It has been proposed that uric acid is an important scavenger ofdeleterious oxygen radicals in biological systems [Ames, B. N., Cathcart, R., Schwiers, E. & Hochstein, P. (1981) ide dismutase are synthetic lethals, which are unable to complete metamorphosis under normal growth conditions. These experiments demonstrate unambiguously the importance of urate in oxygen defense in vivo and support our earlier proposal that the molybdoenzyme genetic system plays a critical role in oxygen defense in Drosophila. They also form the basis for our proposal that metamorphosis in Drosophila imposes a crisis of oxygen stress on the developing imago against which uric acid plays an important organ-specific defense. Finally, the results provide a basis for understanding the syndrome of phenotypes, including the hallmark dull brown eye color, which characterizes mutants of this classic genetic system of Drosophila.Ground-state molecular oxygen (02) is required for aerobic respiration, a process through which it normally undergoes complete tetravalent reduction to H20. However, partially reduced and highly reactive oxygen species [superoxide (O°), hydrogen peroxide, (H202), the hydroxyl radical, (OH-), and singlet oxygen (01)] are also formed as byproducts of normal aerobic metabolism and by the natural proclivity of dioxygen to abstract electrons from a variety of metabolic reactions. The biological consequences of exposure to active oxygen species originate in their reactivity with a variety of important biomolecules including nucleic acids, proteins, carbohydrates, and lipids. Many of the products of these reactions are cytotoxic, mutagenic, and carcinogenic and may be lethal to the organism. These reactions have been widely implicated in the etiology of many diseases and in the overall processes of normal cellular senescence and organismal aging (for a review, see ref.
Mutants of Drosophila melanogaster that lack Cu/Zn superoxide dismutase or urate are hypersensitive to reactive oxygen species (ROS) generated in vivo by the redox-cycling agent paraquat. We have subsequently employed paraquat as a selective agent to identify adult viable mutants potentially defective in other, perhaps unknown, components of ROS metabolism. Paraquat screening of ethyl methanesulfonate-induced second- and third-chromosome mutations yielded 24 paraquat hypersensitive mutants. Two mutants were identified as being new alleles of the previously identified doublesex (dsx) and pink (p) genes. The remainder of the mutations identified previously undescribed genes, including one second chromosome paraquat hypersensitive mutant that was found to exhibit shaking legs, abdomen pulsations, and body shuddering under ether anaesthesia. This recessive mutation was mapped to the polytene chromosome region of 48A5-48B2 and defines a new gene we named quiver (qvr). This mutation is similar in phenotype to the Shaker (Sh), ether-a-gogo (eag), and Hyperkinetic (Hk) mutations, all of which affect potassium channel function in D. melanogaster.
Null mutants for Cu/Zn superoxide dismutase (CuZnSOD)
Constitutive heterochromatic regions of chromosomes are those that remain condensed through most or all of the cell cycle. In Drosophila melanogaster, the constitutive heterochromatic regions, located around the centromere, contain a number of gene loci, but at a much lower density than euchromatin. In the autosomal heterochromatin, the gene loci appear to be unique sequence genes interspersed among blocks of highly repeated sequences. Euchromatic genes do not function well when brought into the vicinity of heterochromatin (position-effect variegation). We test the possibility that the blocks of centromeric heterochromatin provide an environment essential for heterochromatic gene function. To assay directly the functional requirement of autosomal heterochromatic genes to reside in heterochromatin, the rolled (rl) gene, which is normally located deep in chromosome 2R heterochromatin, was relocated within small blocks of heterochromatin to a variety of euchromatic positions by successive series of chromosomal rearrangements. The function of the rl gene is severely affected in rearrangements in which the rl gene is isolated in a small block of heterochromatin, and these position effects can be reverted by rearrangements which bring the rl gene closer to any large block of autosomal or X chromosome heterochromatin. There is some evidence that five other 2R heterochromatic genes are also affected among these rearrangements. These findings demonstrate that the heterochromatic genes, in contrast to euchromatic genes whose function is inhibited by relocation to heterochromatin, require proximity to heterochromatin to function properly, and they argue strongly that a major function of the highly repeated satellite DNA, which comprises most of the heterochromatin, is to provide this heterochromatic environment.
The Su(var)2-5 locus, an essential gene in Drosophila, encodes the heterochromatin-associated protein HP1. Here, we show that the Su(var)2-5 lethal period is late third instar. Maternal HP1 is still detectable in first instar larvae, but disappears by third instar, suggesting that developmentally late lethality is probably the result of depletion of maternal protein. We demonstrate that heterochromatic silencing of a normally euchromatic reporter gene is completely lost by third instar in zygotically HP1 mutant larvae, implying a defect in heterochromatin-mediated transcriptional regulation in these larvae. However, expression of the essential heterochromatic genes rolled and light is reduced in Su(var)2-5 mutant larvae, suggesting that reduced expression of essential heterochromatic genes could underlie the recessive lethality of Su(var)2-5 mutations. These results also show that HP1, initially recognized as a transcriptional silencer, is required for the normal transcriptional activation of heterochromatic genes.
Null mutants for Cu/Zn superoxide dismutase (CuZnSOD) in Drosophila melanogaster are male sterile, have a greatly reduced adult life span, and are hypersensitive to paraquat. We have introduced a synthetic bovine CuZnSOD transgene under the transcriptional control of the D. melanogaster 5C actin promoter into a CuZnSOD-null mutant of D. melanogaster. This was carried out by P-element-mediated transformation of the Drosophila-bovine CuZnSOD transgene into a CuZnSOD+ recipient strain followed by genetic crossing of the transgene into a strain carrying the CuZnSOD-null mutation, cSODn108. The resulting transformants express bovine CuZnSOD exclusively to about 30% of normal Drosophila CuZnSOD levels. Expression of the Drosophila-bovine CuZnSOD transgene in the CuZnSOD-null mutant rescues male fertility and resistance to paraquat to apparently normal levels. However, adult life span is restored to only 30% of normal, and resistance to hyperoxia is 90% of that found in control flies. This striking differential restoration of pleiotropic phenotypes could be the result of a threshhold of CuZnSOD expression necessary for normal male fertility and resistance to the toxicity of paraquat or hyperoxia which is lower than the threshold required to sustain a normal adult life span. Alternatively, the differential rescue of fertility, resistance to active oxygen, and life span might indicate different cell-specific transcriptional requirements for these functions which are normally provided by the control elements of the native CuZnSOD gene but are only partly compensated for by the transcriptional control elements of the actin 5C promoter.
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