Truncating ASXL1 variants rewire cellular metabolism via mitochondrial pyruvate carrier repression
Truncating ASXL1 variants rewire cellular metabolism via mitochondrial pyruvate carrier repression
Lin, I.; Reyes, M. S. S.; Krall, A.; Vashist, N.; Sarkissian, S.; Matulionis, N.; Ning, A.; Stiles, L.; Russell, B. E.; Medina, P. M. B.; Christofk, H. A.; Arboleda, V. A.
AbstractBohring-Opitz syndrome (BOS, OMIM#605309) is a rare neurodevelopmental disorder caused by heterozygous and truncating variants in ASXL1 (Additional Sex Combs Like 1), a chromatin-associated epigenetic regulator that forms the catalytic PR-DUB complex with BAP1. Truncating ASXL1 variants are also recurrent somatic drivers in myeloid leukemia, yet the metabolic consequences of these mutations remain undefined. Using patient derived dermal fibroblasts, we show that truncating ASXL1 variants drive a Warburg-like metabolic state characterized by increased glycolytic flux, and accumulation of pyruvate and lactate. Truncated ASXL1 and BAP1 show aberrant co-occupancy at an H3K4me3-marked intronic regulatory element within MPC2 intron 1, with broadened ASXL1 occupancy extending beyond BRD4-defined regulatory boundaries while BRD4 positioning remains unchanged, consistent with aberrant PR-DUB complex spreading beyond its normally constrained chromatin territory. This altered occupancy is accompanied by modest but significant reduction in MPC2 transcript abundance and a disproportionately larger reduction in MPC1 and MPC2 protein levels, indicating that transcriptional dysregulation at this intronic element is amplified at the protein level through post-transcriptional mechanisms including impaired MPC1/MPC2 heterodimer stability. Pharmacologic MPC inhibition recapitulates both the metabolic and Wnt signaling phenotypes of BOS cells, while canonical Wnt activation increases glycolytic flux without reducing MPC abundance, establishing mitochondrial pyruvate restriction as causally upstream of signaling dysregulation. These findings define a previously unrecognized chromatin-to-metabolism axis connecting gain-of-function ASXL1 truncation to mitochondrial pyruvate transport, identifying MPC as a central mediator of epigenetic-metabolic crosstalk in both a rare developmental syndrome and ASXL1-mutant myeloid malignancy.