IRCCS San Raffaele Hospital. Vita-Salute San Raffaele University Milan, Milan, Italy
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Corrado Campochiaro1, Raffaella Molteni2, Martina Fiumara3, Alessandro Tomelleri4, Elisa Diral5, Davide Stefanoni2, Angelica Varesi3, Alessandra Weber3, Roberta Alfieri6, Luisa Albano3, Maddalena Panigada2, Eleonora Cantoni2, Daniele Canarutto3, Luca Basso-Ricci3, Pamela Quaranta3, Angelo D’Alessandro7, marco Matucci Cerinic8, Raffaella Di Micco3, Serena Scala3, Alessandro Aiuti3, Fabio Ciceri5, Ivan Merelli3, Lorenzo Dagna9, Simone Cenci2, Luigi Naldini3, Samuele Ferrari3 and Giulio Cavalli2, 1IRCCS San Raffaele Hospital, Unit of Immunology, Rheumatology, Allergy and Rare Disease. Vita-Salute San Raffaele University, Milan, Italy, 2Division of Genetics and Cell Biology, IRCCS San Raffaele Scientific Institute, Milan, Italy, 3San Raffaele Telethon Institute for Gene Therapy, IRCCS San Raffaele Scientific Institute, Milan, Italy, 4Unit of Immunology, Rheumatology, Allergy and Rare Diseases, San Raffaele Scientific Institute, Milano, Italy, 5Unit of Haematology and Bone Marrow Transplantation, IRCCS San Raffaele Hospital, Milan, Italy, 6Institute for Biomedical Technologies, National Research Council, Segrate, Italy, 7Department of Biochemistry and Molecular Genetics, University of Colorado Denver - Anschutz Medical Campus, Aurora, CO, 8Unit of Immunology, Rheumatology, Allergy and Rare diseases, IRCCS San Raffaele Hospital, Milan, Milan, Italy, 9Department of Internal Medicine, IRCCS San Raffaele Hospital and Vita-Salute San Raffaele University, Milan, Italy
Background/Purpose: VEXAS syndrome is an adult-onset, X-linked, life-threatening, autoinflammatory and hematological disease caused by somatic mutation in UBA1 gene. To understand its pathophysiology, we aimed to achieve a molecular and phenotypic characterization of hematopoiesis of VEXAS patients and to develop cellular and humanized mouse models by gene editing.
Methods: Six VEXAS patients (p.Met41 >Thr; p.Met41 >Val; p.Met41 >Leu; c.118-1 G >C) were recruited from our Unit. Variant allele frequency (VAF) of UBA1 mutant cells was quantified by targeted sequencing in isolated hematopoietic lineages and hematopoietic stem/progenitor cells (HSPCs). Multiparametric immunophenotypic analysis was performed on peripheral blood and bone marrow (BM), focusing on HSPCs. Circulating monocytes were analyzed by whole RNA-seq and metabolome analysis. Healthy age and sex-matched controls were included. To introduce UBA1 mutations and develop VEXAS models, cutting-edge gene editing technologies were adopted in healthy human HSPCs.
Results: Targeted sequencing in VEXAS patients showed >0.8 VAF in HSPCs. Conversely, VAF largely differed across mature cells, averaging 0.81 in neutrophils, 0.64 in monocytes, 0.42 in NK, 0.07 in T cells, and 0.09 in B cells, supporting a myeloid skewing of mutant HSPCs. Multiparametric immunophenotypic analyses showed unbalanced composition of HSPCs in the BM, with 2-to-3-fold reduction of primitive stem cells, multipotent and lymphoid progenitors, and 2-fold increase of myeloid progenitors, compared to matched healthy individuals. HSPCs, myeloid-biased HSPCs and immature myeloid cells were increased by 3-to-4 fold in the circulation (p< 0.03). Gene expression analysis of circulating monocytes displayed upregulation of inflammatory pathways and metabolic rewiring (Fig. 1, panels A-B). Metabolomic analyses confirmed hyperactivation of the glycolytic pathway and specific lipid metabolism (Fig. 1, C-D). Models of VEXAS generated by gene editing recapitulated patients' hematopoiesis and pathophysiology in vitro and in vivo. UBA1 mutations were installed at VAF >0.9 in HSPCs and generated a myeloid bias in vitro. Transplantation of edited HSPCs in immunodeficient mice resulted in a 100-fold reduction in circulating B cells, while NK and myeloid compartments were preserved. Human BM HSPCs were 5-fold lower than control mice, largely myeloid-biased and presented abnormal vacuolar morphology. Concordantly, VAF was >0.8 in myeloid cells and HSPCs and < 0.3 in B cells.
Conclusion: Mutations in UBA1 drive expansion of HSPCs and enhance myelopoiesis-guided accumulation of myeloid precursors. Mutant lymphoid cells are negatively selected and their myeloid counterpart in peripheral blood displays upregulation of transcriptomic signatures and metabolic pathways indicative of inflammatory activation. Gene editing-based models hold promise to enable preclinical testing and validation of novel therapeutics to treat VEXAS syndrome.
Figure 1. Panel A. Gene expression analysis of peripheral monocytes in VEXAS patients compared to controls. Panel B. Gene-enrichmed pathway analysis in VEXAS patients compared to controls. Panel C. Metabolic analysis in VEXAS patients compared to controls. Panel D. Metabolic-enriched pathway analysis in VEXAS patients compared to controls.
C. Campochiaro: Boehringer Ingelheim, 1, 6, Janssen, 1, 6, Novartis, 1, 6; R. Molteni: None; M. Fiumara: None; A. Tomelleri: Novartis, 1; E. Diral: None; D. Stefanoni: None; A. Varesi: None; A. Weber: None; R. Alfieri: None; L. Albano: None; M. Panigada: None; E. Cantoni: None; D. Canarutto: None; L. Basso-Ricci: None; P. Quaranta: None; A. D’Alessandro: None; m. Matucci Cerinic: accelerong, 2, 6, actelion, 2, 6, bayer, 2, 6, biogen, 2, 6, Boehringer-Ingelheim, 2, 6, Chemomab, 2, 6, corbus, 2, 6, CSL Behring, 2, 6, Eli Lilly, 2, 6, galapagos, 2, 6, Inventiva, 2, 6, Janssen, 2, 6, Merck/MSD, 2, 6, Mitsubishi, 2, 6, Pfizer, 2, 6, regeneron, 2, 6, Roche, 2, 6, samsung, 2, 6; R. Di Micco: None; S. Scala: None; A. Aiuti: None; F. Ciceri: None; I. Merelli: None; L. Dagna: AbbVie, 2, AstraZeneca, 2, Biogen, 2, BMS, 2, 5, Boehringer Ingelheim, 2, Celltrion, 5, Eli Lilly, 2, Galapagos, 2, GSK, 1, Janssen, 2, Kiniksa Pharmaceuticals, 2, 5, Novartis, 2, 6, Pfizer, 2, 5, Sobi, 2, 5, 6; S. Cenci: None; L. Naldini: None; S. Ferrari: None; G. Cavalli: Novartis, 3.