Viral Interactions with Host RNA Decay Pathways

Eukaryotes have evolved a wide variety of RNA decay pathways to maintain cellular homeostasis, carry out programs of gene expression, and respond to changing environmental conditions. Individual RNA turnover mechanisms can operate constitutively or under only particular cellular conditions; similarly, some target many RNAs, while others act with great specificity. It has become increasingly clear that there are extensive interactions between viruses and the host RNA decay machinery. Often, the cellular RNA decay machinery poses a threat to viral gene expression, but viruses can also manipulate RNA decay pathways to promote viral replication. This special issue focuses on how cellular RNA decay factors recognize and degrade viral RNAs and viral strategies to subvert or evade these pathways

The Negative Regulator of Splicing Element of Rous Sarcoma Virus Promotes Polyadenylation

The Rous sarcoma virus gag gene contains a cis-acting negative regulator of splicing (NRS) element that is implicated in viral polyadenylation regulation. To study the mechanism of polyadenylation promotion at the viral poly(A) site located over 8 kb downstream, we performed in vitro polyadenylation analysis. RNA containing only the poly(A) site and flanking sequences in the 3′ long terminal repeat (LTR) was not polyadenylated detectably in vitro; however, if the transcript contained the NRS upstream of the LTR, polyadenylation was observed. Insertion of the viral env 3′ splice site sequence between the NRS and the LTR did not alter the level of polyadenylation appreciably. We conclude that the NRS promotes polyadenylation in vitro and can do so without formation of a splicing complex with a 3′ splice site. We then explored the roles of several cellular factors in NRS-mediated polyadenylation. Mutation of the binding sites of U1 and U11 snRNPs to the NRS did not affect polyadenylation, whereas hnRNP H strongly inhibited polyadenylation. We propose a model in which hnRNP H and SR proteins compete for binding to the NRS. Bound SR proteins may bridge between the NRS and the 3′ LTR and aid in the recruitment of the 3′-end processing machinery

A 3′ UTR sequence stabilizes termination codons in the unspliced RNA of Rous sarcoma virus

Eukaryotic cells target mRNAs to the nonsense-mediated mRNA decay (NMD) pathway when translation terminates within the coding region. In mammalian cells, this is presumably due to a downstream signal deposited during pre-mRNA splicing. In contrast, unspliced retroviral RNA undergoes NMD in chicken cells when premature termination codons (PTCs) are present in the gag gene. Surprisingly, deletion of a 401-nt 3′ UTR sequence immediately downstream of the normal gag termination codon caused this termination event to be recognized as premature. We termed this 3′ UTR region the Rous sarcoma virus (RSV) stability element (RSE). The RSE also stabilized the viral RNA when placed immediately downstream of a PTC in the gag gene. Deletion analysis of the RSE indicated a smaller functional element. We conclude that this 3′ UTR sequence stabilizes termination codons in the RSV RNA, and termination codons not associated with such an RSE sequence undergo NMD

Packaging and reverse transcription of snRNAs by retroviruses may generate pseudogenes

Retroviruses specifically package two copies of their RNA genome in each viral particle, along with some small cellular RNAs, including tRNAs and 7S L RNA. We show here that Rous sarcoma virus (RSV) also packages U6 snRNA at approximately one copy per virion. In addition, trace amounts of U1 and U2 snRNAs were detected in purified virus by Northern blotting. U6 snRNA comigrated with the RSV 70S genomic RNA dimer on sucrose gradients. We observed reverse transcription of U6 snRNA in an endogenous reaction in which RSV particles were the source of both reverse transcriptase and RNA substrates. This finding led us to examine mammalian genomic sequences for the presence of snRNA pseudogenes. A survey of the human, mouse, and rat genomes revealed a high number of spliceosomal snRNA pseudogenes. U6 pseudogenes were the most abundant, with approximately 200 copies in each genome. In the human genome, 67% of U6 snRNA pseudogenes, and a significant number of the other snRNA pseudogenes, were associated with LINE, SINE, or retroviral LTR repeat sequences. We propose that the packaging of snRNAs in retroviral particles leads to their reverse transcription in an infected cell and the integration of snRNA/viral recombinants into the host genome

A nonsense mutation in the fibrillin-1 gene of a Marfan syndrome patient induces NMD and disrupts an exonic splicing enhancer

A nonsense mutation in the fibrillin-1 (FBN1) gene of a Marfan syndrome (MFS) patient induces in-frame exon skipping of FBN1 exon 51. We present evidence, based on both in vivo and in vitro experiments, that the skipping of this exon is due to the disruption of an SC35-dependent splicing enhancer within exon 51. In addition, this nonsense mutation induces nonsense-mediated decay (NMD), which degrades the normally spliced mRNA in the patient's cells. In contrast to NMD, skipping of FBN1 exon 51 does not require translation

Exclusion of exon 2 is a common mRNA splice variant of primate telomerase reverse transcriptases.

Telomeric sequences are added by an enzyme called telomerase that is made of two components: a catalytic protein called telomerase reverse transcriptase (TERT) and an integral RNA template (TR). Telomerase expression is tightly regulated at each step of gene expression, including alternative splicing of TERT mRNA. While over a dozen different alternative splicing events have been reported for human TERT mRNA, these were all in the 3' half of the coding region. We were interested in examining splicing of the 5' half of hTERT mRNA, especially since exon 2 is unusually large (1.3 kb). Internal mammalian exons are usually short, typically only 50 to 300 nucleotides, and most long internal exons are alternatively processed. We used quantitative RT-PCR and high-throughput sequencing data to examine the variety and quantity of mRNA species generated from the hTERT locus. We determined that there are approximately 20-40 molecules of hTERT mRNA per cell in the A431 human cell line. In addition, we describe an abundant, alternatively-spliced mRNA variant that excludes TERT exon 2 and was seen in other primates. This variant causes a frameshift and results in translation termination in exon 3, generating a 12 kDa polypeptide