Non-coding variants in UBA1 lead to vexas Free

Introduction:

Somatic mutations in UBA1, encoding an E1 ubiquitin activating enzyme, have recently been linked to an adult-onset, severe inflammation syndrome called VEXAS (Vacuoles, E1-enzyme, X-linked, Autoinflammatory, Somatic). VEXAS is characterized by systemic inflammation and hematologic abnormalities. While the majority of identified mutations in UBA1 are located in exonic regions, the role of non-coding and intronic mutations in the pathogenesis of VEXAS remains largely unexplored. In this study, we investigated the potential contribution of intronic mutations to VEXAS pathogenesis. Methods: To investigate mutations affecting UBA1 outside the region typically covered in targeted panels (exon 3), whole exome (WES) and genome sequencing (WGS) was performed on peripheral blood of patients with VEXAS-associated clinical presentation previously negative for UBA1 mutations per clinical testing. 265 patients were profiled by WES (~100X) and 36 patients were profiled by WGS (~55X). Clinical history was reviewed for these patients for VEXAS-associated presentation including a combination of hematologic and rheumatologic disease in adults. Participants with known pathogenic or likely pathogenic (P/LP) variants in UBA1 or other genetic causes of systemic autoinflammatory disease were excluded. UBA1 transcript and protein expression were assessed by PCR and western blot, respectively, in one case where peripheral blood mononuclear cells were available. Results: We identified 7 patients with VEXAS-like presentation with intronic single nucleotide variants or deletions. Five patients had a recurrent point mutation (median VAF: 0.78; range: 0.38-0.97). 5 patients had been diagnosed with MDS, and bone marrow biopsy revealed vacuolated progenitor cells in 3 patients. The most frequent clinical manifestations included skin rash (n=6), joint pain (n=4), vasculitis (n=4), and chondritis (n=2). One patient had been diagnosed with acute myeloid leukemia with myelodysplasia related changes, with co-mutations in IDH1 and SRSF2. Two additional patients had mutations in ASXL1 of which one also had a ZRSR2 mutation. No co-occurring myeloid driver gene mutations were found in the other cases.

Noncoding mutations, similar to canonical UBA1 disease causing mutations, were shown to be lineage restricted to myeloid cells. To assess the functional impact of mutations, CD14⁺ monocytes were isolated from the peripheral blood. Compared to the CD14^- fraction, the CD14⁺ fraction revealed a decrease in the UBA1 transcript as well as UBA1 protein level. One patient demonstrated loss of novel UBA1 mutation after hypomethylating agent treatment, and allogeneic transplant, placing the patient in remission.Conclusions:Our findings of intronic and non-coding UBA1 mutations in patients with VEXAS-associated clinical presentation suggests these variants may affect the regulation of UBA1 transcription, representing a potential new mechanism of pathogenesis. Further functional studies are underway to understand how these variants contribute to impaired UBA1 activity and VEXAS disease pathogenesis. Collectively, our results advocate for a broader approach in genetic testing for UBA1 mutations and pave the way for improved diagnostic and therapeutic strategies for VEXAS syndrome.