Targeted neuronal gene expression and longevity in Drosophila.

Earlier studies from this laboratory have shown that in the insect, Drosophila melanogaster, the motorneuron is an important cellular nexus between the metabolism of reactive oxygen species (ROS) and adult lifespan. This was demonstrated by experiments in which expression of CuZn SOD (SOD1) specifically in motorneurons was shown to extend the mean and maximum adult lifespans to 140% of normal, and to rescue the majority of deliterious phenotypes displayed by SOD1-null mutants. We have interpreted these results to mean either that the lifespan of the organism is normally limited by the functional lifespan of this post-mitotic cell type, or that ROS metabolism in motorneurons affects organismic lifespan via a systemic, perhaps neuroendocrine, signaling mechanism. We have now extended these studies to ask: (i) whether expression of catalase (CAT) or of the mitochondrially-localized Mn SOD (SOD2) in motorneurons, either singly or in combination with SOD1, have similar effects on lifespan; (ii) if expression of SOD2 can rescue SOD1-null mutant phenotypes; and (iii) if ROS metabolism in cell types other than motorneurons has significant impact on aging and lifespan determination.

Isolation of larval behavioral mutants in Drosophila melanogaster.

Genetic loci that influence behavior are often difficult to identify and localize in part due to the quantitative nature of behavioral phenotypes. Previous studies had found an association between pupal lethality and altered larval behavior for mutants of several genes. To facilitate the identification and localization of new mutants that influence larval foraging (movement in the presence of food) and general locomotion (movement in the absence of food) behaviors we identified and then screened a collection of strains carrying pupal-lethal mutations for alterations in these larval behaviors. When the lethal mutation segregated with the behavioral alteration this permitted the mapping of the behavioral locus. Nine new loci on the second chromosome were found to affect larval behavior. Of these, seven loci affected foraging and two affected locomotion. Analyses of these new loci will lead to further understanding of the mechanistic bases of larval behavior.

Expression of human FALS SOD in motorneurons of Drosophila.

Mutations in human CuZn superoxide dismutase (SOD) have been associated with familial amyotrophic lateral sclerosis (FALS). Although leading to many experimental advances, this finding has not yet led to a clear understanding of the biochemical mechanism by which mutations in SOD promote the degeneration of motorneurons that causes this incurable paralytic disease. To explore the biochemical mechanism of FALS SOD-mediated neuropathogenesis, we used transgenic methodology to target the expression of a human FALS SOD to motorneurons of Drosophila, an organism known for its phenotypic sensitivity to genetic manipulation of SOD. Earlier, we showed that targeted expression of human SOD in motorneurons of Drosophila causes a dramatic extension of adult lifespan (>40%) and rescues most of the phenotypes of SOD-null mutants. Using the same genetic system, we now ask if targeted expression of a mutant allele of human SOD that is associated with FALS causes paralysis and premature death, or is otherwise injurious in Drosophila as it is in humans and transgenic mice. Here we report that high-level expression of a human FALS SOD in motorneurons is not detrimental and does not promote paralysis and premature death when expressed in motorneurons of Drosophila. In sharp contrast, the expression of FALS SOD in Drosophila actually extends lifespan, augments resistance to oxidative stress and partially rescues SOD-null mutants in a manner predicted by our earlier studies on the expression of wildtype human SOD in Drosophila motorneurons.

Motorneurons, reactive oxygen, and life span in Drosophila.

Aging and life span are widely recognized, but poorly understood, aspects of basic biology. Fortunately, genetic approaches to understanding the mechanisms governing these processes are beginning to bear fruit. One line of investigation has established that incompletely reduced forms of oxygen, arising as by-products of respiration and cellular catabolism, play an important, and perhaps universal, role in aging and life span determination. An important refinement of this model of aging, suggested by recent experiments in our laboratory, is that the critical nexus of the relationship between reactive oxygen species and life span is highly localized and, in fact, may reside principally in the motorneuron. Here we analyze the strengths and weaknesses of the reactive oxygen species/motorneuron model of aging by comparing the studies on which it is based, which used the approach of targeted transgene expression in Drosophila, with studies from other laboratories using different genetic approaches, principally mutation and selection. The results encourage the view that an understanding of the mechanisms that underlie this widely recognized aspect of basic biology is within our grasp.

Transgenic analysis of the cSOD-null phenotypic syndrome in Drosophila.

Cu-Zn superoxide dismutase (cSOD) is an enzyme of critical importance for the inactivation of superoxide radicals generated by cellular metabolic processes. A phenotypic syndrome has been characterized for homozygotes for a null mutation of the Drosophila cSOD gene, many features of which may be relevant to current studies of cSOD mutations in mammals. However, it was possible that some of the features of this syndrome were at least partially attributable to genetic background differences between control and mutant strains. The results reported in this paper document that the previously described features of the cSOD-null phenotype, namely (i) adult sensitivity to paraquat, (ii) male sterility, (iii) female semisterility, (iv) adult life-span reduction, (v) adult hyperoxia sensitivity, (vi) larval radiation sensitivity, and (vii) developmental sensitivity to glutathione depletion, are all rescued by a cSOD+ transgene in a controlled cSOD-null genetic background. This clearly confirms that the phenotype is largely attributable to the cSOD mutation per se. We describe two new features of the cSOD-null phenotype, namely (viii) adult sensitivity to glutathione depletion, and (ix) adult sensitivity to ionizing radiation, which are ameliorated by the cSOD+ transgene. The distinct sensitivity of cSOD-deficient individuals, and the uniform resistance of the cSOD+ control strains, clearly establish the requirement for cSOD in protection against intrinsic and applied oxygen stress and set the stage for tissue-specific expression studies with the goal of elucidating the critical target(s) of damage in cSOD-deficient animals.

Extension of Drosophila lifespan by overexpression of human SOD1 in motorneurons.

Reactive oxygen (RO) has been identified as an important effector in ageing and lifespan determination. The specific cell types, however, in which oxidative damage acts to limit lifespan of the whole organism have not been explicitly identified. The association between mutations in the gene encoding the oxygen radical metabolizing enzyme CuZn superoxide dismutase (SOD1) and loss of motorneurons in the brain and spinal cord that occurs in the life-shortening paralytic disease, Familial Amyotrophic Lateral Sclerosis (FALS; ref. 4), suggests that chronic and unrepaired oxidative damage occurring specifically in motor neurons could be a critical causative factor in ageing. To test this hypothesis, we generated transgenic Drosophila which express human SOD1 specifically in adult motorneurons. We show that overexpression of a single gene, SOD1, in a single cell type, the motorneuron, extends normal lifespan by up to 40% and rescues the lifespan of a short-lived Sod null mutant. Elevated resistance to oxidative stress suggests that the lifespan extension observed in these flies is due to enhanced RO metabolism. These results show that SOD activity in motorneurons is an important factor in ageing and lifespan determination in Drosophila.

Genetic and biochemical analysis of glutathione-S-transferase in the oxygen defense system of Drosophila melanogaster.

Aerobic organisms possess an array of enzymatic defense mechanisms against the toxic effects of active oxygen species. These include CuZn superoxide dismutase (CuZn SOD), catalase (CAT), and glutathione peroxidase (GPOX). Insects, however, lack an independent GPOX enzyme and instead rely on the activity of the more general detoxification enzyme, glutathione-S-transferase (GST), to carry out a peroxidase function. We report here the developmental profile of GST in Drosophila melanogaster and show that GST is induced by paraquat, a known free-radical generating agent. We also report that glutathione (GSH) depletion induced by administration of buthionine sulfoximine (BSO) selectively reduces the viability of mutants lacking CuZnSOD. By measuring GST specific activity in flies carrying deficiencies for the 87B region, we confirm an earlier report that this region contains active GST-encoding genes. Finally, through a biochemical analysis of representative alleles of known lethal complementation gene. The implications of these findings to the role of GSH and GST in D. melanogaster oxygen defense are discussed.