A computational method for predicting regulation of human microRNAs on the influenza virus genome

BackgroundWhile it has been suggested that host microRNAs (miRNAs) may downregulate viral gene expression as an antiviral defense mechanism, such a mechanism has not been explored in the influenza virus for human flu studies. As it is difficult to conduct related experiments on humans, computational studies can provide some insight. Although many computational tools have been designed for miRNA target prediction, there is a need for cross-species prediction, especially for predicting viral targets of human miRNAs. However, finding putative human miRNAs targeting influenza virus genome is still challenging.ResultsWe developed machine-learning features and conducted comprehensive data training for predicting interactions between H1N1 genome segments and host miRNA. We defined our seed region as the first ten nucleotides from the 5' end of the miRNA to the 3' end of the miRNA and integrated various features including the number of consecutive matching bases in the seed region of 10 bases, a triplet feature in seed regions, thermodynamic energy, penalty of bulges and wobbles at binding sites, and the secondary structure of viral RNA for the prediction.ConclusionsCompared to general predictive models, our model fully takes into account the conservation patterns and features of viral RNA secondary structures, and greatly improves the prediction accuracy. Our model identified some key miRNAs including hsa-miR-489, hsa-miR-325, hsa-miR-876-3p and hsa-miR-2117, which target HA, PB2, MP and NS of H1N1, respectively. Our study provided an interesting hypothesis concerning the miRNA-based antiviral defense mechanism against influenza virus in human, i.e., the binding between human miRNA and viral RNAs may not result in gene silencing but rather may block the viral RNA replication.

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

[2]  R. Giegerich,et al.  Fast and effective prediction of microRNA/target duplexes. , 2004, RNA.

[3]  D. Lipman,et al.  National Center for Biotechnology Information , 2019, Springer Reference Medizin.

[4]  Ari Helenius,et al.  How Viruses Enter Animal Cells , 2004, Science.

[5]  A. Hatzigeorgiou,et al.  A combined computational-experimental approach predicts human microRNA targets. , 2004, Genes & development.

[6]  Vinod Scaria,et al.  Targets for human encoded microRNAs in HIV genes. , 2005, Biochemical and biophysical research communications.

[7]  Yvonne Tay,et al.  A Pattern-Based Method for the Identification of MicroRNA Binding Sites and Their Corresponding Heteroduplexes , 2006, Cell.

[8]  M. Homma,et al.  An outbreak of type C influenza in a children's home. , 1983, The Journal of infectious diseases.

[9]  Thorsten Wolff,et al.  The Influenza A Virus NS1 Protein Inhibits Activation of Jun N-Terminal Kinase and AP-1 Transcription Factors , 2002, Journal of Virology.

[10]  O. Voinnet Origin, Biogenesis, and Activity of Plant MicroRNAs , 2009, Cell.

[11]  Anton J. Enright,et al.  MicroRNA targets in Drosophila , 2003, Genome Biology.

[12]  K. Nakajima,et al.  [Influenza virus genome structure and encoded proteins]. , 1997, Nihon rinsho. Japanese journal of clinical medicine.

[13]  Xin Li,et al.  Human encoded miRNAs that regulate the inflenenza virus genome , 2012, 2012 IEEE 6th International Conference on Systems Biology (ISB).

[14]  A. Saïb,et al.  A Cellular MicroRNA Mediates Antiviral Defense in Human Cells , 2005, Science.

[15]  Olga A. Maximova,et al.  MicroRNA Targeting of Neurotropic Flavivirus: Effective Control of Virus Escape and Reversion to Neurovirulent Phenotype , 2012, Journal of Virology.

[16]  Yoshihiro Kawaoka,et al.  Amino Acid Changes in Hemagglutinin Contribute to the Replication of Oseltamivir-Resistant H1N1 Influenza Viruses , 2011, Journal of Virology.

[17]  C. Daub,et al.  BMC Systems Biology , 2007 .

[18]  L. Finelli,et al.  Emergence of a novel swine-origin influenza A (H1N1) virus in humans. , 2009, The New England journal of medicine.

[19]  Adam Drake,et al.  Virus-specific host miRNAs: antiviral defenses or promoters of persistent infection? , 2009, Trends in immunology.

[20]  Joshua J. Forman,et al.  A search for conserved sequences in coding regions reveals that the let-7 microRNA targets Dicer within its coding sequence , 2008, Proceedings of the National Academy of Sciences.

[21]  Kuan-Teh Jeang,et al.  The extent of sequence complementarity correlates with the potency of cellular miRNA-mediated restriction of HIV-1 , 2012, Nucleic acids research.

[22]  Hiroshi Kido,et al.  Novel Type II Transmembrane Serine Proteases, MSPL and TMPRSS13, Proteolytically Activate Membrane Fusion Activity of the Hemagglutinin of Highly Pathogenic Avian Influenza Viruses and Induce Their Multicycle Replication , 2010, Journal of Virology.

[23]  Yoshiki Murakami,et al.  Regulation of the hepatitis C virus genome replication by miR-199a. , 2009, Journal of hepatology.

[24]  M. David,et al.  Interferons and microRNAs. , 2010, Journal of interferon & cytokine research : the official journal of the International Society for Interferon and Cytokine Research.

[25]  Ting Chen,et al.  Modeling Gene Expression with Differential Equations , 1998, Pacific Symposium on Biocomputing.

[26]  Hao Zhang,et al.  RNA secondary structure comparison based on dynamic programming , 2012, 2012 7th International Conference on Computing and Convergence Technology (ICCCT).

[27]  Vinod Scaria,et al.  Host-virus interaction: a new role for microRNAs , 2006, Retrovirology.

[28]  Yvonne Tay,et al.  MicroRNAs to Nanog, Oct4 and Sox2 coding regions modulate embryonic stem cell differentiation , 2008, Nature.

[29]  Susana López,et al.  Molecular anatomy of 2009 influenza virus A (H1N1). , 2009, Archives of medical research.

[30]  D. Bartel MicroRNAs Genomics, Biogenesis, Mechanism, and Function , 2004, Cell.

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

[32]  Li Zhi RNA second structure comparison based on dynamic programming , 2011 .

[33]  Byoung-Tak Zhang,et al.  miTarget: microRNA target gene prediction using a support vector machine , 2006, BMC Bioinformatics.

[34]  Xinxia Peng,et al.  MicroRNA Expression and Virulence in Pandemic Influenza Virus-Infected Mice , 2010, Journal of Virology.

[35]  J. Steitz,et al.  Target mRNAs are repressed as efficiently by microRNA-binding sites in the 5′ UTR as in the 3′ UTR , 2007, Proceedings of the National Academy of Sciences.

[36]  Stijn van Dongen,et al.  miRBase: tools for microRNA genomics , 2007, Nucleic Acids Res..

[37]  K. Gunsalus,et al.  Combinatorial microRNA target predictions , 2005, Nature Genetics.

[38]  Insung Ahn,et al.  Evolutionary analysis of human-origin influenza A virus (H3N2) genes associated with the codon usage patterns since 1993 , 2011, Virus Genes.

[39]  Ian Goodfellow,et al.  Influenza virus polymerase confers independence of the cellular cap-binding factor eIF4E for viral mRNA translation. , 2012, Virology.

[40]  Masaru Tomita,et al.  Computational analysis of microRNA‐mediated antiviral defense in humans , 2007, FEBS letters.

[41]  A. Douglas,et al.  The evolution of human influenza viruses. , 2001, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.