siRNA release from pri-miRNA scaffolds is controlled by the sequence and structure of RNA.
暂无分享,去创建一个
Izabela Makalowska | Julia Starega-Roslan | Marta Olejniczak | M. Szcześniak | I. Makałowska | W. Krzyzosiak | Julia Staręga-Rosłan | P. Galka-Marciniak | M. Olejniczak | Wlodzimierz J Krzyzosiak | Paulina Galka-Marciniak | Michal W Szczesniak
[1] David A. Eichmann,et al. siSPOTR: a tool for designing highly specific and potent siRNAs for human and mouse , 2012, Nucleic acids research.
[2] G. Du,et al. pSM155 and pSM30 vectors for miRNA and shRNA expression. , 2009, Methods in molecular biology.
[3] D. Corey,et al. Allele-selective inhibition of trinucleotide repeat genes. , 2012, Drug discovery today.
[4] J. Rossi,et al. Design of Effective Primary MicroRNA Mimics With Different Basal Stem Conformations , 2016, Molecular therapy. Nucleic acids.
[5] M. L. Hastings,et al. Ensemble analysis of primary microRNA structure reveals an extensive capacity to deform near the Drosha cleavage site. , 2013, Biochemistry.
[6] Christof Fellmann,et al. An optimized microRNA backbone for effective single-copy RNAi. , 2013, Cell reports.
[7] Julia Starega-Roslan,et al. Sequence Features of Drosha and Dicer Cleavage Sites Affect the Complexity of IsomiRs , 2015, International journal of molecular sciences.
[8] F. Guo,et al. The DGCR8 RNA-binding heme domain recognizes primary microRNAs by clamping the hairpin. , 2014, Cell reports.
[9] Ana Kozomara,et al. miRBase: annotating high confidence microRNAs using deep sequencing data , 2013, Nucleic Acids Res..
[10] P. Washbourne,et al. Improved knockdown from artificial microRNAs in an enhanced miR-155 backbone: a designer's guide to potent multi-target RNAi , 2015, Nucleic acids research.
[11] B. Berkhout,et al. Dicer-independent processing of short hairpin RNAs , 2013, Nucleic acids research.
[12] Jennifer A. Doudna,et al. Dicer-TRBP complex formation ensures accurate mammalian microRNA biogenesis. , 2015, Molecular cell.
[13] H. Petry,et al. In vivo knock-down of multidrug resistance transporters ABCC1 and ABCC2 by AAV-delivered shRNAs and by artificial miRNAs , 2011, Journal of RNAi and gene silencing : an international journal of RNA and gene targeting research.
[14] W. Krzyzosiak,et al. RNAimmuno: a database of the nonspecific immunological effects of RNA interference and microRNA reagents. , 2012, RNA.
[15] W. Filipowicz,et al. The widespread regulation of microRNA biogenesis, function and decay , 2010, Nature Reviews Genetics.
[16] S. Elledge,et al. A lentiviral microRNA-based system for single-copy polymerase II-regulated RNA interference in mammalian cells. , 2005, Proceedings of the National Academy of Sciences of the United States of America.
[17] Ryan M Spengler,et al. Artificial miRNAs Targeting Mutant Huntingtin Show Preferential Silencing In Vitro and In Vivo. , 2015, Molecular therapy. Nucleic acids.
[18] David P. Bartel,et al. Beyond Secondary Structure: Primary-Sequence Determinants License Pri-miRNA Hairpins for Processing , 2013, Cell.
[19] Sung W. Rhee,et al. Vascular Smooth Muscle-Specific Knockdown of the Noncardiac Form of the L-Type Calcium Channel by MicroRNA-Based Short Hairpin RNA as a Potential Antihypertensive Therapy , 2009, Journal of Pharmacology and Experimental Therapeutics.
[20] H. Paulson,et al. Silencing mutant ATXN3 expression resolves molecular phenotypes in SCA3 transgenic mice. , 2013, Molecular therapy : the journal of the American Society of Gene Therapy.
[21] Jang-Gi Choi,et al. Multiplexing seven miRNA-Based shRNAs to suppress HIV replication. , 2015, Molecular therapy : the journal of the American Society of Gene Therapy.
[22] W. Krzyzosiak,et al. Nucleotide sequence of miRNA precursor contributes to cleavage site selection by Dicer , 2015, Nucleic acids research.
[23] C. Bracken,et al. IsomiRs--the overlooked repertoire in the dynamic microRNAome. , 2012, Trends in genetics : TIG.
[24] Jacek Blazewicz,et al. Automated 3D structure composition for large RNAs , 2012, Nucleic acids research.
[25] N. Sonenberg,et al. Structural basis for 5′-nucleotide base-specific recognition of guide RNA by human AGO2 , 2010, Nature.
[26] G. Du,et al. Design of expression vectors for RNA interference based on miRNAs and RNA splicing , 2006, The FEBS journal.
[27] D. Bartel,et al. The Menu of Features that Define Primary MicroRNAs and Enable De Novo Design of MicroRNA Genes. , 2015, Molecular cell.
[28] V. Kim,et al. Regulation of microRNA biogenesis , 2014, Nature Reviews Molecular Cell Biology.
[29] W. Krzyzosiak,et al. Inhibition of mutant huntingtin expression by RNA duplex targeting expanded CAG repeats , 2011, Nucleic acids research.
[30] Yonggan Wu,et al. Lower and upper stem–single-stranded RNA junctions together determine the Drosha cleavage site , 2013, Proceedings of the National Academy of Sciences.
[31] K. Krause,et al. Optimization of Critical Hairpin Features Allows miRNA-based Gene Knockdown Upon Single-copy Transduction , 2014, Molecular therapy. Nucleic acids.
[32] B. Berkhout,et al. Inhibition of HIV-1 by multiple siRNAs expressed from a single microRNA polycistron , 2008, Nucleic acids research.
[33] N. Déglon,et al. Allele-Specific RNA Silencing of Mutant Ataxin-3 Mediates Neuroprotection in a Rat Model of Machado-Joseph Disease , 2008, PloS one.
[34] Z. Jia,et al. Construction of HCC-targeting artificial miRNAs using natural miRNA precursors , 2013, Experimental and therapeutic medicine.
[35] H. Petry,et al. Optimization and comparison of knockdown efficacy between polymerase II expressed shRNA and artificial miRNA targeting luciferase and Apolipoprotein B100 , 2012, BMC Biotechnology.
[36] Charles M. Rice,et al. miRNA–target chimeras reveal miRNA 3′-end pairing as a major determinant of Argonaute target specificity , 2015, Nature Communications.
[37] W. Krzyzosiak,et al. Self-duplexing CUG repeats selectively inhibit mutant huntingtin expression , 2013, Nucleic acids research.
[38] Piotr Kozlowski,et al. Structural basis of microRNA length variety , 2010, Nucleic Acids Res..
[39] W. Krzyzosiak,et al. Sequence-non-specific effects of RNA interference triggers and microRNA regulators , 2009, Nucleic acids research.
[40] V. Kim,et al. Functional Anatomy of the Human Microprocessor , 2015, Cell.
[41] H. Petry,et al. Embedding siRNA sequences targeting Apolipoprotein B100 in shRNA and miRNA scaffolds results in differential processing and in vivo efficacy , 2012, Molecular therapy : the journal of the American Society of Gene Therapy.
[42] E. Myers,et al. Basic local alignment search tool. , 1990, Journal of molecular biology.
[43] Hyeshik Chang,et al. Dicer recognizes the 5′ end of RNA for efficient and accurate processing , 2011, Nature.
[44] W. Johnson,et al. Improved annotation of C. elegans microRNAs by deep sequencing reveals structures associated with processing by Drosha and Dicer. , 2011, RNA.
[45] Anne Gatignol,et al. Combinatorial delivery of small interfering RNAs reduces RNAi efficacy by selective incorporation into RISC , 2007, Nucleic acids research.
[46] J. Doudna,et al. Molecular mechanisms of RNA interference. , 2013, Annual review of biophysics.
[47] Jennifer Taylor,et al. Polycistronic RNA polymerase II expression vectors for RNA interference based on BIC/miR-155 , 2006, Nucleic acids research.
[48] Eric J Wagner,et al. Both natural and designed micro RNAs can inhibit the expression of cognate mRNAs when expressed in human cells. , 2002, Molecular cell.
[49] G. Varani,et al. miRNA sensitivity to Drosha levels correlates with pre-miRNA secondary structure , 2014, RNA.
[50] Jiahuai Han,et al. Efficient inhibition of HIV-1 replication by an artificial polycistronic miRNA construct , 2012, Virology Journal.
[51] Patrick J. Paddison,et al. Second-generation shRNA libraries covering the mouse and human genomes , 2005, Nature Genetics.
[52] Julia Starega-Roslan,et al. High-Resolution Northern Blot for a Reliable Analysis of MicroRNAs and Their Precursors , 2011, TheScientificWorldJournal.
[53] I. Martins,et al. Artificial microRNAs as siRNA shuttles: improved safety as compared to shRNAs in vitro and in vivo. , 2009, Molecular therapy : the journal of the American Society of Gene Therapy.
[54] Rodney P Kincaid,et al. A central role for the primary microRNA stem in guiding the position and efficiency of Drosha processing of a viral pri-miRNA , 2014, RNA.
[55] S. Tavazoie,et al. N6-methyladenosine marks primary microRNAs for processing , 2015, Nature.
[56] W. Krzyzosiak,et al. Northern blotting analysis of microRNAs, their precursors and RNA interference triggers , 2011, BMC Molecular Biology.
[57] Yue Zhang,et al. The Loop Position of shRNAs and Pre-miRNAs Is Critical for the Accuracy of Dicer Processing In Vivo , 2012, Cell.
[58] Brian L. Gilmore,et al. Artificial miRNAs mitigate shRNA-mediated toxicity in the brain: Implications for the therapeutic development of RNAi , 2008, Proceedings of the National Academy of Sciences.
[59] Jennifer L. Clancy,et al. Complexity of Murine Cardiomyocyte miRNA Biogenesis, Sequence Variant Expression and Function , 2012, PloS one.
[60] Angela N. Brooks,et al. Structural Basis for Double-Stranded RNA Processing by Dicer , 2006, Science.
[61] D. Bonatto,et al. Scaffolds for Artificial miRNA Expression in Animal Cells. , 2015, Human gene therapy methods.
[62] Chengyi Chang,et al. Intron-mediated RNA interference, intronic microRNAs, and applications. , 2010, Methods in molecular biology.
[63] A. Kim,et al. Global identification of target recognition and cleavage by the Microprocessor in human ES cells , 2014, Nucleic acids research.