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

Omni-PolyA: a method and tool for accurate recognition of Poly(A) signals in human genomic DNA

BACKGROUND

Polyadenylation is a critical stage of RNA processing during the formation of mature mRNA, and is present in most of the known eukaryote protein-coding transcripts and many long non-coding RNAs. The correct identification of poly(A) signals (PAS) not only helps to elucidate the 3'-end genomic boundaries of a transcribed DNA region and gene regulatory mechanisms but also gives insight into the multiple transcript isoforms resulting from alternative PAS. Although progress has been made in the in-silico prediction of genomic signals, the recognition of PAS in DNA genomic sequences remains a challenge.

RESULTS

In this study, we analyzed human genomic DNA sequences for the 12 most common PAS variants. Our analysis has identified a set of features that helps in the recognition of true PAS, which may be involved in the regulation of the polyadenylation process. The proposed features, in combination with a recognition model, resulted in a novel method and tool, Omni-PolyA. Omni-PolyA combines several machine learning techniques such as different classifiers in a tree-like decision structure and genetic algorithms for deriving a robust classification model. We performed a comparison between results obtained by state-of-the-art methods, deep neural networks, and Omni-PolyA. Results show that Omni-PolyA significantly reduced the average classification error rate by 35.37% in the prediction of the 12 considered PAS variants relative to the state-of-the-art results.

CONCLUSIONS

The results of our study demonstrate that Omni-PolyA is currently the most accurate model for the prediction of PAS in human and can serve as a useful complement to other PAS recognition methods. Omni-PolyA is publicly available as an online tool accessible at www.cbrc.kaust.edu.sa/omnipolya/ .

PA-seq for Global Identification of RNA Polyadenylation Sites of Kaposi's Sarcoma-Associated Herpesvirus Transcripts

Kaposi's sarcoma-associated herpesvirus (KSHV) is a human oncovirus linked to the development of several malignancies in immunocompromised patients. Like other herpesviruses, KSHV has a large DNA genome encoding more than 100 distinct gene products. Despite being transcribed and processed by cellular machinery, the structure and organization of KSHV genes in the virus genome differ from what is observed in cellular genes from the human genome. A typical feature of KSHV expression is the production of polycistronic transcripts initiated from different promoters but sharing the same polyadenylation site (pA site). This represents a challenge in determination of the 3' end of individual viral transcripts. Such information is critical for generation of a virus transcriptional map for genetic studies. Here we present PA-seq, a high-throughput method for genome-wide analysis of pA sites of KSHV transcripts in B lymphocytes with latent or lytic KSHV infection. Besides identification of all viral pA sites, PA-seq also provides quantitative information about the levels of viral transcripts associated with each pA site, making it possible to determine the relative expression levels of viral genes at various stages of infection. Due to the indiscriminate nature of PA-seq, the pA sites of host transcripts are also concurrently mapped in the testing samples. Therefore, this technology can simultaneously estimate the expression changes of host genes and RNA polyadenylation upon KSHV infection. © 2016 by John Wiley & Sons, Inc.

Localization of RNAPII and 3' end formation factor CstF subunits on C. elegans genes and operons

Transcription termination is mechanistically coupled to pre-mRNA 3' end formation to prevent transcription much beyond the gene 3' end. C. elegans, however, engages in polycistronic transcription of operons in which 3' end formation between genes is not accompanied by termination. We have performed RNA polymerase II (RNAPII) and CstF ChIP-seq experiments to investigate at a genome-wide level how RNAPII can transcribe through multiple poly-A signals without causing termination. Our data shows that transcription proceeds in some ways as if operons were composed of multiple adjacent single genes. Total RNAPII shows a small peak at the promoter of the gene cluster and a much larger peak at 3' ends. These 3' peaks coincide with maximal phosphorylation of Ser2 within the C-terminal domain (CTD) of RNAPII and maximal localization of the 3' end formation factor CstF. This pattern occurs at all 3' ends including those at internal sites in operons where termination does not occur. Thus the normal mechanism of 3' end formation does not always result in transcription termination. Furthermore, reduction of CstF50 by RNAi did not substantially alter the pattern of CstF64, total RNAPII, or Ser2 phosphorylation at either internal or terminal 3' ends. However, CstF50 RNAi did result in a subtle reduction of CstF64 binding upstream of the site of 3' cleavage, suggesting that the CstF50/CTD interaction may facilitate bringing the 3' end machinery to the transcription complex.

Delineating the structural blueprint of the pre-mRNA 3'-end processing machinery

Processing of mRNA precursors (pre-mRNAs) by polyadenylation is an essential step in gene expression. Polyadenylation consists of two steps, cleavage and poly(A) synthesis, and requires multiple cis elements in the pre-mRNA and a megadalton protein complex bearing the two essential enzymatic activities. While genetic and biochemical studies remain the major approaches in characterizing these factors, structural biology has emerged during the past decade to help understand the molecular assembly and mechanistic details of the process. With structural information about more proteins and higher-order complexes becoming available, we are coming closer to obtaining a structural blueprint of the polyadenylation machinery that explains both how this complex functions and how it is regulated and connected to other cellular processes.

mRNA 3' end processing factors: a phylogenetic comparison

Almost all eukaryotic mRNAs possess 3′ ends with a polyadenylate (poly(A)) tail. This poly(A) tail is not encoded in the genome but is added by the process of polyadenylation. Polyadenylation is a two-step process, and this process is accomplished by multisubunit protein factors. Here, we comprehensively compare the protein machinery responsible for polyadenylation of mRNAs across many evolutionary divergent species, and we have found these protein factors to be remarkably conserved in nature. These data suggest that polyadenylation of mRNAs is an ancient process.

Structural biology of poly(A) site definition

3' processing is an essential step in the maturation of all messenger RNAs (mRNAs) and is a tightly coupled two-step reaction: endonucleolytic cleavage at the poly(A) site is followed by the addition of a poly(A) tail, except for metazoan histone mRNAs, which are cleaved but not polyadenylated. The recognition of a poly(A) site is coordinated by the sequence elements in the mRNA 3' UTR and associated protein factors. In mammalian cells, three well-studied sequence elements, UGUA, AAUAAA, and GU-rich, are recognized by three multisubunit factors: cleavage factor I(m) (CFI(m) ), cleavage and polyadenylation specificity factor (CPSF), and cleavage stimulation factor (CstF), respectively. In the yeast Saccharomyces cerevisiae, UA repeats and A-rich sequence elements are recognized by Hrp1p and cleavage factor IA. Structural studies of protein-RNA complexes have helped decipher the mechanisms underlying sequence recognition and shed light on the role of protein factors in poly(A) site selection and 3' processing machinery assembly. In this review we focus on the interactions between the mRNA cis-elements and the protein factors (CFI(m) , CPSF, CstF, and homologous factors from yeast and other eukaryotes) that define the poly(A) site. WIREs RNA 2011 2 732-747 DOI: 10.1002/wrna.88 For further resources related to this article, please visit the WIREs website.

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.

Regulation of the subcellular distribution of key cellular RNA-processing factors during permissive human cytomegalovirus infection

Alternative splicing and polyadenylation of human cytomegalovirus (HCMV) immediate-early (IE) pre-mRNAs are temporally regulated and rely on cellular RNA-processing factors. This study examined the location and abundance of essential RNA-processing factors, which affect alternative processing of UL37 IE pre-mRNAs, during HCMV infection. Serine/threonine protein kinase 1 (SRPK1) phosphorylates serine/arginine-rich proteins, necessary for pre-spliceosome commitment. It was found that HCMV infection progressively increased the abundance of cytoplasmic SRPK1, which is regulated by subcellular partitioning. The essential polyadenylation factor CstF-64 was similarly increased in abundance, albeit in the nucleus, proximal to and within viral replication compartments (VRCs). In contrast, the location of polypyrimidine tract-binding protein (PTB), known to adversely affect splicing of HCMV major IE RNAs, was temporally regulated during infection. PTB co-localized with CstF-64 in the nucleus at IE times. By early times, PTB was detected in punctate cytoplasmic sites of some infected cells. At late times, PTB relocalized to the nucleus, where it was notably excluded from HCMV VRCs. Moreover, HCMV infection induced the formation of nucleolar stress structures, fibrillarin-containing caps, in close proximity to its VRCs. PTB exclusion from HCMV VRCs required HCMV DNA synthesis and/or late gene expression, whereas the regulation of SRPK1 subcellular distribution did not. Taken together, these results indicated that HCMV increasingly regulates the subcellular distribution and abundance of essential RNA-processing factors, thereby altering their ability to affect the processing of viral pre-mRNAs. These results further suggest that HCMV infection selectively induces sorting of nucleolar and nucleoplasmic components.

Polyadenylation proteins CstF-64 and tauCstF-64 exhibit differential binding affinities for RNA polymers

CstF-64 (cleavage stimulation factor-64), a major regulatory protein of polyadenylation, is absent during male meiosis. Therefore a paralogous variant, tauCstF-64 is expressed in male germ cells to maintain normal spermatogenesis. Based on sequence differences between tauCstF-64 and CstF-64, and on the high incidence of alternative polyadenylation in testes, we hypothesized that the RBDs (RNA-binding domains) of tauCstF-64 and CstF-64 have different affinities for RNA elements. We quantified K(d) values of CstF-64 and tauCstF-64 RBDs for various ribopolymers using an RNA cross-linking assay. The two RBDs had similar affinities for poly(G)18, poly(A)18 or poly(C)18, with affinity for poly(C)18 being the lowest. However, CstF-64 had a higher affinity for poly(U)18 than tauCstF-64, whereas it had a lower affinity for poly(GU)9. Changing Pro-41 to a serine residue in the CstF-64 RBD did not affect its affinity for poly(U)18, but changes in amino acids downstream of the C-terminal alpha-helical region decreased affinity towards poly(U)18. Thus we show that the two CstF-64 paralogues differ in their affinities for specific RNA sequences, and that the region C-terminal to the RBD is mportant in RNA sequence recognition. This supports the hypothesis that tauCstF-64 promotes germ-cell-specific patterns of polyadenylation by binding to different downstream sequence elements.

ELAV inhibits 3'-end processing to promote neural splicing of ewg pre-mRNA

The embryonic lethal abnormal visual system (ELAV) is a gene-specific regulator of alternative pre-mRNA processing in neurons of Drosophila. Here we define a functional in vivo binding site for ELAV in neurons through the development of a reporter gene system in transgenic animals in combination with in vitro binding assays. ELAV binds to erect wing (ewg) RNA 3' of a polyadenylation site in the terminal intron 6. At this polyadenylation site, ELAV inhibits 3'-end processing in vitro in a dose-dependent and sequence-specific manner, and ELAV binding is necessary in vivo to promote splicing of ewg intron 6. Further, the AAUAAA poly(A) complex recognition sequence, together with ELAV, is required to regulate neural 3' splice site choice in vivo. In addition, the use of segmentally labeled RNA substrates in UV cross-linking assays suggest that ELAV does not inhibit or redirect binding of cleavage factor dCstF64 at the regulated polyadenylation site on ewg RNA. These data indicate that binding of 3'-end processing factors, together with ELAV, can regulate alternative splicing.

The role of the yeast cleavage and polyadenylation factor subunit Ydh1p/Cft2p in pre-mRNA 3'-end formation

Cleavage and polyadenylation factor (CPF) is a multi-protein complex that functions in pre-mRNA 3'-end formation and in the RNA polymerase II (RNAP II) transcription cycle. Ydh1p/Cft2p is an essential component of CPF but its precise role in 3'-end processing remained unclear. We found that mutations in YDH1 inhibited both the cleavage and the polyadenylation steps of the 3'-end formation reaction in vitro. Recently, we demonstrated that an important function of CPF lies in the recognition of poly(A) site sequences and RNA binding analyses suggesting that Ydh1p/Cft2p interacts with the poly(A) site region. Here we show that mutant ydh1 strains are deficient in the recognition of the ACT1 cleavage site in vivo. The C-terminal domain (CTD) of RNAP II plays a major role in coupling 3'-end processing and transcription. We provide evidence that Ydh1p/Cft2p interacts with the CTD of RNAP II, several other subunits of CPF and with Pcf11p, a component of CF IA. We propose that Ydh1p/Cft2p contributes to the formation of important interaction surfaces that mediate the dynamic association of CPF with RNAP II, the recognition of poly(A) site sequences and the assembly of the polyadenylation machinery on the RNA substrate.

hnRNP F influences binding of a 64-kilodalton subunit of cleavage stimulation factor to mRNA precursors in mouse B cells

Previous studies on the regulation of polyadenylation of the immunoglobulin (Ig) heavy-chain pre-mRNA argued for trans-acting modifiers of the cleavage-polyadenylation reaction operating differentially during B-cell developmental stages. Using four complementary approaches, we demonstrate that a change in the level of hnRNP F is an important determinant in the regulated use of alternative polyadenylation sites between memory and plasma stage B cells. First, by Western analyses of cellular proteins, the ratio of hnRNP F to H or H' was found to be higher in memory B cells than in plasma cells. In memory B cells the activity of CstF-64 binding to pre-mRNA, but not its amount, was reduced. Second, examination of the complexes formed on input pre-mRNA in nuclear extracts revealed large assemblages containing hnRNP H, H', and F but deficient in CstF-64 in memory B-cell extracts but not in plasma cells. Formation of these large complexes is dependent on the region downstream of the AAUAAA in pre-mRNA, suggesting that CstF-64 and the hnRNPs compete for a similar region. Third, using a recombinant protein we showed that hnRNP F could bind to the region downstream of a poly(A) site, block CstF-64 association with RNA, and inhibit the cleavage reaction. Fourth, overexpression of recombinant hnRNP F in plasma cells resulted in a decrease in the endogenous Ig heavy-chain mRNA secretory form-to-membrane ratio. These results demonstrate that mammalian hnRNP F can act as a negative regulator in the pre-mRNA cleavage reaction and that increased expression of F in memory B cells contributes to the suppression of the Ig heavy-chain secretory poly(A) site.

Intercistronic region required for polycistronic pre-mRNA processing in Caenorhabditis elegans

In Caenorhabditis elegans, polycistronic pre-mRNAs are processed by cleavage and polyadenylation at the 3' ends of the upstream genes and trans splicing, generally to the specialized spliced leader SL2, at the 5' ends of the downstream genes. Previous studies have indicated a relationship between these two events in the processing of a heat shock-induced gpd-2-gpd-3 polycistronic pre-mRNA. Here, we report mutational analysis of the intercistronic region of this operon by linker scan analysis. Surprisingly, no sequences downstream of the 3' end were important for 3'-end formation. In contrast, a U-rich (Ur) element located 29 bp downstream of the site of 3'-end formation was shown to be important for downstream mRNA biosynthesis. This approximately 20-bp element is sufficient for SL2 trans splicing and mRNA accumulation when transplanted to a heterologous context. Furthermore, when the downstream gene was replaced by a gene from another organism, no loss of trans-splicing specificity was observed, suggesting that the Ur element may be the primary signal required for downstream mRNA processing.

The human papillomavirus type 16 negative regulatory RNA element interacts with three proteins that act at different posttranscriptional levels

In human papillomaviruses, expression of the late genes L1 and L2, encoding the capsid proteins, is restricted to the upper layers of the infected epithelium. A 79-nt GU-rich negative regulatory element (NRE) located at the 3' untranslated region of the human papillomavirus 16 L1 gene was identified previously as key to the posttranscriptional control of late gene expression. Here, we demonstrate that in epithelial cells, the NRE can directly bind the U2 auxiliary splicing factor 65-kDa subunit, the cleavage stimulation factor 64-kDa subunit, and the Elav-like HuR protein. On induction of epithelial cell differentiation, levels of the U2 auxiliary splicing factor 65-kDa subunit decrease, levels of the cleavage stimulation factor 64-kDa subunit increase, and the levels of HuR remain unchanged, although redistribution of the HuR from the nucleus to the cytoplasm is observed. Late gene transcripts, which appear to be fully processed, are detected in undifferentiated W12 cells, but are confined in the nucleus. We propose that repression of late gene expression in basal epithelial cells may be caused by nuclear retention or cytoplasmic instability of NRE-containing late gene transcripts.

The Drosophila homologue of the 64 kDa subunit of cleavage stimulation factor interacts with the 77 kDa subunit encoded by the suppressor of forked gene

During mRNA 3' end formation, cleavage stimulation factor (CstF) binds to a GU-rich sequence downstream from the polyadenylation site and helps to stabilise the binding of cleavage-polyadenylation specificity factor (CPSF) to the upstream poly-adenylation sequence (AAUAAA). The 64 kDa subunit of CstF (CstF-64) contains an RNA binding domain and is responsible for the RNA binding activity of CstF. It interacts with CstF-77, which in turn interacts with CPSF. The Drosophila suppressor of forked gene encodes a homologue of CstF-77, and mutations in it affect mRNA 3' end formation in vivo. A Drosophila homologue for CstF-64 has now been isolated, both through homology with the human protein and through protein-protein interaction in yeast with the suppressor of forked gene product. Alignment of CstF-64 homologues shows that the proteins have a conserved N-terminal 200 amino acids, the first half of which is the RNA binding domain with the second half likely to contain the CstF-77 interaction domain; a central region variable in length and rich in glycine, proline and glutamine residues and containing an unusual degenerate repeat motif; and then a conserved C-terminal 50 amino acids. In Drosophila, the CstF-64 gene has a single 63 bp intron, is transcribed throughout development and probably corresponds to l(3)91Cd.

Regulation of human papillomavirus type 31 polyadenylation during the differentiation-dependent life cycle

The L1 and L2 capsid genes of human papillomavirus type 31 (HPV-31) are expressed late in the differentiation-dependent life cycle from a promoter located in the E7 open reading frame (ORF) of the early region. These late HPV genes are transcribed by RNA polymerase II which reads through the region containing early polyadenylation signals and proceeds to a poly(A) site downstream of L1. In this study, we have investigated the mechanisms regulating differentiation-dependent polyadenylation and read-through in HPV-31. HPV-31 early transcripts were found to utilize a heterogeneous series of polyadenylation sites in undifferentiated cells. The sites for polyadenylation extended over a range of 100 nucleotides from within the E5 ORF to upstream of L2. Upon differentiation, the transcription of early genes increased, but no change in the heterogeneous distribution of 3' ends was detected. The early polyadenylation region was found to contain a single consensus hexanucleotide sequence, AAUAAA, as well as three weak binding sites for the cleavage stimulatory factor, CstF. In contrast to the heterogeneity at the early site, the 3' ends of late transcripts encoding L1 and L2 were localized to a narrow region downstream of the late AAUAAA element. The late polyadenylation signal was found to contain a single high-affinity site for CstF, as well as one consensus hexanucleotide sequence. By using a reporter assay, it was determined that the HPV-31 early polyadenylation sequences allowed significant levels of read-through into the late region in undifferentiated cells. Upon differentiation, this read-through was increased by approximately 50%, indicating that use of the early site decreased. Differentiation was also found to induce a 40% reduction in the levels of CstF subunits, which may contribute to the increased read-through of the early sequence. The insertion of the late high-affinity binding site for CstF into the early polyadenylation region significantly reduced the level of read-through, suggesting that these factors modulate read-through activity. Our studies demonstrate that HPV-31 late gene expression is regulated in a large part by posttranscriptional mechanisms, including the polyadenylation of early transcripts.

Formation of mRNA 3' ends in eukaryotes: mechanism, regulation, and interrelationships with other steps in mRNA synthesis

Formation of mRNA 3' ends in eukaryotes requires the interaction of transacting factors with cis-acting signal elements on the RNA precursor by two distinct mechanisms, one for the cleavage of most replication-dependent histone transcripts and the other for cleavage and polyadenylation of the majority of eukaryotic mRNAs. Most of the basic factors have now been identified, as well as some of the key protein-protein and RNA-protein interactions. This processing can be regulated by changing the levels or activity of basic factors or by using activators and repressors, many of which are components of the splicing machinery. These regulatory mechanisms act during differentiation, progression through the cell cycle, or viral infections. Recent findings suggest that the association of cleavage/polyadenylation factors with the transcriptional complex via the carboxyl-terminal domain of the RNA polymerase II (Pol II) large subunit is the means by which the cell restricts polyadenylation to Pol II transcripts. The processing of 3' ends is also important for transcription termination downstream of cleavage sites and for assembly of an export-competent mRNA. The progress of the last few years points to a remarkable coordination and cooperativity in the steps leading to the appearance of translatable mRNA in the cytoplasm.

The upstream sequence element of the C2 complement poly(A) signal activates mRNA 3' end formation by two distinct mechanisms

The poly(A) signal of the C2 complement gene is unusual in that it possesses an upstream sequence element (USE) required for full activity in vivo. We describe here in vitro experiments demonstrating that this USE enhances both the cleavage and poly(A) addition reactions. We also show that the C2 USE can be cross-linked efficiently to a 55-kD protein that we identify as the polypyrimidine tract-binding protein (PTB), implicated previously in modulation of pre-mRNA splicing. Mutation of the PTB-binding site significantly reduces the efficiency of the C2 poly(A) site both in vivo and in vitro. Furthermore, addition of PTB to reconstituted processing reactions enhances cleavage at the C2 poly(A) site, indicating that PTB has a direct role in recognition of this signal. The C2 USE, however, also increases the affinity of general polyadenylation factors independently for the C2 poly(A) signal as detected by enhanced binding of cleavage-stimulaton factor (CstF). Strikingly, this leads to a novel CstF-dependant enhancement of the poly(A) synthesis phase of the reaction. These studies both emphasize the interconnection between splicing and polyadenylation and indicate an unexpected flexibility in the organization of mammalian poly(A) sites.

Auxiliary downstream elements are required for efficient polyadenylation of mammalian pre-mRNAs

We have previously identified a G-rich sequence (GRS) as an auxiliary downstream element (AUX DSE) which influences the processing efficiency of the SV40 late polyadenylation signal. We have now determined that sequences downstream of the core U-rich element (URE) form a fundamental part of mammalian polyadenylation signals. These novel AUX DSEs all influenced the efficiency of 3'-end processing in vitro by stabilizing the assembly of CstF on the core downstream URE. Three possible mechanisms by which AUX DSEs mediate efficient in vitro 3'-end processing have been explored. First, AUX DSEs can promote processing efficiency by maintaining the core elements in an unstructured domain which allows the general polyadenylation factors to efficiently assemble on the RNA substrate. Second, AUX DSEs can enhance processing by forming a stable structure which helps focus binding of CstF to the core downstream URE. Finally, the GRS element, but not the binding site for the bacteriophage R17 coat protein, can substitute for the auxiliary downstream region of the adenovirus L3 polyadenylation signal. This suggests that AUX DSE binding proteins may play an active role in stimulating 3'-end processing by stabilizing the association of CstF with the RNA substrate. AUX DSEs, therefore, serve as a integral part of the polyadenylation signal and can affect signal strength and possibly regulation.

RNA recognition by the human polyadenylation factor CstF

Polyadenylation of mammalian mRNA precursors requires at least two signal sequences in the RNA: the nearly invariant AAUAAA, situated 5' to the site of polyadenylation, and a much more variable GU- or U-rich downstream element. At least some downstream sequences are recognized by the heterotrimeric polyadenylation factor CstF, although how, and indeed if, all variations of this diffuse element are bound by a single factor is unknown. Here we show that the RNP-type RNA binding domain of the 64-kDa subunit of CstF (CstF-64) (64K RBD) is sufficient to define a functional downstream element. Selection-amplification (SELEX) experiments employing a glutathione S-transferase (GST)-64K RBD fusion protein selected GU-rich sequences that defined consensus recognition motifs closely matching those present in natural poly(A) sites. Selected sequences were bound specifically, and with surprisingly high affinities, by intact CstF and were functional in reconstituted, CstF-dependent cleavage assays. Our results also indicate that GU- and U-rich sequences are variants of a single CstF recognition motif. For comparison, SELEX was performed with a GST fusion containing the RBD from the apparent yeast homolog of CstF-64, RNA15. Strikingly, although the two RBDs are almost 50% identical and yeast poly(A) signals are at least as degenerate as the mammalian downstream element, a nearly invariant 12-base U-rich sequence distinct from the CstF-64 consensus was identified. We discuss these results in terms of the function and evolution of mRNA 3'-end signals.

Sequences regulating poly(A) site selection within the adenovirus major late transcription unit influence the interaction of constitutive processing factors with the pre-mRNA

The adenovirus major late transcription unit (MLTU) encodes five families of mRNAs, L1 to L5, each distinguished by a unique poly(A) site. Use of the promoter-proximal L1 poly(A) site predominates during early infection, whereas poly(A) site choice shifts to the promoter-distal sites during late infection. A mini-MLTU containing only the L1 and L3 poly(A) sites has been shown to reproduce this processing switch. In vivo analysis has revealed that sequences extending 5' and 3' of the L1 core poly(A) site are required for efficient processing as well as for regulated expression. By replacement of the L1 core poly(A) site with that of the ground squirrel hepatitis virus poly(A) site, we now demonstrate that the L1 flanking sequences can enhance the processing of a heterologous poly(A). Upon recombination of the chimeric L1-ground squirrel hepatitis virus poly(A) site onto the viral chromosome, the L1 flanking sequences were also found to be sufficient to reproduce the processing switch during the course of viral infection. Subsequent in vitro analysis has shown that the L1 flanking sequences function to enhance the stability of binding of cleavage and polyadenylation specificity factor to the core poly(A) site. The impact of L1 flanking sequences on the binding of cleavage and polyadenylation specificity factor suggests that the regulation of the MLTU poly(A) site selection is mediated by the interaction of constitutive processing factors.

Regulation of poly(A) site use during mouse B-cell development involves a change in the binding of a general polyadenylation factor in a B-cell stage-specific manner

During the development of mouse B cells there is a regulated shift from the production of membrane to the secretion-specific forms of immunoglobulin (Ig) mRNA, which predominate in the late-stage or plasma B cells. By DNA transfection experiments we have previously shown that there is an increase in polyadenylation efficiency accompanying the shift to secretion-specific forms of Ig mRNA (C. R. Lassman, S. Matis, B. L. Hall, D. L. Toppmeyer, and C. Milcarek, J. Immunol. 148:1251-1260, 1992). When we look in vitro at nuclear extracts prepared from early or memory versus late-stage or plasma B cells, we see cell stage-specific differences in the proteins which are UV cross-linked to the input RNAs. We have characterized one of these proteins as the 64-kDa subunit of the general polyadenylation factor cleavage-stimulatory factor (CstF) by immunoprecipitation of UV-cross-linked material. The amount of 64-kDa protein and its mobility on two-dimensional gels do not vary between the B-cell stages. However, the activity of binding of the protein to both Ig and non-Ig substrates increases four- to eightfold in the late-stage or plasma cell lines relative to the binding seen in the early or memory B-cell lines. Therefore, the binding activity of a constitutive factor required for polyadenylation is altered in a B-cell-specific fashion. The increased binding of the 64-kDa protein may lead to a generalized increase in polyadenylation efficiency in plasma cells versus early or memory B cells which may be responsible for the increased use of the secretory poly(A) site seen in vivo.

Characterization of the polyomavirus late polyadenylation signal

The polyomavirus late polyadenylation signal is used inefficiently during the late phase of a productive viral infection. Inefficient polyadenylation serves an important purpose for viral propagation, as it allows a splicing event that stabilizes late transcripts (G. R. Adami, C. W. Marlor, N. L. Barrett, and G. G. Carmichale, J. Virol. 63:85-93, 1989; R. P. Hyde-DeRuyscher and G. G. Carmichael, J. Virol. 64:5823-5832, 1990). We have recently shown that late-strand readthrough transcripts serve as natural antisense molecules to downregulate early-strand RNA levels at late times in infection (Z. Liu, D. B. Batt, and G. G. Carmichael, Proc. Natl. Acad. Sci. USA 91:4258-4262, 1994). Thus, poor polyadenylation contributes to the early-late switch by allowing the formation of more stable late RNAs and by forming antisense RNA to early RNAs. The importance of late poly(A) site inefficiency in the viral life cycle has prompted us to map the cis elements of this site. Since the polyomavirus late site proved a poor substrate for in vitro polyadenylation, we used an in vivo assay which allowed us to map the cis sequences required for its function. In this assay, various fragments containing the AAUAAA and different surrounding sequences were placed 1.4 kb upstream of a second, wild-type signal. The second signal served to stabilize transcripts that are not processed at the upstream site, allowing accurate quantitation of relative poly(A) site use by an RNase protection assay. Processing was primary at the upstream site when a large fragment surrounding the poly(A) signal (50 nucleotides [nt] upstream and 90 nt downstream) was tested in this assay, demonstrating that this fragment contains the essential cis elements. Deletion analysis of this fragment revealed that most but not all upstream sequences can be removed with little effect on polyadenylation efficiency, indicating the absence of a strong stimulatory upstream element. Deletion of all but 25 nt downstream of the AAUAAA reduced polyadenylation activity only by half, demonstrating that processing can occur at this site despite the lack of downstream sequences. Thus, the core cis element for polyadenylation is quite small, with most important cis-acting elements lying within 19 nt upstream and 25 nt downstream of the AAUAAA sequence. This core contains the AAUAAA hexanucleotide, an upstream A/U-rich element, and three identical repeats of a 6-nt sequence, UAUUCA. Polyadenylation was eliminated or greatly reduced when either the AAUAAA or the three repeats were mutated.

Cleavage site determinants in the mammalian polyadenylation signal

Using a series of position and nucleotide variants of the SV40 late polyadenylation signal we have demonstrated that three sequence elements determine the precise site of 3-end cleavage in mammalian pre-mRNAs: an upstream AAUAAA element, a down-stream U-rich element consisting of five nucleotides, at least four of which are uridine, and a nucleotide preference at the site of cleavage in the order A > U > C >> G. Cleavage occurs no closer than 11 bases, but no further than 23 bases from the AAUAAA element. The downstream U-rich element is usually located 10-30 bases from the cleavage site. The relative position of the AAUAAA and the U-rich elements define the approximate region within a 13 base domain in which cleavage will occur. The exact position of cleavage is then determined by the local nucleotide sequence in the order of preference noted above. This model accounts for nearly three quarters of polyadenylation signals surveyed and is consistent with previous experimental observations.

The G-rich auxiliary downstream element has distinct sequence and position requirements and mediates efficient 3' end pre-mRNA processing through a trans-acting factor

A downstream G-rich sequence (GRS), GGGGGAGGUGUGGG, has been previously shown to influence the efficiency of 3' end processing of the SV40 late polyadenylation signal. We have now defined several important parameters for GRS-mediated polyadenylation. The ability of the GRS to influence 3' end processing efficiency was sensitive to individual and multiple point mutations within the element, as well as the position of the element in the downstream region. Competition analysis indicated that the GRS functioned through a titratable trans-acting factor. The GRS-specific DSEF-1 protein was found to be bound to the same population of RNAs as the 64 kDa protein of the general polyadenylation factor CstF, indicating that DSEF-1 is associated with RNA substrates undergoing 3' end processing. Furthermore, an association was obtained between the relative strength of DSEF-1 protein binding to GRS variants and the relative ability of the GRS variants to mediate efficient cleavage in vitro. Finally, mutations in the GRS affected the efficiency of cross-linking of the 64 kDa protein of CstF. These data define a novel class of auxiliary downstream element and suggest an important role for DSEF-1 in 3' end processing.

Identification of an activity in B-cell extracts that selectively impairs the formation of an immunoglobulin mu s poly(A) site processing complex

The immunoglobulin mu heavy-chain transcription unit is differentially expressed during B-cell development, producing mRNAs that encode secreted (mu s) and membrane-bound (mu m) forms of the heavy-chain polypeptide. Whereas the mu s mRNA and the mu m mRNA are produced in approximately equal abundance in B cells, an increase in the utilization of the mu s poly(A) site contributes to the production of the mu s mRNA as the predominant form in a plasma cell. Previous experiments have demonstrated a correlation between the formation of a stable complex on a poly(A) site and the relative function of the poly(A) site. We have thus investigated the parameters determining the interaction of these factors with the immunoglobulin poly(A) sites. Assays of complex formation involving the two immunoglobulin poly(A) sites by using HeLa cell activities revealed the formation of stable complexes with no apparent difference between the mu s site and the mu m site. In contrast, the mu s-specific complex was markedly less stable when a B-cell extract was used. Fractionation of B-cell extracts has revealed an activity that specifically destabilizes the mu s polyadenylation complex, suggesting that the function of this poly(A) site may be regulated by both positive- and negative-acting factors.

Characterization of cleavage and polyadenylation specificity factor and cloning of its 100-kilodalton subunit

During the formation of the 3' ends of mRNA, the cleavage and polyadenylation specificity factor (CPSF) is required for 3' cleavage of the transcript as well as for subsequent polyadenylation. Using peptide sequences from a tryptic digest, we have cloned the 100-kDa subunit of CPSF. This subunit is a novel protein showing no homology to any known polypeptide in databases. Polyclonal antibodies against the C terminus of the protein inhibit the polyadenylation reaction. Polyclonal and monoclonal antibodies were used to characterize the composition of CPSF. Immunoprecipitations of CPSF from HeLa cell extracts and from labeled chromatographic fractions show the coprecipitation of all four subunits of 160, 100, 73, and 30 kDa. Proteins of 160 and 30 kDa that are specifically cross-linked to precursor RNA by UV irradiation were identified as CPSF subunits by immunoprecipitation. Immunofluorescent detection of CPSF in HeLa cells localized it in the nucleoplasm, excluding cytoplasm and nucleolar structures.

Characterization of cleavage and polyadenylation specificity factor and cloning of its 100-kilodalton subunit

During the formation of the 3' ends of mRNA, the cleavage and polyadenylation specificity factor (CPSF) is required for 3' cleavage of the transcript as well as for subsequent polyadenylation. Using peptide sequences from a tryptic digest, we have cloned the 100-kDa subunit of CPSF. This subunit is a novel protein showing no homology to any known polypeptide in databases. Polyclonal antibodies against the C terminus of the protein inhibit the polyadenylation reaction. Polyclonal and monoclonal antibodies were used to characterize the composition of CPSF. Immunoprecipitations of CPSF from HeLa cell extracts and from labeled chromatographic fractions show the coprecipitation of all four subunits of 160, 100, 73, and 30 kDa. Proteins of 160 and 30 kDa that are specifically cross-linked to precursor RNA by UV irradiation were identified as CPSF subunits by immunoprecipitation. Immunofluorescent detection of CPSF in HeLa cells localized it in the nucleoplasm, excluding cytoplasm and nucleolar structures.

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.

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.

Sequence elements upstream of the 3' cleavage site confer substrate strength to the adenovirus L1 and L3 polyadenylation sites

The adenovirus major late transcription unit is a well-characterized transcription unit which relies heavily on alternative pre-mRNA processing to generate distinct populations of mRNA during the early and late stages of viral infection. In the early stage of infection, two major late transcription unit mRNA transcripts are generated through use of the first (L1) of five available poly(A) sites (L1 through L5). This contrasts with the late stage of infection when as many as 45 distinct mRNAs are generated, with each of the five poly(A) sites being used. In previous work characterizing elements involved in alternative poly(A) site use, we showed that the L1 poly(A) site is processed less efficiently than the L3 poly(A) site both in vitro and in vivo. Because of the dramatic difference in processing efficiency and the role processing efficiency plays in production of steady-state levels of mRNA, we have identified the sequence elements that account for the differences in L1 and L3 poly(A) site processing efficiency. We have found that the element most likely to be responsible for poly(A) site strength, the GU/U-rich downstream element, plays a minor role in the different processing efficiencies observed for the L1 and L3 poly(A) sites. The sequence element most responsible for inefficient processing of the L1 poly(A) site includes the L1 AAUAAA consensus sequence and those sequences which immediately surround the consensus hexanucleotide. This region of the L1 poly(A) site contributes to an inability to form a stable processing complex with the downstream GU/U-rich element. In contrast to the L1 element, the L3 poly(A) site has a consensus hexanucleotide and surrounding sequences which can form a stable processing complex in cooperation with the downstream GU/U-rich element. The L3 poly(A) site is also aided by the presence of sequences upstream of the hexanucleotide which facilitate processing efficiency. The sequence UUCUUUUU, present in the L3 upstream region, is shown to enhance processing efficiency as well as stable complex formation (shown by increased binding of the 64-kDa cleavage stimulatory factor subunit) and acts as a binding site for heterogeneous nuclear ribonucleoprotein C proteins.

Sequence elements upstream of the 3' cleavage site confer substrate strength to the adenovirus L1 and L3 polyadenylation sites

The adenovirus major late transcription unit is a well-characterized transcription unit which relies heavily on alternative pre-mRNA processing to generate distinct populations of mRNA during the early and late stages of viral infection. In the early stage of infection, two major late transcription unit mRNA transcripts are generated through use of the first (L1) of five available poly(A) sites (L1 through L5). This contrasts with the late stage of infection when as many as 45 distinct mRNAs are generated, with each of the five poly(A) sites being used. In previous work characterizing elements involved in alternative poly(A) site use, we showed that the L1 poly(A) site is processed less efficiently than the L3 poly(A) site both in vitro and in vivo. Because of the dramatic difference in processing efficiency and the role processing efficiency plays in production of steady-state levels of mRNA, we have identified the sequence elements that account for the differences in L1 and L3 poly(A) site processing efficiency. We have found that the element most likely to be responsible for poly(A) site strength, the GU/U-rich downstream element, plays a minor role in the different processing efficiencies observed for the L1 and L3 poly(A) sites. The sequence element most responsible for inefficient processing of the L1 poly(A) site includes the L1 AAUAAA consensus sequence and those sequences which immediately surround the consensus hexanucleotide. This region of the L1 poly(A) site contributes to an inability to form a stable processing complex with the downstream GU/U-rich element. In contrast to the L1 element, the L3 poly(A) site has a consensus hexanucleotide and surrounding sequences which can form a stable processing complex in cooperation with the downstream GU/U-rich element. The L3 poly(A) site is also aided by the presence of sequences upstream of the hexanucleotide which facilitate processing efficiency. The sequence UUCUUUUU, present in the L3 upstream region, is shown to enhance processing efficiency as well as stable complex formation (shown by increased binding of the 64-kDa cleavage stimulatory factor subunit) and acts as a binding site for heterogeneous nuclear ribonucleoprotein C proteins.

GRSF-1: a poly(A)+ mRNA binding protein which interacts with a conserved G-rich element

Computer predictions identified similarities to a 14-base G-rich element in numerous mRNAs at a variety of locations. A Northwestern screening strategy was used to obtain a cDNA clone from a HeLa cell library using the G-rich RNA element as a probe. A cellular protein (called GRSF-1), which was encoded by this cDNA, binds RNAs containing the G-rich element. GRSF-1 was distinct from DSEF-1, a nuclear protein we have previously identified that interacts with the G-rich element, based on differences in molecular weight and partial peptide maps, as well as the lack of cross-reactivity with GRSF-1 specific monoclonal antibodies. Using indirect immunofluorescence microscopy, we localized GRSF-1 to the cytoplasm. In vivo UV cross-linking further demonstrated that GRSF-1 was bound to poly(A)+ mRNA in living human cells. Western blot analysis revealed four cytoplasmic proteins which expressed GRSF-1 specific epitopes. GRSF-1 contains three potential RNA recognition motifs and two auxiliary domains. Curiously, the domain organization of GRSF-1 is similar to the RNA binding proteins PUB1, ELAV, HuD, Hel-N1, mcs94-1 and RBP9.

Transcription termination and polyadenylation in retroviruses

The provirus structure of retroviruses is bracketed by long terminal repeats (LTRs). The two LTRs (5' and 3') are identical in nucleotide sequence and organization. They contain signals for transcription initiation as well as termination and cleavage polyadenylation. As in eukaryotic pre-mRNAs, the two common signals, the polyadenylation signal, AAUAAA, or a variant AGUAAA, and the G+U-rich sequence are present in all retroviruses. However, the AAUAAA sequence is present in the U3 region in some retroviruses and in the R region in other retroviruses. As in animal cell RNAs, both AAUAAA and G+U-rich sequences apparently contribute to the 3'-end processing of retroviral RNAs. In addition, at least in a few cases examined, the sequences in the U3 region determine the efficiency of 3'-end processing. In retroviruses in which the AAUAAA is localized in the R region, the poly(A) signal in the 3' LTR but not the 5' LTR must be selectively used for the production of genomic RNA. It appears that the short distance between the 5' cap site and polyadenylation signal in the 5' LTR precludes premature termination and polyadenylation. Since 5' and 3' LTRs are identical in sequence and structural organization yet function differently, it is speculated that flanking cellular DNA sequences, chromatin structure, and binding of transcription factors may be involved in the functional divergence of 5' and 3' LTRs of retroviruses.

Alternative poly(A) site utilization during adenovirus infection coincides with a decrease in the activity of a poly(A) site processing factor

The recognition and processing of a pre-mRNA to create a poly(A) addition site, a necessary step in mRNA biogenesis, can also be a regulatory event in instances in which the frequency of use of a poly(A) site varies. One such case is found during the course of an adenovirus infection. Five poly(A) sites are utilized within the major late transcription unit to produce more than 20 distinct mRNAs during the late phase of infection. The proximal half of the major late transcription unit is also expressed during the early phase of a viral infection. During this early phase of expression, the L1 poly(A) site is used three times more frequently than the L3 poly(A) site. In contrast, the L3 site is used three times more frequently than the L1 site during the late phase of infection. Recent experiments have suggested that the recognition of the poly(A) site GU-rich downstream element by the CF1 processing factor may be a rate-determining step in poly(A) site selection. We demonstrate that the interaction of CF1 with the L1 poly(A) site is less stable than the interaction of CF1 with the L3 poly(A) site. We also find that there is a substantial decrease in the level of CF1 activity when an adenovirus infection proceeds to the late phase. We suggest that this reduction in CF1 activity, coupled with the relative instability of the interaction with the L1 poly(A) site, contributes to the reduced use of the L1 poly(A) site during the late stage of an adenovirus infection.

Alternative poly(A) site utilization during adenovirus infection coincides with a decrease in the activity of a poly(A) site processing factor

The recognition and processing of a pre-mRNA to create a poly(A) addition site, a necessary step in mRNA biogenesis, can also be a regulatory event in instances in which the frequency of use of a poly(A) site varies. One such case is found during the course of an adenovirus infection. Five poly(A) sites are utilized within the major late transcription unit to produce more than 20 distinct mRNAs during the late phase of infection. The proximal half of the major late transcription unit is also expressed during the early phase of a viral infection. During this early phase of expression, the L1 poly(A) site is used three times more frequently than the L3 poly(A) site. In contrast, the L3 site is used three times more frequently than the L1 site during the late phase of infection. Recent experiments have suggested that the recognition of the poly(A) site GU-rich downstream element by the CF1 processing factor may be a rate-determining step in poly(A) site selection. We demonstrate that the interaction of CF1 with the L1 poly(A) site is less stable than the interaction of CF1 with the L3 poly(A) site. We also find that there is a substantial decrease in the level of CF1 activity when an adenovirus infection proceeds to the late phase. We suggest that this reduction in CF1 activity, coupled with the relative instability of the interaction with the L1 poly(A) site, contributes to the reduced use of the L1 poly(A) site during the late stage of an adenovirus infection.

The human 64-kDa polyadenylylation factor contains a ribonucleoprotein-type RNA binding domain and unusual auxiliary motifs

Cleavage stimulation factor is one of the multiple factors required for 3'-end cleavage of mammalian pre-mRNAs. We have shown previously that this factor is composed of three subunits with estimated molecular masses of 77, 64, and 50 kDa and that the 64-kDa subunit can be UV-crosslinked to RNA in a polyadenylylation signal (AAUAAA)-dependent manner. We have now isolated cDNAs encoding the 64-kDa subunit of human cleavage stimulation factor. The 64-kDa subunit contains a ribonucleoprotein-type RNA binding domain in the N-terminal region and a repeat structure in the C-terminal region in which a pentapeptide sequence (consensus MEARA/G) is repeated 12 times and the formation of a long alpha-helix stabilized by salt bridges is predicted. An approximately 270-amino acid segment surrounding this repeat structure is highly enriched in proline and glycine residues (approximately 20% for each). When cloned 64-kDa subunit was expressed in Escherichia coli, an N-terminal fragment containing the RNA binding domain bound to RNAs in a polyadenylylation-signal-independent manner, suggesting that the RNA binding domain is directly involved in the binding of the 64-kDa subunit to pre-mRNAs.

Sequences regulating temporal poly(A) site switching in the adenovirus major late transcription unit

Temporal regulation of poly(A) site choice occurs in an adenovirus recombinant encoding a miniature version of the major late transcription unit with two poly(A) sites, L1 and L3. Using deletion mutagenesis, we have looked directly for cis-acting elements regulating poly(A) site choice in this recombinant. From this work, we draw two main conclusions. First, elements other than the AAUAAA and downstream sequences of the L1 poly(A) site are required for temporal regulation of poly(A) site choice during infection. Second, these regions function in two distinct modes during infection. The two regions enhance selection of the L1 poly(A) site in an additive manner during an early infection, but deletion of either element abolishes the switch in poly(A) site choice during a late infection. This work documents the first example of a regulatory element downstream of a core poly(A) region.

Regulation of polyadenylation in hepatitis B viruses: stimulation by the upstream activating signal PS1 is orientation-dependent, distance-independent, and additive

Hepatitis B viruses replicate by reverse transcription of a genomic RNA which harbors terminal redundancies. The synthesis of this RNA requires that transcription proceed twice through the polyadenylation (pA) site which, in mammalian strains, is flanked by the variant hexanucleotide UAUAAA and a T-rich downstream domain. These core elements are by themselves virtually defective in 3' end processing and require multiple upstream accessory elements which regulate pA site use. In ground squirrel hepatitis B virus (GSHV), one of these signals (PS1; -215 to -107 relative to UAUAAA) is transcribed only at the 3' end of genomic RNA and as such is analogous to retroviral U3 sequences. PS1 cooperates with other signals to enhance pA site use to very high levels and can be further sub-divided into two regions (A and B) which contribute equally to 3' end processing. Critical residues within PS1B have been localized to a 15 bp A/T-rich stretch which displays homology to other known upstream activating signals. A 15 bp segment within PS1A which has the identical A/T content but a divergent primary sequence plays a diminished role in processing. Furthermore, PS1 can activate GSHV core element usage autonomously. This stimulation has been shown to be additive since multiple copies of PS1 progressively increase polyadenylation, a phenomenon which also demands that PS1 exert its influence from a variety of distances from the hexanucleotide signal.

Sequences regulating temporal poly(A) site switching in the adenovirus major late transcription unit

Temporal regulation of poly(A) site choice occurs in an adenovirus recombinant encoding a miniature version of the major late transcription unit with two poly(A) sites, L1 and L3. Using deletion mutagenesis, we have looked directly for cis-acting elements regulating poly(A) site choice in this recombinant. From this work, we draw two main conclusions. First, elements other than the AAUAAA and downstream sequences of the L1 poly(A) site are required for temporal regulation of poly(A) site choice during infection. Second, these regions function in two distinct modes during infection. The two regions enhance selection of the L1 poly(A) site in an additive manner during an early infection, but deletion of either element abolishes the switch in poly(A) site choice during a late infection. This work documents the first example of a regulatory element downstream of a core poly(A) region.

Molecular analyses of two poly(A) site-processing factors that determine the recognition and efficiency of cleavage of the pre-mRNA

Poly(A) site processing of a pre-mRNA requires the participation of multiple nuclear factors. Two of these factors recognize specific sequences in the pre-mRNA and form a stable processing complex. Since these initial interactions are likely critical for the recognition of the poly(A) site and the efficiency of poly(A) site use, we have characterized these factors and the nature of their interaction with the pre-mRNA. The AAUAAA specificity factor PF2 is a large, multicomponent complex composed of at least five distinct polypeptides ranging in molecular size from 170 to 42 kDa. The 170-kDa polypeptide appears to mediate interaction with the pre-mRNA. Factor CF1, which provides specificity for the downstream G + U-rich element and stabilizes the PF2 interaction on the RNA, is also a multicomponent complex but is less complex than PF2. CF1 is composed of three polypeptides of molecular sizes 76, 64, and 48 kDa. UV cross-linking assays demonstrate that the 64-kDa polypeptide makes direct contact with the RNA, dependent on the G + U-rich downstream sequence element. Moreover, it is clear that these RNA-protein interactions are influenced by the apparent cooperative interaction involving PF2 and CF1, interactions that contribute to the efficiency of poly(A) site processing.

Molecular analyses of two poly(A) site-processing factors that determine the recognition and efficiency of cleavage of the pre-mRNA

Poly(A) site processing of a pre-mRNA requires the participation of multiple nuclear factors. Two of these factors recognize specific sequences in the pre-mRNA and form a stable processing complex. Since these initial interactions are likely critical for the recognition of the poly(A) site and the efficiency of poly(A) site use, we have characterized these factors and the nature of their interaction with the pre-mRNA. The AAUAAA specificity factor PF2 is a large, multicomponent complex composed of at least five distinct polypeptides ranging in molecular size from 170 to 42 kDa. The 170-kDa polypeptide appears to mediate interaction with the pre-mRNA. Factor CF1, which provides specificity for the downstream G + U-rich element and stabilizes the PF2 interaction on the RNA, is also a multicomponent complex but is less complex than PF2. CF1 is composed of three polypeptides of molecular sizes 76, 64, and 48 kDa. UV cross-linking assays demonstrate that the 64-kDa polypeptide makes direct contact with the RNA, dependent on the G + U-rich downstream sequence element. Moreover, it is clear that these RNA-protein interactions are influenced by the apparent cooperative interaction involving PF2 and CF1, interactions that contribute to the efficiency of poly(A) site processing.

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.

A uridylate tract mediates efficient heterogeneous nuclear ribonucleoprotein C protein-RNA cross-linking and functionally substitutes for the downstream element of the polyadenylation signal

Every RNA added to an in vitro polyadenylation extract became stably associated with both the heterogeneous nuclear ribonucleoprotein (hnRNP) A and C proteins, as assayed by immunoprecipitation analysis using specific monoclonal antibodies. UV-cross-linking analysis, however, which assays the specific spatial relationship of certain amino acids and RNA bases, indicated that the hnRNP C proteins, but not the A proteins, were associated with downstream sequences of the simian virus 40 late polyadenylation signal in a sequence-mediated manner. A tract of five consecutive uridylate residues was required for this interaction. The insertion of a five-base U tract into a pGEM4 polylinker-derived transcript was sufficient to direct sequence-specific cross-linking of the C proteins to RNA. Finally, the five-base uridylate tract restored efficient in vitro processing to several independent poly(A) signals in which it substituted for downstream element sequences. The role of the downstream element in polyadenylation efficiency, therefore, may be mediated by sequence-directed alignment or phasing of an hnRNP complex.

A uridylate tract mediates efficient heterogeneous nuclear ribonucleoprotein C protein-RNA cross-linking and functionally substitutes for the downstream element of the polyadenylation signal

Every RNA added to an in vitro polyadenylation extract became stably associated with both the heterogeneous nuclear ribonucleoprotein (hnRNP) A and C proteins, as assayed by immunoprecipitation analysis using specific monoclonal antibodies. UV-cross-linking analysis, however, which assays the specific spatial relationship of certain amino acids and RNA bases, indicated that the hnRNP C proteins, but not the A proteins, were associated with downstream sequences of the simian virus 40 late polyadenylation signal in a sequence-mediated manner. A tract of five consecutive uridylate residues was required for this interaction. The insertion of a five-base U tract into a pGEM4 polylinker-derived transcript was sufficient to direct sequence-specific cross-linking of the C proteins to RNA. Finally, the five-base uridylate tract restored efficient in vitro processing to several independent poly(A) signals in which it substituted for downstream element sequences. The role of the downstream element in polyadenylation efficiency, therefore, may be mediated by sequence-directed alignment or phasing of an hnRNP complex.