Mutant glycyl-tRNA synthetase (Gars) ameliorates SOD1G93A motor neuron degeneration phenotype but has little affect on Loa dynein heavy chain mutant mice

Abstract

Background: In humans, mutations in the enzyme glycyl-tRNA synthetase (GARS) cause motor and sensory axon loss in the peripheral nervous system, and clinical phenotypes ranging from Charcot-Marie-Tooth neuropathy to a severe infantile form of spinal muscular atrophy. GARS is ubiquitously expressed and may have functions in addition to its canonical role in protein synthesis through catalyzing the addition of glycine to cognate tRNAs. Methodology/Principal Findings: We have recently described a new mouse model with a point mutation in the Gars gene resulting in a cysteine to arginine change at residue 201. Heterozygous GarsC201R/+ mice have locomotor and sensory deficits. In an investigation of genetic mutations that lead to death of motor and sensory neurons, we have crossed the GarsC201R/+ mice to two other mutants: the TgSOD1G93A model of human amyotrophic lateral sclerosis and the Legs at odd angles mouse (Dync1h1Loa) which has a defect in the heavy chain of the dynein complex. We found the Dync1h1Loa/+; GarsC201R/+ double heterozygous mice are more impaired than either parent, and this is may be an additive effect of both mutations. Surprisingly, the GarsC201R mutation significantly delayed disease onset in the SOD1G93A;GarsC201R/+ double heterozygous mutant mice and increased lifespan by 29% on the genetic background investigated. Conclusions/Significance: These findings raise intriguing possibilities for the study of pathogenetic mechanisms in all three mouse mutant strains. © 2009 Banks et al.