ABSTRACT
Transcription of the majority of eukaryotic genes is accompanied by splicing, a process that depends on the assembly of the spliceosome on introns. The timing of spliceosome assembly varies significantly between introns, transcripts, genes and species. While quick co-transcriptional intron removal has been demonstrated for many mammalian genes, most splicing events do not occur immediately after intron synthesis. In this study, we utilized the highly expressed Tg gene, which forms exceptionally long transcription loops (Leidescher et al., 2022), providing a convenient model for studying splicing dynamics using advanced light microscopy. Our single-cell oligopainting-based analysis revealed a delay in splicing several tens of kilobases downstream of a transcribed intron, a finding further supported by standard cell population analyses. We speculate that this phenomenon is due to the abnormally high transcription rate of the Tg gene, which may lead to a localized deficiency in splicing factors and, consequently, delayed spliceosome assembly on thousands of nascent transcripts decorating the gene. Additionally, we found that, in contrast to short introns (<10 kb), long Tg intron (>50 kb) is spliced promptly, providing further support for the idea that intron length may modulate splicing speed.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
No new experiments; only major revision of the text