Succinate Dehydrogenase loss causes cascading metabolic effects that impair pyrimidine biosynthesis

Impaired availability of the amino acid aspartate can be a metabolic constraint of cell proliferation in diverse biological contexts. However, the kinetics of aspartate depletion, and its ramifications on downstream metabolism and cell proliferation, remain poorly understood. Here, we deploy the aspartate biosensor jAspSnFR3 with live cell imaging to resolve temporal relationships between aspartate and cell proliferation from genetic, pharmacological, and nutritional manipulations. In cells with impaired aspartate acquisition from mitochondrial complex I inhibition or constrained uptake in aspartate auxotrophs, we find that the proliferation defects lag changes in aspartate levels and only manifest once aspartate levels fall below a critical threshold, supporting the functional link between aspartate levels and cell proliferation in these contexts. In another context of aspartate synthesis inhibition, impairing succinate dehydrogenase (SDH), we find a more complex metabolic interaction, with initial aspartate depletion followed by a rebound of aspartate levels over time. We find that this aspartate rebound effect results from SDH inhibition disproportionately impairing pyrimidine synthesis by inhibiting aspartate transcarbamoylase (ATCase) through the dual effect of diminishing aspartate substrate availability while accumulating succinate, which functions as a competitive inhibitor of aspartate utilization. Finally, we uncover that the nucleotide imbalance from SDH inhibition causes replication stress and introduces a vulnerability to ATR kinase inhibition. Altogether, these findings identify a mechanistic role for succinate in modulating nucleotide synthesis and demonstrate how cascading metabolic interactions can unfold to impact cell function.