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

Bipartite structure of the downstream element of the mouse beta globin (major) poly(A) signal

The downstream region of the mouse beta (major) globin poly(A) signal was mutated and analyzed for function in transfected COS cells. From analysis of unidirectional Bal31 deletions, the 3' boundary of the downstream element was defined as +22 (22 nucleotides downstream from the cleavage site). Analysis of cluster mutations, in which 5 or 6 adjacent bases were replaced with a random CA-containing sequence in a manner that did not alter spacing, confirmed +22 as the 3' boundary of the downstream element. The analysis also revealed two short UG-rich sequences, located from +5 to +10 and from +17 to +22, as major functional components. In contrast, a more refined series of mutations, in which clusters of 3 bases were replaced, failed to cause loss of function. We conclude that the downstream element of the mouse beta globin poly(A) signal is bipartite in structure, and that portions of its sequence are functionally redundant.

Ara-ATP impairs 3'-end processing of pre-mRNAs by inhibiting both cleavage and polyadenylation

Previous studies have demonstrated that Ara-ATP can inhibit poly(A) polymerase activity by competing with ATP. To elucidate the mechanism of action of this compound, its effect on the cleavage and polyadenylation of two specific substrates, SV40L and adenovirus L3 pre-mRNAs, was studied in HeLa nuclear extracts. Unlike cordycepin 5' triphosphate, Ara-ATP inhibited both cleavage and poly(A) addition. Addition of poly(A) polymerase fraction devoid of any other factors required for the processing reactions overcame the inhibitory effect on cleavage as well as polyadenylation of pre-mRNAs. These data suggest that Ara-ATP inhibits both cleavage and polyadenylation reactions by interacting with the ATP-binding site on poly(A) polymerase, the activity of which is essential for the cleavage reaction. Ara-ATP also blocked formation of the post-cleavage and polyadenylation-specific complexes, which further confirmed the inhibitory effect of the ATP analog on the two tightly coupled 3'-end processing reactions.

An RNA-binding protein specifically interacts with a functionally important domain of the downstream element of the simian virus 40 late polyadenylation signal

We have identified an RNA-binding protein which interacts with the downstream element of the simian virus 40 late polyadenylation signal in a sequence-specific manner. A partially purified 50-kDa protein, which we have named DSEF-1, retains RNA-binding specificity as assayed by band shift and UV cross-linking analyses. RNA footprinting assays, using end-labeled RNA ladder fragments in conjunction with native gel electrophoresis, have identified the DSEF-1 binding site as 5'-GGGGGAGGUGUGGG-3'. This 14-base sequence serves as an efficient DSEF-1 binding site when placed within a GEM4 polylinker-derived RNA. Finally, the DSEF-1 binding site restored efficient in vitro 3' end processing to derivatives of the simian virus 40 late polyadenylation signal in which it substituted for the entire downstream region. DSEF-1, therefore, may be a sequence-specific binding factor which regulates the efficiency of polyadenylation site usage.

An RNA-binding protein specifically interacts with a functionally important domain of the downstream element of the simian virus 40 late polyadenylation signal

We have identified an RNA-binding protein which interacts with the downstream element of the simian virus 40 late polyadenylation signal in a sequence-specific manner. A partially purified 50-kDa protein, which we have named DSEF-1, retains RNA-binding specificity as assayed by band shift and UV cross-linking analyses. RNA footprinting assays, using end-labeled RNA ladder fragments in conjunction with native gel electrophoresis, have identified the DSEF-1 binding site as 5'-GGGGGAGGUGUGGG-3'. This 14-base sequence serves as an efficient DSEF-1 binding site when placed within a GEM4 polylinker-derived RNA. Finally, the DSEF-1 binding site restored efficient in vitro 3' end processing to derivatives of the simian virus 40 late polyadenylation signal in which it substituted for the entire downstream region. DSEF-1, therefore, may be a sequence-specific binding factor which regulates the efficiency of polyadenylation site usage.

Characterization of the apolipoprotein B mRNA editing enzyme: no similarity to the proposed mechanism of RNA editing in kinetoplastid protozoa

Intestinal apolipoprotein B mRNA is edited at nucleotide 6666 by a C to U transition resulting in a translational stop codon. The enzymatic properties of the editing activity were characterised in vitro using rat enterocyte cytosolic extract. The editing activity has no nucleotide or ion cofactor requirement. It shows substrate saturation with an apparent Km for the RNA substrate of 2.2 nM. The editing enzyme requires no lag period prior to catalysis, and does not assemble into a higher order complex on the RNA substrate. In crude cytosolic extract editing activity is completely abolished by treatment with micrococcal nuclease or RNAse A. Partially purified editing enzyme is no longer sensitive to nucleases, but is inhibited in a dose dependent manner by nuclease inactivated crude extract. The buoyant density of partially purified editing enzyme is 1.3 g/ml, that of pure protein. Therefore, the apolipoprotein B mRNA editing activity consists of a well defined enzyme with no RNA component. The nuclease sensitivity in crude cytosolic extract is explained by the generation of inhibitors for the editing enzyme. The editing of apo B mRNA has little similarity to complex mRNA processing events such as splicing and unlike editing in kinetoplastid protozoa does not utilise guide RNAs.

Potential role of poly(A) polymerase in the assembly of polyadenylation-specific RNP complexes

To elucidate the mechanism by which poly(A) polymerase functions in the 3'-end processing of pre-mRNAs, polyadenylation-specific RNP complexes were isolated by sedimentation in sucrose density gradients and the fractions were analyzed for the presence of the enzyme. At early stages of the reaction, the RNP complexes were resolved into distinct peaks which sedimented at approximately 18S and 25S. When reactions were carried out under conditions which support cleavage or polyadenylation, the pre-mRNA was specifically assembled into the larger 25S RNP complexes. Polyclonal antibodies raised against the enzyme purified from a rat hepatoma, which have been shown to inhibit cleavage and polyadenylation (Terns, M., and Jacob, S. T., Mol. Cell. Biol. 9:1435-1444, 1989) also prevented assembly of the 25S polyadenylation-specific RNP complexes. Furthermore, formation of these complexes required the presence of a chromatographic fraction containing poly(A) polymerase. UV cross-linking analysis indicated that the purified enzyme could be readily cross-linked to pre-mRNA but in an apparent sequence-independent manner. Reconstitution studies with the fractionated components showed that formation of the 25S RNP complex required the poly(A) polymerase fraction. Although the enzyme has not been directly localized to the specific complexes, the data presented in this report supports the role of poly(A) polymerase as an essential component of polyadenylation-specific complexes which functions both as a structural and enzymatic constituent.

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.

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.

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.

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 multicomponent complex is required for the AAUAAA-dependent cross-linking of a 64-kilodalton protein to polyadenylation substrates

A 64-kilodalton (kDa) polypeptide that is cross-linked by UV light specifically to polyadenylation substrate RNAs containing a functional AAUAAA element has been identified previously. Fractionated HeLa nuclear components that can be combined to regenerate efficient and accurate polyadenylation in vitro have now been screened for the presence of the 64-kDa protein. None of the individual components contained an activity which could generate the 64-kDa species upon UV cross-linking in the presence of substrate RNA. It was necessary to mix two components, cleavage stimulation factor and specificity factor, to reconstitute 64-kDa protein-RNA cross-linking. The addition of cleavage factors to this mixture very efficiently reconstituted the AAUAAA-specific 64-kDa protein-RNA interaction. The 64-kDa protein, therefore, is present in highly purified, reconstituted polyadenylation reactions. However, it is necessary to form a multicomponent complex to efficiently cross-link the protein to a substrate RNA.

A multicomponent complex is required for the AAUAAA-dependent cross-linking of a 64-kilodalton protein to polyadenylation substrates

A 64-kilodalton (kDa) polypeptide that is cross-linked by UV light specifically to polyadenylation substrate RNAs containing a functional AAUAAA element has been identified previously. Fractionated HeLa nuclear components that can be combined to regenerate efficient and accurate polyadenylation in vitro have now been screened for the presence of the 64-kDa protein. None of the individual components contained an activity which could generate the 64-kDa species upon UV cross-linking in the presence of substrate RNA. It was necessary to mix two components, cleavage stimulation factor and specificity factor, to reconstitute 64-kDa protein-RNA cross-linking. The addition of cleavage factors to this mixture very efficiently reconstituted the AAUAAA-specific 64-kDa protein-RNA interaction. The 64-kDa protein, therefore, is present in highly purified, reconstituted polyadenylation reactions. However, it is necessary to form a multicomponent complex to efficiently cross-link the protein to a substrate RNA.

Sequences upstream of AAUAAA influence poly(A) site selection in a complex transcription unit

The adenovirus major late transcription unit (MLTU) encodes five colinear mRNA families, L1 through L5, each distinguished by a unique poly(A) site. Site selection is regulated during the course of infection, predominating early at the L1 site and late at the L2 through L5 sites. Two general mechanisms can be invoked to explain predominant usage of the L1 site early in infection. MLTU site selection may proceed in a first-come, first-serve manner whereby the L1 site is used most frequently because it is closest to the promoter. Alternatively, specific sequences flanking the L1 site may control predominant L1 site usage in a position-independent manner. To distinguish between these mechanisms, we constructed deletions in the L1 flanking sequences and inserted the mutated sites into either simple transcription units or mini-MLTUs encoding two poly(A) sites. The pattern of site selection for each construct was then quantitated by S1 nuclease analysis after transfection into 293 cells. The results indicated that L1 sequences upstream of AAUAAA define a novel selector element that can cause predominant L1 site usage at either position of a tandem transcription unit. The element did not significantly affect the stability or nucleocytoplasmic transport of L1 transcripts and was not required for efficient 3'-end processing in simple transcription units. Predominant L1 site usage required physical linkage of the processing signals and was independent of the major late promoter.

Polyadenylation-specific complexes undergo a transition early in the polymerization of a poly(A) tail

We have analyzed several properties of the complex that forms between RNAs that end at the poly(A) site of simian virus 40 late mRNA and factors present in a HeLa cell nuclear extract. Formation of this polyadenylation-specific complex requires the sequence AAUAAA and a proximal 3' end. We have observed three changes in the polyadenylation complex early in the addition of the poly(A) tail. First, the complex becomes heparin sensitive after the addition of approximately 10 adenosines. Second, a 68-kilodalton protein present in the complex, which can be cross-linked by UV light to the RNA before polyadenylation has begun, no longer can be cross-linked after approximately 10 adenosines have been added. Third, after 30 adenosines have been added, the AAUAAA sequence becomes accessible to a complementary oligonucleotide and RNase H. This accessibility gradually increases with longer poly(A) tail lengths until, with the addition of 60 A's, all substrates are accessible at AAUAAA. Sheets and Wickens (Genes Dev. 3:1401-1412, 1989) have recently demonstrated two phases in the addition of a poly(A) tail: the first requires AAUAAA, whereas the second is independent of AAUAAA but requires a short oligo(A) primer. The data reported here further support a biphasic model for poly(A) addition and may indicate disengagement of specific factors from AAUAAA after the initiation phase.

Polyadenylation-specific complexes undergo a transition early in the polymerization of a poly(A) tail

We have analyzed several properties of the complex that forms between RNAs that end at the poly(A) site of simian virus 40 late mRNA and factors present in a HeLa cell nuclear extract. Formation of this polyadenylation-specific complex requires the sequence AAUAAA and a proximal 3' end. We have observed three changes in the polyadenylation complex early in the addition of the poly(A) tail. First, the complex becomes heparin sensitive after the addition of approximately 10 adenosines. Second, a 68-kilodalton protein present in the complex, which can be cross-linked by UV light to the RNA before polyadenylation has begun, no longer can be cross-linked after approximately 10 adenosines have been added. Third, after 30 adenosines have been added, the AAUAAA sequence becomes accessible to a complementary oligonucleotide and RNase H. This accessibility gradually increases with longer poly(A) tail lengths until, with the addition of 60 A's, all substrates are accessible at AAUAAA. Sheets and Wickens (Genes Dev. 3:1401-1412, 1989) have recently demonstrated two phases in the addition of a poly(A) tail: the first requires AAUAAA, whereas the second is independent of AAUAAA but requires a short oligo(A) primer. The data reported here further support a biphasic model for poly(A) addition and may indicate disengagement of specific factors from AAUAAA after the initiation phase.

Sequences upstream of AAUAAA influence poly(A) site selection in a complex transcription unit

The adenovirus major late transcription unit (MLTU) encodes five colinear mRNA families, L1 through L5, each distinguished by a unique poly(A) site. Site selection is regulated during the course of infection, predominating early at the L1 site and late at the L2 through L5 sites. Two general mechanisms can be invoked to explain predominant usage of the L1 site early in infection. MLTU site selection may proceed in a first-come, first-serve manner whereby the L1 site is used most frequently because it is closest to the promoter. Alternatively, specific sequences flanking the L1 site may control predominant L1 site usage in a position-independent manner. To distinguish between these mechanisms, we constructed deletions in the L1 flanking sequences and inserted the mutated sites into either simple transcription units or mini-MLTUs encoding two poly(A) sites. The pattern of site selection for each construct was then quantitated by S1 nuclease analysis after transfection into 293 cells. The results indicated that L1 sequences upstream of AAUAAA define a novel selector element that can cause predominant L1 site usage at either position of a tandem transcription unit. The element did not significantly affect the stability or nucleocytoplasmic transport of L1 transcripts and was not required for efficient 3'-end processing in simple transcription units. Predominant L1 site usage required physical linkage of the processing signals and was independent of the major late promoter.

Role of poly(A) polymerase in the cleavage and polyadenylation of mRNA precursor

To determine the role of poly(A) polymerase in 3'-end processing of mRNA, the effect of purified poly(A) polymerase antibodies on endonucleolytic cleavage and polyadenylation was studied in HeLa nuclear extracts, using adenovirus L3 pre-mRNA as the substrate. Both Mg2+- and Mn2+-dependent reactions catalyzing addition of 200 to 250 and 400 to 800 adenylic acid residues, respectively, were inhibited by the antibodies, which suggested that the two reactions were catalyzed by the same enzyme. Anti-poly(A) polymerase antibodies also inhibited the cleavage reaction when the reaction was coupled or chemically uncoupled with polyadenylation. These antibodies also prevented formation of specific complexes between the RNA substrate and components of nuclear extracts during cleavage or polyadenylation, with the concurrent appearance of another, antibody-specific complex. These studies demonstrate that (i) previously characterized poly(A) polymerase is the enzyme responsible for addition of the poly(A) tract at the correct cleavage site and probably for the elongation of poly(A) chains and (ii) the coupling of these two 3'-end processing reactions appears to result from the potential requirement of poly(A) polymerase for the cleavage reaction. The results suggest that the specific endonuclease is associated with poly(A) polymerase in a functional complex.

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.

Mutational analysis of a yeast transcriptional terminator

We have isolated and mutagenized a DNA fragment from Saccharomyces cerevisiae that specifies mRNA 3' end formation for the convergently transcribed CYC1 and UTR1 genes. An in vivo plasmid supercoiling assay previously showed that this fragment is a transcriptional terminator, and "run-on" assays shown here are consistent with this interpretation. The poly(A) sites in the mRNAs formed by the fragment are the same whether the fragment resides at the native location or at a heterologous location. No single linker substitution abolishes the fragment's activity, whereas certain large, nonoverlapping deletions have strong, deleterious effects. Therefore, the yeast terminator behaves more like rho-dependent bacterial terminators than terminators of higher eukaryotes. That a number of deletions or substitutions have different effects in the two orientations suggests that the fragment contains the sequences of two, unidirectional terminator elements.

Functional analysis of point mutations in the AAUAAA motif of the SV40 late polyadenylation signal

We have constructed 14 independent point mutations in the conserved AAUAAA element of the SV40 late polyadenylation signal in order to study the recognition and function of alternative polyadenylation signals. A variant RNA containing an AUUAAA was polyadenylated at 20% the level of wild-type substrate RNA, while all other derivatives tested were not functional in vitro. The AUUAAA variant RNA formed specific complexes in native polyacrylamide gels and crosslinked to the AAUAAA-specific 64kd polypeptide, but at a lower efficiency than wild-type substrate 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.

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.

Role of poly(A) polymerase in the cleavage and polyadenylation of mRNA precursor

To determine the role of poly(A) polymerase in 3'-end processing of mRNA, the effect of purified poly(A) polymerase antibodies on endonucleolytic cleavage and polyadenylation was studied in HeLa nuclear extracts, using adenovirus L3 pre-mRNA as the substrate. Both Mg2+- and Mn2+-dependent reactions catalyzing addition of 200 to 250 and 400 to 800 adenylic acid residues, respectively, were inhibited by the antibodies, which suggested that the two reactions were catalyzed by the same enzyme. Anti-poly(A) polymerase antibodies also inhibited the cleavage reaction when the reaction was coupled or chemically uncoupled with polyadenylation. These antibodies also prevented formation of specific complexes between the RNA substrate and components of nuclear extracts during cleavage or polyadenylation, with the concurrent appearance of another, antibody-specific complex. These studies demonstrate that (i) previously characterized poly(A) polymerase is the enzyme responsible for addition of the poly(A) tract at the correct cleavage site and probably for the elongation of poly(A) chains and (ii) the coupling of these two 3'-end processing reactions appears to result from the potential requirement of poly(A) polymerase for the cleavage reaction. The results suggest that the specific endonuclease is associated with poly(A) polymerase in a functional complex.

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.