Position of the Final Intron in Full-Length Transcripts: Determined by NMD?

Nonsense-mediated decay (NMD) pathways for detection and degradation of transcripts containing premature termination (stop) codons (PTCs) are ubiquitous among the eukaryotes. NMD uses the presence of a second signal downstream of a termination codon to distinguish a PTC from a true stop codon. In mammals and perhaps other eukaryotes, the second signal is a protein complex closely associated with exon-exon junctions formed after removal of spliceosomal introns. A valid transcript in such species must have its 3'-most intron positioned so as not to serve as a second signal relative to the true stop. This requirement has been termed the "55-bp rule", in reference to the position within the 3' untranslated region (3' UTR) of valid transcripts downstream of which introns should not be found. However, as more information has become available, it is apparent that the 55-bp rule still holds in species with NMD pathways, which are not intron dependent. To clarify the applicability of the 55-bp rule, we constructed a large database of 3'-most intron positions within full-length transcripts from 4 eukaryotes, 2 of which (human and mouse) use intron positions for NMD, 1 of which (Drosophila melanogaster) does not, and 1 of which (Arabidopsis thaliana) may not use intron positions. Surprisingly, we found intron numbers to be sharply reduced within 3' UTRs in comparison to coding sequences starting immediately downstream of true stop, rather than 55 bp; this strong threshold existed for all 4 species. We suggest that a more general mechanism--higher rates of intron inclusion within 3' UTRs--is better able to explain this threshold. We propose that 3' UTRs are better able to tolerate loss of intron integrity than other gene regions, due to the generally greater length of conserved sequences important within 3' UTR exons. This mechanism may also help to explain the roughly 3 times greater length of 3' UTRs in comparison to 5' UTRs.