Accurate cleavage and polyadenylation of exogenous RNA substrate

Purified precursor RNA containing the L3 polyadenylation site of late adenovirus 2 mRNA is accurately cleaved and polyadenylated when incubated with nuclear extract from HeLa cells. The reaction is very efficient; 75% of the precursor is correctly processed. Cleavage is rapidly followed by polymerization of an initial poly(A) tract of approximately 130 nucleotides. Additional adenosine residues are added during further incubation. In the presence of the ATP analog alpha-beta-methylene-adenosine 5' triphosphate, the precursor RNA is cleaved but not polyadenylated, suggesting that processing is not coupled to the synthesis of the initial poly(A) tract. In the absence of free Mg2+, a small RNA of approximately 46 nucleotides is stabilized against degradation. Fingerprint analysis suggests this RNA is produced by endonucleolytic cleavage at the L3 site. Like the in vitro splicing reaction, the in vitro polyadenylation reaction is inhibited by adding antiserum against the small nuclear ribonucleoprotein particle containing U1 RNA.     

The AAUAAA sequence is required both for cleavage and for polyadenylation of simian virus 40 pre-mRNA in vitro.

The sequence AAUAAA is found near the polyadenylation site of eucaryotic mRNAs. This sequence is required for accurate and efficient cleavage and polyadenylation of pre-mRNAs in vivo. In this study we show that synthetic simian virus 40 late pre-mRNAs are cleaved and polyadenylated in vitro in a HeLa cell nuclear extract, and that cleavage in vitro is abolished by each of four different single-base changes in AAUAAA. In this same extract, precleaved RNAs (RNAs with 3' termini at the polyadenylation site) are efficiently polyadenylated. This in vitro polyadenylation reaction also requires the AAUAAA sequence.     

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.     

Processing at immunoglobulin polyadenylation sites in lymphoid cell extracts.

We have developed an in vitro system for polyadenylation of RNA substrates in cell-free nuclear extracts prepared from murine cells of lymphoid origin. RNA substrates containing the adenovirus L3, murine immunoglobulin (IgM) secreted and membrane polyadenylation sites were accurately polyadenylated in these extracts. Kinetic analysis showed that the rate of polyadenylation in vitro responds proportionally to the substrate concentration. Quantitation of the initial rate of polyadenylation at the three sites permitted comparison of the activities of extracts prepared from HeLa cells, B cells (Wehi 231) and plasmacytoma cells (P9.37.11). From this analysis, we concluded that in all three extracts the polyadenylation activity at the L3 site was higher than that of either of the IgM sites. In contrast to the preferential utilization of the secreted site in vivo in plasmacytomas, this site was not selectively processed in plasmacytoma as compared to B cell extracts. The efficiency of polyadenylation at both IgM sites in the plasmacytoma extract was significantly lower than that in the B cell extract. The common low activity at the IgM sites in the plasmacytoma cell extract suggests that the rate-limiting step for polyadenylation at these two sites differs from that at the L3 site.     

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.     

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.     

U2 as well as U1 small nuclear ribonucleoproteins are involved in premessenger RNA splicing

Two different experimental approaches have provided evidence that both U2 and U1 snRNPs function in pre-mRNA splicing. When the U2 snRNPs in a nuclear extract are selectively degraded using ribonuclease H and either of two deoxyoligonucleotides complementary to U2 RNA, splicing activity is abolished. Mixing an extract in which U2 has been degraded with one in which U1 has been degraded recovers activity. Use of anti-(U2)RNP autoantibodies demonstrates that U2 snRNPs associate with the precursor RNA during in vitro splicing. At 60 min, but not at 0 min, into the reaction intron fragments that include the branch-point sequence are immunoprecipitated by anti-(U2)RNP. At all times, U1 snRNPs bind the 5' splice site of the pre-mRNA. Possible interactions of the U2 snRNP with the U1 snRNP and with the pre-mRNA during splicing are considered.     

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.     

Ribonucleoprotein complex formation during pre-mRNA splicing in vitro.

The ribonucleoprotein (RNP) structures of the pre-mRNA and RNA processing products generated during in vitro splicing of an SP6/beta-globin pre-mRNA were characterized by sucrose gradient sedimentation analysis. Early, during the initial lag phase of the splicing reaction, the pre-mRNA sedimented heterogeneously but was detected in both 40S and 60S RNP complexes. An RNA substrate lacking a 3' splice site consensus sequence was not assembled into the 60S RNP complex. The two splicing intermediates, the first exon RNA species and an RNA species containing the intron and the second exon in a lariat configuration (IVS1-exon 2 RNA species), were found exclusively in a 60S RNP complex. These two splicing intermediates cosedimented under a variety of conditions, indicating that they are contained in the same RNP complex. The products of the splicing reaction, accurately spliced RNA and the excised IVS1 lariat RNA species, are released from the 60S RNP complex and detected in smaller RNP complexes. Sequence-specific RNA-factor interactions within these RNP complexes were evidenced by the preferential protection of the pre-mRNA branch point from RNase A digestion and protection of the 2'-5' phosphodiester bond of the lariat RNA species from enzymatic debranching. The various RNP complexes were further characterized and could be distinguished by immunoprecipitation with anti-Sm and anti-(U1)RNP antibodies.