Disruption of lactate metabolism in the peripheral nervous system leads to motor-selective deficits

Abstract

Abstract Schwann cells (SCs) myelinate and provide trophic support to axons in the peripheral nervous system (PNS) and disruption of SC cellular metabolism leads to demyelination and axon degeneration, both symptoms of peripheral neuropathies. The lactate shuttle hypothesis proposes that glycolytic support cells supply lactate to adjacent axons to sustain their high metabolic demands, a process that requires the interconversion of lactate and pyruvate via lactate dehydrogenase (LDH) in both SCs and neurons. To test this hypothesis in the PNS, we selectively knocked out the genes for both LDH enzymes, LDHA and LDHB, in motor neurons (MNs), sensory neurons (SNs), or SCs. Interestingly, motor axons and their synapses progressively degenerate when LDH is deleted from either MNs or SCs; however, defects in sensory axons or their terminals were not observed when LDH was excised from either SNs or SCs. Deletion of LDH in SCs also leads to a decrease in total ATP levels in peripheral nerves despite a marked accumulation of pyruvate and glycolytic intermediates, consistent with the failure of pyruvate to lactate conversion in SCs leading to energetic deficits in axons. These results support a model in which motor axons are more dependent on SC-derived lactate than are sensory axons, a specific dependency that suggests LDH and lactate shuttling influence the course of motor-dominated neuropathies such as ALS.