Chromatin-sensitive cryptic promoters putatively drive expression of alternative protein isoforms in yeast.

Wei W, Hennig BP, Wang J, Zhang Y, Piazza I, Pareja Sanchez Y, Chabbert CD, Adjalley SH, Steinmetz LM, Pelechano V

Genome Res. 29 (12) 1974-1984 [2019-12-00; online 2019-11-18]

Cryptic transcription is widespread and generates a heterogeneous group of RNA molecules of unknown function. To improve our understanding of cryptic transcription, we investigated their transcription start site (TSS) usage, chromatin organization, and posttranscriptional consequences in Saccharomyces cerevisiae We show that TSSs of chromatin-sensitive internal cryptic transcripts retain comparable features of canonical TSSs in terms of DNA sequence, directionality, and chromatin accessibility. We define the 5' and 3' boundaries of cryptic transcripts and show that, contrary to RNA degradation-sensitive ones, they often overlap with the end of the gene, thereby using the canonical polyadenylation site, and associate to polyribosomes. We show that chromatin-sensitive cryptic transcripts can be recognized by ribosomes and may produce truncated polypeptides from downstream, in-frame start codons. Finally, we confirm the presence of the predicted polypeptides by reanalyzing N-terminal proteomic data sets. Our work suggests that a fraction of chromatin-sensitive internal cryptic promoters initiates the transcription of alternative truncated mRNA isoforms. The expression of these chromatin-sensitive isoforms is conserved from yeast to human, expanding the functional consequences of cryptic transcription and proteome complexity.

Bioinformatics Support for Computational Resources [Service]

PubMed 31740578

DOI 10.1101/gr.243378.118

Crossref 10.1101/gr.243378.118

pmc: PMC6886497
pii: gr.243378.118
medline: 9509184

Publications 9.5.0