An RNA secondary structure juxtaposes two remote genetic signals for human T-cell leukemia virus type I RNA 3'-end processing.

Sequence analysis of the human T-cell leukemia virus type I (HTLV-I) long terminal repeat (LTR) does not reveal a polyadenylation consensus sequence, AAUAAA, close to the polyadenylation site at the 3' end of the viral RNA. Using site-directed mutagenesis, we demonstrated that two cis-acting signals are required for efficient RNA processing in HTLV-I LTR: (i) a remote AAUAAA hexamer at a distance of 276 nucleotides upstream of the polyadenylation site, and (ii) the 20-nucleotide GU-rich sequence immediately downstream from the poly(A) site. It has been postulated that the folding of RNA into a secondary structure juxtaposes the AAUAAA sequence, in a noncontiguous manner, to within 14 nucleotides of the polyadenylation site. To test this hypothesis, we introduced deletions and point mutations within the U3 and R regions of the LTR. RNA 3'-end processing occurred efficiently at the authentic HTLV-I poly(A) site after deletion of the sequences predicted to form the secondary structure. Thus, the genetic analysis supports the hypothesis that folding of the HTLV-I RNA in the U3 and R regions juxtaposes the AAUAAA sequence and the poly(A) site to the correct functional distance. This unique arrangement of RNA-processing signals is also found in the related retroviruses HTLV-II and bovine leukemia virus.     

Elements upstream of the AAUAAA within the human immunodeficiency virus polyadenylation signal are required for efficient polyadenylation in vitro.

Recent in vivo studies have identified specific sequences between 56 and 93 nucleotides upstream of a polyadenylation [poly(A)] consensus sequence, AAUAAA, in human immunodeficiency virus type 1 (HIV-1) that affect the efficiency of 3'-end processing at this site (A. Valsamakis, S. Zeichner, S. Carswell, and J. C. Alwine, Proc. Natl. Acad. Sci. USA 88:2108-2112, 1991). We have used HeLa cell nuclear extracts and precursor RNAs bearing the HIV-1 poly(A) signal to study the role of upstream sequences in vitro. Precursor RNAs containing the HIV-1 AAUAAA and necessary upstream (U3 region) and downstream (U5 region) sequences directed accurate cleavage and polyadenylation in vitro. The in vitro requirement for upstream sequences was demonstrated by using deletion and linker substitution mutations. The data showed that sequences between 56 and 93 nucleotides upstream of AAUAAA, which were required for efficient polyadenylation in vivo, were also required for efficient cleavage and polyadenylation in vitro. This is the first demonstration of the function of upstream sequences in vitro. Previous in vivo studies suggested that efficient polyadenylation at the HIV-1 poly(A) signal requires a spacing of at least 250 nucleotides between the 5' cap site and the AAUAAA. Our in vitro analyses indicated that a precursor containing the defined upstream and downstream sequences was efficiently cleaved at the polyadenylation site when the distance between the 5' cap and the AAUAAA was reduced to at least 140 nucleotides, which is less than the distance predicted from in vivo studies. This cleavage was dependent on the presence of the upstream element.     

A 64 kd nuclear protein binds to RNA segments that include the AAUAAA polyadenylation motif

A 64 kd protein was shown to bind to RNAs that contain functional polyadenylation signals by a UV cross-linking procedure in which label was transferred from RNA substrate to protein in cell-free polyadenylation extracts. The 64 kd nuclear protein bound specifically to three different substrates (adenovirus type 5 L3, SV40 early, and SV40 late polyadenylation domains), as determined by competition experiments and partial protease analysis. Deleted derivatives of the SV40 late substrate that retained the sequence 5'-CUGCAAUAAACAAGUU-3' were able to bind the 64 kd polypeptide. This sequence contains the canonical AAUAAA element that has been shown to be indispensable for polyadenylation. A single nucleotide change, converting AAUAAA to AAGAAA, prevented binding of the 64 kd moiety. The 64 kd protein was shown to be distinct from poly(A) polymerase by biochemical fractionation.     

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.     

Polyadenylation of maternal mRNA during oocyte maturation: poly(A) addition in vitro requires a regulated RNA binding activity and a poly(A) polymerase.

Specific maternal mRNAs receive poly(A) during early development as a means of translational regulation. In this report, we investigated the mechanism and control of poly(A) addition during frog oocyte maturation, in which oocytes advance from first to second meiosis becoming eggs. We analyzed polyadenylation in vitro in oocyte and egg extracts. In vivo, polyadenylation during maturation requires AAUAAA and a U-rich element. The same sequences are required for polyadenylation in egg extracts in vitro. The in vitro reaction requires at least two separable components: a poly(A) polymerase and an RNA binding activity with specificity for AAUAAA and the U-rich element. The poly(A) polymerase is similar to nuclear poly(A) polymerases in mammalian cells. Through a 2000-fold partial purification, the frog egg and mammalian enzymes were found to be very similar. More importantly, a purified calf thymus poly(A) polymerase acquired the sequence specificity seen during frog oocyte maturation when mixed with the frog egg RNA binding fraction, demonstrating the interchangeability of the two enzymes. To determine how polyadenylation is activated during maturation, we compared polymerase and RNA binding activities in oocyte and egg extracts. Although oocyte extracts were much less active in maturation-specific polyadenylation, they contained nearly as much poly(A) polymerase activity. In contrast, the RNA binding activity differed dramatically in oocyte and egg extracts: oocyte extracts contained less binding activity and the activity that was present exhibited an altered mobility in gel retardation assays. Finally, we demonstrate that components present in the RNA binding fraction are rate-limiting in the oocyte extract, suggesting that fraction contains the target that is activated by progesterone treatment. This target may be the RNA binding activity itself. We propose that in spite of the many biological differences between them, nuclear polyadenylation and cytoplasmic polyadenylation during early development may be catalyzed by similar, or even identical, components.     

Site-directed ribose methylation identifies 2'-OH groups in polyadenylation substrates critical for AAUAAA recognition and poly(A) addition

The importance of sugar contacts for the sequence-specific recognition that occurs during polyadenylation of mRNAs was investigated with chemically synthesized substrates containing 2'-O-CH3 groups at selected riboses. An RNA (5'-CUGCAAUAAACAAGU-UAA-3') with 2'-O-CH3 ribose at each nucleotide except for the AAUAAA sequence and 3'-terminal adenosine was efficiently polyadenylated in vitro. Methylation of single riboses within AAUAAA inhibited both poly(A) addition and binding of the specificity factor, but the magnitude of inhibition varied greatly at different nucleotides. Nucleotides that showed sensitivity to base substitutions did not necessarily show sensitivity to ribose methylation, and vice versa. The data indicate that the specificity factor interacts with AAUAAA through RNA-protein contacts involving essential recognition of both sugars and bases at different nucleotide positions.     

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.     

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.     

Cleavage and polyadenylation factor CPF specifically interacts with the pre-mRNA 3'' processing signal AAUAAA.

Cleavage and polyadenylation factor (CPF) is required for the cleavage as well as for the subsequent polyadenylation reaction during 3' processing of messenger RNA precursors. Here, we have investigated the interaction of CPF and poly(A) polymerase with short RNA substrates. CPF activates poly(A) polymerase to elongate RNA primers carrying the canonical hexamer recognition signal AAUAAA. CPF specifically binds to such RNA as shown by gel mobility shift assays and competition experiments. Upon binding of CPF, two polypeptides of 35 kDa and 160 kDa can be covalently crosslinked to the RNA by irradiation with UV light. These polypeptides may correspond to the smallest and the largest subunit contained in purified CPF fractions. In addition, chemical modification-exclusion experiments demonstrate that CPF interacts directly with the AAUAAA recognition signal in the RNA. The entire hexamer signal is involved in binding of CPF since modification of any of its bases interferes with complex formation.     

Purification of the cleavage and polyadenylation factor involved in the 3'-processing of messenger RNA precursors

Polyadenylation of messenger RNA precursors requires the nucleotide sequence AAUAAA and two factors: poly(A) polymerase and a specificity factor termed cleavage and polyadenylation factor (CPF). We have purified CPF from calf thymus and from HeLa cells to near homogeneity. Four polypeptides with molecular masses of 160, 100, 73, and 30 kDa cofractionate with CPF activity. Glycerol gradient centrifugation and gel filtration indicate that these four proteins form one large complex with a sedimentation constant of 12 S, a Stokes radius near 100 A, and a native molecular mass near 500 kDa. Purified CPF binds specifically to an RNA that contains the AAUAAA sequence. Mutation of the AAUAAA sequence inhibits CPF binding as well as polyadenylation. Purified CPF contains only trace amounts of RNA and does not react with antibodies against common epitopes of small nuclear ribonucleoprotein particles. Thus, contrary to previous indications, CPF does not appear to be a small nuclear ribonucleoprotein particle.     

In vitro cleavage of the simian virus 40 early polyadenylation site adjacent to a required downstream TG sequence.

Exogenous RNA containing the simian virus 40 early polyadenylation site was efficiently and accurately polyadenylated in in vitro nuclear extracts. Correct cleavage required ATP. In the absence of ATP, nonpoly(A)+ products accumulated which were 18 to 20 nucleotides longer than the RNA generated by correct cleavage; the longer RNA terminated adjacent to the downstream TG element required for polyadenylation. In the presence of ATP analogs, alternate cleavage was not observed; instead, correct cleavage without poly(A) addition occurred. ATP-independent cleavage of simian virus 40 early RNA had many of the same properties as correct cleavage including requirements for an intact AAUAAA element, a proximal 3' terminus, and extract small nuclear ribonucleoproteins. This similarity in reaction parameters suggested that ATP-independent cleavage is an activity of the normal polyadenylation machinery. The ATP-independent cleavage product, however, did not behave as an intermediate in polyadenylation. The alternate RNA did not preferentially chase into correctly cleaved material upon readdition of ATP; instead, poly(A) was added to the 3' terminus of the cleaved RNA during a chase. Purified ATP-independent cleavage RNA, however, was a substrate for correct cleavage when reintroduced into the nuclear extract. Thus, alternate cleavage of polyadenylation sites adjacent to a required downstream sequence element is directed by the polyadenylation machinery in the absence of ATP.     

RNA structure is a critical determinant of poly(A) site recognition by cleavage and polyadenylation specificity factor.

Sequence conservation among mammalian poly(A) sites is limited to the sequence AAUAAA, coupled with an amorphous downstream U- or GU-rich region. Since these sequences may also occur within the coding region of mRNAs, additional information must be required to define authentic poly(A) sites. Several poly(A) sites have been shown to contain sequences outside the core elements that enhance the efficiency of 3' processing in vivo and in vitro. The human immunodeficiency virus type 1, equine infectious anemia virus, and adenovirus L1 3' processing enhancers have been shown to promote the binding of cleavage and polyadenylation specificity factor (CPSF), the factor responsible for recognition of AAUAAA, to the pre-mRNA, thereby facilitating the assembly of a stable 3' processing complex. We have used in vitro selection to examine the mechanism by which the human immunodeficiency virus type 1 3' processing enhancer promotes the interaction of CPSF with the AAUAAA hexamer. Surprisingly, RNAs selected for efficient polyadenylation were related by structure rather than sequence. Therefore, in the absence of extensive sequence conservation, our results strongly suggest that RNA structure is a critical determinant of poly(A) site recognition by CPSF and may play a key role in poly(A) site definition.     

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.     

Isolation and expression of cDNA clones encoding mammalian poly(A) polymerase.

cDNA clones encoding mammalian poly(A) polymerase were isolated with probes generated by the polymerase chain reaction based on amino acid sequences derived from the purified enzyme. A bovine cDNA clone was obtained encoding a protein of 82 kDa. Expression in Escherichia coli resulted in the appearance of a poly(A) polymerase activity that was dependent on the addition of the purified specificity factor CPF and the presence of the polyadenylation signal AAUAAA in the RNA substrate. The activity copurified with a polypeptide of the expected size. A second class of cDNAs encoded a polypeptide of 43 kDa which was closely related to the N-terminal half of the 82 kDa protein. Northern blots showed two mRNAs of 4.2 and 2.4 kb that probably correspond to the two classes of cDNAs, as well as a third band of 1.3 kb. The sequence of the N-terminal half of bovine poly(A) polymerase is 47% identical with the amino acid sequence of the corresponding part of yeast poly(A) polymerase. Homologies to other proteins are of uncertain significance.