that 17AAG could be considered in GvHD prevention in human. Moreover, we show that Gp96 is secreted in serum of patients developing an acute GvHD with intestinal involvement. We propose to validate the relevance of Gp96 as an intestinal GvHD biomarker is a larger study. Finally, we find that Gp96 associate with complement component 3, a protein involved in innate and adaptive immunity, and inhibit some of its functions. Functional consequences of this association are discussed.

Maladie du greffon contre l’hôte

HSP90

Gp96

17AAG

Complément C3

Graft-versus-host disease

Intestinal graft-versus-host disease

HSP90

Gp96

17AAG

Complement C3

571.9

616

Mechanisms of Molecular Chaperone Surface Binding and Endocytosis: Insights into the Molecular Basis for GRP94 Immune Function

Jockheck-Clark, Angela Roberta

January 2010

<p>Extracellular GRP94 can elicit both innate and adaptive immune responses by interacting with endocytic and signaling receptors on professional antigen presenting cells (pAPCs). CD91 was the first receptor proposed to facilitate GRP94-mediated immune responses. Using a GRP94 affinity matrix, a CD91 fragment was isolated from the detergent-solubilized membranes of a pAPC cell line. It was then demonstrated that CD91 ligands could inhibit GRP94-mediated peptide cross-presentation, suggesting that CD91 played a critical role in this process. While these studies implied that CD91 could function as a GRP94 endocytic receptor, later works suggested that CD91 may not recognize GRP94 at the cell surface. These opposing observations have lead to a significant controversy surrounding the identity of CD91 as an endocytic receptor for GRP94. Because the ability of CD91 to directly mediate GRP94 surface binding and uptake has not been established, the studies included in this dissertation have focused on evaluating the ability of CD91 to facilitate three processes that are necessary for GRP94-mediated peptide cross-presentation: surface binding, internalization, and processing.</p><p>These studies utilized a recombinantly-expressed N-terminal domain of GRP94 (GRP94.NTD), which was previously shown to have nearly identical biological activity to full length GRP94. The ability of CD91 to directly bind and internalize GRP94.NTD was examined using murine embryonic fibroblast (MEF) cell lines whose expression of CD91 was either reduced via siRNA, or eliminated by genetic disruption of the CD91 locus. Binding competition experiments were also conducted. Together, these studies reveal that CD91 does not directly interact with GRP94 at the cell surface. The ability of CD91 to directly facilitate GRP94 internalization was examined using various internalization and internalization competition assays. These studies demonstrated that GRP94.NTD and the CD91 ligand RAP were internalized through spatially and kinetically distinct pathways, that CD91 was not necessary for GRP94.NTD internalization, and that RAP did not inhibit GRP94 endocytosis. Together, these studies strongly suggest that CD91 does not directly facilitate GRP94 internalization. When these studies were extended to DC2.4 mouse dendritic cells, the CD91 ligand RAP reduced GRP94.NTD internalization/process by ~15%. This suggests that CD91 may indirectly facilitate GRP94 internalization in pAPC cell lines. Lastly, cross-presentation studies were utilized to examine the ability of various CD91 ligands to influence GRP94.NTD-mediated peptide cross-presentation through a post-uptake mechanism using the DC2.4/OT-1 system. Although it was discovered that DC2.4 cells can internalize and process GRP94.NTD/peptide complexes through fluid-phase endocytosis, CD91 ligands did not significantly inhibit GRP94-mediated peptide cross-presentation by DC2.4 cells. These studies demonstrate that CD91 does not play a primary role in GRP94-mediated peptide cross-presentation.</p><p>In the course of these studies, cell surface heparan sulfate proteoglycans (HSPGs) were identified as novel cell surface binding sites for GRP94.NTD on MEF cells. This conclusion was established using three distinct experimental approaches. GRP94.NTD surface binding was significantly decreased following heparin pre-treatment, following incubation with the sulfation inhibitor sodium chlorate, and following digestion with extracellular heparinase II. Conversely, these treatments did not significantly influence GRP94.NTD binding to RAW264.7 mouse macrophage-like cells. This suggested that GRP94.NTD-HSPG cell surface interactions may require the expression of a specific type of cell surface HSPG that is not expressed by RAW264.7 cells. However, additional studies strongly suggested that GRP94.NTD-HSPG cell surface interactions were mediated by the heparan sulfate-containing side chains rather than the presence of a specific cell surface HSPG core protein.</p><p>This dissertation focuses on the critical re-examination of CD91 functions in GRP94 surface binding, uptake, and cross-presentation. Together, these results clarify conflicting data on CD91 function in GRP94 surface binding and endocytosis. This dissertation also describes the identification of cell surface HSPGs as GRP94 binding sites on MEF cells. These studies extend the diversity of surface receptors that recognize of GRP94, and suggest that cell surface HSPG-dependent interactions may contribute to the biology of GRP94-elicited immune responses.</p> / Dissertation

Biology, Cell

Biology, Molecular

Health Sciences, Immunology

CD91

cross-presentation

endocytosis

gp96

GRP94