Abstract
Alternative cleavage and polyadenylation influence the coding and regulatory potential of mRNAs and where transcription termination occurs. Although widespread, few regulators of this process are known. The Arabidopsis thaliana protein FPA is a rare example of a trans-acting regulator of poly(A) site choice. Analysing fpa mutants therefore provides an opportunity to reveal generic consequences of disrupting this process. We used direct RNA sequencing to quantify shifts in RNA 3′ formation in fpa mutants. Here we show that specific chimeric RNAs formed between the exons of otherwise separate genes are a striking consequence of loss of FPA function. We define intergenic read-through transcripts resulting from defective RNA 3′ end formation in fpa mutants and detail cryptic splicing and antisense transcription associated with these read-through RNAs. We identify alternative polyadenylation within introns that is sensitive to FPA and show FPA-dependent shifts in IBM1 poly(A) site selection that differ from those recently defined in mutants defective in intragenic heterochromatin and DNA methylation. Finally, we show that defective termination at specific loci in fpa mutants is shared with dicer-like 1 (dcl1) or dcl4 mutants, leading us to develop alternative explanations for some silencing roles of these proteins. We relate our findings to the impact that altered patterns of 3′ end formation can have on gene and genome organisation.
Highlights
Eukaryotic mRNA 39 ends are defined by a protein complex that cleaves pre-mRNA in close association with RNA polymerase II (Pol II) and adds a poly(A) tail to the free 39 end [1,2]
When genes are transcribed into mRNA by RNA polymerase II, the poly(A) signal guides cleavage of the precursor mRNA at a particular site; this is accompanied by the addition of a poly(A) tail to the mRNA and termination of transcription
We discovered a rare example of a regulator of poly(A) site choice, called FPA, while studying flower development in the model plant Arabidopsis thaliana
Summary
Eukaryotic mRNA 39 ends are defined by a protein complex that cleaves pre-mRNA in close association with RNA polymerase II (Pol II) and adds a poly(A) tail to the free 39 end [1,2]. This event is closely associated with transcription termination, since cleavage exposes the 59 end of the nascent RNA to a 59–39 exonuclease that degrades the RNA up to the exit channel of Pol II, contributing to termination [3]. The widespread nature of this control has only become apparent relatively recently [1,2]
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