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.     

Cytoplasmic processing events in the polyadenylate region of Physarum messenger RNA

Cytoplasmic processing events in the poly(A) region of mRNA fromPhysarum polycephalum are reviewed. Two classes of poly-containing RNA [poly(A)⁺ RNA] exist in the cytoplasm. One contains very short poly(A) sequences, averaging about 15 adenylate residues, while the other contains relatively long poly(A) sequences, averaging about 60 residues. Molecules with short poly(A) sequences are found exclusively in the polysomes while those with long poly(A) sequences are restricted to the free cytoplasmic mRNP. Since proteins are associated with only the long poly(A) sequences the poly(A) · protein complex is also restricted to the free mRNP. The long poly(A) sequences are relatively short-lived. They are degraded by two distinct processes, a shortening process in which 15–20 residues are gradually removed and a turnover process in which long poly(A) tracts are rapidly converted to the short sequences. This process, along with the dissociation of the poly(A) · protein complex, occurs when poly(A)⁺ RNA molecules located in free mRNP are transferred to the polysomes. Poly(A) · protein complex dissociation appears to preceed poly(A) turnover during translational selection. The significance of these processing events in relation to mRNA maturation is discussed.     

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.     

3'-terminal processing of ribosomal RNA precursors in mammalian cells.

The 3'-terminal structures of ribosomal 28S RNA and its precursors from rat and mouse were analyzed by means of periodate oxidation followed by reduction with 3H-borohydride. 3'-terminal labeled nucleoside derivatives produced by RNase T2 digestion were determined by thin-layer chromatography and oligonucleotides generated by RNase T1 digestion were analyzed by DEAE-Sephadex chromatography. In the rat, the major 3'-terminal sequences of ribosomal 28S RNA, nucleolar 28S, 32S, 41S, and 45S RNAs were YGUoh, GZ2Uoh, GZ12Uoh, GZ2Uoh, and GZ7Goh, respectively, whereas in the mouse corresponding sequences were YGUoh, GZ1,2, or 3Uoh, Goh, Uoh and GZ 13Uoh, respectively. (Y: pyrimidine nucleoside, Z: any nucleoside other than guanosine) These results suggest that a "transcribed spacer" sequence is present at the 3'-terminus of the 45S pre-ribosomal RNA, which is gradually removed during the steps of processing.     

Anomalous RNA substrates for mammalian tRNA 3' processing endoribonuclease

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) is an enzyme responsible for the removal of a 3' trailer from pre-tRNA. The enzyme can also recognize and cleave any target RNA that forms a pre-tRNA-like complex with another RNA. To investigate the interaction between 3' tRNase and substrates, we tested various anomalous pre-tRNA-like complexes for cleavage by pig 3' tRNase. We examined how base mismatches in the acceptor stem affect 3' tRNase cleavage of RNA complexes, and found that even one base mismatch in the acceptor stem drastically reduces the cleavage efficiency. Mammalian 3' tRNase was able to recognize complexes between target RNAs and 5'-half tDNAs, and cleave the target RNAs, although inefficiently, whereas the enzyme had no activity to cleave phosphodiester bonds of DNA. A relatively long RNA target, the Escherichia coli chloramphenicol acetyltransferase (CAT) mRNA, was cleaved by 3' tRNase in the presence of appropriate 5'-half tRNAs. We also demonstrated that an RNA complex of lin-4 and lin-14 from Caenorhabditis elegans can be recognized and cleaved by pig 3' tRNase.     

A multicomponent complex is involved in the splicing of messenger RNA precursors

A multicomponent complex termed spliceosome (splicing body) is unique to the splicing of messenger RNA precursors in vitro. This 60S RNA-protein complex contains RNAs from the previously characterized bipartite splicing intermediate, the 5' exon RNA, and the lariat intervening sequence-3' exon RNA, as well as some intact 455 nucleotide precursor RNA. This complex contains snRNPs, particularly U1 RNP, as shown by immunoprecipitation with specific antisera. Formation of the 60S complex appears to be an early and essential step in splicing, because the 60S complex forms during the early stage, or lag time, of the reaction before the first covalent modification, cleavage at the 5' splice site of precursor RNA. The 60S complex forms only under conditions that permit splicing; both ATP and a precursor RNA containing authentic 5' and 3' splice sites are required for formation, while antiserum specific for U1 RNP inhibits its formation. RNA within the 60S complex, predominantly precursor RNA, was chased into products with accelerated kinetics and more complete conversion than purified precursor RNA.     

Loss of the polyadenylate segment from mammalian messenger RNA: Selective cleavage of this sequence from polyribosomes

Treatment of mouse sarcoma 180 ascites cell polysomes with low levels of micrococcal nuclease, under conditions that cause relatively little fragmentation of the messenger RNA chains, results in considerable loss of poly(A) from these chains. This treatment generates a substantial amount of functional poly(A)-lacking mRNA. Brief incubation of cytoplasmic extracts of the ascites cells, and of mouse liver extracts, has similar effects on the polysomes present in the extracts and on the generation of poly(A)-lacking mRNA chains.The poly(A) segment is released from the polysomes treated with micrococcal nuclease as a nucleoprotein complex, and is protected from the action of the enzyme because of its association with protein. There is considerable poly(A) hydrolysis in incubated ascites cell extracts, and accumulation of a poly(A)-protein complex does not take place in this case. The liver extracts have little poly(A)-hydrolyzing activity, and free poly(A)-protein complexes are observed in these extracts.The poly(A)-cleavage process shows evidence of considerable selectivity. The newly synthesized mRNA population is more susceptible to this process than is the steady-state population. Moreover, only a portion of the steady-state mRNA loses its poly(A) readily upon incubation with micrococcal nuclease. Two-dimensional gel electrophoresis of translation products from total and poly(A)-lacking polysomal RNA preparations shows that not all mRNA species lose their poly(A) upon incubation of polysomes in ascites cell extracts. The sensitive population resembles the normal population of translatable poly (A)-lacking mRNA that is obtained from untreated polysomes. Individual species within this population show wide differences in their degree of susceptibility to the poly(A)-release process in vitro. Analysis by one-dimensional gel electrophoresis indicates that the same general population is generated by the incubation of cytoplasmic extracts and by the treatment of polysomes with micrococcal nuclease.It is suggested that the 3′ non-coding region of mRNA in polysomes is particularly sensitive to endonucleolytic cleavage, and that loss of poly(A) via this cleavage may be a normal cellular process. The diversity in nucleotide sequence and in overall configuration in this region could provide a basis for the observed differences in susceptibility to cleavage by nucleases.     

Differences and similarities between Drosophila and mammalian 3' end processing of histone pre-mRNAs

We used nuclear extracts from Drosophila Kc cells to characterize 3' end processing of Drosophila histone pre-mRNAs. Drosophila SLBP plays a critical role in recruiting the U 7 snRNP to the pre-mRNA and is essential for processing all five Drosophila histone pre-mRNAs. The Drosophila processing machinery strongly prefers cleavage after a fourth nucleotide following the stem-loop and favors an adenosine over pyrimidines in this position. Increasing the distance between the stem-loop and the HDE does not result in a corresponding shift of the cleavage site, suggesting that in Drosophila processing the U 7 snRNP does not function as a molecular ruler. Instead, SLBP directs the cleavage site close to the stem-loop. The upstream cleavage product generated in Drosophila nuclear extracts contains a 3' OH, and the downstream cleavage product is degraded by a nuclease dependent on the U 7 snRNP, suggesting that the cleavage factor has been conserved between Drosophila and mammalian processing. A 2'O-methyl oligonucleotide complementary to the first 17 nt of the Drosophila U 7 snRNA was not able to deplete the U 7 snRNP from Drosophila nuclear extracts, suggesting that the 5' end of the Drosophila U 7 snRNA is inaccessible. This oligonucleotide selectively inhibited processing of only two Drosophila pre-mRNAs and had no effect on processing of the other three pre-mRNAs. Together, these studies demonstrate that although Drosophila and mammalian histone pre-mRNA processing share common features, there are also significant differences, likely reflecting divergence in the mechanism of 3' end processing between vertebrates and invertebrates.     

Size heterogeneity of polyadenylate sequences in mouse globin messenger RNA

Heterogeneity in the length of the poly(A) region has been demonstrated in mouse α and β-globin messenger RNAs. This finding is based on the initial observation that only 30% of the globin mRNA purified by oligo(dT)-cellulose affinity chromatography binds to Millipore filters under conditions where other poly(A)-containing mRNAs have been shown to bind, and the subsequent finding that the bound and non-bound fractions contain different size classes of poly(A). The poly(A) size was determined by polyacrylamide gel electrophoresis of the T₁ and pancreatic RNAase-resistant fragments. The unbound mRNA fraction gives a fragment 35 to 45 adenine nucleotides long, while the bound mRNA contains two fragments with average lengths of 55 to 65 and 75 to 120 nucleotides.The heterogeneity of the poly(A) region is present in both α and β-globin mRNAs as both Millipore-bound and unbound RNA fractions directed the synthesis of comparable amounts of mouse α and β-globin chains.Change in the distribution of the various size classes of poly(A) was analyzed by Millipore binding assays after various times of labeling in vivo. The percentage of labeled mRNA bound to Millipore filters decreased with time, suggesting either a shortening of the poly(A) region or differential synthesis of mRNAs containing shorter poly(A) at earlier stages in erythropoeisis.