A dNmnat-sensitized in vivo platform for unbiased discovery of regulators of neurodegeneration

Axon degeneration drives nervous system dysfunction in diverse neurological diseases and injuries. While key regulators of injury-induced Wallerian degeneration have been identified, approaches have largely relied on axotomy, a particularly extreme injury for a neuron. Here, we developed a forward genetic screening platform in the adult Drosophila wing that sensitizes neurons to degeneration through depletion of nicotinamide mononucleotide adenylyltransferase (dNmnat), the essential NAD ⁺ biosynthetic enzyme. We screened 9,393 mutagenized chromosomes and recovered 59 mutations that suppress neurodegeneration induced by dNmant depletion, including the known pro-degenerative molecule dSarm, thereby validating our approach. We show loss of CG4098 , the Drosophila homolog of the mammalian enzyme NUDT9, robustly preserved axons and induced widespread remodeling of NAD ⁺ -related metabolites, which provides a new link between cADP-ribose hydrolase activity and neuronal survival. We further show mutations in the transcription factor Abrupt resulted in elevated dNmnat protein levels and blocked axon degeneration, suggesting Abrupt normally tunes dNmnat levels and neuronal NAD ⁺ homeostasis. dNmnat depletion is thus a versatile approach for unbiased discovery of axon death pathway components, each of which may provide new entry points for therapeutic strategies to preserve axons in neurodegenerative diseases.