Downstream sequence elements with different affinities for the hnRNP H/H' protein influence the processing efficiency of mammalian polyadenylation signals

Auxiliary factors likely play an important role in determining the polyadenylation efficiency of mammalian pre-mRNAs. We previously identified an auxiliary factor, hnRNP H/H′, which stimulates 3′-end processing through an interaction with sequences downstream of the core elements of the SV40 late polyadenylation signal. Using in vitro reconstitution assays we have demonstrated that hnRNP H/H′ can stimulate processing of two additional model polyadenylation signals by binding at similar relative downstream locations but with significantly different affinities. A short tract of G residues was determined to be a common property of all three hnRNP H/H′ binding sites. A survey of mammalian polyadenylation signals identified potential G-rich hnRNP H/H′ binding sites at similar downstream locations in ~34% of these signals. All of the novel G-rich elements tested were found to bind hnRNP H/H′ protein and the processing of selected signals identified in the survey was stimulated by the protein both in vivo and in vitro. Downstream G-rich tracts, therefore, are a common auxiliary element in mammalian polyadenylation signals. Sequences capable of binding hnRNP H protein with varying affinities may play a role in determining the processing efficiency of a significant number of mammalian polyadenylation signals.     

Recognition of polyadenylation sites in yeast pre-mRNAs by cleavage and polyadenylation factor.

Recognition of poly(A) sites in yeast pre-mRNAs is poorly understood. Employing an in vitro cleavage system with cleavage and polyadenylation factor (CPF) and cleavage factor IA we show that the efficiency and positioning elements are dispensable for poly(A)-site recognition within a short CYC1 substrate in vitro. Instead, U-rich elements immediately upstream and downstream of the poly(A) site mediate cleavage-site recognition within CYC1 and ADH1 pre-mRNAs. These elements act in concert with the poly(A) site to produce multiple recognition sites for the processing machinery, since combinations of mutations within these elements were most effective in cleavage inhibition. Intriguingly, introduction of a U-rich element downstream of the GAL7 poly(A) site strongly enhanced cleavage, underscoring the importance of downstream sequences in general. RNA- binding analyses demonstrate that cleavage depends on the recognition of the poly(A)-site region by CPF. Consistent with in vitro results, mutation of sequences upstream and downstream of the poly(A) site affected 3'-end formation in vivo. A model for yeast pre-mRNA cleavage-site recognition outlines an unanticipated high conservation of yeast and mammalian 3'-end processing mechanisms.     

The 64-kilodalton subunit of the CstF polyadenylation factor binds to pre-mRNAs downstream of the cleavage site and influences cleavage site location.

The CstF polyadenylation factor is a multisubunit complex required for efficient cleavage and polyadenylation of pre-mRNAs. Using an RNase H-mediated mapping technique, we show that the 64-kDa subunit of CstF can be photo cross-linked to pre-mRNAs at U-rich regions located downstream of the cleavage site of the simian virus 40 late and adenovirus L3 pre-mRNAs. This positional specificity of cross-linking is a consequence of CstF interaction with the polyadenylation complex, since the 64-kDa protein by itself is cross-linked at multiple positions on a pre-mRNA template. During polyadenylation, four consecutive U residues can substitute for the native downstream U-rich sequence on the simian virus 40 pre-mRNA, mediating efficient 64-kDa protein cross-linking at the downstream position. Furthermore, the position of the U stretch not only enables the 64-kDa polypeptide to be cross-linked to the pre-mRNA but also influences the site of cleavage. A search of the GenBank database revealed that a substantial portion of mammalian polyadenylation sites carried four or more consecutive U residues positioned so that they should function as sites for interaction with the 64-kDa protein downstream of the cleavage site. Our results indicate that the polyadenylation machinery physically spans the cleavage site, directing cleavage factors to a position located between the upstream AAUAAA motif, where the cleavage and polyadenylation specificity factor is thought to interact, and the downstream U-rich binding site for the 64-kDa subunit of CstF.     

Isolation and characterization of polyadenylation complexes assembled in vitro

We developed a two-step purification of mammalian polyadenylation complexes assembled in vitro. Biotinylated pre-mRNAs containing viral or immunoglobulin poly(A) sites were incubated with nuclear extracts prepared from mouse myeloma cells under conditions permissive for in vitro cleavage and polyadenylation and the mixture was fractionated by gel filtration; complexes containing biotinylated pre-mRNA and bound proteins were affinity purified on avidin-agarose resin. Western analysis of known components of the polyadenylation complex demonstrated copurification of polyadenylation factors with poly(A) site-containing RNA but not with control RNA substrates containing either no polyadenylation signals or a point mutation of the AAUAAA polyadenylation signal. Polyadenylation complexes that were assembled on exogenous RNA eluted from the Sephacryl column in fractions consistent with their size range extending from 2 to 4 x 10(6) Mr. Complexes endogenous to the extract were of approximately the same apparent size, but more heterogeneous in distribution. This method can be used to study polyadenylation/cleavage complexes that may form upon a number of different RNA sequences, an important step towards defining which factors might differentially associate with specific RNAs.     

Upstream elements present in the 3'-untranslated region of collagen genes influence the processing efficiency of overlapping polyadenylation signals

3'-Untranslated regions (UTRs) of genes often contain key regulatory elements involved in gene expression control. A high degree of evolutionary conservation in regions of the 3'-UTR suggests important, conserved elements. In particular, we are interested in those elements involved in regulation of 3' end formation. In addition to canonical sequence elements, auxiliary sequences likely play an important role in determining the polyadenylation efficiency of mammalian pre-mRNAs. We identified highly conserved sequence elements upstream of the AAUAAA in three human collagen genes, COL1A1, COL1A2, and COL2A1, and demonstrate that these upstream sequence elements (USEs) influence polyadenylation efficiency. Mutation of the USEs decreases polyadenylation efficiency both in vitro and in vivo, and inclusion of competitor oligoribonucleotides representing the USEs specifically inhibit polyadenylation. We have also shown that insertion of a USE into a weak polyadenylation signal can enhance 3' end formation. Close inspection of the COL1A2 3'-UTR reveals an unusual feature of two closely spaced, competing polyadenylation signals. Taken together, these data demonstrate that USEs are important auxiliary polyadenylation elements in mammalian genes.     

The C proteins of heterogeneous nuclear ribonucleoprotein complexes interact with RNA sequences downstream of polyadenylation cleavage sites.

The heterogeneous nuclear ribonucleoprotein C1 and C2 proteins were preferentially cross-linked by treatment with UV light in nuclear extracts to RNAs containing six different polyadenylation signals. The domain required for the interaction was located downstream of the poly(A) cleavage site, since deletion of this segment from several polyadenylation substrate RNAs greatly reduced cross-linking efficiency. In addition, RNAs containing only downstream sequences were efficiently cross-linked to C proteins, while fully processed, polyadenylated RNAs were not. Analysis of mutated variants of the simian virus 40 late polyadenylation signal showed that uridylate-rich sequences located in the region between 30 and 55 nucleotides downstream of the cleavage site were required for efficient cross-linking of C proteins. This downstream domain of the simian virus 40 late poly(A) addition signal has been shown to influence the efficiency of the polyadenylation reaction. However, there was not a strict correlation between cross-linking of C proteins and the efficiency of polyadenylation.     

Cleavage site determinants in the mammalian polyadenylation signal.

Using a series of position and nucleotide variants of the SV40 late polyadenylation signal we have demonstrated that three sequence elements determine the precise site of 3-end cleavage in mammalian pre-mRNAs: an upstream AAUAAA element, a down-stream U-rich element consisting of five nucleotides, at least four of which are uridine, and a nucleotide preference at the site of cleavage in the order A > U > C >> G. Cleavage occurs no closer than 11 bases, but no further than 23 bases from the AAUAAA element. The downstream U-rich element is usually located 10-30 bases from the cleavage site. The relative position of the AAUAAA and the U-rich elements define the approximate region within a 13 base domain in which cleavage will occur. The exact position of cleavage is then determined by the local nucleotide sequence in the order of preference noted above. This model accounts for nearly three quarters of polyadenylation signals surveyed and is consistent with previous experimental observations.     

CstF-64 and 3′-UTR cis-element determine Star-PAP specificity for target mRNA selection by excluding PAPα

Almost all eukaryotic mRNAs have a poly (A) tail at the 3′-end. Canonical PAPs (PAPα/γ) polyadenylate nuclear pre-mRNAs. The recent identification of the non-canonical Star-PAP revealed specificity of nuclear PAPs for pre-mRNAs, yet the mechanism how Star-PAP selects mRNA targets is still elusive. Moreover, how Star-PAP target mRNAs having canonical AAUAAA signal are not regulated by PAPα is unclear. We investigate specificity mechanisms of Star-PAP that selects pre-mRNA targets for polyadenylation. Star-PAP assembles distinct 3′-end processing complex and controls pre-mRNAs independent of PAPα. We identified a Star-PAP recognition nucleotide motif and showed that suboptimal DSE on Star-PAP target pre-mRNA 3′-UTRs inhibit CstF-64 binding, thus preventing PAPα recruitment onto it. Altering 3′-UTR cis-elements on a Star-PAP target pre-mRNA can switch the regulatory PAP from Star-PAP to PAPα. Our results suggest a mechanism of poly (A) site selection that has potential implication on the regulation of alternative polyadenylation.     

3'-end processing of the maize 27 kDa zein mRNA

Cis -regulatory elements involved in the mRNA 3'-end processing of the 27 kDa zein gene have been investigated by deletion and site-directed mutagenesis analyses. In the 3' flanking region of the 27 kDa zein gene, several AATAAA-like sequences and a sequence resembling the mammalian GT-rich sequence are present around the polyadenylation sites. Among the multiple AATAAA-like sequences, the duplicated AATGAA motifs, located 30–40 bp upstream from the polyadenylation sites, have been shown to play roles as polyadenylation signals. Although either of the two AATGAA motifs can function as a polyadenylation signal in chimeric gene constructs, the one proximal to the polyadenylation sites is likely to be the functional polyadenylation signal in the 27 kDa zein gene. Deletion of the downstream GT-rich sequence as well as alteration of the sequence surrounding the poly-adenylation sites has little effect on the mRNA 3'-end processing. However, the sequence elements located upstream from the polyadenylation signals are essential for the mRNA 3'-end processing. Mutations in the AATGAA motifs or the upstream sequences reduced the level of a reporter gene expression. A model depicting the mechanism involved in the 3'-end processing of the 27 kDa zein mRNA is presented.     

A physical and functional link between splicing factors promotes pre-mRNA 3′ end processing

Polypyrimidine tract-binding protein (PTB) is a splicing regulator that also plays a positive role in pre-mRNA 3′ end processing when bound upstream of the polyadenylation signal (pA signal). Here, we address the mechanism of PTB stimulatory function in mRNA 3′ end formation. We identify PTB as the protein factor whose binding to the human β-globin (HBB) 3′ UTR is abrogated by a 3′ end processing-inactivating mutation. We show that PTB promotes both in vitro 3′ end cleavage and polyadenylation and recruits directly the splicing factor hnRNP H to G-rich sequences associated with several pA signals. Increased binding of hnRNP H results in stimulation of polyadenylation through a direct interaction with poly(A) polymerase. Therefore, our results provide evidence of a concerted regulation of pA signal recognition by splicing factors bound to auxiliary polyadenylation sequence elements.     

Cleavage and polyadenylation of messenger RNA precursors in vitro occurs within large and specific 3' processing complexes.

We have investigated the assembly of complexes associated with in vitro cleavage and polyadenylation of synthetic pre-mRNAs by native gel electrophoresis. Incubation of SP6-generated pre-mRNA containing the adenovirus L3 polyadenylation site in HeLa cell nuclear extract results in the rapid assembly of specific complexes. Formation of these complexes precedes the appearance of cleaved intermediates and polyadenylated products and is dependent on an intact polyadenylation signal within the pre-mRNA. The specific complexes do not form on RNAs with point mutations in the AAUAAA sequence upstream of the L3 polyadenylation site. Furthermore, such mutant RNAs cannot compete for factors involved in the assembly of specific complexes on wild-type pre-mRNA. Upon complex formation a 67-nucleotide region of the L3 pre-mRNA is protected from RNase T1 digestion. This region contains both the upstream AAUAAA signal and the GU-rich downstream sequences. Cleavage and polyadenylation occur within the specific complexes and the processed RNA is subsequently released. We propose that the assembly of specific complexes represents an essential step during pre-mRNA 3' end formation in vitro.     

Identification of a novel sequence that governs both polyadenylation and alternative splicing in region E3 of adenovirus.

Region E3 encodes four major overlapping mRNAs with different splicing patterns. There are two poly(A) sites, an upstream site called E3A and a downstream site called E3B. We have analyzed virus mutants with deletions or insertions in E3 in order to identify sequences that function in the alternative processing of E3 pre-mRNAs, and to understand what determines which poly(A) sites and which splice sites are used. In previous studies we established that the 5' boundary of the E3A poly(A) signal is at an ATTAAA sequence. We now show, using viable virus mutants, that the 3' boundary of the E3A signal is located within 47-62 nucleotides (nt) downstream of the ATTAAA (17-32 nt downstream of the last microheterogenous poly(A) addition site). Our data further suggest that the spacing between the ATTAAA, the cleavage sites, and the essential downstream sequences may be important in E3A 3' end formation. Of particular interest, these mutants suggest a novel mechanism for the control of alternative pre-mRNA processing. Mutants which are almost completely defective in E3A 3' end formation display greatly increased use of a 3' splice site located 4 nt upstream of the ATTAAA. The mRNA that uses this 3' splice site is polyadenylated at the E3B poly(A) site. We suggest, for this particular case, that alternative pre-mRNA processing could be determined by a competition between trans-acting factors that function in E3A 3' end formation or in splicing. These factors could compete for overlapping sequences in pre-mRNA.     

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.