Metallothioneins and resistance to cadmium poisoning in Drosophila cells

Toxicity of cadmium on Drosophila cell lines has been studied. Maximal tolerance for cadmium chloride is 10 microM. Metallothioneins are induced in Drosophila cells following cadmium addition. A stable cadmium resistant cell line (Cd R200) has been selected starting from the haploid D clone. The Cd R200 cells are diploid and display metallothionein levels 22 times higher than cells of the original line fully induced with cadmium. The 200 microM CdCl2 tolerance upper limit in Cd R200 line is overcome if L-cysteine is supplemented to the medium. It is thus possible, in the presence of 5 mM L-cysteine, to select cells able to resist 800 microM CdCl2. These cells produce 4 times more metallothioneins than Cd R200 cells.     

Interactions of Oxygen at High Pressure and Radiation in Drosophila

Oxygen at high pressure (OHP) and X-irradiation can interact in the fruit fly Drosophila melanogaster to potentiate toxic actions characteristic of one agent alone. 1000 kvp X-irradiation in doses of 30, 60, and 75 kr accelerated the acute immobilization of young male Drosophila by oxygen at 7.8 atm, up to rates twice that observed with such oxygen pressure alone. X-irradiation alone in these dosages did not acutely immobilize the Drosophila. X-irradiation during exposure to 7.8 atm pO₂ was more effective and consistent in producing this potentiation than was X-irradiation that preceded exposure to OHP. Acute OHP toxicity in young female Drosophila was not potentiated by 75 kr of X-irradiation. On the other hand, shortening of the life span of young male Drosophila by the above doses of X-irradiation was augmented significantly by a concurrent 40 min exposure to OHP (which alone did not significantly decrease life span). This shows, for the first time, that oxygen can affect not only the acute effects of radiation, but also the residual irreversible effects indicated by the life span shortening.     

Oxygen regulation of airway branching in Drosophila is mediated by branchless FGF.

The Drosophila tracheal (respiratory) system is a tubular epithelial network that delivers oxygen to internal tissues. Sprouting of the major tracheal branches is stereotyped and controlled by hard-wired developmental cues. Here we show that ramification of the fine terminal branches is variable and regulated by oxygen, and that this process is controlled by a local signal or signals produced by oxygen-starved cells. We provide evidence that the critical signal is Branchless (Bnl) FGF, the same growth factor that patterns the major branches during embryogenesis. During larval life, oxygen deprivation stimulates expression of Bnl, and the secreted growth factor functions as a chemoattractant that guides new terminal branches to the expressing cells. Thus, a single growth factor is reiteratively used to pattern each level of airway branching, and the change in branch patterning results from a switch from developmental to physiological control of its expression.     

Oxygen poisoning of NAD biosynthesis: a proposed site of cellular oxygen toxicity.

Quinolinate phosphoribosyl transferase was rapidly inactivated in $\text{Escherichia}\text{coli}$ exposed to hyperbaric oxygen. The enzyme is essential for de novo biosynthesis of NAD in $\text{E.}\text{coli}$ and man. Because of its sensitivity and essentiality, inactivation of this enzyme is proposed as a significant mechanism of cellular oxygen toxicity. Niacin which enters the NAD biosynthetic pathway below the oxygen-poisoned enzyme provided significant protection against the decrease in pyridine nucleotides and the growth inhibition from hyperoxia in $\text{E.}\text{coli}$ and could be useful in cases of human oxygen poisoning.     

Heterozygous Mutation of Opa1 in Drosophila Shortens Lifespan Mediated through Increased Reactive Oxygen Species Production

Optic atrophy 1 (OPA1) is a dynamin-like GTPase located in the inner mitochondrial membrane and mutations in OPA1 are associated with autosomal dominant optic atrophy (DOA). OPA1 plays important roles in mitochondrial fusion, cristae remodeling and apoptosis. Our previous study showed that dOpa1 mutation caused elevated reactive oxygen species (ROS) production and resulted in damage and death of the cone and pigment cells in Drosophila eyes. Since ROS-induced oxidative damage to the cells is one of the primary causes of aging, in this study, we examined the effects of heterozygous dOpa1 mutation on the lifespan. We found that heterozygous dOpa1 mutation caused shortened lifespan, increased susceptibility to oxidative stress and elevated production of ROS in the whole Drosophila. Antioxidant treatment partially restored lifespan in the male dOpa1 mutants, but had no effects in the females. Heterozygous dOpa1 mutation caused an impairment of respiratory chain complex activities, especially complexes II and III, and reversible decreased aconitase activity. Heterozygous dOpa1 mutation is also associated with irregular and dysmorphic mitochondria in the muscle. Our results, for the first time, demonstrate the important role of OPA1 in aging and lifespan, which is most likely mediated through augmented ROS production.     

Organophosphate poisoning in marmosets

Due to faulty use of a chlorpyriphos-diazinon combination as a pesticide within a laboratory animal house, 19 marmosets of 2 species (Saguinus fuscicollis and Callithrix jacchus) of 98 at risk died from organophosphorous poisoning (19%) mortality). The clinical signs were those of cholinesterase inhibitors. The morphological lesions consisted predominantly of haemorrhages in several organs, particularly the CNS, and of bone marrow necroses.