Polyadenylation of mRNA: minimal substrates and a requirement for the 2'' hydroxyl of the U in AAUAAA.

mRNA-specific polyadenylation can be assayed in vitro by using synthetic RNAs that end at or near the natural cleavage site. This reaction requires the highly conserved sequence AAUAAA. At least two distinct nuclear components, an AAUAAA specificity factor and poly(A) polymerase, are required to catalyze the reaction. In this study, we identified structural features of the RNA substrate that are critical for mRNA-specific polyadenylation. We found that a substrate that contained only 11 nucleotides, of which the first six were AAUAAA, underwent AAUAAA-specific polyadenylation. This is the shortest substrate we have used that supports polyadenylation: removal of a single nucleotide from either end of this RNA abolished the reaction. Although AAUAAA appeared to be the only strict sequence requirement for polyadenylation, the number of nucleotides between AAUAAA and the 3' end was critical. Substrates with seven or fewer nucleotides beyond AAUAAA received poly(A) with decreased efficiency yet still bound efficiently to specificity factor. We infer that on these shortened substrates, poly(A) polymerase cannot simultaneously contact the specificity factor bound to AAUAAA and the 3' end of the RNA. By incorporating 2'-deoxyuridine into the U of AAUAAA, we demonstrated that the 2' hydroxyl of the U in AAUAAA was required for the binding of specificity factor to the substrate and hence for poly(A) addition. This finding may indicate that at least one of the factors involved in the interaction with AAUAAA is a protein.     

A novel poly(A)-binding protein acts as a specificity factor in the second phase of messenger RNA polyadenylation

Polyadenylation of mRNA precursors by poly(A) polymerase depends on a specificity factor, CPF, recognizing the polyadenylation signal AAUAAA. This paper describes an apparently novel poly(A)-binding protein that acts as a second specificity factor, mediating the recognition of the growing poly(A) tail. A transition from a slow initiation phase of polyadenylation to rapid elongation occurs when the growing tail is long enough to serve as a binding site for the poly(A)-binding protein. Elongation of an RNA carrying a tail of 10 or more adenylate residues can occur independently of CPF. A sharp decrease in the poly(A) chain growth rate after the addition of approximately 200 adenylate residues invites speculations about a role of the poly(A)-binding protein in poly(A) tail length control.     

The RNA helicase Mtr4p modulates polyadenylation in the TRAMP complex

Many steps in nuclear RNA processing, surveillance, and degradation require TRAMP, a complex containing the poly(A) polymerase Trf4p, the Zn-knuckle protein Air2p, and the RNA helicase Mtr4p. TRAMP polyadenylates RNAs designated for decay or trimming by the nuclear exosome. It has been unclear how polyadenylation by TRAMP differs from polyadenylation by conventional poly(A) polymerase, which produces poly(A) tails that stabilize RNAs. Using reconstituted S. cerevisiae TRAMP, we show that TRAMP inherently suppresses poly(A) addition after only 3-4 adenosines. This poly(A) tail length restriction is controlled by Mtr4p. The helicase detects the number of 3'-terminal adenosines and, over several adenylation steps, elicits precisely tuned adjustments of ATP affinities and rate constants for adenylation and TRAMP dissociation. Our data establish Mtr4p as a critical regulator of polyadenylation by TRAMP and reveal that an RNA helicase can control the activity of another enzyme in a highly complex fashion and in response to features in RNA.     

Point mutations in AAUAAA and the poly (A) addition site: effects on the accuracy and efficiency of cleavage and polyadenylation in vitro.

Three sequences in the vicinity of poly (A) addition sites are conserved among vertebrate mRNAs. We analyze the effects of single base changes in each position of AAUAAA and in the nucleotide to which poly (A) is added on 3' end formation in vitro. All 18 possible single base changes of the AAUAAA sequence greatly reduce addition of poly (A) to RNAs that end at the poly (A) addition site, and prevent cleavage of RNAs that extend beyond. The magnitude of reduction varies greatly with the position changed and the base introduced. For any given mutation, cleavage and polyadenylation are reduced to similar extents, strongly suggesting that the same factor interacts with AAUAAA in both reactions. Mutations at and near the conserved adenosine to which poly (A) is added disturb the accuracy, but not the efficiency, of 3' end formation. For example, point mutations at the conserved adenosine shift the 3' end of the most abundant 5' half-molecule downstream by a single nucleotide. The mechanism by which these mutations might exert their effects on the precision of 3' end formation are discussed.     

Assembly of a processive messenger RNA polyadenylation complex.

Polyadenylation of mRNA precursors by poly(A) polymerase depends on two specificity factors and their recognition sequences. These are cleavage and polyadenylation specificity factor (CPSF), recognizing the polyadenylation signal AAUAAA, and poly(A) binding protein II (PAB II), interacting with the growing poly(A) tail. Their effects are independent of ATP and an RNA 5'-cap. Analysis of RNA-protein interactions by non-denaturing gel electrophoresis shows that CPSF, PAB II and poly(A) polymerase form a quaternary complex with the substrate RNA that transiently stabilizes the binding of poly(A) polymerase to the RNA 3'-end. Only the complex formed from all three proteins is competent for the processive synthesis of a full-length poly(A) tail.     

Specific pre-cleavage and post-cleavage complexes involved in the formation of SV40 late mRNA 3'' termini in vitro.

Complexes form between processing factors present in a crude nuclear extract from HeLa cells and a simian virus 40 (SV40) late pre-mRNA which spans the polyadenylation [poly(A)] site. A specific 'pre-cleavage complex' forms on the pre-mRNA before cleavage. Formation of this complex requires the highly conserved sequence AAUAAA: it is prevented by mutations in AAUAAA, and by annealing DNA oligonucleotides to that sequence. After cleavage, the 5' half-molecule is found in a distinct 'post-cleavage complex'. In contrast, the 3' half-molecule is released. After cleavage and polyadenylation, polyadenylated RNA also is released. De novo formation of the post-cleavage complex requires AAUAAA and a nearby 3' terminus. Competition experiments suggest that a component which recognizes AAUAAA is required for formation of both pre- and post-cleavage complexes.     

Opposing polymerase-deadenylase activities regulate cytoplasmic polyadenylation

Cytoplasmic polyadenylation is one mechanism that regulates translation in early animal development. In Xenopus oocytes, polyadenylation of dormant mRNAs, including cyclin B1, is controlled by the cis-acting cytoplasmic polyadenylation element (CPE) and hexanucleotide AAUAAA through associations with CPEB and CPSF, respectively. Previously, we demonstrated that the scaffold protein symplekin contacts CPEB and CPSF and helps them interact with Gld2, a poly(A) polymerase. Here, we report the mechanism by which poly(A) tail length is regulated. Cyclin B1 pre-mRNA acquires a long poly(A) tail in the nucleus that is subsequently shortened in the cytoplasm. The shortening is controlled by CPEB and PARN, a poly(A)-specific ribonuclease. Gld2 and PARN both reside in the CPEB-containing complex. However, because PARN is more active than Gld2, the poly(A) tail is short. When oocytes mature, CPEB phosphorylation causes PARN to be expelled from the ribonucleoprotein complex, which allows Gld2 to elongate poly(A) by default.     

Multiple sequence elements and a maternal mRNA product control cdk2 RNA polyadenylation and translation during early Xenopus development.

Cytoplasmic poly(A) elongation is one mechanism that regulates translational recruitment of maternal mRNA in early development. In Xenopus laevis, poly(A) elongation is controlled by two cis elements in the 3' untranslated regions of responsive mRNAs: the hexanucleotide AAUAAA and a U-rich structure with the general sequence UUUUUAAU, which is referred to as the cytoplasmic polyadenylation element (CPE). B4 RNA, which contains these sequences, is polyadenylated during oocyte maturation and maintains a poly(A) tail in early embryos. However, cdk2 RNA, which also contains these sequences, is polyadenylated during maturation but deadenylated after fertilization. This suggests that cis-acting elements in cdk2 RNA signal the removal of the poly(A) tail at this time. By using poly(A) RNA-injected eggs, we showed that two elements which reside 5' of the CPE and 3' of the hexanucleotide act synergistically to promote embryonic deadenylation of this RNA. When an identical RNA lacking a poly(A) tail was injected, these sequences also prevented poly(A) addition. When fused to CAT RNA, the cdk2 3' untranslated region, which contains these elements, as well as the CPE and the hexanucleotide, promoted poly(A) addition and enhanced chloramphenicol acetyltransferase activity during maturation, as well as repression of these events after fertilization. Incubation of fertilized eggs with cycloheximide prevented the embryonic inhibition of cdk2 RNA polyadenylation but did not affect the robust polyadenylation of B4 RNA. This suggests that a maternal mRNA, whose translation occurs only after fertilization, is necessary for the cdk2 deadenylation or inhibition of RNA polyadenylation. This was further suggested when poly(A)+ RNA isolated from two-cell embryos was injected into oocytes that were then allowed to mature. Such oocytes became deficient for cdk2 RNA polyadenylation but remained proficient for B4 RNA polyadenylation. These data show that CPE function is developmentally regulated by multiple sequences and factors.     

Several distinct types of sequence elements are required for efficient mRNA 3'' end formation in a pea rbcS gene.

We have conducted an extensive linker substitution analysis of the polyadenylation signal from a pea rbcS gene. From these studies, we can identify at least two, and perhaps three, distinct classes of cis element involved in mRNA 3' end formation in this gene. One of these, termed the far-upstream element, is located between 60 and 120 nt upstream from its associated polyadenylation sites and appears to be largely composed of a series of UG motifs. A second, termed the near-upstream element, is more proximate to poly(A) sites and may be functionally analogous to the mammalian polyadenylation signal AAUAAA, even though the actual sequences involved may not be AAUAAA. The third possible class is the putative cleavage and polyadenylation site itself. We find that the rbcS-E9 far-upstream element can replace the analogous element in another plant polyadenylation signal, that from cauliflower mosaic virus, and that one near-upstream element can function with either of two poly(A) sites. Thus, these different cis elements are largely interchangeable. Our studies indicate that a cellular plant gene possesses upstream elements distinct from AAUAAA that are involved in mRNA 3' end formation and that plant genes probably have modular, multicomponent polyadenylation signals.     

A small nuclear ribonucleoprotein associates with the AAUAAA polyadenylation signal in vitro

RNAs containing the polyadenylation sites for adenovirus L3 or E2a mRNA or for SV40 early or late mRNA are substrates for cleavage and poly(A) addition in an extract of HeLa cell nuclei. When polyadenylation reactions are probed with ribonuclease T1 and antibodies directed against either the Sm protein determinant or the trimethylguanosine cap structure at the 5' end of U RNAs in small nuclear ribonucleoproteins, RNA fragments containing the AAUAAA polyadenylation signal are immunoprecipitated. The RNA cleavage step that occurs prior to poly(A) addition is inhibited by micrococcal nuclease digestion of the nuclear extract. The immunoprecipitation of fragments containing the AAUAAA sequence can be altered, but not always abolished, by pretreatment with micrococcal nuclease. We discuss the involvement of small nuclear ribonucleoproteins in the cleavage and poly(A) addition reactions that form the 3' ends of most eukaryotic mRNAs.     

Hierarchy of polyadenylation site usage by bovine papillomavirus in transformed mouse cells.

The great majority of viral mRNAs in mouse C127 cells transformed by bovine papillomavirus type 1 (BPV) have a common 3' end at the early polyadenylation site which is 23 nucleotides (nt) downstream of a canonical poly(A) consensus signal. Twenty percent of BPV mRNA from productively infected cells bypasses the early polyadenylation site and uses the late polyadenylation site approximately 3,000 nt downstream. To inactivate the BPV early polyadenylation site, the early poly(A) consensus signal was mutated from AAUAAA to UGUAAA. Surprisingly, this mutation did not result in significant read-through expression of downstream RNA. Rather, RNA mapping and cDNA cloning experiments demonstrate that virtually all of the mutant RNA is cleaved and polyadenylated at heterogeneous sites approximately 100 nt upstream of the wild-type early polyadenylation site. In addition, cells transformed by wild-type BPV harbor a small population of mRNAs with 3' ends located in this upstream region. These experiments demonstrate that inactivation of the major poly(A) signal induces preferential use of otherwise very minor upstream poly(A) sites. Mutational analysis suggests that polyadenylation at the minor sites is controlled, at least in part, by UAUAUA, an unusual variant of the poly(A) consensus signal approximately 25 nt upstream of the minor polyadenylation sites. These experiments indicate that inactivation of the major early polyadenylation signal is not sufficient to induce expression of the BPV late genes in transformed mouse cells.     

Assembly of a polyadenylation-specific 25S ribonucleoprotein complex in vitro.

Extracts from HeLa cell nuclei assemble RNAs containing the adenovirus type 2 L3 polyadenylation site into a number of rapidly sedimenting heterodisperse complexes. Briefly treating reaction mixtures prior to sedimentation with heparin reveals a core 25S assembly formed with substrate RNA but not an inactive RNA containing a U----C mutation in the AAUAAA hexanucleotide sequence. The requirements for assembly of this heparin-stable core complex parallel those for cleavage and polyadenylation in vitro, including a functional hexanucleotide, ATP, and a uridylate-rich tract downstream of the cleavage site. The AAUAAA and a downstream U-rich element are resistant in the assembly to attack by RNase H. The poly(A) site between the two protected elements is accessible, but is attacked more slowly than in naked RNA, suggesting that a specific factor or secondary structure is located nearby. The presence of a factor bound to the AAUAAA in the complex is independently demonstrated by immunoprecipitation of a specific T1 oligonucleotide containing the element from the 25S fraction. Precipitation of this fragment from reaction mixtures is blocked by the U----C mutation. However, neither ATP nor the downstream sequence element is required for binding of this factor in the nuclear extract, suggesting that recognition of the AAUAAA is an initial event in complex assembly.     

RNA processing in vitro produces mature 3'' ends of a variety of Saccharomyces cerevisiae mRNAs.

Ammonium sulfate fractionation of a Saccharomyces cerevisiae whole-cell extract yielded a preparation which carried out correct and efficient endonucleolytic cleavage and polyadenylation of yeast precursor mRNA substrates corresponding to a variety of yeast genes. These included CYC1 (iso-1-cytochrome c), HIS4 (histidine biosynthesis), GAL7 (galactose-1-phosphate uridyltransferase), H2B2 (histone H2B2), PRT2 (a protein of unknown function), and CBP1 (cytochrome b mRNA processing). The reaction processed these pre-mRNAs with varying efficiencies, with cleavage and polyadenylation exceeding 70% in some cases. In each case, the poly(A) tail corresponded to the addition of approximately 60 adenosine residues, which agrees with the usual length of poly(A) tails formed in vivo. Addition of cordycepin triphosphate or substitution of CTP for ATP in these reactions inhibited polyadenylation but not endonucleolytic cleavage and resulted in accumulation of the cleaved RNA product. Although this system readily generated yeast mRNA 3' ends, no processing occurred on a human alpha-globin pre-mRNA containing the highly conserved AAUAAA polyadenylation signal of higher eucaryotes. This sequence and adjacent signals used in mammalian systems are thus not sufficient to direct mRNA 3' end formation in yeast. Despite the lack of a highly conserved nucleotide sequence signal, the same purified fraction processed the 3' ends of a variety of unrelated yeast pre-mRNAs, suggesting that endonuclease cleavage and polyadenylation may produce the mature 3' ends of all mRNAs in S. cerevisiae.