Antioxidant role of the GABA shunt in regulating redox balance in blood progenitors during Drosophila hematopoiesis

Redox balance is crucial for normal development of stem and progenitor cells that reside in oxidative environments. This study explores the mechanisms of redox homeostasis in such niches and investigates myeloid-like blood progenitor cells that generate reactive oxygen species (ROS) and moderate it developmentally. Our findings reveal that during lymph gland development, as the blood-progenitor cells oxidize pyruvate via the TCA cycle leading to the generation of ROS, these cell also de novo synthesize GSH to counter excessive ROS and ensure redox balance. GABA metabolism, through GABA-shunt, restricts pyruvate dehydrogenase (PDH) activity and consequently TCA rate. This allows a metabolic route to sustain serine levels in these cells which is the rate limiting precursor controlling de novo GSH production. Disruption of GABA metabolism leads to a metabolic imbalance, characterized by excessive PDH activity, heightened TCA rate leading to impaired serine/GSH production and overall ROS dysregulation. Overall, the study presents a unique metabolic state whereby, in the blood-progenitor cells, by keeping PDH and TCA activity in check and promoting serine/GSH generation, GABA metabolism establishes a metabolic framework that optimises the use of ROS in blood-progenitors, while ensuring redox homeostasis.