Several aspects of eukaryotic mRNA processing are linked to transcription. In Saccharomyces cerevisiae, overexpression of the mRNA export factor Sub2p suppresses the growth defect of hpr1 null cells, yet the protein Hpr1p and the associated THO protein complex are implicated in transcriptional elongation. Indeed, we find that a pool of heat shock HSP104 transcripts are 3-end truncated in THO complex mutant as well as sub2 mutant backgrounds. Surprisingly, however, this defect can be suppressed by deletion of the 3-5 exonuclease Rrp6p. This indicates that incomplete RNAs result from nuclear degradation rather than from a failure to efficiently elongate transcription. RNAs that are not degraded are retained at the transcription site in a Rrp6p-dependent manner. Interestingly, the addition of a RRP6 deletion to sub2 or to THO complex mutants shows a strong synthetic growth phenotype, suggesting that the failure to retain and/or degrade defective mRNAs is deleterious. mRNAs produced in the 3-end processing mutants rna14-3 and rna15-2, as well as an RNA harboring a 3 end generated by a self-cleaving hammerhead ribozyme, are also retained in Rrp6p-dependent transcription site foci. Taken together, our results show that several classes of defective RNPs are subject to a quality control step that impedes release from transcription site foci and suggest that suboptimal messenger ribonucleoprotein assembly leads to RNA degradation by Rrp6p.The physical separation of mRNA biogenesis and bulk protein synthesis in eukaryotic cells necessitates molecular transport between the nuclear and cytoplasmic compartments. To form a mature translatable mRNA, several processing steps must be completed accurately in the nucleus. In successful formation of mature translatable mRNAs, the 5Ј end of the transcript acquires a methylated guanosine cap structure, introns are excised, and the 3Ј end is cleaved and polyadenylated (for a review, see reference 31). These pre-mRNA modifications serve to protect the transcript from the cellular degradation systems as well as prepare it for downstream events. Over the past few years, it has been established that pre-mRNA processing is carefully coordinated with transcription, and processing events are thought to occur mostly while the premRNA is nascent, i.e., still emerging from the transcription machinery (29). Nuclear mRNA export is tightly linked to pre-mRNA processing and, consequently, probably also to transcription. In metazoans, although not strictly required for export, pre-mRNA splicing has been found to make loading of export factors onto the mRNA more efficient: the exon junction complex associates with the mRNA as a consequence of splicing, and the exon junction complex-associated proteins Aly/REF and UAP56 are important for productive mRNA export (14,22,24,25,28,32). The Saccharomyces cerevisiae orthologues of these two proteins (the RNA binding protein Yra1p and the DECD-box RNA helicase Sub2p, respectively) are also involved in mRNA export in this organism (18,37,38,40). Aly/Yra1p is b...
