Conditional mutants of the yeast mRNA capping enzyme show that the cap enhances, but is not required for, mRNA splicing.

The 5' end of eukaryotic mRNAs are modified by the addition of a 7-methyl guanosine (m7G) cap. The role of the cap in translation has been well established. Additionally, studies conducted in vitro or in microinjected Xenopus oocytes have implicated the cap in RNA processing and transport. To determine the fate of uncapped mRNA in intact yeast cells, conditional alleles of the gene encoding the capping enzyme guanylyltransferase subunit (CEG1) were generated. RNA analysis of temperature-sensitive ceg1 strains revealed an accumulation of unspliced pre-mRNAs and a corresponding decrease in spliced mRNAs at the restrictive temperature. A substantial proportion of spliced mRNA was also uncapped. Therefore, the cap appears to stimulate, but is not absolutely required for, splicing in vivo. In addition, steady-state levels of several mRNAs were decreased, perhaps due to increased degradation of uncapped mRNAs. In contrast to splicing, mRNA polyadenylation and transport to the cytoplasm were unaffected.     

Accelerated mRNA decay in conditional mutants of yeast mRNA capping enzyme.

Current models of mRNA decay in yeast posit that 3' deadenylation precedes enzymatic removal of the 5' cap, which then exposes the naked end to 5' exonuclease action. Here, we analyzed gene expression in Saccharomyces cerevisiae cells bearing conditional mutations of Ceg1 (capping enzyme), a 52 kDa protein that transfers GMP from GTP to the 5' end of mRNA to form the GpppN cap structure. Shift of ceg1 mutants to restrictive temperature elicited a rapid decline in the rate of protein synthesis, which correlated with a sharp reduction in the steady-state levels of multiple individual mRNAs. ceg1 mutations prevented the accumulation of SSA1 and SSA4 mRNAs that were newly synthesized at the restrictive temperature. Uncapped poly(A)+ SSA4 mRNA accumulated in cells lacking the 5' exoribonuclease Xrn1. These findings provide genetic evidence for the long-held idea that the cap guanylate is critical for mRNA stability. The deadenylation-decapping-degradation pathway appears to be short-circuited when Ceg1 is inactivated.     

Tetracycline aptamer-controlled regulation of pre-mRNA splicing in yeast

Splicing of pre-mRNA is a critical step in mRNA maturation and disturbances cause several genetic disorders. We apply the synthetic tetracycline (tc)-binding riboswitch to establish a gene expression system for conditional tc-dependent control of pre-mRNA splicing in yeast. Efficient regulation is obtained when the aptamer is inserted close to the 5′splice site (SS) with the consensus sequence of the SS located within the aptamer stem. Structural probing indicates limited spontaneous cleavage within this stem in the absence of the ligand. Addition of tc leads to tightening of the stem and the whole aptamer structure which probably prevents recognition of the 5′SS. Combination of more then one aptamer-regulated intron increases the extent of regulation leading to highly efficient conditional gene expression systems. Our findings highlight the potential of direct RNA–ligand interaction for regulation of gene expression.     

Short artificial hairpins sequester splicing signals and inhibit yeast pre-mRNA splicing.

To examine the stability of yeast (Saccharomyces cerevisiae) pre-mRNA structures, we inserted a series of small sequence elements that generated potential RNA hairpins at the 5' splice site and branch point regions. We analyzed spliceosome assembly and splicing in vitro as well as splicing and nuclear pre-mRNA retention in vivo. Surprisingly, the inhibition of in vivo splicing approximately paralleled that of in vitro splicing. Even a 6-nucleotide hairpin could be shown to inhibit splicing, and a 15-nucleotide hairpin gave rise to almost complete inhibition. The in vitro results indicate that hairpins that sequester the 5' splice site have a major effect on the early steps of spliceosome assembly, including U1 small nuclear ribonucleoprotein binding. The in vivo experiments lead to comparable conclusions as the sequestering hairpins apparently result in the transport of pre-mRNA to the cytoplasm. The observations are compared with previous data from both yeast and mammalian systems and suggest an important effect of pre-mRNA structure on in vivo splicing.     

Exploitation of a thermosensitive splicing event to study pre-mRNA splicing in vivo.

The spliced form of MuSVts110 viral RNA is approximately 20-fold more abundant at growth temperatures of 33 degrees C or lower than at 37 to 41 degrees C. This difference is due to changes in the efficiency of MuSVts110 RNA splicing rather than selective thermolability of the spliced species at 37 to 41 degrees C or general thermosensitivity of RNA splicing in MuSVts110-infected cells. Moreover, RNA transcribed from MuSVts110 DNA introduced into a variety of cell lines is spliced in a temperature-sensitive fashion, suggesting that the structure of the viral RNA controls the efficiency of the event. We exploited this novel splicing event to study the cleavage and ligation events during splicing in vivo. No spliced viral mRNA or splicing intermediates were observed in MuSVts110-infected cells (6m2 cells) at 39 degrees C. However, after a short (about 30-min) lag following a shift to 33 degrees C, viral pre-mRNA cleaved at the 5' splice site began to accumulate. Ligated exons were not detected until about 60 min following the initial detection of cleavage at the 5' splice site, suggesting that these two splicing reactions did not occur concurrently. Splicing of viral RNA in the MuSVts110 revertant 54-5A4, which lacks the sequence -AG/TGT- at the usual 3' splice site, was studied. Cleavage at the 5' splice site in the revertant viral RNA proceeded in a temperature-sensitive fashion. No novel cryptic 3' splice sites were activated; however, splicing at an alternate upstream 3' splice site used at low efficiency in normal MuSVts110 RNA was increased to a level close to that of 5'-splice-site cleavage in the revertant viral RNA. Increased splicing at this site in 54-5A4 viral RNA is probably driven by the unavailability of the usual 3' splice site for exon ligation. The thermosensitivity of this alternate splice event suggests that the sequences governing the thermodependence of MuSVts110 RNA splicing do not involve any particular 3' splice site or branch point sequence, but rather lie near the 5' end of the intron.     

DcpS scavenger decapping enzyme can modulate pre-mRNA splicing

The human scavenger decapping enzyme, DcpS, functions to hydrolyze the resulting cap structure following cytoplasmic mRNA decay yet is, surprisingly, a nuclear protein by immunofluorescence. Here, we show that DcpS is a nucleocytoplasmic shuttling protein that contains separable nuclear import and Crm-1-dependent export signals. We postulated that the presence of DcpS in both cellular compartments and its ability to hydrolyze cap structure may impact other cellular events dependent on cap-binding proteins. An shRNA-engineered cell line with markedly diminished DcpS levels led to a corresponding reduction in cap-proximal intron splicing of a reporter minigene and endogenous genes. The impaired cap catabolism and resultant imbalanced cap concentrations were postulated to sequester the cap-binding complex (CBC) from its normal splicing function. In support of this explanation, DcpS efficiently displaced the nuclear cap-binding protein Cbp20 from cap structure, and complementation with Cbp20 reversed the reduced splicing, indicating that modulation of splicing by DcpS is mediated through Cbp20. Our studies demonstrate that the significance of DcpS extends beyond its well-characterized role in mRNA decay and involves a broader range of functions in RNA processing including nuclear pre-mRNA splicing.     

Modulation of alternative pre-mRNA splicing in vivo by pinin

Pre-mRNA splicing occurs in a large macromolecular RNA-protein complex called the spliceosome. The major components of the spliceosome include snRNP and SR proteins. We have previously identified an SR-like protein, pinin (pnn), which is localized not only in nuclear speckles but also at desmosomes. The nuclear localization of pnn is a dynamic process because pnn can be found not only with SR proteins in nuclear speckles but also in enlarged speckles following treatment of cells with RNA polymerase II inhibitors, DRB, and alpha-amanitin. Using adenovirus E1A and chimeric calcitonin/dhfr construct as a splicing reporter minigene in combination with cellular cotransfection, we found that pnn regulates alternative 5(') and 3(') splicing by decreasing the use of distal splice sites. Regulation of 5(') splice site choice was also observed for RNPS1, a general splicing activator that interacts with pnn in nuclear speckles. The regulatory ability of pnn in alternative 5(') splicing, however, was not dependent on RNPS1 and a pnn mutant, lacking the N-terminal 167 amino acids, behaved like a dominant negative species, inhibiting E1A splicing when applied in splicing assays. These results provide direct evidence that pnn functions as a splicing regulator which participates itself directly in splicing reaction or indirectly via other components of splicing machinery.     

A conserved mRNA export machinery coupled to pre-mRNA splicing

Recent advances have led to a new understanding of how mRNAs are exported from the nucleus to the cytoplasm. This process requires a heterodimeric mRNA export receptor that is part of an elaborate machinery conserved from yeast to humans. Export of mRNAs is coupled to upstream steps in gene expression, such as pre-mRNA splicing, and to downstream events, including nonsense-mediated decay.     

Human pre-mRNA splicing signals.

A sample of 764 pairs of human pre-mRNA exon-intron and intron-exon boundaries, extracted from the European Molecular Biology Laboratory data bank, is analyzed to provide a species-optimized characterization of donor and acceptor sites, evaluate the information content of the two signals (found to be about 8 and 9 bits respectively) and check the independent-base approximation (which holds well) and the "GT-AG" rule (to which, a few well-documented exceptions are found). No correlation is detected between the strength ("discrimination energy") of an actual donor-site signal and that of its corresponding acceptor-site counterpart, nor between that of either signal, or the cumulative strength of both, and the length of the intervening intron. The discrimination-energy distributions of the two signals are determined. Because of the large sample size and its single-species origin, the two distributions can be presumed to be representative of their underlying genomic counterparts. The size distribution of the introns shows a lower cut-off of 70 nucleotides (in essential agreement with published experimental results), and apparently no periodicities. A smaller sample of mammalian branch sites, taken from the literature, is similarly analyzed to attempt a characterization of this rather elusive signal, and provides some indication that at least part of the "long pyrimidine stretch", usually considered an integral constituent of the 3' splice signal, may be just as strongly associated with the branch site, in agreement with recent experimental observations. The usefulness of these characterizations for splice-junction searches is assessed on a test sequence.     

Site-specific deoxynucleotide substitutions in yeast U6 snRNA block splicing of pre-mRNA in vitro.

We have identified 2'-hydroxyl groups of the U6 phosphate-ribose backbone which are required for reconstitution of splicing activity in U6-depleted yeast extract. To screen the 2'-hydroxyls of yeast U6 at nucleotides 39-88, spanning the conserved central domain, synthetic U6 RNAs were constructed with deoxyribonucleotides incorporated site specifically. Only four individual deoxynucleotide substitutions blocked splicing activity: dA51 (in the ACAGAG sequence), dA62 (next to the AGC triad), and dU70 and dC72 (both in the loop of the 3' intramolecular stem-loop). Native gel analysis revealed that these deoxy-substituted U6 RNAs were competent for assembly of spliceosomes. Interestingly, a 2'-O-methyl substituent at A51, A62, U70 or C72 did not inhibit splicing activity, indicating that the essential 2'-OH groups at these positions in U6 act as hydrogen bond acceptors or neutral coordinated ligands. The requisite 2'-hydroxyls at A62, U70 and C72 show both similarities and differences relative to the positions of essential 2'-hydroxyls of catalytic domain V of group II ribozymes. The identification of the essential 2'-hydroxyls at positions 62, 70 and 72 corroborates that the 3' intramolecular stem-loop in U6 plays an important role in pre-mRNA splicing.     

The purified yeast pre-mRNA splicing factor PRP2 is an RNA-dependent NTPase.

Unlike autocatalyzed self-splicing reactions, nuclear pre-mRNA splicing requires transacting macromolecules and ATP. A protein encoded by the PRP2 gene of Saccharomyces cerevisiae is required, in conjunction with ATP, for the first cleavage-ligation reaction of pre-mRNA splicing. In this study, we have purified two forms of the PRP2 gene product with apparent molecular weights of 100 kDa and 92 kDa, from a yeast strain overproducing the protein. Both proteins were indistinguishable in their ability to complement extracts derived from a heat-sensitive prp2 mutant. Furthermore, we show that the PRP2 protein is capable of hydrolyzing nucleoside triphosphates in the presence of single-stranded RNAs such as poly(U). However, purified PRP2 by itself did not unwind double-stranded RNA substrates. The fact that an RNA-dependent NTPase activity is intrinsic to PRP2 may account for the ATP requirement in the first catalytic reaction of pre-mRNA splicing.