Abstract
To identify regulators of pre-mRNA splicing in plants, we developed a forward genetic screen based on an alternatively spliced GFP reporter gene in Arabidopsis thaliana. In wild-type plants, three major splice variants issue from the GFP gene but only one represents a translatable GFP mRNA. Compared to wild-type seedlings, which exhibit an intermediate level of GFP expression, mutants identified in the screen feature either a “GFP-weak” or “Hyper-GFP” phenotype depending on the ratio of the three splice variants. GFP-weak mutants, including previously identified prp8 and rtf2, contain a higher proportion of unspliced transcript or canonically spliced transcript, neither of which is translatable into GFP protein. In contrast, the coilin-deficient hyper-gfp1 (hgf1) mutant displays a higher proportion of translatable GFP mRNA, which arises from enhanced splicing of a U2-type intron with noncanonical AT–AC splice sites. Here we report three new hgf mutants that are defective, respectively, in spliceosome-associated proteins SMU1, SmF, and CWC16, an Yju2/CCDC130-related protein that has not yet been described in plants. The smu1 and cwc16 mutants have substantially increased levels of translatable GFP transcript owing to preferential splicing of the U2-type AT–AC intron, suggesting that SMU1 and CWC16 influence splice site selection in GFP pre-mRNA. Genome-wide analyses of splicing in smu1 and cwc16 mutants revealed a number of introns that were variably spliced from endogenous pre-mRNAs. These results indicate that SMU1 and CWC16, which are predicted to act directly prior to and during the first catalytic step of splicing, respectively, function more generally to modulate splicing patterns in plants.
Highlights
Splicing of precursor mRNA through excision of noncoding regions and joining of adjacent coding regions is essential for the expression of most eukaryotic protein-coding genes
We report three new mutants identified in the screen that are defective, respectively, in splicing factors SMU1, SmF, and CWC16, which are related to budding yeast first step factor Yju2 and human CCDC130
We present evidence indicating that SMU1 and CWC16, which have not yet been studied in plants, can influence splice site selection and alternative splicing patterns in Arabidopsis
Summary
Splicing of precursor mRNA (pre-mRNA) through excision of noncoding regions (introns) and joining of adjacent coding regions (exons) is essential for the expression of most eukaryotic protein-coding genes. Selection of alternative splice sites is influenced by exonic and intronic cis-regulatory elements known as splicing enhancers and silencers, which bind trans-acting splicing factors such as SR (serine/arginine-rich) proteins and hnRNPs (heterogeneous ribonucleoproteins) (Barta et al 2008; Matera and Wang 2014; Meyer 2016; Sveen et al 2016). The spliceosome of budding yeast comprises 50–60 core snRNP subunits and around 100 additional splicing-associated proteins, most of which are conserved in higher eukaryotes (Koncz et al 2012). Less is known about splicesome composition in plants, the Arabidopsis genome is predicted to encode approximately 430 conserved spliceosomal factors, indicating a degree of structural and mechanistic complexity comparable to that observed in metazoans (Koncz et al 2012). We present evidence indicating that SMU1 and CWC16, which have not yet been studied in plants, can influence splice site selection and alternative splicing patterns in Arabidopsis
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