Pierre-Joseph Royer

Profiling dendritic cell maturation with dedicated microarrays

Dendritic cell (DC) maturation is the process by which immature DC in the periphery differentiate into fully competent antigen‐presenting cells that initiate the T cell response. However, DC respond to many distinct maturation stimuli, and different types of mature DC induce qualitatively different T cell responses. As DC maturation involves the coordinated regulation of hundreds of genes, comprehensive assessment of DC maturation status would ideally involve monitoring the expression of all of these transcripts. However, whole‐genome microarrays are not well‐suited for routine phenotyping of DC, as the vast majority of genes represented on such chips are not relevant to DC biology, and their cost limits their use for most laboratories. We therefore developed a DC‐dedicated microarray, or “DC Chip”, incorporating probes for 121 genes up‐regulated during DC maturation, 93 genes down‐regulated during maturation, 14 DC‐specific genes, and 90 other genes with known or probable immune functions. These microarrays were used to study the kinetics of DC maturation and the differences in maturation profiles among five healthy donors after stimulation with tumor necrosis factor‐α + polyI:C. Results obtained with the DC Chip were consistent with flow cytometry, enzyme‐linked immunosorbent assay, and real‐time polymerase chain reaction, as well as previously published data. Furthermore, the coordinated regulation of a cluster of genes (indoleamine dioxygenase, kynureninase, kynurenine monoxygenase, tryptophanyl tRNA synthetase, and 3‐hydroxyanthranilate 3,4‐dioxygenase) involved in tryptophan metabolism was observed. These data demonstrate the use of the DC Chip for monitoring the molecular processes involved in the orientation of the immune response by DC.

Culture Medium and Protein Supplementation in the Generation and Maturation of Dendritic Cells

Dendritic cells (DC) are powerful antigen‐presenting cells that have drawn many attentions due to the recent development of anti‐cancer vaccines. Clinical grade production of monocyte‐derived DC (Mo‐DC) is extensively studied, and many efforts are made to develop and improve clinical standard operating procedures. Most of the parameters involved, such as the cytokines and maturation agents, have been widely assessed. However, very few are investigated about how culture medium and additional protein components affect DC yield, viability and maturation. Thus, our study aimed to compare the impact of standard culture medium on Mo‐DC differentiation and maturation. Commercially available media for hematopoietic cell culture as well as different protein supplementations, that is foetal calf serum (FCS), autologous plasma (AP), human serum (HS) and human serum albumin (HSA) were tested. Culture yields, cell viability and DC maturation were investigated. Differentiation yields were similar between the conditions used. However, we evidenced significant differences in terms of cytotoxicity and DC maturation (phenotypic and functional). This underscores the importance of defining culture medium composition in clinical standard operating procedures to insure quality control, and also when preparing DC for experimental uses.

Efficient monocyte-derived dendritic cell generation in patients with acute myeloid leukemia after chemotherapy treatment: Application to active immunotherapy

OBJECTIVE While complete remission in acute myeloid leukemia (AML) can be achieved after chemotherapy (CT), relapses occur for the majority of patients, underlying the need to eliminate residual disease. Based on dendritic cell (DC) vaccination, the triggering of an immune response against residual leukemia cells after CT could maintain patients in remission. The aim of our study was to assess, for vaccine preparation, generation of monocyte-derived DCs in AML patients after CT. MATERIALS AND METHODS We evaluated efficiency of the production, yields, maturation, and functional properties of DCs from 22 AML patients at different CT stages compared to those from 15 healthy donors. RESULTS We demonstrated that monocyte-derived DC production is successful later than 3 weeks after the last CT cycle, whatever the CT was. Immature DCs demonstrated functional phagocytic activity. Mature DCs displayed migratory, T-cell stimulatory and Th1-activation capacities. Our results also suggest a favorable period from 20 to 60 days after CT for potent monocyte-derived DC production and immune activation. CONCLUSION In defining patient-sampling conditions, this preclinical study has direct implications for AML DC-based immunotherapy.

Chronic lung allograft dysfunction: a systematic review of mechanisms

Abstract Chronic lung allograft dysfunction (CLAD) is the major limitation of long-term survival after lung transplantation. Chronic lung allograft dysfunction manifests as bronchiolitis obliterans syndrome or the recently described restrictive allograft syndrome. Although numerous risk factors have been identified so far, the physiopathological mechanisms of CLAD remain poorly understood. We investigate here the immune mechanisms involved in the development of CLAD after lung transplantation. We explore the innate or adaptive immune reactions induced by the allograft itself or by the environment and how they lead to allograft dysfunction. Because current literature suggests bronchiolitis obliterans syndrome and restrictive allograft syndrome as 2 distinct entities, we focus on the specific factors behind one or the other syndromes. Chronic lung allograft dysfunction is a multifactorial disease that remains irreversible and unpredictable so far. We thus finally discuss the potential of systems-biology approach to predict its occurrence and to better understand its underlying mechanisms.

Sensitivity of human pleural mesothelioma to oncolytic measles virus depends on defects of the type I interferon response.

Attenuated measles virus (MV) is currently being evaluated as an oncolytic virus in clinical trials and could represent a new therapeutic approach for malignant pleural mesothelioma (MPM). Herein, we screened the sensitivity to MV infection and replication of twenty-two human MPM cell lines and some healthy primary cells. We show that MV replicates in fifteen of the twenty-two MPM cell lines. Despite overexpression of CD46 by a majority of MPM cell lines compared to healthy cells, we found that the sensitivity to MV replication did not correlate with this overexpression. We then evaluated the antiviral type I interferon (IFN) responses of MPM cell lines and healthy cells. We found that healthy cells and the seven insensitive MPM cell lines developed a type I IFN response in presence of the virus, thereby inhibiting replication. In contrast, eleven of the fifteen sensitive MPM cell lines were unable to develop a complete type I IFN response in presence of MV. Finally, we show that addition of type I IFN onto MV sensitive tumor cell lines inhibits replication. These results demonstrate that defects in type I IFN response are frequent in MPM and that MV takes advantage of these defects to exert oncolytic activity.