Project description:We aimed to elucidate the mechanism by which retrotransposon (RT) knockdown extends female lifespan in drosophila. To do so we compared two, single RT (412 and Roo) shRNA knockdowns (KD) to a scrambled hairpin control.

Project description:H4K16ac activates retrotransposons and contributes to their cis regulatory function

Project description:Aging is characterized by a gradual decline in protein homeostasis. However, how protein dynamics changes with normal aging and in disease is less well understood. Here, we systemically characterize age-modulated proteome in Drosophila, from head and muscle tissues of somatic cells, and the testis as reproductive tissue.

Project description:This SuperSeries is composed of the following subset Series: GSE24992: Drosophila brain microRNA expression with age: miRNA profiling GSE25007: Drosophila brain gene expression with age: mRNA profiling GSE25008: Drosophila brain gene expression between wildtype and miR-34 null flies Refer to individual Series. Aging is the most prominent risk factor for human neurodegenerative disease, but underlying mechanisms that connect two processes are less well characterized. With age, the brain undergoes functional decline and perhaps degeneration. Such decline may not just contribute to normal aging, but also enhance susceptibility to and progression of age-related neurodegenerative diseases. Therefore, defining intrinsic factors and pathways that underline the normal integrity of the adult nervous system may lead to insights that potentially link aging and neurodegeneration. Here, we report a highly conserved microRNA (miRNA), miR-34, as a modulator of aging and neurodegeneration. Using Drosophila, we show that fly miR-34 expression is brain-enriched and strikingly upregulated with age. Functional studies reveal that, whereas animals without miR-34 are normal as young adults, upon aging, they gradually show late-onset deficits characteristic of accelerated brain aging; these include a transcriptional signature of aged animals, coupled with rapid functional decline, loss of brain integrity, followed by a catastrophic decline in adult viability. Moreover, upregulation of miR-34 protects against neurodegeneration induced by pathogenic human polyglutamine (polyQ) disease protein. We next reveal a dramatic effect of miR-34 to silence the Eip74EF gene of steroid hormone pathways in the adult, which is crucial to maintain the normal aging. Collectively, these data define a miR-34-mediated mechanism that specifically affects long-term integrity of the adult nervous system. miR-34 function in Drosophila may thus present a link that functionally connects aging and neurodegeneration. Our studies implicate essential roles of miRNA- dependent pathways in maintenance of the adult brain, disease pathogenesis and healthy aging.

Project description:RNAseq of Aging Drosophila ISCs

Project description:Wild-type Drosophila melanogaster expressing nuclear GFP-KASH fusion protein in photoreceptors for cell type-specific gene expression profiling (Rh1-Gal4>UAS-GFPKASH ; Genotype = w1118;; P{w+mC=[UAS-GFP-Msp300KASH}attP2, P{ry+t7.2=rh1-GAL4}3, ry506) were raised in 12:12h light:dark cycle at 25°C. Flies were aged for 10 or 40 days post-eclosion, and eyes were harvested from male flies for global quantitative proteomic analysis. Significantly changed proteins were identified that may contribute to age-associated retinal degeneration and loss of visual function in the aging Drosophila eye.

Project description:Acetylome and proteome of WT (5905), gcn5 loss-of-function, and GCN5 overexpression Drosophila at age of 3d Acetylome and proteome of WT (5905) Drosophila during aging (at age of 3d, 15d, 30d, and 45d)

Project description:H4K16ac activates retrotransposons and contributes to their cis regulatory function [RNA-seq]

Project description:H4K16ac activates retrotransposons and contributes to their cis regulatory function [CUT&TAG]

Project description:H4K16ac activates retrotransposons and contributes to their cis regulatory function [ATAC-seq]