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.     

Sedimentation analysis of polyadenylation-specific complexes.

Precursor RNA containing the adenovirus L3 polyadenylation site is assembled into a 50S complex upon incubation with HeLa nuclear extract at 30 degrees C. The cofactor and sequence requirements for 50S complex formation are similar to those of the in vitro polyadenylation reaction. Assembly of this complex requires ATP but is not dependent upon synthesis of a poly(A) tract. In addition, a 50S complex does not form on substrate RNA in which the AAUAAA hexanucleotide upstream of the poly(A) site has been mutated to AAGAAA or on RNA in which sequences between +5 and +48 nucleotides downstream of the site have been removed. These mutations also prevent in vitro processing of substrate RNA. Kinetic studies suggest that the 50S complex is an intermediate in the polyadenylation reaction. It forms at an early stage in the reaction and at later times contains both poly(A)+ RNA as well as unreacted precursor. U-type small nuclear ribonucleoprotein particles are components of the 50S complex, as shown by immunoprecipitation with antiserum specific to the trimethyl cap of these small nuclear RNAs.     

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.     

Analysis of RNA cleavage at the adenovirus-2 L3 polyadenylation site.

Processing at the L3 polyadenylation site of human adenovirus-2 involves endonucleolytic cleavage generating the 3' terminal sequence -UAOH to which adenosine residues are added. This dinucleotide is 19 nucleotides downstream of the AAUAAA polyadenylation signal. The ATP analog cordycepin triphosphate (3' dATP) inhibits poly(A) synthesis, but precursor RNA is processed to give a product terminating in -UAAH. Addition of only one adenosine analog demonstrates that the initial poly(A) tract is synthesized by polymerization of single residues rather than by ligation of preformed poly(A). Cleavage is not coupled to polyadenylation since incubation with an ATP analog containing a non-hydrolyzable alpha--beta bond generates a product with a 3' terminus coincident with the -UAOH) addition site. Addition of this accurately processed RNA to a nuclear extract results in efficient polyadenylation, suggesting that downstream sequences are not required for synthesis of the poly(A) tract. Finally, processing at the L3 poly(A) site may involve both endonucleolytic and exonucleolytic activities.     

Functionally significant secondary structure of the simian virus 40 late polyadenylation signal

The structure of the highly efficient simian virus 40 late polyadenylation signal (LPA signal) is more complex than those of most known mammalian polyadenylation signals. It contains efficiency elements both upstream and downstream of the AAUAAA region, and the downstream region contains three defined elements (two U-rich elements and one G-rich element) instead of the single U- or GU-rich element found in most polyadenylation signals. Since many reports have indicated that the secondary structure in RNA may play a significant role in RNA processing, we have used nuclease structure analysis techniques to determine the secondary structure of the LPA signal. We find that the LPA signal has a functionally significant secondary structure. Much of the region upstream of AAUAAA is sensitive to single-strand-specific nucleases. The region downstream of AAUAAA has both double- and single-stranded characteristics. Both U-rich elements are predominately sensitive to the double-strand-specific nuclease RNase V(1), while the G-rich element is primarily single stranded. The U-rich element closest to AAUAAA contains four distinct RNase V(1)-sensitive regions, which we have designated structural region 1 (SR1), SR2, SR3, and SR4. Linker scanning mutants in the downstream region were analyzed both for structure and for function by in vitro cleavage analyses. These data show that the ability of the downstream region, particularly SR3, to form double-stranded structures correlates with efficient in vitro cleavage. We discuss the possibility that secondary structure downstream of the AAUAAA may be important for the functions of polyadenylation signals in general.     

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.     

Sequences downstream of AAUAAA signals affect pre-mRNA cleavage and polyadenylation in vitro both directly and indirectly.

To investigate the role of sequences lying downstream of the conserved AAUAAA hexanucleotide in pre-mRNA cleavage and polyadenylation, deletions or substitutions were constructed in polyadenylation signals from simian virus 40 and adenovirus, and their effects were assayed in both crude and fractionated HeLa cell nuclear extracts. As expected, these sequences influenced the efficiency of both cleavage and polyadenylation as well as the accuracy of the cleavage reaction. Sequences near or upstream of the actual site of poly(A) addition appeared to specify a unique cleavage site, since their deletion resulted, in some cases, in heterogeneous cleavage. Furthermore, the sequences that allowed the simian virus 40 late pre-RNA to be cleaved preferentially by partially purified cleavage activity were also those at the cleavage site itself. Interestingly, sequences downstream of the cleavage site interacted with factors not directly involved in catalyzing cleavage and polyadenylation, since the effects of deletions were substantially diminished when partially purified components were used in assays. In addition, these sequences contained elements that could affect 3'-end formation both positively and negatively.     

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.     

Recognition of GU-rich polyadenylation regulatory elements by human CstF-64 protein

Vertebrate polyadenylation sites are identified by the AAUAAA signal and by GU-rich sequences downstream of the cleavage site. These are recognized by a heterotrimeric protein complex (CstF) through its 64 kDa subunit (CstF-64); the strength of this interaction affects the efficiency of poly(A) site utilization. We present the structure of the RNA-binding domain of CstF-64 containing an RNA recognition motif (RRM) augmented by N- and C-terminal helices. The C-terminal helix unfolds upon RNA binding and extends into the hinge domain where interactions with factors responsible for assembly of the polyadenylation complex occur. We propose that this conformational change initiates assembly. Consecutive Us are required for a strong CstF-GU interaction and we show how UU dinucleotides are recognized. Contacts outside the UU pocket fine tune the protein-RNA interaction and provide different affinities for distinct GU-rich elements. The protein-RNA interface remains mobile, most likely a requirement to bind many GU-rich sequences and yet discriminate against other RNAs. The structural distinction between sequences that form stable and unstable complexes provides an operational distinction between weakly and strongly processed poly(A) sites.     

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.     

Formation of mRNA 3'' termini: stability and dissociation of a complex involving the AAUAAA sequence.

Formation of the 3' termini of mRNAs in animal cells involves endonucleolytic cleavage of a pre-mRNA, followed by polyadenylation of the newly formed end. Here we demonstrate that, during cleavage in vitro, the highly conserved AAUAAA sequence of the pre-mRNA forms a complex with a factor present in a crude nuclear extract. This complex is required for cleavage and polyadenylation. It normally is transient, but is very stable on cleaved RNA to which a single terminal cordycepin residue has been added. The complex can form either during the cleavage reaction, or on a synthetic RNA that ends at the polyadenylation site. Mutations which prevent cleavage also prevent complex formation. The complex dissociates during or after polyadenylation, enabling the released activities to catalyze a second round of cleavage.     

Identification and characterization of two internal cleavage and polyadenylation sites of parvovirus B19 RNA

Polyadenylation of B19 pre-mRNAs at the major internal site, (pA)p1, is programmed by the nonconsensus core cleavage and polyadenylation specificity factor-binding hexanucleotide AUUAAA. Efficient use of this element requires both downstream and upstream cis-acting elements and is further influenced by an adjacent AAUAAC motif. The primary hexanucleotide element must be nonconsensus to allow efficient readthrough of P6-generated pre-mRNAs into the capsid-coding region. An additional cleavage and polyadenylation site, (pA)p2, 296 nucleotides downstream of (pA)p1 was shown to be used following both B19 infection and transfection of a genomic clone. RNAs polyadenylated at (pA)p2 comprise approximately 10% of B19 RNAs that are polyadenylated internally.     

Characterization of the Distal Polyadenylation Site of the ?-Adducin (Add2) Pre-mRNA

Most genes have multiple polyadenylation sites (PAS), which are often selected in a tissue-specific manner, altering protein products and affecting mRNA stability, subcellular localization and/or translability. Here we studied the polyadenylation mechanisms associated to the beta-adducin gene (Add2). We have previously shown that the Add2 gene has a very tight regulation of alternative polyadenylation, using proximal PAS in erythroid tissues, and a distal one in brain. Using chimeric minigenes and cell transfections we identified the core elements responsible for polyadenylation at the distal PAS. Deletion of either the hexanucleotide motif (Hm) or the downstream element (DSE) resulted in reduction of mature mRNA levels and activation of cryptic PAS, suggesting an important role for the DSE in polyadenylation of the distal Add2 PAS. Point mutation of the UG repeats present in the DSE, located immediately after the cleavage site, resulted in a reduction of processed mRNA and in the activation of the same cryptic site. RNA-EMSA showed that this region is active in forming RNA-protein complexes. Competition experiments showed that RNA lacking the DSE was not able to compete the RNA-protein complexes, supporting the hypothesis of an essential important role for the DSE. Next, using a RNA-pull down approach we identified some of the proteins bound to the DSE. Among these proteins we found PTB, TDP-43, FBP1 and FBP2, nucleolin, RNA helicase A and vigilin. All these proteins have a role in RNA metabolism, but only PTB has a reported function in polyadenylation. Additional experiments are needed to determine the precise functional role of these proteins in Add2 polyadenylation.