Philip S. Hartman

Coenzyme Q10 can prolong C. elegans lifespan by lowering oxidative stress.

The mev-1 gene encodes cytochrome b, a large subunit of the Complex II enzyme succinate-CoQ oxidoreductase. The mev-1(kn1) mutants are hypersensitive to oxidative stress and age precociously, probably because of elevated superoxide anion production in mitochondria. Coenzyme Q (CoQ) is essential for the mitochondrial respiratory chain. Here, we show that CoQ(10) and Vitamin E extended the life span of wild-type Caenorhabditis elegans. Conversely, only CoQ(10) recovered the life shortening effects seen in mev-1. We also show that CoQ(10) but not Vitamin E reduced superoxide anion levels in wild type and mev-1. Another previously described phenotype of mev-1 animals is the presence of supernumerary apoptotic cells. We now demonstrate that CoQ(10) (but not Vitamin E) suppressed these supernumerary apoptoses. Collectively these data suggest that exogenously supplied CoQ(10) can play a significant anti-aging function. It may do so either by acting as an antioxidant to dismutate the free radical superoxide anion or by reducing the uncoupling of reactions during election transport that could otherwise result in superoxide anion production. The latter activity has not been ascribed to CoQ(10); however, it is known that conditions that uncouple electron transport reactions can lead to elevated superoxide anion production.

Age-related changes of mitochondrial structure and function in Caenorhabditis elegans

A number of observations have been made to examine the role that mitochrondrial energetics and superoxide anion production play in the aging of wild-type Caenorhabditis elegans. Ultrastructural analyses reveal the presence of swollen mitochondria, presumably produced by fusion events. Two key mitochondrial functions - the activity of two electron transport chain complexes and oxygen consumption - decreased as animals aged. Carbonylated proteins, one byproduct of oxidative stress, accumulated in mitochondria much more than in the cytoplasm. This is consistent with the notion that mitochondria are the primary source of endogenous reactive oxygen species. However, the level of mitochondrially generated superoxide anion did not change significantly during aging, suggesting that the accumulation of oxidative damage is not due to excessive production of superoxide anion in geriatric animals. In concert, these data support the notion that the mitochondrial function is an important aging determinant in wild-type C. elegans.

The p38 signal transduction pathway participates in the oxidative stress-mediated translocation of DAF-16 to Caenorhabditis elegans nuclei

Much attention has focused on the insulin-like signaling pathway in Caenorhabditis elegans because of its pivotal role in life-span determination and oxidative stress resistance. The daf-16 gene encodes a fork-head transcription factor that is negatively regulated by this insulin-signaling pathway. The DAF-16 protein is translocated to the nucleus when animals were subjected to oxidative stress in the form of paraquat. This oxidative stress-mediated translocation was blocked by mutation of the p38-related sek-1 (MAPKK) mutant and DAF-16 instead remained cytoplasmic. The fact that DAF-16 translocation by oxidative stress is epistatic to sek-1 suggests that oxidative stress mediates regulation of DAF-16 through activating the p38 signal transduction pathway upstream of daf-16 so as to mobilize DAF-16 to the nucleus and activate transcription.

Protein oxidation during aging of the nematode Caenorhabditis elegans.

The nematode Caenorhabditis elegans has proven a robust genetic model for studies of aging, including the roles of oxidative stress and protein damage. In this review, we focus on the genetics of select long-lived (e.g., age-1, daf-2, daf-16) and short-lived (e.g., mev-1) mutants that have proven useful in revealing the relationships that exist among oxidative stress, life span, and protein oxidation. The former are known to control an insulin/IGF-1-like pathway in C. elegans, while the latter affect mitochondrial function.

Effect of oxidative stress on translocation of DAF-16 in oxygen-sensitive mutants, mev-1 and gas-1 of Caenorhabditis elegans

Mutations in the mev-1 and gas-1 genes of the nematode Caenorhabditis elegans render animals hypersensitive to oxygen and paraquat, and lead to premature aging. We show that both mutants overproduce superoxide anion in isolated sub-mitochondrial particles, which probably explains their hypersensitivity to oxidative stress. The daf-16 gene encodes a fork-head transcription factor that is negatively regulated by an insulin-signaling pathway. In wild-type animals, the DAF-16 protein normally resides in the cytoplasm and only becomes translocated to nuclei upon activating stimuli such as oxidative stress. Conversely, DAF-16 resides constitutively in the nuclei of mev-1 and gas-1 mutants even under normal growth conditions. Supplementation of the antioxidant coenzyme Q(10) reversed this nuclear translocation of DAF-16. Since both gas-1 and mev-1 encode subunits of electron transport chain complexes, these data illustrate how mitochondrial perturbations can impact signal transduction pathways.

An endonuclease fromCaenorhabditis elegans: Partial purification and characterization

A deoxyribonuclease was partially purified from the free-living nematodeCaenorhabditis elegans. The DNase functioned as an endonuclease and introduced both single-strand nicks and double-strand breaks into DNA. The enzyme hydrolyzed double-stranded DNA seven times more rapidly than single-stranded DNA. DNase activity was not affected by the addition of divalent cations below 1mm but was inhibited at higher ionic concentrations. In addition, the enzyme was not inhibited in the presence of 10mm EDTA. The enzyme was inhibited by salt concentrations greater than 20mm. Three independent mutations in thenuc-1 gene were shown to reduce nuclease activity to less than 1% of that seen in wild-type organisms.

Enhancement of Oxidative Damage to Cultured Cells and Caenorhabditis elegans by Mitochondrial Electron Transport Inhibitors

The mechanisms that lead to mitochondrial damage under oxidative stress conditions were examined in primary and cultured cells as well as in the nematode Caenorhabditis elegans ( C. elegans ) treated simultaneously with electron transport inhibitors and oxygen gas. Oxygen loading enhanced the damage of PC 12 cells by thenoyltrifluoroacetone (TTFA, a complex II inhibitor), but did not by rotenone (a complex I inhibitor), antimycin (a complex III inhibitor), and sodium azide (a complex IV inhibitor). In primary hepatocytes, the enhancement was observed with the addition of sodium azide and rotenone, but not by TTFA or antimycin. In the nematode, only rotenone and TTFA enhanced the sensitivity under hyperoxia. These results demonstrate that highly specific inhibitors of electron transport can induce oxygen hypersensitivity in cell levels such as PC 12 cells and primary hepatocytes, and animal level of C. elegans . In addition the cell damage is different dependent on cell type and organism.

Oxidative stress pretreatment increases the X-radiation resistance of the nematode Caenorhabditis elegans

Pre-exposure of wild-type Caenorhabditis elegans to oxygen conferred a protective effect against the lethality imposed by subsequent X-irradiation. In contrast, two mutants (rad-1 and rad-2) that are UV and ionizing radiation hypersensitive but not oxygen sensitive, did not exhibit this adaptive response. To explore the molecular basis of protection, the expression of several key genes was examined using Northern blot analyses to measure mRNA levels. In the wild-type, expression of the heat shock protein genes, hsp16-1 and hsp16-48, increased dramatically after incubation under high oxygen. Expression of two superoxide dismutase genes (sod-1 and sod-3) was relatively unaffected. Unlike the wild-type, the basal levels of these four genes were significantly lower in the rad-1 and rad-2 mutants under atmospheric conditions. These genes were partially induced in response to oxidative stress. These data suggest that at least a portion of the hypersensitive phenotype of rad-1 and rad-2 may be attributed to inappropriate gene expression.

UV IRRADIATION OF WILD TYPE AND RADIATION‐SENSITIVE MUTANTS OF THE NEMATODE Caenorhabditis elegans: FERTILITIES, SURVIVAL, AND PARENTAL EFFECTS

Abstract— Survival after UV irradiation was examined in wild type and four radiation‐sensitive (rad) mutants of Caenorhabditis elegans. Synchronous populations were employed to assess radiation sensitivities at different developmental stages. In addition, the effects of irradiation on male and hermaphrodite fertilities were measured. Wild‐type sensitivity was maximal early in embryogenesis. Different age‐dependent patterns of radiation sensitivity were obtained with the rad mutants. The effects of parental genotype were also tested. A parental wild‐type allele was capable of quickly elevating the radiation resistance of embryos derived from homozygous rad hermaphrodites. In a second parental‐effect test, homozygous rad embryos displayed greater radiation resistance when derived from heterozygous rather than homozygous hermaphrodites. The results indicate that radiation sensitivity in this metazoan is determined by complex interactions of gene products.

Mitochondrial reactive oxygen species generation by the SDHC V69E mutation causes low birth weight and neonatal growth retardation.

We have previously demonstrated that excessive mitochondrial reactive oxygen species caused by mutations in the SDHC subunit of Complex II resulted in premature death in C. elegans and Drosophila, tumors in mouse cells and infertility in transgenic mice. We now report the generation and initial characterization of conditional transgenic mice (Tet-mev-1) using our uniquely developed Tet-On/Off system, which equilibrates transgene expression to endogenous levels. The mice experienced mitochondrial respiratory chain dysfunction that induced reactive oxygen species overproduction. The mitochondrial oxidative stress resulted in excessive apoptosis leading to low birth weight and growth retardation in the neonatal developmental phase in Tet-mev-1 mice.