Human Fip1 is a subunit of CPSF that binds to U-rich RNA elements and stimulates poly(A) polymerase

In mammals, polyadenylation of mRNA precursors (pre-mRNAs) by poly(A) polymerase (PAP) depends on cleavage and polyadenylation specificity factor (CPSF). CPSF is a multisubunit complex that binds to the canonical AAUAAA hexamer and to U-rich upstream sequence elements on the pre-mRNA, thereby stimulating the otherwise weakly active and nonspecific polymerase to elongate efficiently RNAs containing a poly(A) signal. Based on sequence similarity to the Saccharomyces cerevisiae polyadenylation factor Fip1p, we have identified human Fip1 (hFip1) and found that the protein is an integral subunit of CPSF. hFip1 interacts with PAP and has an arginine-rich RNA-binding motif that preferentially binds to U-rich sequence elements on the pre-mRNA. Recombinant hFip1 is sufficient to stimulate the in vitro polyadenylation activity of PAP in a U-rich element-dependent manner. hFip1, CPSF160 and PAP form a ternary complex in vitro, suggesting that hFip1 and CPSF160 act together in poly(A) site recognition and in cooperative recruitment of PAP to the RNA. These results show that hFip1 significantly contributes to CPSF-mediated stimulation of PAP activity.     

The poly A polymerase Star-PAP controls 3'-end cleavage by promoting CPSF interaction and specificity toward the pre-mRNA

Star-PAP is a poly (A) polymerase (PAP) that is putatively required for 3'-end cleavage and polyadenylation of a select set of pre-messenger RNAs (mRNAs), including heme oxygenase (HO-1) mRNA. To investigate the underlying mechanism, the cleavage and polyadenylation of pre-mRNA was reconstituted with nuclear lysates. siRNA knockdown of Star-PAP abolished cleavage of HO-1, and this phenotype could be rescued by recombinant Star-PAP but not PAPα. Star-PAP directly associated with cleavage and polyadenylation specificity factor (CPSF) 160 and 73 subunits and also the targeted pre-mRNA. In vitro and in vivo Star-PAP was required for the stable association of CPSF complex to pre-mRNA and then CPSF 73 specifically cleaved the mRNA at the 3'-cleavage site. This mechanism is distinct from canonical PAPα, which is recruited to the cleavage complex by interacting with CPSF 160. The data support a model where Star-PAP binds to the RNA, recruits the CPSF complex to the 3'-end of pre-mRNA and then defines cleavage by CPSF 73 and subsequent polyadenylation of its target mRNAs.     

Pta1, a Component of Yeast CF II, Is Required for Both Cleavage and Poly(A) Addition of mRNA Precursor

CF II, a factor required for cleavage of the 3' ends of mRNA precursor in Saccharomyces cerevisiae, has been shown to contain four polypeptides. The three largest subunits, Cft1/Yhh1, Cft2/Ydh1, and Brr5/Ysh1, are homologs of the three largest subunits of mammalian cleavage-polyadenylation specificity factor (CPSF), an activity needed for both cleavage and poly(A) addition. In this report, we show by protein sequencing and immunoreactivity that the fourth subunit of CF II is Pta1, an essential 90-kDa protein originally implicated in tRNA splicing. Yth1, the yeast homolog of the CPSF 30-kDa subunit, is not detected in this complex. Extracts prepared from pta1 mutant strains are impaired in the cleavage and the poly(A) addition of both GAL7 and CYC1 substrates and exhibit little processing activity even after prolonged incubation. However, activity is efficiently rescued by the addition of purified CF II to the defective extracts. Extract from a strain with a mutation in the CF IA subunit Rna14 also restored processing, but extract from a brr5-1 strain did not. The amounts of Pta1 and other CF II subunits are reduced in pta1 strains, suggesting that levels of the subunits may be coordinately regulated. Coimmunoprecipitation experiments indicate that the CF II in extract can be found in a stable complex containing Pap1, CF II, and the Fip1 and Yth1 subunits of polyadenylation factor I. While purified CF II does not appear to retain the association with these other factors, this larger complex may be the form recruited onto pre-mRNA in vivo. The involvement of Pta1 in both steps of mRNA 3'-end formation supports the conclusion that CF II is the functional homolog of CPSF.     

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.     

A multisubunit 3'' end processing factor from yeast containing poly(A) polymerase and homologues of the subunits of mammalian cleavage and polyadenylation specificity factor.

Polyadenylation is the second step in 3' end formation of most eukaryotic mRNAs. In Saccharomyces cerevisiae, this step requires three trans-acting factors: poly(A) polymerase (Pap1p), cleavage factor I (CF I) and polyadenylation factor I (PF I). Here, we describe the purification and subunit composition of a multiprotein complex containing Pap1p and PF I activities. PF I-Pap1p was purified to homogeneity by complementation of extracts mutant in the Fip1p subunit of PF I. In addition to Fip1p and Pap1p, the factor comprises homologues of all four subunits of mammalian cleavage and polyadenylation specificity factor (CPSF), as well as Ptalp, which previously has been implicated in pre-tRNA processing, and several as yet uncharacterized proteins. As expected for a PF I subunit, pta1-1 mutant extracts are deficient for polyadenylation in vitro. PF I also appears to be functionally related to CPSF, as it polyadenylates a substrate RNA more efficiently than Pap1p alone. Possibly, the observed interaction of the complex with RNA tethers Pap1p to its substrate.     

3' cleavage and polyadenylation of mRNA precursors in vitro requires a poly(A) polymerase, a cleavage factor, and a snRNP

We have separated and purified three factors from HeLa cell nuclear extracts that together can accurately cleave and polyadenylate pre-mRNAs containing the adenovirus L3 polyadenylation site. One of the factors is a poly(A) polymerase with a molecular weight of approximately 50-60 kd. The second activity is a cleavage factor with a native molecular weight in the range of 70-120 kd. The third component is a factor (cleavage and polyadenylation factor, CPF) that is needed for the cleavage reaction and, in addition, confers specificity to the poly(A) polymerase activity; the native molecular weight of CPF is approximately 200 kd. Poly(A) polymerase together with CPF is sufficient to specifically polyadenylate pre-mRNA substrates that have been precleaved at the poly(A) addition site. In contrast, all three components are required for accurate cleavage and polyadenylation of pre-mRNA substrates. Further purification of CPF by buoyant density centrifugation, ion exchange, and affinity column chromatography or by gel filtration demonstrates that CPF activity resides in a ribonucleoprotein and copurifies with U11 snRNP.     

Direct interactions between subunits of CPSF and the U2 snRNP contribute to the coupling of pre-mRNA 3' end processing and splicing

Eukaryotic pre-mRNAs are capped at their 5' ends, polyadenylated at their 3' ends, and spliced before being exported from the nucleus to the cytoplasm. Although the three processing reactions can be studied separately in vitro, they are coupled in vivo. We identified subunits of the U2 snRNP in highly purified CPSF and showed that the two complexes physically interact. We therefore tested whether this interaction contributes to the coupling of 3' end processing and splicing. We found that CPSF is necessary for efficient splicing activity in coupled assays and that mutations in the pre-mRNA binding site of the U2 snRNP resulted in impaired splicing and in much reduced cleavage efficiency. Moreover, we showed that efficient cleavage required the presence of the U2 snRNA in coupled assays. We therefore propose that the interaction between CPSF and the U2 snRNP contributes to the coupling of splicing and 3' end formation.     

Distinct roles of two Yth1p domains in 3'-end cleavage and polyadenylation of yeast pre-mRNAs

Yth1p is the yeast homologue of the 30 kDa subunit of mammalian cleavage and polyadenylation specificity factor (CPSF). The protein is part of the cleavage and polyadenylation factor CPF, which includes cleavage factor II (CF II) and polyadenylation factor I (PF I), and is required for both steps in pre-mRNA 3'-end processing. Yth1p is an RNA-binding protein that was previously shown to be essential for polyadenylation. Here, we demonstrate that Yth1p is also required for the cleavage reaction and that two protein domains have distinct roles in 3'-end processing. The C-terminal part is required in polyadenylation to tether Fip1p and poly(A) polymerase to the rest of CPF. A single point mutation in the highly conserved second zinc finger impairs both cleavage and polyadenylation, and affects the ability of Yth1p to interact with the pre-mRNA and other CPF subunits. Finally, we find that Yth1p binds to CYC1 pre-mRNA in the vicinity of the cleavage site. Our results indicate that Yth1p is important for the integrity of CPF and participates in the recognition of the cleavage site.     

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.     

Influenza A virus NS1 protein targets poly(A)-binding protein II of the cellular 3'-end processing machinery

Influenza A virus NS1 protein (NS1A protein) via its effector domain targets the poly(A)-binding protein II (PABII) of the cellular 3'-end processing machinery. In vitro the NS1A protein binds the PABII protein, and in vivo causes PABII protein molecules to relocalize from nuclear speckles to a uniform distribution throughout the nucleoplasm. In vitro the NS1A protein inhibits the ability of PABII to stimulate the processive synthesis of long poly(A) tails catalyzed by poly(A) polymerase (PAP). Such inhibition also occurs in vivo in influenza virus-infected cells, where the NS1A protein via its effector domain causes the nuclear accumulation of cellular pre-mRNAs which contain short ( approximately 12 nucleotide) poly(A) tails. Consequently, although the NS1A protein also binds the 30 kDa subunit of the cleavage and polyadenylation specificity factor (CPSF), 3' cleavage of some cellular pre-mRNAs still occurs in virus-infected cells, followed by the PAP-catalyzed addition of short poly(A) tails. Subsequent elongation of these short poly(A) tails is blocked because the NS1A protein inhibits PABII function. Nuclear-cytoplasmic shuttling of PABII, an activity implicating this protein in the nuclear export of cellular mRNAs, is also inhibited by the NS1A protein. In vitro assays suggest that the 30 kDa CPSF and PABII proteins bind to non-overlapping regions of the NS1A protein effector domain and indicate that these two 3' processing proteins also directly bind to each other.     

Characterization of a Drosophila homologue of the 160-kDa subunit of the cleavage and polyadenylation specificity factor CPSF

Processing of the 3′ end of mRNA precursors depends on several proteins. The multisubunit cleavage and polyadenylation specificity factor (CPSF) is required for cleavage of the mRNA precursor as well as polyadenylation. CPSF interacts with the cleavage stimulatory factor complex (CstF), and this interaction increases the specificity of binding. Following cleavage downstream of the AAUAAA site, CPSF and poly(A) polymerase (PAP) are required for efficient polyadenylation. Recently, it has been shown that 160-kDa subunit of CPSF interacts directly with the 77-kDa subunit of CstF, which is homologous to the product encoded by the Drosophila gene su(f), and with PAP. Here we report the cloning and characterization of a Drosophila homologue of CPSF-160. The 1329-amino acid dCPSF protein exhibits about 45% and 20% sequence identity, respectively, to its mammalian and yeast counterparts over its entire length. We show that the CPSF homologue is expressed throughout development and that CPSF is essential for viability. Mutations in the cpsf gene did not alter the phenotype of homozygous su(f) mutations, suggesting that, for most genes, processing of 3′ termini is not sensitive to small changes in cpsf and su(f) dosage. Received: 6 June 1997 / Accepted: 5 November 1997     

Characterization of a Drosophila homologue of the 160-kDa subunit of the cleavage and polyadenylation specificity factor CPSF

Processing of the 3′ end of mRNA precursors depends on several proteins. The multisubunit cleavage and polyadenylation specificity factor (CPSF) is required for cleavage of the mRNA precursor as well as polyadenylation. CPSF interacts with the cleavage stimulatory factor complex (CstF), and this interaction increases the specificity of binding. Following cleavage downstream of the AAUAAA site, CPSF and poly(A) polymerase (PAP) are required for efficient polyadenylation. Recently, it has been shown that 160-kDa subunit of CPSF interacts directly with the 77-kDa subunit of CstF, which is homologous to the product encoded by the Drosophila gene su(f), and with PAP. Here we report the cloning and characterization of a Drosophila homologue of CPSF-160. The 1329-amino acid dCPSF protein exhibits about 45% and 20% sequence identity, respectively, to its mammalian and yeast counterparts over its entire length. We show that the CPSF homologue is expressed throughout development and that CPSF is essential for viability. Mutations in the cpsf gene did not alter the phenotype of homozygous su(f) mutations, suggesting that, for most genes, processing of 3′ termini is not sensitive to small changes in cpsf and su(f) dosage.     

A mechanism for the regulation of pre-mRNA 3' processing by human cleavage factor Im

Human cleavage factor I(m) (CFI(m)) is a heterodimeric RNA binding protein complex that functions at an early step in the assembly of the pre-mRNA 3' processing complex. In this report we show that CFI(m) can stimulate both cleavage and poly(A) addition, and can act to suppress poly(A) site cleavage in a sequence-dependent manner. Elevated levels of CFI(m) suppressed cleavage at the primary poly(A) site of the pre-mRNA encoding the 68 kDa subunit of CFI(m). CFI(m)-mediated suppression of poly(A) site cleavage was dependent upon the presence of three copies of an RNA element initially identified by CFI(m)-SELEX. These data provide evidence for a mechanism for the regulation of poly(A) site selection by a basal pre-mRNA 3' processing factor.     

A novel plant in vitro assay system for pre-mRNA cleavage during 3'-end formation

Messenger RNA (mRNA) maturation in eukaryotic cells requires the formation of the 3' end, which includes two tightly coupled steps: the committing cleavage reaction that requires both correct cis-element signals and cleavage complex formation, and the polyadenylation step that adds a polyadenosine [poly(A)] tract to the newly generated 3' end. An in vitro biochemical assay plays a critical role in studying this process. The lack of such an assay system in plants hampered the study of plant mRNA 3'-end formation for the last two decades. To address this, we have now established and characterized a plant in vitro cleavage assay system, in which nuclear protein extracts from Arabidopsis (Arabidopsis thaliana) suspension cell cultures can accurately cleave different pre-mRNAs at expected in vivo authenticated poly(A) sites. The specific activity is dependent on appropriate cis-elements on the substrate RNA. When complemented by yeast (Saccharomyces cerevisiae) poly(A) polymerase, about 150-nucleotide poly(A) tracts were added specifically to the newly cleaved 3' ends in a cooperative manner. The reconstituted polyadenylation reaction is indicative that authentic cleavage products were generated. Our results not only provide a novel plant pre-mRNA cleavage assay system, but also suggest a cross-kingdom functional complementation of yeast poly(A) polymerase in a plant system.     

A common mechanism for the enhancement of mRNA 3' processing by U3 sequences in two distantly related lentiviruses.

The protein coding regions of all retroviral pre-mRNAs are flanked by a direct repeat of R-U5 sequences. In many retroviruses, the R-U5 repeat contains a complete core poly(A) site-composed of a highly conserved AAUAAA hexamer and a GU-rich downstream element. A mechanism that allows for the bypass of the 5' core poly(A) site and the exclusive use of the 3' core poly(A) site must therefore exist. In human immunodeficiency virus type 1 (HIV-1), sequences within the U3 region appear to play a key role in poly(A) site selection. U3 sequences are required for efficient 3' processing at the HIV-1 poly(A) site both in vivo and in vitro. These sequences serve to promote the interaction of cleavage and polyadenylation specificity factor (CPSF) with the core poly(A) site. We have now demonstrated the presence of a functionally analogous 3' processing enhancer within the U3 region of a distantly related lentivirus, equine infectious anemia virus (EIAV). U3 sequences enhanced the processing of the EIAV core poly(A) site sevenfold in vitro. The U3 sequences also enhanced the stability of CPSF binding at the core poly(A) site. Optimal processing required the TAR RNA secondary structure that resides within the R region 28 nucleotides upstream of the AAUAAA hexamer. Disruption of TAR reduced processing, while compensatory changes that restored the RNA structure also restored processing to the wild-type level, suggesting a position dependence of the U3-encoded enhancer sequences. Finally, the reciprocal exchange of the EIAV and HIV U3 regions demonstrated the ability of each of these sequences to enhance both 3' processing and the binding of CPSF in the context of the heterologous core poly(A) site. The impact of U3 sequences upon the interaction of CPSF at the core poly(A) site may therefore represent a common strategy for retroviral poly(A) site selection.     

An interaction between an Arabidopsis poly(A) polymerase and a homologue of the 100 kDa subunit of CPSF

The Arabidopsis genome possesses a number of sequences that are predicted to encode proteins that are similar to mammalian and yeast polyadenylation factor subunits. One of these resides on chromosome V and has the potential to encode a polypeptide related to the 100 kDa subunit of the mammalian cleavage and polyadenylation specificity factor (CPSF). This gene encodes a ca. 2400 nucleotide mRNA that in turn can be translated to yield a polypeptide that is 39% identical to the mammalian CPSF100 protein. Antibodies raised against the Arabidopsis protein recognized distinctive polypeptides in nuclear extracts prepared from pea and wheat germ, consistent with the hypothesis that the Arabidopsis protein is resident in a nuclear polyadenylation complex. Interestingly, the Arabidopsis CPSF100 was found to interact with a portion of a nuclear poly(A) polymerase. This interaction was attributable to a 60 amino acid domain in the CPSF100 polypeptide and the N-terminal 220 amino acids of the poly(A) polymerase. An analogous interaction has yet to be described in other eukaryotes. The interaction with PAP thus indicates that the plant CPSF100 polypeptide is likely part of the 3-end processing machinery, but suggests that this complex may function differently in plants than it does in mammals and yeast.