Abstract
Backmasking is a recording technique used to hide a sound or message in a music track in reverse, meaning that it is only audible when the record is played backwards. Analogously, the compact yeast genome encodes for diverse sources of information such as overlapping coding and non-coding transcripts, and protein-binding sites on the two complementary DNA strands. Examples are the consensus binding site sequences of the RNA-binding proteins Nrd1 and Nab3 that target non-coding transcripts for degradation. Here, by examining the overlap of stable (SUTs, stable unannotated transcripts) and unstable (CUTs, cryptic unstable transcripts) transcripts with protein-coding genes, we show that the predicted Nrd1 and Nab3-binding site sequences occur at differing frequencies. They are always depleted in the sense direction of protein-coding genes, thus avoiding degradation of the transcript. However in the antisense direction, predicted binding sites occur at high frequencies in genes with overlapping unstable ncRNAs (CUTs), so limiting the availability of non-functional transcripts. In contrast they are depleted in genes with overlapping stable ncRNAs (SUTs), presumably to avoid degrading the non-coding transcript. The protein-coding genes maintain similar amino-acid contents, but they display distinct codon usages so that Nrd1 and Nab3-binding sites can arise at differing frequencies in antisense depending on the overlapping transcript type. Our study demonstrates how yeast has evolved to encode multiple layers of information—protein-coding genes in one strand and the relative chance of degrading antisense RNA in the other strand—in the same regions of a compact genome.
Highlights
About 85% of the Saccharomyces cerevisiae genome is transcribed [1]: in addition to messenger RNAs and the classical non-coding RNAs such as small nuclear RNAs, transfer RNAs and ribosomal RNAs [2], other ncRNAs with unknown functions have been described [3,4]. Some of these latter RNAs play a role in gene regulation [5,6,7,8,9,10,11,12] and they have been classified as stable uncharacterised transcripts (SUTs) and cryptic unstable transcripts (CUTs), depending on whether or not their expression is observed in wild-type cells (SUTs) or only upon deletion of RRP6, a component of the exosome (CUTs) [9]
First we assessed the occurrence of the consensus binding motifs for Nrd1 (UGUA, GAUG, UGUAG) and Nab3 (UCUU, CUUG, UCUUG) within the different types of transcripts produced from the yeast genome
Results showing the binding of Nrd1 and Nab3 to increase with the numbers of predicted binding sites [21,22] imply that a larger number of these near the transcription start site suggests a higher degradation rate for transcripts produced from these genes. (See Figure 1A for a schematic indicating these regions.) Figure 1B displays the average frequencies of predicted Nrd1 and Nab3-binding sites in the first 400 bp of transcripts; as previously described [10,17], CUTs encode the largest number of predicted binding sites, reflecting their fast degradation, followed by SUTs and ORF transcripts
Summary
About 85% of the Saccharomyces cerevisiae genome is transcribed [1]: in addition to messenger RNAs (mRNA) and the classical non-coding RNAs (ncRNA) such as small nuclear RNAs, transfer RNAs and ribosomal RNAs [2], other ncRNAs with unknown functions have been described [3,4] Some of these latter RNAs play a role in gene regulation [5,6,7,8,9,10,11,12] and they have been classified as stable uncharacterised transcripts (SUTs) and cryptic unstable transcripts (CUTs), depending on whether or not their expression is observed in wild-type cells (SUTs) or only upon deletion of RRP6, a component of the exosome (CUTs) [9]. The binding affinities of Nrd and Nab, and subsequently the termination and degradation efficiency of this pathway, increases with the number of predicted binding sites in a transcript [21,22]
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