Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process

Meyer K, Köster T, Staiger D (2015)
Biomolecules 5(3): 1717-1740.

Zeitschriftenaufsatz | Veröffentlicht | Englisch
 
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URN
urn:nbn:de:0070-pub-27646954
Autor*in
Meyer, KatjaUniBi; Köster, TinoUniBi ; Staiger, DorotheeUniBi
Einrichtung
Fakultät für Biologie > RNA Biologie und Molekulare Physiologie
Abstract / Bemerkung
Alternative pre-messenger RNA splicing in higher plants emerges as an important layer of regulation upon exposure to exogenous and endogenous cues. Accordingly, mutants defective in RNA-binding proteins predicted to function in the splicing process show severe phenotypic alterations. Among those are developmental defects, impaired responses to pathogen threat or abiotic stress factors, and misregulation of the circadian timing system. A suite of splicing factors has been identified in the model plant Arabidopsis thaliana. Here we summarize recent insights on how defects in these splicing factors impair plant performance.
Stichworte
Arabidopsis; splicing; RNA-binding protein
Erscheinungsjahr
2015
Zeitschriftentitel
Biomolecules
Band
5
Ausgabe
3
Seite(n)
1717-1740
Urheberrecht / Lizenzen
Creative Commons Namensnennung 4.0 International Public License (CC-BY 4.0)
ISSN
2218-273X
Page URI
https://pub.uni-bielefeld.de/record/2764695

Zitieren

Meyer K, Köster T, Staiger D. Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process. Biomolecules. 2015;5(3):1717-1740.
Meyer, K., Köster, T., & Staiger, D. (2015). Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process. Biomolecules, 5(3), 1717-1740. doi:10.3390/biom5031717
Meyer, Katja, Köster, Tino, and Staiger, Dorothee. 2015. “Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process”. Biomolecules 5 (3): 1717-1740.
Meyer, K., Köster, T., and Staiger, D. (2015). Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process. Biomolecules 5, 1717-1740.
Meyer, K., Köster, T., & Staiger, D., 2015. Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process. Biomolecules, 5(3), p 1717-1740.
K. Meyer, T. Köster, and D. Staiger, “Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process”, Biomolecules, vol. 5, 2015, pp. 1717-1740.
Meyer, K., Köster, T., Staiger, D.: Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process. Biomolecules. 5, 1717-1740 (2015).
Meyer, Katja, Köster, Tino, and Staiger, Dorothee. “Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process”. Biomolecules 5.3 (2015): 1717-1740.
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2019-09-06T09:18:32Z
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17 Zitationen in Europe PMC

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Arginine methylation mediated by the Arabidopsis homolog of PRMT5 is essential for proper pre-mRNA splicing.
Deng X, Gu L, Liu C, Lu T, Lu F, Lu Z, Cui P, Pei Y, Wang B, Hu S, Cao X., Proc. Natl. Acad. Sci. U.S.A. 107(44), 2010
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The arginine methyltransferase CARM1 regulates the coupling of transcription and mRNA processing.
Cheng D, Cote J, Shaaban S, Bedford MT., Mol. Cell 25(1), 2007
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Redundant requirement for a pair of PROTEIN ARGININE METHYLTRANSFERASE4 homologs for the proper regulation of Arabidopsis flowering time.
Niu L, Zhang Y, Pei Y, Liu C, Cao X., Plant Physiol. 148(1), 2008
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STABILIZED1, a stress-upregulated nuclear protein, is required for pre-mRNA splicing, mRNA turnover, and stress tolerance in Arabidopsis.
Lee BH, Kapoor A, Zhu J, Zhu JK., Plant Cell 18(7), 2006
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Disordered cold regulated15 proteins protect chloroplast membranes during freezing through binding and folding, but do not stabilize chloroplast enzymes in vivo.
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The Splicing Factor PRP31 Is Involved in Transcriptional Gene Silencing and Stress Response in Arabidopsis.
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LACHESIS restricts gametic cell fate in the female gametophyte of Arabidopsis.
Gross-Hardt R, Kagi C, Baumann N, Moore JM, Baskar R, Gagliano WB, Jurgens G, Grossniklaus U., PLoS Biol. 5(3), 2007
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GAMETOPHYTIC FACTOR 1, involved in pre-mRNA splicing, is essential for megagametogenesis and embryogenesis in Arabidopsis.
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CLO/GFA1 and ATO are novel regulators of gametic cell fate in plants.
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Alternative polyadenylation of antisense RNAs and flowering time control.
Hornyik C, Duc C, Rataj K, Terzi LC, Simpson GG., Biochem. Soc. Trans. 38(4), 2010
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Structure and function of an RNase H domain at the heart of the spliceosome.
Pena V, Rozov A, Fabrizio P, Luhrmann R, Wahl MC., EMBO J. 27(21), 2008
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Prp8 protein: at the heart of the spliceosome.
Grainger RJ, Beggs JD., RNA 11(5), 2005
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Functional consequences of splicing of the antisense transcript COOLAIR on FLC transcription.
Marquardt S, Raitskin O, Wu Z, Liu F, Sun Q, Dean C., Mol. Cell 54(1), 2014
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The Arabidopsis thaliana AT PRP39-1 gene, encoding a tetratricopeptide repeat protein with similarity to the yeast pre-mRNA processing protein PRP39, affects flowering time.
Wang C, Tian Q, Hou Z, Mucha M, Aukerman M, Olsen OA., Plant Cell Rep. 26(8), 2007
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The RNA binding protein ELF9 directly reduces SUPPRESSOR OF OVEREXPRESSION OF CO1 transcript levels in arabidopsis, possibly via nonsense-mediated mRNA decay.
Song HR, Song JD, Cho JN, Amasino RM, Noh B, Noh YS., Plant Cell 21(4), 2009
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The conserved splicing factor SUA controls alternative splicing of the developmental regulator ABI3 in Arabidopsis.
Sugliani M, Brambilla V, Clerkx EJ, Koornneef M, Soppe WJ., Plant Cell 22(6), 2010
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The function of the NineTeen Complex (NTC) in regulating spliceosome conformations and fidelity during pre-mRNA splicing.
Hogg R, McGrail JC, O'Keefe RT., Biochem. Soc. Trans. 38(4), 2010
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Regulation of plant innate immunity by three proteins in a complex conserved across the plant and animal kingdoms.
Palma K, Zhao Q, Cheng YT, Bi D, Monaghan J, Cheng W, Zhang Y, Li X., Genes Dev. 21(12), 2007
PMID: 17575050
A gain-of-function mutation in a plant disease resistance gene leads to constitutive activation of downstream signal transduction pathways in suppressor of npr1-1, constitutive 1.
Zhang Y, Goritschnig S, Dong X, Li X., Plant Cell 15(11), 2003
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Two Prp19-like U-box proteins in the MOS4-associated complex play redundant roles in plant innate immunity.
Monaghan J, Xu F, Gao M, Zhao Q, Palma K, Long C, Chen S, Zhang Y, Li X., PLoS Pathog. 5(7), 2009
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The cyclin L homolog MOS12 and the MOS4-associated complex are required for the proper splicing of plant resistance genes.
Xu F, Xu S, Wiermer M, Zhang Y, Li X., Plant J. 70(6), 2012
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Splicing of receptor-like kinase-encoding SNC4 and CERK1 is regulated by two conserved splicing factors that are required for plant immunity.
Zhang Z, Liu Y, Ding P, Li Y, Kong Q, Zhang Y., Mol Plant 7(12), 2014
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Two putative RNA-binding proteins function with unequal genetic redundancy in the MOS4-associated complex.
Monaghan J, Xu F, Xu S, Zhang Y, Li X., Plant Physiol. 154(4), 2010
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Cwc2 and its human homologue RBM22 promote an active conformation of the spliceosome catalytic centre.
Rasche N, Dybkov O, Schmitzova J, Akyildiz B, Fabrizio P, Luhrmann R., EMBO J. 31(6), 2012
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SKIP is a component of the spliceosome linking alternative splicing and the circadian clock in Arabidopsis.
Wang X, Wu F, Xie Q, Wang H, Wang Y, Yue Y, Gahura O, Ma S, Liu L, Cao Y, Jiao Y, Puta F, McClung CR, Xu X, Ma L., Plant Cell 24(8), 2012
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SKIP Confers Osmotic Tolerance during Salt Stress by Controlling Alternative Gene Splicing in Arabidopsis.
Feng J, Li J, Gao Z, Lu Y, Yu J, Zheng Q, Yan S, Zhang W, He H, Ma L, Zhu Z., Mol Plant 8(7), 2015
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Mutation of Arabidopsis spliceosomal timekeeper locus1 causes circadian clock defects.
Jones MA, Williams BA, McNicol J, Simpson CG, Brown JW, Harmer SL., Plant Cell 24(10), 2012
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A role for TREX components in the release of spliced mRNA from nuclear speckle domains.
Dias AP, Dufu K, Lei H, Reed R., Nat Commun 1(), 2010
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HYPER RECOMBINATION1 of the THO/TREX complex plays a role in controlling transcription of the REVERSION-TO-ETHYLENE SENSITIVITY1 gene in Arabidopsis.
Xu C, Zhou X, Wen CK., PLoS Genet. 11(2), 2015
PMID: 25680185
Characterization of EMU, the Arabidopsis homolog of the yeast THO complex member HPR1.
Furumizu C, Tsukaya H, Komeda Y., RNA 16(9), 2010
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THO2, a core member of the THO/TREX complex, is required for microRNA production in Arabidopsis.
Francisco-Mangilet AG, Karlsson P, Kim MH, Eo HJ, Oh SA, Kim JH, Kulcheski FR, Park SK, Manavella PA., Plant J. 82(6), 2015
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A KH-domain RNA-binding protein interacts with FIERY2/CTD phosphatase-like 1 and splicing factors and is important for pre-mRNA splicing in Arabidopsis.
Chen T, Cui P, Chen H, Ali S, Zhang S, Xiong L., PLoS Genet. 9(10), 2013
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A DEAD box RNA helicase is critical for pre-mRNA splicing, cold-responsive gene regulation, and cold tolerance in Arabidopsis.
Guan Q, Wu J, Zhang Y, Jiang C, Liu R, Chai C, Zhu J., Plant Cell 25(1), 2013
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Differential expression of alternatively spliced mRNAs of Arabidopsis SR protein homologs, atSR30 and atSR45a, in response to environmental stress.
Tanabe N, Yoshimura K, Kimura A, Yabuta Y, Shigeoka S., Plant Cell Physiol. 48(7), 2007
PMID: 17556373
Plant-specific SR-related protein atSR45a interacts with spliceosomal proteins in plant nucleus.
Tanabe N, Kimura A, Yoshimura K, Shigeoka S., Plant Mol. Biol. 70(3), 2009
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An Rtf2 Domain-Containing Protein Influences Pre-mRNA Splicing and Is Essential for Embryonic Development in Arabidopsis thaliana.
Sasaki T, Kanno T, Liang SC, Chen PY, Liao WW, Lin WD, Matzke AJ, Matzke M., Genetics 200(2), 2015
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Arabidopsis root initiation defective1, a DEAH-box RNA helicase involved in pre-mRNA splicing, is essential for plant development.
Ohtani M, Demura T, Sugiyama M., Plant Cell 25(6), 2013
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Involvement of the nuclear cap-binding protein complex in alternative splicing in Arabidopsis thaliana.
Raczynska KD, Simpson CG, Ciesiolka A, Szewc L, Lewandowska D, McNicol J, Szweykowska-Kulinska Z, Brown JW, Jarmolowski A., Nucleic Acids Res. 38(1), 2009
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Dual roles of the nuclear cap-binding complex and SERRATE in pre-mRNA splicing and microRNA processing in Arabidopsis thaliana.
Laubinger S, Sachsenberg T, Zeller G, Busch W, Lohmann JU, Ratsch G, Weigel D., Proc. Natl. Acad. Sci. U.S.A. 105(25), 2008
PMID: 18550839
Biogenesis, turnover, and mode of action of plant microRNAs.
Rogers K, Chen X., Plant Cell 25(7), 2013
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Widespread translational inhibition by plant miRNAs and siRNAs.
Brodersen P, Sakvarelidze-Achard L, Bruun-Rasmussen M, Dunoyer P, Yamamoto YY, Sieburth L, Voinnet O., Science 320(5880), 2008
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Regulation of miRNA abundance by RNA binding protein TOUGH in Arabidopsis.
Ren G, Xie M, Dou Y, Zhang S, Zhang C, Yu B., Proc. Natl. Acad. Sci. U.S.A. 109(31), 2012
PMID: 22802657
Two cap-binding proteins CBP20 and CBP80 are involved in processing primary MicroRNAs.
Kim S, Yang JY, Xu J, Jang IC, Prigge MJ, Chua NH., Plant Cell Physiol. 49(11), 2008
PMID: 18829588
A link between RNA metabolism and silencing affecting Arabidopsis development.
Gregory BD, O'Malley RC, Lister R, Urich MA, Tonti-Filippini J, Chen H, Millar AH, Ecker JR., Dev. Cell 14(6), 2008
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The interaction between DCL1 and HYL1 is important for efficient and precise processing of pri-miRNA in plant microRNA biogenesis.
Kurihara Y, Takashi Y, Watanabe Y., RNA 12(2), 2006
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Fast-forward genetics identifies plant CPL phosphatases as regulators of miRNA processing factor HYL1.
Manavella PA, Hagmann J, Ott F, Laubinger S, Franz M, Macek B, Weigel D., Cell 151(4), 2012
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The FHA domain proteins DAWDLE in Arabidopsis and SNIP1 in humans act in small RNA biogenesis.
Yu B, Bi L, Zheng B, Ji L, Chevalier D, Agarwal M, Ramachandran V, Li W, Lagrange T, Walker JC, Chen X., Proc. Natl. Acad. Sci. U.S.A. 105(29), 2008
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Proteomic analysis identifies a new complex required for nuclear pre-mRNA retention and splicing.
Dziembowski A, Ventura AP, Rutz B, Caspary F, Faux C, Halgand F, Laprevote O, Seraphin B., EMBO J. 23(24), 2004
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The SERRATE protein is involved in alternative splicing in Arabidopsis thaliana.
Raczynska KD, Stepien A, Kierzkowski D, Kalak M, Bajczyk M, McNicol J, Simpson CG, Szweykowska-Kulinska Z, Brown JW, Jarmolowski A., Nucleic Acids Res. 42(2), 2013
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Regulation of pri-miRNA processing by the hnRNP-like protein AtGRP7 in Arabidopsis.
Koster T, Meyer K, Weinholdt C, Smith LM, Lummer M, Speth C, Grosse I, Weigel D, Staiger D., Nucleic Acids Res. 42(15), 2014
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CDC5, a DNA binding protein, positively regulates posttranscriptional processing and/or transcription of primary microRNA transcripts.
Zhang S, Xie M, Ren G, Yu B., Proc. Natl. Acad. Sci. U.S.A. 110(43), 2013
PMID: 24101471
PRL1, an RNA-binding protein, positively regulates the accumulation of miRNAs and siRNAs in Arabidopsis.
Zhang S, Liu Y, Yu B., PLoS Genet. 10(12), 2014
PMID: 25474114
STA1, an Arabidopsis pre-mRNA processing factor 6 homolog, is a new player involved in miRNA biogenesis.
Ben Chaabane S, Liu R, Chinnusamy V, Kwon Y, Park JH, Kim SY, Zhu JK, Yang SW, Lee BH., Nucleic Acids Res. 41(3), 2012
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A proteomic analysis of oligo(dT)-bound mRNP containing oxidative stress-induced Arabidopsis thaliana RNA-binding proteins ATGRP7 and ATGRP8.
Schmidt F, Marnef A, Cheung MK, Wilson I, Hancock J, Staiger D, Ladomery M., Mol. Biol. Rep. 37(2), 2009
PMID: 19672695
Insights into RNA biology from an atlas of mammalian mRNA-binding proteins.
Castello A, Fischer B, Eichelbaum K, Horos R, Beckmann BM, Strein C, Davey NE, Humphreys DT, Preiss T, Steinmetz LM, Krijgsveld J, Hentze MW., Cell 149(6), 2012
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Genome analysis: RNA recognition motif (RRM) and K homology (KH) domain RNA-binding proteins from the flowering plant Arabidopsis thaliana.
Lorkovic ZJ, Barta A., Nucleic Acids Res. 30(3), 2002
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