Your search keyword '"Nemoto, Shino"' showing total 3 results

1. The Mammalian Longevity-associated Gene Product p66shc Regulates Mitochondrial Metabolism.

Author

Nemoto, Shino, Combs, Christian A., French, Stephanie, Bong-Hyun Ahn, Fergusson, Maria M., Balaban, Robert S., and Finkel, Toren

Subjects

*BLOOD testing, *LABORATORY mice, *MITOCHONDRIA, *FIBROBLASTS, *RODENTS, *BIOCHEMISTRY

Abstract

Previous studies have determined that mice with a homozygous deletion in the adapter protein p66shc have an extended life span and that cells derived from these mice exhibit lower levels of reactive oxygen species. Here we demonstrate that a fraction of p66shc localizes to the mitochondria and that p66shc-/- fibroblasts have altered mitochondrial energetics. In particular, despite similar cytochrome content, under basal conditions, the oxygen consumption of spontaneously immortalized p6shc-/- mouse embryonic fibroblasts were lower than similarly maintained wild type cells. Differences in oxygen consumption were particularly evident under chemically uncoupled conditions, demonstrating that p66shc-/- cells have a reduction in both their resting and maximal oxidative capacity. We further demonstrate that reconstitution of p66shc expression in p66shc-/- cells increases oxygen consumption. The observed defect in oxidative capacity seen in p66shc-/- cells is partially offset by augmented levels of aerobic glycolysis. This metabolic switch is manifested by p66shc-/- cells exhibiting an increase in lactate production and a stricter requirement for extracellular glucose in order to maintain intracellular ATP levels. In addition, using an in vivo NADH photobleaching technique, we demonstrate that mitochondrial NADH metabolism is reduced in p6shc-/- cells. These results demonstrate that p66shc regulates mitochondrial oxidative capacity and suggest that p66shc may extend life span by repartitioning metabolic energy conversion away from oxidative and toward glycolytic pathways. [ABSTRACT FROM AUTHOR]

Published

2006

2. Mitochondria, Oxidants, and Aging.

Author

Balaban, Robert S., Nemoto, Shino, and Finlel, Toren

Subjects

*AGING, *REACTIVE oxygen species, *CELL culture, *DEVELOPMENTAL biology, *BIOCHEMISTRY, *LIFE sciences

Abstract

The tree radical theory of aging postulates that the production of intracellular reactive oxygen species is the major determinant of life span. Numerous cell culture, invertebrate, and mammalian models exist that lend support to this half-century-old hypothesis. Here we review the evidence that both supports and conflicts with the free radical theory and examine the growing link between mitochondrial metabolism, oxidant formation, and the biology of aging. [ABSTRACT FROM AUTHOR]

Published

2005

3. Nutrient Availability Regulates SIRT 1 Through a Forkhead-Dependent Pathway.

Author

Nemoto, Shino, Fergusson, Maria M., and Finkel, Toren

Subjects

*GENETIC transcription, *TRANSCRIPTION factors, *BIOCHEMISTRY, *DEVELOPMENTAL biology, *PROTEINS, *CELLS

Abstract

Nutrient availability regulates life-span in a wide range of organisms. We demonstrate that in mammalian cells, acute nutrient withdrawal simultaneously augments expression of the SIRT1 deacetylase and activates the Forkhead transcription factor Foxo3a. Knockdown of Foxo3a expression inhibited the starvation-induced increase in SIRT1 expression. Stimulation of SIRT1 transcription by FoxoBa was mediated through two p53 binding sites present in the SIRT1 promoter, and a nutrient-sensitive physical interaction was observed between Foxo3a and p53. SIRT1 expression was not induced in starved p53-deficient mice. Thus, in mammalian cells, p53, Foxo3a, and SIRT1, three proteins separately implicated in aging, constitute a nutrient-sensing pathway. [ABSTRACT FROM AUTHOR]

Published

2004