Interplay between mutant DNMT3A and UBA1 worsens survival through altered inflammatory and metabolic pathways Free

VEXAS (vacuoles, E1 enzyme, X-linked, autoinflammatory, somatic) is an adult-onset autoinflammatory disorder defined by somatic UBA1 mutations in hematopoietic stem cells (HSCs). Given the higher median age at onset and prevalent inflammation, approximately 60% of patients have concurrent clonal hematopoiesis (CH) involving epigenetic regulators, DNMT3A and TET2. We have previously demonstrated (Gutierrez-Rodrigues, Blood 2023) that DNMT3A and TET2 mutations in VEXAS are independently associated with increased mortality, without an increased risk of myelodysplastic syndrome (MDS) or acute myeloid leukemia (AML). To define the role of CH in VEXAS, we investigated the impact of CH on mortality and related epigenetic dysregulation in primary VEXAS patient samples and validated these findings using an adenine base-editing (ABE) strategy to model cooccurring UBA1 and DNMT3A mutations in CD34+ HSCs.

After IRB approval, 114 VEXAS patients from the Mayo Clinic and the NIH were retrospectively assessed, including 104 screened for CH by error-corrected DNA sequencing (ECS). DNA methylation changes were identified using the Illumina Infinium MethylationEPIC BeadChip and genome-wide using Biomodal 6-base sequencing on peripheral blood samples (PB). Cellular indexing of transcriptomes and epitopes (CITE)-seq was performed using the 10x Chromium 3' GEX platform; 21,114 pooled cells were subjected to UMAP dimensionality reduction, followed by Azimuth based cell identification. HSCs from different donors were base edited for UBA1 M41T mutation with and without cooccurring DNMT3A splice-site mutations. Levels of cytokines in cell culture supernatants were measured using Olink technology, transcriptomic changes were assessed using bulk RNA-seq. Statistical analyses were carried out using R.

Patients' median age was 68 (62-74) years; 95% were white and 99% were males. 39% had a pathogenic CH variant, with DNMT3A (18%; median VAF: 42%; range 6-46%) and TET2 (11.5%; median VAF: 11%; range: 2-37%) being most common (2% had both). While the presence of any CH mutation did not impact survival (7.7 vs 11.5yrs, p =0.69), DNMT3Amt CH had an age-independent negative impact on mortality (9.2 vs 5.6yrs, p=0.02), without an increased risk of MDS/AML (p=0.31).

Changes in DNA methylation were profiled using the methylation array in 19 VEXAS patients without CH (Median Age: 68 years) and in 9 with DNMT3Amt CH (Median Age: 74 years), respectively. VEXAS samples with DNMT3Amt CH displayed a hypomethylation phenotype compared to VEXAS samples with no CH, with 4,096 unique hypomethylated CpGs, occurring mainly at gene enhancers (Enh) and transcriptional states (Tx, TxWk). This loss of DNA methylation was enriched in inflammatory pathways with extensive hypomethylation observed in the promoters and gene bodies of IL-1 family genes. CITE-seq performed on 7 VEXAS samples (4 DNMT3Amt CH vs 3 no CH) demonstrated an upregulation of gene expression predominantly in T-cell subsets. This increased expression was enriched in inflammatory genes, largely centered around IL-1 and IL-18 family signaling. Pathway analysis revealed an enrichment in respiratory electron transport and oxidative phosphorylation (oxphos), with the VEXAS samples with DNMT3Amt CH demonstrating significantly increased oxphos gene signatures.

Base editing of CD34+ cells was done using an adenine base-editing (ABE) strategy to model dual UBA1 and DNMT3A splice-site mutations. We observed that the HSCs base edited for the UBA1 M41T recapitulated the cellular hallmarks of VEXAS demonstrating reduced ubiquitination, unfolded protein response (UPR) activation, and increased inflammation. The addition of cooccurring DNMT3A mutations resulted in decreased DNMT3A expression, further increasing inflammatory markers, confirming altered inflammatory and metabolic pathways.

Our study validates the age-independent, negative prognostic impact of DNMT3Amt CH on survival in VEXAS syndrome. DNMT3A mutations mediate epigenetic and transcriptional priming associated with upregulation of inflammatory and mitochondrial function pathways. These findings have been validated in a base edited cell model with UBA1 and DNMT3A co-mutations.