Age-driven modulation of tRNA-derived fragments in Drosophila and their potential targets

BackgroundDevelopment of sequencing technologies and supporting computation enable discovery of small RNA molecules that previously escaped detection or were ignored due to low count numbers. While the focus in the analysis of small RNA libraries has been primarily on microRNAs (miRNAs), recent studies have reported findings of fragments of transfer RNAs (tRFs) across a range of organisms.ResultsHere we describe Drosophila melanogaster tRFs, which appear to have a number of structural and functional features similar to those of miRNAs but are less abundant. As is the case with miRNAs, (i) tRFs seem to have distinct isoforms preferentially originating from 5’ or 3’ end of a precursor molecule (in this case, tRNA), (ii) ends of tRFs appear to contain short “seed” sequences matching conserved regions across 12 Drosophila genomes, preferentially in 3’ UTRs but also in introns and exons; (iii) tRFs display specific isoform loading into Ago1 and Ago2 and thus likely function in RISC complexes; (iii) levels of loading in Ago1 and Ago2 differ considerably; and (iv) both tRF expression and loading appear to be age-dependent, indicating potential regulatory changes from young to adult organisms.ConclusionsWe found that Drosophila tRF reads mapped to both nuclear and mitochondrial tRNA genes for all 20 amino acids, while previous studies have usually reported fragments from only a few tRNAs. These tRFs show a number of similarities with miRNAs, including seed sequences. Based on complementarity with conserved Drosophila regions we identified such seed sequences and their possible targets with matches in the 3’UTR regions. Strikingly, the potential target genes of the most abundant tRFs show significant Gene Ontology enrichment in development and neuronal function. The latter suggests that involvement of tRFs in the RNA interfering pathway may play a role in brain activity or brain changes with age.ReviewersThis article was reviewed by Eugene Koonin, Neil Smalheiser and Alexander Kel.

[1]  Lisa Fish,et al.  Endogenous tRNA-Derived Fragments Suppress Breast Cancer Progression via YBX1 Displacement , 2015, Cell.

[2]  Huifu Guo,et al.  PAR-1 Kinase Phosphorylates Dlg and Regulates Its Postsynaptic Targeting at the Drosophila Neuromuscular Junction , 2007, Neuron.

[3]  Rogerio Margis,et al.  Description of plant tRNA-derived RNA fragments (tRFs) associated with argonaute and identification of their putative targets , 2013, Biology Direct.

[4]  Pavel Ivanov,et al.  tRNA fragments in human health and disease , 2014, FEBS letters.

[5]  Kyle Kai-How Farh,et al.  Expanding the microRNA targeting code: functional sites with centered pairing. , 2010, Molecular cell.

[6]  P. Jin,et al.  MicroRNA-277 Modulates the Neurodegeneration Caused by Fragile X Premutation rCGG Repeats , 2012, PLoS genetics.

[7]  J. G. Patton,et al.  Transcriptome-wide analysis of small RNA expression in early zebrafish development. , 2012, RNA.

[8]  Andrea Califano,et al.  tRNA-derived microRNA modulates proliferation and the DNA damage response and is down-regulated in B cell lymphoma , 2013, Proceedings of the National Academy of Sciences.

[9]  Z. Weng,et al.  Sorting of Drosophila small silencing RNAs partitions microRNA* strands into the RNA interference pathway. , 2010, RNA.

[10]  Ammar S Naqvi,et al.  The Exoribonuclease Nibbler Controls 3′ End Processing of MicroRNAs in Drosophila , 2011, Current Biology.

[11]  C. Burge,et al.  Conserved Seed Pairing, Often Flanked by Adenosines, Indicates that Thousands of Human Genes are MicroRNA Targets , 2005, Cell.

[12]  V. Kim MicroRNA biogenesis: coordinated cropping and dicing , 2005, Nature Reviews Molecular Cell Biology.

[13]  D. Karolchik,et al.  The UCSC Genome Browser database: 2016 update , 2015, bioRxiv.

[14]  Steven P Gygi,et al.  Angiogenin-induced tRNA fragments inhibit translation initiation. , 2011, Molecular cell.

[15]  M. Ramaswami,et al.  Syndapin promotes formation of a postsynaptic membrane system in Drosophila. , 2009, Molecular biology of the cell.

[16]  C. Goodman,et al.  The Transmembrane Tyrosine Phosphatase DLAR Controls Motor Axon Guidance in Drosophila , 1996, Cell.

[17]  David Tollervey,et al.  RNA in pieces. , 2011, Trends in genetics : TIG.

[18]  N. Polacek,et al.  tRNA-Derived Fragments Target the Ribosome and Function as Regulatory Non-Coding RNA in Haloferax volcanii , 2012, Archaea.

[19]  James B. Brown,et al.  Global patterns of tissue-specific alternative polyadenylation in Drosophila. , 2012, Cell reports.

[20]  D. Van Vactor,et al.  Complex interactions amongst N-cadherin, DLAR, and Liprin-alpha regulate Drosophila photoreceptor axon targeting. , 2009, Developmental biology.

[21]  Gert-Jan Hendriks,et al.  Impact of age-associated increase in 2′-O-methylation of miRNAs on aging and neurodegeneration in Drosophila , 2014, Genes & development.

[22]  R. Parker,et al.  The RNase Rny1p cleaves tRNAs and promotes cell death during oxidative stress in Saccharomyces cerevisiae , 2009, The Journal of cell biology.

[23]  Daniel Gautheret,et al.  Genome-wide discovery and analysis of microRNAs and other small RNAs from rice embryogenic callus , 2011, RNA biology.

[24]  Tomohiro Miyoshi,et al.  Many ways to generate microRNA-like small RNAs: non-canonical pathways for microRNA production , 2010, Molecular Genetics and Genomics.

[25]  M. Tatar,et al.  Activin Signaling Targeted by Insulin/dFOXO Regulates Aging and Muscle Proteostasis in Drosophila , 2013, PLoS genetics.

[26]  Wei Li,et al.  A novel class of tRNA-derived small RNAs extremely enriched in mature mouse sperm , 2012, Cell Research.

[27]  Y. Tomari,et al.  Drosophila argonaute1 and argonaute2 employ distinct mechanisms for translational repression. , 2009, Molecular cell.

[28]  D. Bartel MicroRNAs: Target Recognition and Regulatory Functions , 2009, Cell.

[29]  P. Bryant,et al.  DLG1: chromosome location of the closest human homologue of the Drosophila discs large tumor suppressor gene. , 1995, Genomics.

[30]  C. Burge,et al.  Prediction of Mammalian MicroRNA Targets , 2003, Cell.

[31]  Yong Sun Lee,et al.  Compartmentalized, functional role of angiogenin during spotted fever group rickettsia-induced endothelial barrier dysfunction: evidence of possible mediation by host tRNA-derived small noncoding RNAs , 2013, BMC Infectious Diseases.

[32]  A. Cayota,et al.  Hints of tRNA-Derived Small RNAs Role in RNA Silencing Mechanisms , 2012, Genes.

[33]  Daniela C. Zarnescu,et al.  Biochemical and genetic interaction between the fragile X mental retardation protein and the microRNA pathway , 2004, Nature Neuroscience.

[34]  Hui Zhou,et al.  Stress-induced tRNA-derived RNAs: a novel class of small RNAs in the primitive eukaryote Giardia lamblia , 2008, Nucleic acids research.

[35]  L. Lim,et al.  MicroRNA targeting specificity in mammals: determinants beyond seed pairing. , 2007, Molecular cell.

[36]  A. Marchfelder,et al.  Regulatory RNAs in Haloferax volcanii. , 2011, Biochemical Society transactions.

[37]  Tiange Cui,et al.  Visualization of nucleotide substitutions in the (micro)transcriptome , 2014, BMC Genomics.

[38]  Fedor V. Karginov,et al.  Developmentally regulated cleavage of tRNAs in the bacterium Streptomyces coelicolor , 2007, Nucleic acids research.

[39]  S. Warren,et al.  Transcription, translation and fragile X syndrome. , 2006, Current opinion in genetics & development.

[40]  A. Malhotra,et al.  A novel class of small RNAs: tRNA-derived RNA fragments (tRFs). , 2009, Genes & development.

[41]  G. Hutvagner,et al.  Transfer RNA‐derived fragments: origins, processing, and functions , 2011, Wiley interdisciplinary reviews. RNA.

[42]  M. Blanchette,et al.  Two new and distinct roles for Drosophila Argonaute-2 in the nucleus: alternative pre-mRNA splicing and transcriptional repression. , 2013, Genes & development.

[43]  S. S. Ajay,et al.  Identification and functional characterization of tRNA-derived RNA fragments (tRFs) in respiratory syncytial virus infection. , 2013, Molecular therapy : the journal of the American Society of Gene Therapy.

[44]  M. Ashburner,et al.  Gene Ontology: tool for the unification of biology , 2000, Nature Genetics.

[45]  Joel S Parker,et al.  microRNA expression in the prefrontal cortex of individuals with schizophrenia and schizoaffective disorder , 2007, Genome Biology.

[46]  Richard David-Rus,et al.  Altered MicroRNA Expression Profiles in Postmortem Brain Samples from Individuals with Schizophrenia and Bipolar Disorder , 2011, Biological Psychiatry.

[47]  Peter F. Stadler,et al.  Small ncRNA transcriptome analysis from Aspergillus fumigatus suggests a novel mechanism for regulation of protein synthesis , 2008, Nucleic acids research.

[48]  M. Siomi,et al.  A Drosophila fragile X protein interacts with components of RNAi and ribosomal proteins. , 2002, Genes & development.

[49]  Melanie A. Huntley,et al.  Evolution of genes and genomes on the Drosophila phylogeny , 2007, Nature.