Maria E. Giannakou

dFOXO-independent effects of reduced insulin-like signaling in drosophila

The insulin/insulin‐like growth factor‐like signaling (IIS) pathway in metazoans has evolutionarily conserved roles in growth control, metabolic homeostasis, stress responses, reproduction, and lifespan. Genetic manipulations that reduce IIS in the nematode worm Caenorhabditis elegans, the fruit fly Drosophila melanogaster, and the mouse have been shown not only to produce substantial increases in lifespan but also to ameliorate several age‐related diseases. In C. elegans, the multitude of phenotypes produced by the reduction in IIS are all suppressed in the absence of the worm FOXO transcription factor, DAF‐16, suggesting that they are all under common regulation. It is not yet clear in other animal models whether the activity of FOXOs mediate all of the physiological effects of reduced IIS, especially increased lifespan. We have addressed this issue by examining the effects of reduced IIS in the absence of dFOXO in Drosophila, using a newly generated null allele of dfoxo. We found that the removal of dFOXO almost completely blocks IIS‐dependent lifespan extension. However, unlike in C. elegans, removal of dFOXO does not suppress the body size, fecundity, or oxidative stress resistance phenotypes of IIS‐compromised flies. In contrast, IIS‐dependent xenobiotic resistance is fully dependent on dFOXO activity. Our results therefore suggest that there is evolutionary divergence in the downstream mechanisms that mediate the effects of IIS. They also imply that in Drosophila, additional factors act alongside dFOXO to produce IIS‐dependent responses in body size, fecundity, and oxidative stress resistance and that these phenotypes are not causal in IIS‐mediated extension of lifespan.

Role of dFOXO in lifespan extension by dietary restriction in Drosophila melanogaster: not required, but its activity modulates the response

Dietary restriction (DR) increases lifespan in diverse organisms. However, the mechanisms by which DR increases survival are unclear. The insulin/IGF‐like signaling (IIS) pathway has been implicated in the response to DR in some studies, while in others it has appeared to play little or no role. We used the fruitfly Drosophila melanogaster to investigate the responses to DR of flies mutant for the transcription factor dFOXO, the main transcription factor target of IIS. We found that lifespan extension by DR does not require dFOXO. However, flies with dFOXO overexpressed in the adult fat body showed an altered response to DR and behaved as though partially dietarily restricted. These results suggest that, although DR extends lifespan of flies in the absence of dFOXO, the presence of active dFOXO modulates the response to DR, possibly by modifying expression of its target genes, and may therefore mediate the normal response to DR.

Dynamics of the action of dFOXO on adult mortality in Drosophila

The insulin/insulin growth factor (IGF)‐like signaling (IIS) pathway has a conserved role in regulating lifespan in Caenorhabditis elegans, Drosophila and mice. Extension of lifespan by reduced IIS has been shown in C. elegans to require the key IIS target, forkhead box class O (FOXO) transcription factor, DAF‐16. dFOXO, the Drosophila DAF‐16 orthologue, is also an IIS target, and its overexpression in adult fat body increases lifespan. In C. elegans, IIS acts exclusively during adulthood to determine adult survival. We show here, using an inducible overexpression system, that in Drosophila continuous dFOXO overexpression in adult fat body reduces mortality rate throughout adulthood. We switched the IIS status of the flies at different adult ages and examined the effects of these switches on dFOXO expression and mortality rates. dFOXO protein levels were switched up or down by the inducible expression system at all ages examined. If IIS status is reversed early in adulthood, similar to the effects of another intervention that reduces adult mortality in Drosophila, dietary restriction (DR), there is a complete switch of subsequent mortality rate to that of flies chronically exposed to the new IIS regime. At this age, IIS thus acts acutely to determine risk of death. Mortality rates continued to respond to a switch in IIS status up to 4 weeks of adult age, but not thereafter. However, unlike DR, as IIS status was altered at progressively later ages, mortality rates showed incomplete switching and responded with progressively smaller changes. These findings indicate that alteration of expression levels of dFOXO may have declining effects on IIS status with age, that there could be some process that prevents or lessens the physiological response to a switch in IIS status or that, unlike DR, this pathway regulates aging‐related damage. The decreased mortality and increased lifespan of dFOXO overexpressing flies was uncoupled from any effect on female fecundity and from expression levels of Drosophila insulin‐like peptides in the brain.

Altered Patterns of Gene Expression in Arabidopsis Elicited by Cauliflower Mosaic Virus (CaMV) Infection and by a CaMV Gene VI Transgene

Cauliflower mosaic virus (CaMV) gene VI protein (P6) is an important determinant of symptom expression. Differential display polymerase chain reaction (PCR) was used to identify changes in gene expression in Arabidopsis elicited by a P6 transgene that causes a symptomatic phenotype. We used slot blot hybridization to measure the abundance of mRNAs complementary to 66 candidate PCR products in transgenic, CaMV-infected, and uninfected Arabidopsis plants. CaMV-infected and P6 transgenic plants showed broadly similar changes in abundance of mRNA species. In P6 transgenic plants we detected 18 PCR products that showed unambiguous changes in abundance plus another 15 that showed more limited changes (approximately twofold). CaMV-infected plants showed 17 unambiguous and 13 limited changes. Down-regulated species include those encoding a novel, phenol-like sulfotransferase, and a glycine-rich, RNA-binding protein. Up-regulated species included ones encoding an myb protein, glycine-rich and stress-inducible proteins, and a member of a previously unreported gene family. CaMV infection causes alterations in expression of many Arabidopsis genes. Transgene-mediated expression of P6 mimics virus infection in its effect on host gene expression, providing a potential mechanism for this process.

Expression of human uncoupling protein-3 in Drosophila insulin- producing cells increases insulin-like peptide (DILP) levels and shortens lifespan

Uncoupling proteins (UCPs) can dissipate mitochondrial protonmotive force by increasing the proton conductance of the inner membrane and through this effect could decrease ROS production, ameliorate oxidative stress and extend lifespan. We investigated whether ubiquitous, pan-neuronal or neurosecretory cell-specific expression of human UCP3 (hUCP3) in adult Drosophila melanogaster affected lifespan. Low, ubiquitous expression of hUCP3 at levels found in rodent skeletal muscle mitochondria did not affect proton conductance in mitochondria isolated from whole flies, but high pan-neuronal expression of hUCP3 increased the proton conductance of mitochondria isolated from fly heads. Expression of hUCP3 at moderate levels in adult neurons led to a marginal lifespan-extension in males. However, high expression of hUCP3 in neuronal tissue shortened lifespan. The life-shortening effect was replicated when hUCP3 was expressed specifically in median neurosecretory cells (mNSC), which express three of the Drosophila insulin-like peptides (DILPs). Expression of hUCP3 in the mNSC did not alter expression of dilp2, dilp3 or dilp5 mRNA, but led to increased amounts of DILP2 in fly heads. These data suggest that lowering mitochondrial coupling by high expression of hUCP3 alters mNSC function in a way that appears to increase DILP-levels in fly heads and lead to a concomitant decrease in lifespan.

Identification of novel modifiers of Aβ toxicity by transcriptomic analysis in the fruitfly

The strongest risk factor for developing Alzheimers Disease (AD) is age. Here, we study the relationship between ageing and AD using a systems biology approach that employs a Drosophila (fruitfly) model of AD in which the flies overexpress the human Aβ42 peptide. We identified 712 genes that are differentially expressed between control and Aβ-expressing flies. We further divided these genes according to how they change over the animals lifetime and discovered that the AD-related gene expression signature is age-independent. We have identified a number of differentially expressed pathways that are likely to play an important role in the disease, including oxidative stress and innate immunity. In particular, we uncovered two new modifiers of the Aβ phenotype, namely Sod3 and PGRP-SC1b.

Modeling Serpin Conformational Diseases in Drosophila melanogaster

Transgenic Drosophila melanogaster have been used to model both the physiological and pathological behavior of serpins. The ability to generate flies expressing serpins and to rapidly assess associated phenotypes contributes to the power of this paradigm. While providing a whole-organism model of serpinopathies the powerful toolkit of genetic interventions allows precise molecular dissection of important biological pathways. In this chapter, we summarize the contribution that flies have made to the serpin field and then describe some of the experimental methods that are employed in these studies. In particular, we will describe the generation of transgenic flies, the assessment of phenotypes, and the principles of how to perform a genetic screen.