Abstract
Detection of complex splice sites (SSs) and polyadenylation sites (PASs) of eukaryotic genes is essential for the elucidation of gene regulatory mechanisms. Transcriptome-wide studies using high-throughput sequencing (HTS) have revealed prevalent alternative splicing (AS) and alternative polyadenylation (APA) in plants. However, small-scale and high-depth HTS aimed at detecting genes or gene families are very few and limited. We explored a convenient and flexible method for profiling SSs and PASs, which combines rapid amplification of 3′-cDNA ends (3′-RACE) and HTS. Fourteen NAC (NAM, ATAF1/2, CUC2) transcription factor genes of Populus trichocarpa were analyzed by 3′-RACE-seq. Based on experimental reproducibility, boundary sequence analysis and reverse transcription PCR (RT-PCR) verification, only canonical SSs were considered to be authentic. Based on stringent criteria, candidate PASs without any internal priming features were chosen as authentic PASs and assumed to be PAS-rich markers. Thirty-four novel canonical SSs, six intronic/internal exons and thirty 3′-UTR PAS-rich markers were revealed by 3′-RACE-seq. Using 3′-RACE and real-time PCR, we confirmed that three APA transcripts ending in/around PAS-rich markers were differentially regulated in response to plant hormones. Our results indicate that 3′-RACE-seq is a robust and cost-effective method to discover SSs and label active regions subjected to APA for genes or gene families. The method is suitable for small-scale AS and APA research in the initial stage.
Highlights
Precise splicing and polyadenylation are required for production of translatable mRNA
In order to cover most of the target genes, the gene-specific primers were designed adjacent to the initiation codon
We explored a 30 -RACE-seq method to simultaneously identify splice and polyadenylation sites in plants
Summary
Precise splicing and polyadenylation are required for production of translatable mRNA. There is more than one way to choose splice sites (SSs) and polyadenylation sites (PASs), resulting in alternative splicing (AS) and alternative polyadenylation (APA) [1]. Both AS and APA contribute to gene expression regulation and can increase proteome complexity. The frequency of detected AS continually increases along with sequencing depth, sampling type diversification and technical advances. An early HTS study of Arabidopsis revealed an AS frequency of 42% in multi-exonic genes [6]. With a normalized library and longer reads, AS frequency in Arabidopsis was estimated to be 61% [8].
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