Preclinical Assessment for Gene Addition Strategy in Familial Hemophagocytic Lymphohistiocytosis Related to Munc 13-4 Deficiency

Introduction: Familial Hemophagocytic Lymphohistiocytosis (FHL) comprises a group of rare genetic disorders with defect cytotoxicity in T and NK cells predisposing to severe hyperinflammation with the clinical hallmark of the Hemophagocytic LymphoHistiocytosis (HLH) syndrome. The uncontrolled proliferation of activated T-CD8 lymphocytes and macrophages infiltrates lymphoid tissues, bone marrow, and multiple organs including the brain. Thus, if untreated full-scale FHL is usually fatal. FHL3 is due to mutations in the UNC13D gene coding for Munc 13-4 protein, one of the components of the perforin-dependent cytotoxicity apparatus. This condition accounts for 30% to 35 % of all genetic cases of HLH. Hematopoietic stem and progenitor cell (HSPC) transplantation, which is the only curative treatment for FHL3 to date, remains difficult even when a compatible donor is available because of the patients' critical inflammatory background. In this context, gene therapy could be a promising therapeutic option, especially for those patients without HLA-compatible donor.

Method: The feasibility and efficacy of gene addition strategy for FHL3 have been previously demonstrated in mouse models. We then translated this approach to human cells using a third-generation self-inactivated lentivirus vector pseudo-typed with a conventional vesicular stomatitis virus-G (VSVG) expressing a codon-optimized UNC13D gene under the transcriptional control of EF1 alpha (LV-EF1a-UNC13D). HSPC or CD3+ T-cells were transduced with a GMP-like-grade LV-EF1a-UNC13D lentiviral vector. We studied the restoration of cytotoxic function.

Results: Our GMP transduction protocol led to efficient transcription of optimized mRNA codon and expression of Munc 13-4 protein as evidenced by RT qPCR and western blot, respectively. Interestingly, we show restored cytotoxicity activity after CD34+ differentiation toward CD3+ T-cells and NK cells. The vector copy number is compatible with a clinical approach. In vivo experiments are ongoing to validate the absence of genotoxicity in this setting.

Discussion conclusion: Our results support the feasibility and efficacy of UNCD13D gene transfer into hematopoietic stem and progenitor cells or T cells from Munc 13-4 deficient patients. Alternatively, gene therapy of HSPCs could be combined with transduced autologous T-cells infusion. The first attempts regarding this option are encouraging. UNC13D gene addition strategy could dramatically improve the care of FHL3 patients lacking an HLA-genoidentical donor.