Maintaining transcriptional fidelity is essential for precise gene regulation and genome stability. Despite this, cryptic antisense transcription, occurring opposite to canonical coding sequences, is a pervasive feature across all domains of life. How such potentially harmful cryptic sites are regulated remains incompletely understood. Here, we show that nucleosome arrays within gene bodies play a key role in suppressing cryptic transcription. Using the fission yeast Schizosaccharomyces pombe as a model, we demonstrate that the CHD-family chromatin remodeler Hrp3 coordinates with the transcription elongation machinery, via the transcriptional regulator Prf1/RTF1, to position nucleosomes at sites of cryptic transcription initiation within gene bodies. In the absence of Hrp3, AT-rich sequences within gene bodies lose nucleosome occupancy, exposing promoter-like sequences that drive cryptic initiation. While cryptic transcription is generally detrimental, we identify a subset of antisense transcripts that encode critical meiotic genes, suggesting that cryptic transcription can also serve as a source of regulatory innovation. These findings define an elongation‑coupled chromatin pathway that preserves transcriptional fidelity and reveal how nucleosome remodeling shapes antisense transcription, cellular homeostasis, and adaptive potential.
Kok et al. (Fri,) studied this question.