Project description:It is well appreciated that reactive oxygen species (ROS) are deleterious to mammals, including humans, especially when generated in abnormally large quantities from cellular metabolism. Whereas the mechanisms leading to the production of ROS are rather well delineated, the mechanisms underlying tissue susceptibility or tolerance to oxidant stress remain elusive. Through an experimental selection over many generations, we have previously generated Drosophila melanogaster flies that tolerate tremendous oxidant stress and have shown that the family of antimicrobial peptides (AMP) is over-represented in these tolerant flies. Furthermore, we have also demonstrated that overexpression of even one AMP at a time (e.g. Diptericin) allows wild type flies to survive much better in hyperoxia. In the current study, we used a number of experimental approaches to investigate the potential mechanisms underlying hyperoxia tolerance in flies with antimicrobial peptide overexpression. We demonstrate that flies with Diptericin overexpression resist oxidative stress by increasing antioxidant enzyme activities and preventing an increase in ROS level after hyperoxia. Depleting the GSH pool using buthionine sulfoximine limits fly survival, thus confirming that enhanced survival observed in these flies is related to improved redox homeostasis. We conclude that a) AMPs play an important role in tolerance to oxidant stress; b) overexpression of Diptericin changes the cellular redox balance between oxidant and antioxidant, and c) this change in redox balance plays an important role in survival in hyperoxia. Expression profiles of Drosophila melanogaster with anti-microbial peptide over-expression (experimental sample; n=3) and controls (UAS-AMP alone not crossed to da-GAL4; n=3) were determined using Affymetrix Drosophila Genome 2.0 Arrays.

Project description:MicroRNA precursors (pre-miRNAs) are short hairpin RNAs that are rapidly processed into mature microRNAs (miRNAs) in the cytoplasm. Due to their low abundance in cells, sequencing-based studies of pre-miRNAs have been limited. We successfully enriched for and deep sequenced pre-miRNAs in human cells by capturing these RNAs during their interaction with Argonaute (AGO) proteins. Using this approach, we detected > 350 pre-miRNAs in human cells and > 250 pre-miRNAs in a reanalysis of a similar study in mouse cells. We uncovered widespread trimming and non-templated additions to 3â?? ends of pre-miRNAs and mature miRNAs. Additionally, we identified novel AGO2-cleaved pre-miRNAs and created an index for microRNA precursor processing efficiency. This analysis revealed a subset of pre-miRNAs that produce low levels of mature miRNAs despite abundant precursors, including an annotated miRNA in the 5â?? UTR of the DiGeorge syndrome critical region 8 (Dgcr8) mRNA transcript. This led us to search for other AGO-associated stem-loops originating from other mRNA species, which identified hundreds of putative pre-miRNAs derived from mRNA sequences in both the mouse and human transcriptomes. Intriguingly, we found that iron responsive elements in ferritin heavy and light chain mRNAs are processed into AGO-associated stem-loops in both mouse and humans but do not produce functional small RNAs. In summary, we provide a wealth of information on mammalian pre-miRNAs, and identify novel microRNA and microRNA-like elements localized in mRNAs. pre-miRNA-seq and miRNA-seq from HEK293T cells. Reanalysis of HEK293T smRNA-seq, MEF pre-miRNA and MEF smRNA-seq (processed data for these Samples are linked below). The reanalyzed HEK293T Samples are from Series GSE66224 and consists of Samples GSM1617437 and GSM1617438. The reanalyzed MEF pre-miRNA and MEF smRNA-seq Samples were downloaded from European Nucleotide Archive (http://www.ebi.ac.uk/ena/) under the accession number PRJEB6756 (ERX525474 and ERX525475). RNA-seq analysis of HEK293T cells following knockdown of DGCR8, DROSHA or Luciferase.

Project description:Uridylation of hairpin-RNAs by Tailor confines the emergence of miRNAs in Drosophila

Project description:It is well appreciated that reactive oxygen species (ROS) are deleterious to mammals, including humans, especially when generated in abnormally large quantities from cellular metabolism. Whereas the mechanisms leading to the production of ROS are rather well delineated, the mechanisms underlying tissue susceptibility or tolerance to oxidant stress remain elusive. Through an experimental selection over many generations, we have previously generated Drosophila melanogaster flies that tolerate tremendous oxidant stress and have shown that the family of antimicrobial peptides (AMP) is over-represented in these tolerant flies. Furthermore, we have also demonstrated that overexpression of even one AMP at a time (e.g. Diptericin) allows wild type flies to survive much better in hyperoxia. In the current study, we used a number of experimental approaches to investigate the potential mechanisms underlying hyperoxia tolerance in flies with antimicrobial peptide overexpression. We demonstrate that flies with Diptericin overexpression resist oxidative stress by increasing antioxidant enzyme activities and preventing an increase in ROS level after hyperoxia. Depleting the GSH pool using buthionine sulfoximine limits fly survival, thus confirming that enhanced survival observed in these flies is related to improved redox homeostasis. We conclude that a) AMPs play an important role in tolerance to oxidant stress; b) overexpression of Diptericin changes the cellular redox balance between oxidant and antioxidant, and c) this change in redox balance plays an important role in survival in hyperoxia.

Project description:MicroRNAs (miRNAs) are small regulatory RNAs that derive from distinctive hairpin transcripts. To learn more about the miRNAs of mammals, we sequenced 60 million small RNAs from mouse brain, ovary, testes, embryonic stem cells, three embryonic stages, and whole newborns. Analysis of these sequences confirmed 387 annotated miRNA genes and identified 110 novel miRNA genes. Over 150 previously annotated miRNAs and hundreds of candidates failed to yield sequenced RNAs with miRNA-like features. Ectopically expressing these previously proposed miRNA hairpins also did not yield small RNAs, whereas ectopically expressing the confirmed and newly identified hairpins usually did yield small RNAs with the classical miRNA features, including dependence on the Drosha endonuclease for processing. These experiments, which suggest that previous estimates of conserved mammalian miRNAs were inflated, provide a substantially revised list of confidently identified mammalian miRNAs from which to infer the general features of mammalian miRNAs. Our analyses also revealed new aspects of miRNA biogenesis and modification, including tissue-specific strand preferences, sequential Dicer cleavage of a metazoan pre-miRNA, newly identified instances of miRNA editing, and evidence for widespread Lin28-like miRNA regulation.

Project description:A method for the long-term maintenance of germ-free flies was established using aseptic isolators. The methodology effectively and reliably yields large numbers of germ-free flies in homogeneous cultures. Germ-free flies exhibited increased lifespan (only female flies) and decreased egg production, markedly reduced fat storage, less midday sleep, and enhanced aggressiveness (male flies). Fructilactobacillus—a species of fly intestinal microbes—was re-colonized in germ-free flies, and these gnotobiotic flies were successfully maintained for numerous generations. The proteome of those flies were analyzed.

Project description:One of the critical substances that mammals highly regulate via the respiratory, cardiovascular and neurologic systems is O2. Both low and high O2 levels can induce major morbidities as well as mortality. Indeed, O2 has been often considered as both an elixir and a poison in humans. In current study, we have used an experimental selection approach to generate Drosophila strains that are tolerant to severe hyperoxic environment. Gene expression profiling is then applied to investigate the mechanisms underlying hyperoxia tolerance in the newly generated strains. 27 isogenic D. melanogaster Lines were pooled and following long-term selection over generations with increased oxygen level in the culture environment. The differences in gene expression were compared between adapted flies and generation matched naive controls by microarray.

Project description:Viral small RNAs from Drosophila melanogaster flies infected with FHVdeltaB2 or FHV.

Project description:Eukaryotic genome is compartmentalized into structural and functional domains. One of the concepts of higher order organization of chromatin posits that the DNA is organized in constrained loops that behave as independent functional domains. A predominantly ribo-proteinaceous nucleoskeleton, termed as Nuclear Matrix (NuMat) is proposed to provide the structural platform for attachment of these loops. The DNA sequence located at the base of the loops are known as the Matrix Attachment Regions (MARs). NuMat relates to all nuclear processes and has been shown to be cell type specific in composition. It is a biochemically defined structure and several protocols have been used to isolate the NuMat where some of the steps have been critically evaluated. In the present study we have looked into the dynamics of MARs when the isolation process is varied and also during embryonic development of D. melanogaster. Our results show that a subset of MARs termed here as “Core-MARs” are fixed and unalterable anchor points in the Drosophila genome as they remain associated with NuMat at all developmental stages and do not depend on the isolation procedure used. Core-MARs are abundant in the pericentromeric heterochromatin. On the other hand, MARs in the euchromatin are dynamic and reflect the transcriptomic profile of the developmental stage of the host cell. New MARs are generated by nuclear stabilization (a critical step in the isolation procedure), and during development, mostly at the paused RNA polymerase II (Pol II) promoters. Paused Pol II MARs depend on RNA transcription for NuMat association. RNase A treatment leads to collapse of the NuMat and loss of paused Pol II promoter MARs. Our data reveals the role of MARs in functional compartmentalization of D. melanogaster genome and adds to the current understanding of nuclear architecture and 3D organization of a functionally dynamic nucleus.

Project description:MicroRNAs (miRNAs) are small regulatory RNAs that derive from distinctive hairpin transcripts. To learn more about the miRNAs of mammals, we sequenced 60 million small RNAs from mouse brain, ovary, testes, embryonic stem cells, three embryonic stages, and whole newborns. Analysis of these sequences confirmed 387 annotated miRNA genes and identified 110 novel miRNA genes. Over 150 previously annotated miRNAs and hundreds of candidates failed to yield sequenced RNAs with miRNA-like features. Ectopically expressing these previously proposed miRNA hairpins also did not yield small RNAs, whereas ectopically expressing the confirmed and newly identified hairpins usually did yield small RNAs with the classical miRNA features, including dependence on the Drosha endonuclease for processing. These experiments, which suggest that previous estimates of conserved mammalian miRNAs were inflated, provide a substantially revised list of confidently identified mammalian miRNAs from which to infer the general features of mammalian miRNAs. Our analyses also revealed new aspects of miRNA biogenesis and modification, including tissue-specific strand preferences, sequential Dicer cleavage of a metazoan pre-miRNA, newly identified instances of miRNA editing, and evidence for widespread Lin28-like miRNA regulation. For miRNA discovery, small RNAs were sequenced from mouse brain, ovary, testes, three embryonic stages, and whole newborns; for ectopic over-expression assays, pre-miRNA hairpins and the surrounding regions were transfected into HEK293T, and the small RNA were sequenced from the transfected cells 39-48 hours after transfection.