Project description:Comparison of wild type and heterozygote and homozygote chico mutants ( Clancy, et al. Extension of Life-Span by Loss of CHICO, a Drosophila Insulin Receptor Substrate Protein. Science 292 (5514), 104.) on Affymetrix Drosophila2 GeneChip. The flies (Drosophila melanogaster) are 7 day old adult females.

Project description:Chronic early life stress increases adult susceptibility to numerous health problems linked to chronic inflammation. One way that this may occur is via glucocorticoid-induced developmental programming. To gain insight into such programming, we treated zebrafish embryos with cortisol and examined the effects on adults. In adulthood, the treated fish maintained elevated basal cortisol levels in the absence of exogenous cortisol, and constitutively mis-expressed genes involved in defense response and its regulation. Adults derived from cortisol-treated embryos displayed defective tailfin regeneration, heightened basal expression of pro-inflammatory genes, and failure to appropriately regulate those genes following injury or immunological challenge. These results support the hypothesis that chronically elevated glucocorticoid signaling early in life directs development of a pro-inflammatory adult phenotype, at the expense of immunoregulation and somatic regenerative capacity.

Project description:Chronically activated JAK/STAT signaling leads to several lung diseases, including lung cancer, asthma, and chronic obstructive pulmonary disease. We used the fruit fly Drosophila melanogaster to elucidate the molecular processes which transform elevated JAK/STAT signaling in airway epithelial cells into pathology.

Project description:Genome-wide profiling of rhythmic gene expression has offered new avenues for studying the contribution of circadian clock to diverse biological processes. Sleep has been considered one of the most important physiological processes that are regulated by the circadian clock, however, the effects of chronic sleep loss on rhythmic gene expression remain poorly understood. In the present study, we exploited Drosophila sleep mutants insomniac1 (inc1) and wide awakeD2 (wakeD2) as models for chronic sleep loss. We profiled the transcriptomes of heads collected from 4-week-old wild type flies, inc1 and wakeD2 at timepoints around the clock. Analysis of gene oscillation revealed a substantial loss of rhythmicity in inc1 and wakeD2 compared to wild type flies, with most of the affected genes common to both mutants. The disruption of gene oscillation was not due to changes in average gene expression levels. We also identified a subset of genes whose loss of rhythmicity was shared among animals with chronic sleep loss and old flies, suggesting a contribution of aging to chronic, sleep-loss-induced disruption of gene oscillation.

Project description:Cell type specific gene expression profiling was performed with adult Drosophila photoreceptors. Two genotypes were compared: ninaE wild type control and ninaEG69D/+ mutants that have chronic endoplasmic reticulum stress. To specifically isolate RNAs from these cell types, we drove nuclear envelope-localized EGFP::Msp300KASH expression with the photoreceptor specific Rh1-Gal4 driver. Anti-GFP beads were used to isolate the nuclei from those adult fly photoreceptor cells. Novaseq was used to perform RNA-seq.

Project description:Chronic early life stress increases adult susceptibility to numerous health problems linked to chronic inflammation. One way that this may occur is via glucocorticoid-induced developmental programming. To gain insight into such programming, we treated zebrafish embryos with cortisol and examined the effects on adults. In adulthood, the treated fish maintained elevated basal cortisol levels in the absence of exogenous cortisol, and constitutively mis-expressed genes involved in defense response and its regulation. Adults derived from cortisol-treated embryos displayed defective tailfin regeneration, heightened basal expression of pro-inflammatory genes, and failure to appropriately regulate those genes following injury or immunological challenge. These results support the hypothesis that chronically elevated glucocorticoid signaling early in life directs development of a pro-inflammatory adult phenotype, at the expense of immunoregulation and somatic regenerative capacity. 30 samples total were analyzed. 9 caudal fins samples (0, 2 and 4dpa), 3 blood samples and 3 muscle samples from adults exposed to DMSO control as embryos. 9 caudal fins samples (0, 2 and 4dpa), 3 blood samples and 3 muscle samples from adults exposed to cortisol (1 micromolar) as embryos.

Project description:This SuperSeries is composed of the following subset Series: GSE36533: Transcriptomic analysis of the woodchuck model of chronic hepatitis B: Liver gene expression in uninfected, resolved and chronically infected woodchucks GSE36541: Transcriptomic analysis of the woodchuck model of chronic hepatitis B: Kidney gene expression in uninfected, resolved and chronically infected woodchucks GSE36544: Transcriptomic analysis of the woodchuck model of chronic hepatitis B: Spleen gene expression in uninfected, resolved and chronically infected woodchucks GSE36545: Transcriptomic analysis of the woodchuck model of chronic hepatitis B: Liver gene expression in tumor and non-tumor samples from chronically infected woodchucks Refer to individual Series

Project description:Sleep is a conserved physiological process, and sleep loss typically imposes negative effects on animal health. However, natural short sleepers, who sleep less without the usual negative effects of sleep deprivation, exist in the human population. One example are individuals that possess rare genetic mutations in the human dec2 gene; these individuals sleep on average ~6hrs/day rather than the typical 8hrs/day. Like many natural short sleepers, humans harboring the dec2P384R mutation do not exhibit any obvious adverse phenotypes typically associated with sleep loss, suggesting that these individuals may require less total sleep/day to achieve the same physiological outcomes. Potentially, the dec2P384R mutation could activate compensatory mechanisms that allow these individuals to thrive with less sleep. To test this directly, we used a dec2P384R short sleep Drosophila model to understand the effects of the dec2P384R mutation on animal health and dissect the genetic mechanisms that might drive these physiological changes. We found that expression of the mammalian dec2P384R mutation in fly sleep neurons was sufficient to mimic the short sleep phenotype observed in mammals. Remarkably, dec2P384R lived significantly longer with improved health and memory despite having a short sleep phenotype. The improved physiological effects in dec2P384R mutants were enabled, in part, by enhanced mitochondrial fitness and upregulation of multiple stress response pathways. Moreover, we provide evidence that the improved health in dec2P384R mutants may also contribute to the short sleep phenotype, and this may extend to other pro-longevity mutants.

Project description:Gene expression profiling was carried out on peripheral blood mononuclear cell mRNA samples collected from 93 older adults participating in the Chicago Health Aging and Social Relations Study (CHASRS). The primary research question is whether gene expression differs in participants who are chronically lonely. Keywords: Risk prediction Gene expression profiling was carried out on peripheral blood mononuclear cell mRNA samples collected from 93 older adults participating in the Chicago Health Aging and Social Relations Study (CHASRS). The primary research question is whether gene expression differs in participants who are chronically lonely.

Project description:In gonadal tissues, the Piwi-interacting (piRNA) pathway preserves genomic integrity by employing 23-29nt small RNAs complexed with argonaute proteins to suppress parasitic mobile sequences of DNA called transposable elements (TEs). While recent evidence suggests that the piRNA pathway may be present in select somatic cells outside the gonads, the role of a non-gonadal somatic piRNA pathway is not well characterized. Here we report a functional somatic piRNA pathway in the adult Drosophila fat body including the presence of the piRNA effector protein Piwi and canonical 23-29nt long TE-mapping piRNAs. piwi mutants exhibit depletion of fat body piRNAs, increased TE mobilization, increased levels of DNA damage, and reduced lipid stores. These mutants are starvation-sensitive, immunologically compromised, and short-lived, all phenotypes associated with compromised fat body function. These findings demonstrate the presence of a functional non-gonadal somatic piRNA pathway in the adult fat body that impacts normal metabolism and overall organismal health.