Stress-Induced Alternative Splicing Provides a Mechanism for the Regulation of MicroRNA Processing in Arabidopsis thaliana

Ke, Yan; Liu, Peng; Wu, Changai; Yang, Guodong; Xu, Rui; Guo, Qian-Huan; Huang, Jinguang; Zheng, Chengchao

doi:10.1016/j.molcel.2012.08.032

Cited by 168 publications

(188 citation statements)

References 55 publications

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“…Alternative splicing has recently been implicated as playing a major role in these processes during stresses, including disease, heat, drought, and others (Deom et al, 1987;Iida et al, 2004;Jeong et al, 2011;Kakumanu et al, 2012;Chang et al, 2014;Mandadi and Scholthof, 2015). Gene expression changes in splicing factors are a major factor in determining stress-induced alternative splicing changes (Yan et al, 2012;Leviatan et al, 2013;Staiger and Brown, 2013). For example, Cui et al (2014) recently showed that overexpression of the splicing factor SAD1 conferred increased splicing precision and resulted in increased tolerance to salt stress in Arabidopsis (Arabidopsis thaliana).…”

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confidence: 99%

Genome-Wide Analysis of Alternative Splicing during Development and Drought Stress in Maize

et al. 2015

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Alternative splicing plays a crucial role in plant development as well as stress responses. Although alternative splicing has been studied during development and in response to stress, the interplay between these two factors remains an open question. To assess the effects of drought stress on developmentally regulated splicing in maize (Zea mays), 94 RNA-seq libraries from ear, tassel, and leaf of the B73 public inbred line were constructed at four developmental stages under both well-watered and drought conditions. This analysis was supplemented with a publicly available series of 53 libraries from developing seed, embryo, and endosperm. More than 48,000 novel isoforms, often with stage-or condition-specific expression, were uncovered, suggesting that developmentally regulated alternative splicing occurs in thousands of genes. Drought induced large developmental splicing changes in leaf and ear but relatively few in tassel. Most developmental stage-specific splicing changes affected by drought were tissue dependent, whereas stage-independent changes frequently overlapped between leaf and ear. A linear relationship was found between gene expression changes in splicing factors and alternative spicing of other genes during development. Collectively, these results demonstrate that alternative splicing is strongly associated with tissue type, developmental stage, and stress condition.After transcription, the majority of eukaryotic premRNA is subjected to a series of posttranscriptional modifications, including the removal of introns to form a mature mRNA (Stamm et al., 2005). Although some introns are removed constitutively, many can be processed in a variety of alternative ways, including exon skipping, intron retention, alternative acceptor, alternative donor, and alternative position (change in both acceptor and donor positions; Lorkovic et al., 2000). These alternative splicing events form a crucial regulatory level and have the ability to alter an mRNA's stability, localization, and protein products. Alternative splicing events are controlled by a variety of cis-elements, including the presence of consensus splice sequences at the intron-exon border and intronic and exonic splicing enhancer sequences (Pertea et al., 2007). Trans-acting factors also exert a strong effect on splicing and are mostly composed of Ser/Arg-rich proteins, which typically promote intron removal, and heterogenous nuclear ribonucleoproteins, which typically inhibit it (Erkelenz et al., 2013). A host of other indirect factors can affect splicing, including transcription rate, methylation status, and any cellular conditions that alter RNA secondary structure (Kornblihtt et al

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confidence: 99%

Genome-Wide Analysis of Alternative Splicing during Development and Drought Stress in Maize

et al. 2015

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“…Intronic miRNAs can be subject to inefficient splicing or alternative splicing which can affect the miRNA production. Expression of intronic miR400 is downregulated by heat treatment due to an alternative splicing event which causes the miRNA to be retained in the host gene [49]. To investigate miRNA origins, we first added introns to the barley annotation file from the International Barley Sequencing Consortium (ftp://ftpmips.helmholtz-muenchen.de/plants/barley/ p u b l i c _ d a t a / g e n e s / b a r l e y _ H i g h C o n f _ g e n e s _ MIPS_21Aug12_Transcript_and_CDS_structure.gff) using Genome Tools (version 1.4.1) and converted the .gff file into .bed format.…”

Section: Origins Of Predicted Mirnasmentioning

confidence: 99%

In silico identification and characterization of conserved plant microRNAs in barley

Hornyik

Bayer

et al. 2014

Open Life Sciences

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“…Until now, 12 intronic miRNAs have been found in the genome of Arabidopsis thaliana. 37,38 Our bioinformatic and experimental studies revealed that 17 more miRNAs of A. thaliana are also encoded within introns of protein -and noncoding genes (manuscript in preparation). Thus, in the A. thaliana genome approximately 8% of miRNAs are encoded within introns of host genes, while the remaining represent independent transcriptional units.…”

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confidence: 99%

“…17,18,39,40 These introns undergo complex alternative splicing, providing a possible mechanism for the regulation of miRNA processing in A. thaliana. 38,41 Our estimations have shown that approximately 50% of A. thaliana miRNA genes contains intron(s). In the majority of intron-containing precursors, the miRNA-enclosing hairpin loop structure is located within the first exon.…”

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“…Thus, exonic localization of miR400 inhibits its efficient processing from the stress-induced mRNA isoform. 38 Alternative splicing of pri-miRNAs has been observed in many cases of intron-containing miRNA genes. The picture that emerges is that introns and alternative splicing have highly relevant roles in regulating the miRNA levels in very specific conditions, and also contribute to proper plant response to stress conditions (Fig.…”

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The crosstalk between plant microRNA biogenesis factors and the spliceosome

Szweykowska-Kulińska

Jarmołowski

Vazquez

2013

Plant Signaling & Behavior

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Stress-Induced Alternative Splicing Provides a Mechanism for the Regulation of MicroRNA Processing in Arabidopsis thaliana

Cited by 168 publications

References 55 publications

Genome-Wide Analysis of Alternative Splicing during Development and Drought Stress in Maize

Genome-Wide Analysis of Alternative Splicing during Development and Drought Stress in Maize

In silico identification and characterization of conserved plant microRNAs in barley

The crosstalk between plant microRNA biogenesis factors and the spliceosome

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