Accurate cleavage and polyadenylation of exogenous RNA substrate

Purified precursor RNA containing the L3 polyadenylation site of late adenovirus 2 mRNA is accurately cleaved and polyadenylated when incubated with nuclear extract from HeLa cells. The reaction is very efficient; 75% of the precursor is correctly processed. Cleavage is rapidly followed by polymerization of an initial poly(A) tract of approximately 130 nucleotides. Additional adenosine residues are added during further incubation. In the presence of the ATP analog alpha-beta-methylene-adenosine 5' triphosphate, the precursor RNA is cleaved but not polyadenylated, suggesting that processing is not coupled to the synthesis of the initial poly(A) tract. In the absence of free Mg2+, a small RNA of approximately 46 nucleotides is stabilized against degradation. Fingerprint analysis suggests this RNA is produced by endonucleolytic cleavage at the L3 site. Like the in vitro splicing reaction, the in vitro polyadenylation reaction is inhibited by adding antiserum against the small nuclear ribonucleoprotein particle containing U1 RNA.     

Conditional defect in mRNA 3'' end processing caused by a mutation in the gene for poly(A) polymerase.

Maturation of most eukaryotic mRNA 3' ends requires endonucleolytic cleavage and polyadenylation of precursor mRNAs. To further understand the mechanism and function of mRNA 3' end processing, we identified a temperature-sensitive mutant of Saccharomyces cerevisiae defective for polyadenylation. Genetic analysis showed that the polyadenylation defect and the temperature sensitivity for growth result from a single mutation. Biochemical analysis of extracts from this mutant shows that the polyadenylation defect occurs at a step following normal site-specific cleavage of a pre-mRNA at its polyadenylation site. Molecular cloning and characterization of the wild-type allele of the mutated gene revealed that it (PAP1) encodes a previously characterized poly(A) polymerase with unknown RNA substrate specificity. Analysis of mRNA levels and structure in vivo indicate that shift of growing, mutant cells to the nonpermissive temperature results in the production of poly(A)-deficient mRNAs which appear to end at their normal cleavage sites. Interestingly, measurement of the rate of protein synthesis after the temperature shift shows that translation continues long after the apparent loss of polyadenylated mRNA. Our characterization of the pap1-1 defect implicates this gene as essential for mRNA 3' end formation in S. cerevisiae.     

Plant mitochondrial polyadenylated mRNAs are degraded by a 3'- to 5'-exoribonuclease activity, which proceeds unimpeded by stable secondary structures

Recently, we and others have reported that mRNAs may be polyadenylated in plant mitochondria, and that polyadenylation accelerates the degradation rate of mRNAs. To further characterize the molecular mechanisms involved in plant mitochondrial mRNA degradation, we have analyzed the polyadenylation and degradation processes of potato atp9 mRNAs. The overall majority of polyadenylation sites of potato atp9 mRNAs is located at or in the vicinity of their mature 3'-extremities. We show that a 3'- to 5'-exoribonuclease activity is responsible for the preferential degradation of polyadenylated mRNAs as compared with non-polyadenylated mRNAs, and that 20-30 adenosine residues constitute the optimal poly(A) tail size for inducing degradation of RNA substrates in vitro. The addition of as few as seven non-adenosine nucleotides 3' to the poly(A) tail is sufficient to almost completely inhibit the in vitro degradation of the RNA substrate. Interestingly, the exoribonuclease activity proceeds unimpeded by stable secondary structures present in RNA substrates. From these results, we propose that in plant mitochondria, poly(A) tails added at the 3' ends of mRNAs promote an efficient 3'- to 5'- degradation process.     

A novel plant in vitro assay system for pre-mRNA cleavage during 3'-end formation

Messenger RNA (mRNA) maturation in eukaryotic cells requires the formation of the 3' end, which includes two tightly coupled steps: the committing cleavage reaction that requires both correct cis-element signals and cleavage complex formation, and the polyadenylation step that adds a polyadenosine [poly(A)] tract to the newly generated 3' end. An in vitro biochemical assay plays a critical role in studying this process. The lack of such an assay system in plants hampered the study of plant mRNA 3'-end formation for the last two decades. To address this, we have now established and characterized a plant in vitro cleavage assay system, in which nuclear protein extracts from Arabidopsis (Arabidopsis thaliana) suspension cell cultures can accurately cleave different pre-mRNAs at expected in vivo authenticated poly(A) sites. The specific activity is dependent on appropriate cis-elements on the substrate RNA. When complemented by yeast (Saccharomyces cerevisiae) poly(A) polymerase, about 150-nucleotide poly(A) tracts were added specifically to the newly cleaved 3' ends in a cooperative manner. The reconstituted polyadenylation reaction is indicative that authentic cleavage products were generated. Our results not only provide a novel plant pre-mRNA cleavage assay system, but also suggest a cross-kingdom functional complementation of yeast poly(A) polymerase in a plant system.     

Polyadenylation accelerates degradation of chloroplast mRNA.

The expression of chloroplast genes is regulated by several mechanisms, one of which is the modulation of RNA stability. To understand how this regulatory step is controlled during chloroplast development, we have begun to define the mechanism of plastid mRNA degradation. We show here that the degradation petD mRNA involves endonucleolytic cleavage at specific sites upstream of the 3' stem-loop structure. The endonucleolytic petD cleavage products can be polyadenylated in vitro, and similar polyadenylated RNA products are detectable in vivo. PCR analysis of the psbA and psaA-psaB-rps14 operons revealed other polyadenylated endonucleolytic cleavage products, indicating that poly(A) addition appears to be an integral modification during chloroplast mRNA degradation. Polyadenylation promotes efficient degradation of the cleaved petD RNAs by a 3'-5' exoribonuclease. Furthermore, polyadenylation also plays an important role in the degradation of the petD mRNA 3' end. Although the 3' end stem-loop is usually resistant to nucleases, adenylation renders the secondary structure susceptible to the 3'-5' exoribonuclease. Analysis of 3' ends confirms that polyadenylation occurs in vivo, and reveals that the extent of adenylation increases during the degradation of plastid mRNA in the dark. Based on these results, we propose a novel mechanism for polyadenylation in the regulation of plastid mRNA degradation.     

Separation and characterization of a poly(A) polymerase and a cleavage/specificity factor required for pre-mRNA polyadenylation

To study the mechanism and factors required to form the 3' ends of polyadenylated mRNAs, we have fractionated HeLa cell nuclear extracts carrying out the normally coupled cleavage and polyadenylation reactions. Each reaction is catalyzed by a distinct, separable activity. The partially purified cleavage enzyme (at least 360,000 MW) retained the specificity displayed in nuclear extracts, since substitutions in the AAUAAA signal sequence inhibited cleavage. In contrast, the fractionated poly(A) polymerase (300,000 MW) lost all specificity. When fractions containing the cleavage and polyadenylation activities were mixed, the efficiency and specificity of the polyadenylation reaction were restored. Interestingly, the cleavage activity by itself functioned well on only one of four precursor RNAs tested. However, when mixed with the poly(A) polymerase-containing fraction, the cleavage activity processed the four precursors with comparable efficiencies.     

Eukaryotic initiation factor 4G-poly(A) binding protein interaction is required for poly(A) tail-mediated stimulation of picornavirus internal ribosome entry segment-driven translation but not for X-mediated stimulation of hepatitis C virus translation

Efficient translation of most eukaryotic mRNAs results from synergistic cooperation between the 5' m(7)GpppN cap and the 3' poly(A) tail. In contrast to such mRNAs, the polyadenylated genomic RNAs of picornaviruses are not capped, and translation is initiated internally, driven by an extensive sequence termed IRES (for internal ribosome entry segment). Here we have used our recently described poly(A)-dependent rabbit reticulocyte lysate cell-free translation system to study the role of mRNA polyadenylation in IRES-driven translation. Polyadenylation significantly stimulated translation driven by representatives of each of the three types of picornaviral IRES (poliovirus, encephalomyocarditis virus, and hepatitis A virus, respectively). This did not result from a poly(A)-dependent alteration of mRNA stability in our in vitro translation system but was very sensitive to salt concentration. Disruption of the eukaryotic initiation factor 4G-poly(A) binding protein (eIF4G-PABP) interaction or cleavage of eIF4G abolished or severely reduced poly(A) tail-mediated stimulation of picornavirus IRES-driven translation. In contrast, translation driven by the flaviviral hepatitis C virus (HCV) IRES was not stimulated by polyadenylation but rather by the authentic viral RNA 3' end: the highly structured X region. X region-mediated stimulation of HCV IRES activity was not affected by disruption of the eIF4G-PABP interaction. These data demonstrate that the protein-protein interactions required for synergistic cooperativity on capped and polyadenylated cellular mRNAs mediate 3'-end stimulation of picornaviral IRES activity but not HCV IRES activity. Their implications for the picornavirus infectious cycle and for the increasing number of identified cellular IRES-carrying mRNAs are discussed.     

RNA quality control: degradation of defective transfer RNA

The distinction between stable (tRNA and rRNA) and unstable (mRNA) RNA has been considered an important feature of bacterial RNA metabolism. One factor thought to contribute to the difference between these RNA populations is polyadenylation, which promotes degradation of unstable RNA. However, the recent discovery that polyadenylation also occurs on stable RNA led us to examine whether poly(A) might serve as a signal for eliminating defective stable RNAs, and thus play a role in RNA quality control. Here we show that a readily denaturable, mutant tRNA(Trp) does not accumulate to normal levels in Escherichia coli because its precursor is rapidly degraded. Degradation is largely dependent on polyadenylation of the precursor by poly(A) polymerase and on its removal by polynucleotide phosphorylase. Thus, in the absence of these two enzymes large amounts of tRNA(Trp) precursor accumulate. We propose that defective stable RNA precursors that are poorly converted to their mature forms may be polyadenylated and subsequently degraded. These data indicate that quality control of stable RNA metabolism in many ways resembles normal turnover of unstable RNA.     

Poly(A) polymerase purified from HeLa cell nuclear extract is required for both cleavage and polyadenylation of pre-mRNA in vitro.

We have partially purified a poly(A) polymerase (PAP) from HeLa cell nuclear extract which is involved in the 3'-end formation of polyadenylated mRNA. PAP had a molecular weight of approximately 50 to 60 kilodaltons. In the presence of manganese ions, PAP was able to polyadenylate RNA nonspecifically. However, in the presence of magnesium ions PAP required the addition of a cleavage and polyadenylation factor to specifically polyadenylate pre-mRNAs that contain an intact AAUAAA sequence and end at the poly(A) addition site (precleaved RNA substrates). The purified fraction containing PAP was also required in combination with a cleavage and polyadenylation factor and a cleavage factor for the correct cleavage at the poly(A) site of pre-mRNAs. Since the two activities of the PAP fractions, PAP and cleavage activity, could not be separated by extensive purification, we concluded that the two activities are contained in a single component, a PAP that is also required for the specific cleavage preceding the polyadenylation of pre-mRNA.     

Signal sequence for generation of mRNA 3'' end in the Saccharomyces cerevisiae GAL7 gene.

We have identified a signal sequence (designated core signal) necessary to specify formation of mRNA 3' end of the GAL7 gene in Saccharomyces cerevisiae within a DNA segment 26 bp long. The sequence was located 4-5 nucleotides upstream from the 3' end, i.e. the polyadenylation site, of the GAL7 mRNA. Replacement of a DNA segment encompassing the polyadenylation site with a pBR322 DNA, leaving the core signal intact, resulted in alteration of the mRNA 3' end by several nucleotides, suggesting the existence of an additional signal (designated end signal) at or near the polyadenylation site. The normal end formation was abolished when the core signal was placed in the reverse orientation. A considerable fraction of pre-mRNA synthesized in vitro with SP6 RNA polymerase on the template of a DNA fragment containing these signals was cleaved and polyadenylated presumably at the in vitro 3' end during incubation in a cell-free system of yeast. By contrast pre-mRNA synthesized on the template with the core signal alone was processed but much less efficiently. No such processing was seen when the pre-mRNA either lacked the core signal or contained it in the reverse orientation.