Nucleocytoplasmic transport: Ran, beta and beyond.

Proteins, RNAs and even large macromolecular complexes are transported into and out of nuclei with remarkable rapidity and specificity. Nucleocytoplasmic transport must therefore be efficient and selective. Characterization of the roles of the importin beta family of transport receptors and of the Ran GTPase has showed how these characteristics can be achieved, but there are many examples of nucleocytoplasmic transport that do not fit this model. Here, we discuss current understanding of various transport mechanisms and evaluate cases in which the molecules and mechanisms underlying nucleocytoplasmic transport are used to carry out important cellular functions in the absence of a nucleus.

Herpes simplex virus ICP27 protein provides viral mRNAs with access to the cellular mRNA export pathway.

The role of herpes simplex virus ICP27 protein in mRNA export is investigated by microinjection into Xenopus laevis oocytes. ICP27 dramatically stimulates the export of intronless viral mRNAs, but has no effect on the export of cellular mRNAs, U snRNAs or tRNA. Use of inhibitors shows, in contrast to previous suggestions, that ICP27 neither shuttles nor exports viral mRNA via the CRM1 pathway. Instead, ICP27-mediated viral RNA export requires REF and TAP/NXF1, factors involved in cellular mRNA export. ICP27 binds directly to REF and complexes containing ICP27, REF and TAP are found in vitro and in virally infected cells. A mutant ICP27 that does not interact with REF is inactive in viral mRNA export. We propose that ICP27 associates with viral mRNAs and recruits TAP/NXF1 via its interaction with REF proteins, allowing the otherwise inefficiently exported viral mRNAs to access the TAP-mediated export pathway. This represents a novel mechanism for export of viral mRNAs.

Intercistronic region required for polycistronic pre-mRNA processing in Caenorhabditis elegans.

In Caenorhabditis elegans, polycistronic pre-mRNAs are processed by cleavage and polyadenylation at the 3' ends of the upstream genes and trans splicing, generally to the specialized spliced leader SL2, at the 5' ends of the downstream genes. Previous studies have indicated a relationship between these two events in the processing of a heat shock-induced gpd-2-gpd-3 polycistronic pre-mRNA. Here, we report mutational analysis of the intercistronic region of this operon by linker scan analysis. Surprisingly, no sequences downstream of the 3' end were important for 3'-end formation. In contrast, a U-rich (Ur) element located 29 bp downstream of the site of 3'-end formation was shown to be important for downstream mRNA biosynthesis. This approximately 20-bp element is sufficient for SL2 trans splicing and mRNA accumulation when transplanted to a heterologous context. Furthermore, when the downstream gene was replaced by a gene from another organism, no loss of trans-splicing specificity was observed, suggesting that the Ur element may be the primary signal required for downstream mRNA processing.

The role of exportin-t in selective nuclear export of mature tRNAs.

Exportin-t (Xpo-t) is a vertebrate nuclear export receptor for tRNAs that binds tRNA cooperatively with GTP-loaded Ran. Xpo-t antibodies are shown to efficiently block tRNA export from Xenopus oocyte nuclei suggesting that it is responsible for at least the majority of tRNA export in these cells. We examine the mechanism by which Xpo-t-RanGTP specifically exports mature tRNAs rather than other forms of nuclear RNA, including tRNA precursors. Chemical and enzymatic footprinting together with phosphate modification interference reveals an extensive interaction between the backbone of the TPsiC and acceptor arms of tRNAPhe and Xpo-t-RanGTP. Analysis of mutant or precursor tRNA forms demonstrates that, aside from these recognition elements, accurate 5' and 3' end-processing of tRNA affects Xpo-t-RanGTP interaction and nuclear export, while aminoacylation is not essential. Intron-containing, end-processed, pre-tRNAs can be bound by Xpo-t-RanGTP and are rapidly exported from the nucleus if Xpo-t is present in excess. These results suggest that at least two mechanisms are involved in discrimination of pre-tRNAs and mature tRNAs prior to nuclear export.

Relationship between 3' end formation and SL2-specific trans-splicing in polycistronic Caenorhabditis elegans pre-mRNA processing.

About 25% of the genes in the nematode Caenorhabditis elegans are in operons, polycistronic transcription units in which the genes are only 100-400 bp apart. The operon pre-mRNAs are processed into monocistronic mRNAs by a combination of cleavage and polyadenylation at the 3' end of the upstream mRNA and SL2 trans-splicing at the 5' end of the downstream mRNA. To determine whether 3' end formation and SL2 trans-splicing are coupled mechanistically, we tested a gpd-2/gpd-3 operon construct driven by a C. elegans heat shock promoter, and measured the effects of inhibition of 3' end formation and/or trans-splicing on the processing of the polycistronic RNA in vivo. The results indicate that proper 3' end formation of the upstream mRNA in an operon is required for SL2-specificity of downstream mRNA trans-splicing. In contrast, trans-splicing of the downstream mRNA is not necessary for correct 3' end formation of the upstream mRNA. In addition, shortening the distance between the 5' cap and the AAUAAA of gpd-2 (the upstream gene) decreases the efficiency of 3' end formation and is accompanied by a replacement of SL2 with SL1 at the trans-splice site of gpd-3, the downstream gene. These results indicate that SL2 trans-splicing, in C. elegans, is coupled mechanistically to 3' end formation in the processing of polycistronic pre-mRNAs.

Operons in C. elegans: polycistronic mRNA precursors are processed by trans-splicing of SL2 to downstream coding regions.

The mRNAs of six C. elegans genes are known to be trans-spliced to SL2. We report here that a similarly oriented gene is located 100-300 bp upstream of each. We present evidence that the genes in these clusters are cotranscribed and downstream mRNAs are formed by cleavage at the polyadenylation site and trans-splicing. From one three-gene cluster we isolated cDNA clones representing both polycistronic RNAs and mRNAs polyadenylated at the free 3' end created by trans-splicing, suggesting that polycistronic RNAs can be processed by trans-splicing. Several experiments indicate that SL2 trans-splicing is a consequence of a gene's downstream location in an operon. In particular, when an SL1-accepting gene was moved to a downstream location, its mRNA was trans-spliced largely to SL2. The possible regulatory significance of cotranscription of C. elegans genes is discussed.