Project description:Translational Changes Upon Dietary Restriction in Drosophila

Project description:we performed proteome sequencing in Drosophila at day 7 (young) and day 42 (old) under dietary restriction (DR)and ad libitum (AL) conditions.

Project description:Translatome profiling of Drosophila intestinal enterocytes upon Dietary Restriction

Project description:Intestinal cancers are highly responsive to their nutrient environment. However, previous studies integrating nutrition into the network of cancer progression are largely inconsistent. We therefore investigated the effects of dietary restriction, which is the most consistently found beneficial nutritional intervention, on the development of intestinal stem cell tumors in a Drosophila melanogaster model. Submission to dietary restriction led to a decline in tumor mass and a morphological as well as functional rehabilitation of the intestine. Nevertheless, flies submitted to dietary restriction exhibited a drastically reduced lifespan due to substantial loss of body mass. To circumvent these destructive consequences, we applied a nutritional regimen consisting of alternating phases of dietary restriction and a fully nutritious diet. Strikingly, the recurrent diet reduced tumor mass and reinstated gut functionality to the same extend as continuous dietary restriction, while restoring the lifespan of tumor-bearing flies back to the level of healthy controls.

Project description:Dietary restriction is a nutritional intervention that consistently increases life span in animals. To identify alternative, more acceptable nutritional regimes that nevertheless extend life span, we used the fruit fly Drosophila melanogaster as a model. We tested if weekly recurring nutritional regimes composed of phases of ad libitum feeding and dietary restriction can increase life span. Short periods of dietary restriction (up to 2 days) followed by longer ad libitum phases increased life span only marginally, whereas regimes comprising longer contiguous periods (3 days and more) became clearly positive, reaching similar life span extensions as those seen if dietary restriction was applied persistently. Female flies were substantially more responsive to these interventions than males. The finding that a minimal period of 3-4 days of dietary restriction is required to induce robust life span extensions was mirrored by the observation that substantial physiological and transcriptional changes occurred in a similar temporal pattern. Moreover, these dietary restriction induced changes were also detectable after switching to ad libitum feeding. Among the physiological changes induced by these phases of dietary restriction, a reduced metabolic rate and a substantial and long-lasting reduction in insulin signaling were most compelling. Age associated molecular signatures comprising mechanisms that reduce insulin signaling showed up after longer periods of dietary restriction in the fly’s fat body, thus showing how molecular alterations transduce into life span related physiological changes.

Project description:Feeding resveratrol to Drosophila melanogaster extends lifespan. Studies of microarray show similarities between calorie/dietary restriction and resveratrol on both a gene expression and biological pathway level.

Project description:mRNA expression profiling of genes regulated by dietary restriction and SEK-1.

Project description:Transcription profiling by array of Drosophila females following dietary restriction, overexpression of sir2, and knockdown of p53

Project description:Calorie/Dietary Restriction and Resveratrol in Female Drosophila Melanogaster Head/Thorax

Project description:Dietary amino acids restriction extends lifespan in diverse species ranging from flies to mammals. The evolutionarily conserved serine/threonine kinase General Control Nonderepressible 2 (GCN2) is a key sensor of amino acid deficiency and has been implicated in lifespan regulation upon dietary restriction. However, the role of individual essential amino acids (EAA) in modulating organismal lifespan and the underlying molecular mechanisms through which EAA mediate these effects are only partially understood. We generated a novel Drosophila GCN2 null mutant and systematically analyzed its response to individual amino acid deficiency.