Elements upstream of the AAUAAA within the human immunodeficiency virus polyadenylation signal are required for efficient polyadenylation in vitro.

Recent in vivo studies have identified specific sequences between 56 and 93 nucleotides upstream of a polyadenylation [poly(A)] consensus sequence, AAUAAA, in human immunodeficiency virus type 1 (HIV-1) that affect the efficiency of 3'-end processing at this site (A. Valsamakis, S. Zeichner, S. Carswell, and J. C. Alwine, Proc. Natl. Acad. Sci. USA 88:2108-2112, 1991). We have used HeLa cell nuclear extracts and precursor RNAs bearing the HIV-1 poly(A) signal to study the role of upstream sequences in vitro. Precursor RNAs containing the HIV-1 AAUAAA and necessary upstream (U3 region) and downstream (U5 region) sequences directed accurate cleavage and polyadenylation in vitro. The in vitro requirement for upstream sequences was demonstrated by using deletion and linker substitution mutations. The data showed that sequences between 56 and 93 nucleotides upstream of AAUAAA, which were required for efficient polyadenylation in vivo, were also required for efficient cleavage and polyadenylation in vitro. This is the first demonstration of the function of upstream sequences in vitro. Previous in vivo studies suggested that efficient polyadenylation at the HIV-1 poly(A) signal requires a spacing of at least 250 nucleotides between the 5' cap site and the AAUAAA. Our in vitro analyses indicated that a precursor containing the defined upstream and downstream sequences was efficiently cleaved at the polyadenylation site when the distance between the 5' cap and the AAUAAA was reduced to at least 140 nucleotides, which is less than the distance predicted from in vivo studies. This cleavage was dependent on the presence of the upstream element.     

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.     

Upstream sequences and cap proximity in the regulation of polyadenylation in ground squirrel hepatitis virus.

The polyadenylation signal of mammalian hepadnaviruses is unusual in that its hexanucleotide element is the variant UAUAAA rather than AAUAAA. This signal functions inefficiently and must be augmented by multiple activator elements located in the upstream 400 nucleotides (nt) to promote efficient processing. Here we characterize one of these upstream elements, termed PS2, in the ground squirrel hepatitis virus. PS2 is located within the 107 nt 5' to the UAUAAA and raises the efficiency of polyadenylation by this signal from < 10% to 50 to 60%. It can function independently of the more 5' activator elements and conversely is not required for their function. Its action is orientation dependent, and a predicted stem-loop structure within the element is not necessary for its activity. PS2 is the sole upstream element that maps within the terminal redundancy of viral genomic RNA. Thus, it is present, together with the UAUAAA, at both the 5' and 3' ends of this RNA. During genomic RNA synthesis, the poly(A) signals in the 5' repeat are bypassed, while those in the 3' copy are used. The ability of PS2 to function independently of the other, more upstream activators suggests that the absence of the latter elements from the 5' redundancy is insufficient to account for bypass of the 5' poly(A) site, as we had earlier proposed. Rather, the short distance from the cap site to the UAUAAA at the 5' end of genomic RNA actively suppresses its use, as this suppression can be experimentally relieved by increasing this distance to 230 to 400 nt.     

3' nontranslated RNA signals required for replication of hepatitis C virus RNA

We describe a mutational analysis of the 3' nontranslated RNA (3'NTR) signals required for replication of subgenomic hepatitis C virus (HCV) RNAs. A series of deletion mutants was constructed within the background of an HCV-N replicon that induces the expression of secreted alkaline phosphatase in order to examine the requirements for each of the three domains comprising the 3'NTR, namely, the highly conserved 3' terminal 98-nucleotide (nt) segment (3'X), an upstream poly(U)-poly(UC) [poly(U/UC)] tract, and the variable region (VR) located at the 5' end of the 3'NTR. Each of these domains was found to contribute to efficient replication of the viral RNA in transiently transfected hepatoma cells. Replication was not detected when any of the three putative stem-loop structures within the 3'X region were deleted. Similarly, complete deletion of the poly(U/UC) tract abolished replication. Replacement of a minimum of 50 to 62 nt of poly(U/UC) sequence was required for detectable RNA replication when the native sequence was restored in a stepwise fashion from its 3' end. Lengthier poly(U/UC) sequences, and possibly pure homopolymeric poly(U) tracts, were associated with more efficient RNA amplification. Finally, while multiple deletion mutations were tolerated within VR, each led to a partial loss of replication capacity. The impaired replication capacity of the deletion mutants could not be explained by reduced translational activity or by decreased stability of the RNA, suggesting that each of these mutations may impair recognition of the RNA by the viral replicase during an early step in negative-strand RNA synthesis. The results indicate that the 3'-most 150 nt of the HCV-N genome [the 3'X region and the 3' 52 nt of the poly(U/UC) tract] contain RNA signals that are essential for replication, while the remainder of the 3'NTR plays a facilitating role in replication but is not absolutely required.     

The Retroviruses Human Immunodeficiency Virus Type 1 and Moloney Murine Leukemia Virus Adopt Radically Different Strategies To Regulate Promoter-Proximal Polyadenylation

Maximal gene expression in retroviruses requires that polyadenylation in the 5' long terminal repeat (LTR) is suppressed. In human immunodeficiency virus type 1 (HIV-1) the promoter-proximal poly(A) site is blocked by interaction of U1 snRNP with the closely positioned major splice donor site (MSD) 200 nucleotides downstream. Here we investigated whether the same mechanism applies to down-regulate 5' LTR polyadenylation in Moloney murine leukemia virus (MoMLV). Although the same molecular architecture is present in both viruses, the MoMLV poly(A) signal in the 5' LTR is active whether or not the MSD is mutated. This surprising difference between the two retroviruses is not due to their actual poly(A) signals or MSD sequences, since exchange of either element between the two viral sequences does not alter their ability to regulate 5' LTR poly(A) site use. Instead we demonstrate that sequence between the cap and AAUAAA is required for MSD-dependent poly(A) regulation in HIV-1, indicating a key role for this part of the LTR in poly(A) site suppression. We also show that the MoMLV poly(A) signal is an intrinsically weak RNA-processing signal. This suggests that in the absence of a poly(A) site suppression mechanism, MoMLV is forced to use a weak poly(A) signal.     

Hierarchy of polyadenylation site usage by bovine papillomavirus in transformed mouse cells.

The great majority of viral mRNAs in mouse C127 cells transformed by bovine papillomavirus type 1 (BPV) have a common 3' end at the early polyadenylation site which is 23 nucleotides (nt) downstream of a canonical poly(A) consensus signal. Twenty percent of BPV mRNA from productively infected cells bypasses the early polyadenylation site and uses the late polyadenylation site approximately 3,000 nt downstream. To inactivate the BPV early polyadenylation site, the early poly(A) consensus signal was mutated from AAUAAA to UGUAAA. Surprisingly, this mutation did not result in significant read-through expression of downstream RNA. Rather, RNA mapping and cDNA cloning experiments demonstrate that virtually all of the mutant RNA is cleaved and polyadenylated at heterogeneous sites approximately 100 nt upstream of the wild-type early polyadenylation site. In addition, cells transformed by wild-type BPV harbor a small population of mRNAs with 3' ends located in this upstream region. These experiments demonstrate that inactivation of the major poly(A) signal induces preferential use of otherwise very minor upstream poly(A) sites. Mutational analysis suggests that polyadenylation at the minor sites is controlled, at least in part, by UAUAUA, an unusual variant of the poly(A) consensus signal approximately 25 nt upstream of the minor polyadenylation sites. These experiments indicate that inactivation of the major early polyadenylation signal is not sufficient to induce expression of the BPV late genes in transformed mouse cells.     

Mapping of branch sites in trans-spliced pre-mRNAs of Trypanosoma brucei.

The process of trans splicing is essential to the maturation of all mRNAs in the Trypanosomatidae, a family of protozoan parasites, and to specific mRNAs in several species of nematode. In Trypanosoma brucei, a 39-nucleotide (nt) leader sequence originating from a small, 139-nt donor RNA (the spliced leader [SL] RNA) is spliced to the 5' end of mRNAs. An intermediate in this trans-splicing process is a Y structure which contains the 3' 100 nt of the SL RNA covalently linked to the pre-mRNA via a 2'-5' phosphodiester bond at the branch point residue. We mapped the branch points in T. brucei alpha- and beta-tubulin pre-mRNAs. The primary branch acceptors for the alpha- and beta-tubulins are 44 and 56 nt upstream of the 3' splice sites, respectively, and are A residues. Minor branch acceptors were detected 42 and 49 nt upstream of the alpha-tubulin splice site and 58 nt upstream of the splice site in beta-tubulin. The regions surrounding these branch points lack homology to the consensus sequences determined for mammalian cells and yeasts; there is also no conservation among the sequences themselves. Thus, the identified sequences suggest that the mechanism of branch point recognition in T. brucei differs from the mechanism of recognition by U2 RNA that has been proposed for other eucaryotes.     

RNA structure and packaging signals in the 5' leader region of the human immunodeficiency virus type 1 genome

The leader region of the human immunodeficiency virus type 1 (HIV-1) genome has a highly folded structure, comprising at least two RNA stem-loops [the transactivation response (TAR) and poly(A) hairpins] near its 5' end and four others (SL1 to SL4) downstream. Each of these stem-loops contributes to the function of the HIV-1 packaging signal, which efficiently targets genomic RNA into nascent virions. The central 140-base region of the leader, which includes the U5 and primer binding site (PBS) sequences, is also believed to adopt a complex structure, but the nature of this structure and its possible role in RNA packaging have not been extensively explored. Here we report a mutational analysis identifying at least three separate loci within the U5-PBS region which, when mutated, impair both HIV-1 packaging specificity and infectivity in a single-round proviral assay. In common with those of all previously described packaging signals in the leader, the function of one of these loci appeared to depend on secondary structure rather than on sequence alone. By contrast, the activity of the other two loci did not correlate with any predicted conformations. Moreover, unlike SL1 to SL4, the TAR, poly(A), and U5-PBS hairpins were not bound with high affinity by the nucleocapsid portion of the HIV-1 Gag protein in vitro, implying that they contribute to packaging through a mechanism distinct from that of SL1 to SL4. Our findings confirm the existence and importance of secondary structure around the PBS and demonstrate that functional packaging signals are distributed across the entire HIV-1 leader.     

An RNA secondary structure juxtaposes two remote genetic signals for human T-cell leukemia virus type I RNA 3'-end processing.

Sequence analysis of the human T-cell leukemia virus type I (HTLV-I) long terminal repeat (LTR) does not reveal a polyadenylation consensus sequence, AAUAAA, close to the polyadenylation site at the 3' end of the viral RNA. Using site-directed mutagenesis, we demonstrated that two cis-acting signals are required for efficient RNA processing in HTLV-I LTR: (i) a remote AAUAAA hexamer at a distance of 276 nucleotides upstream of the polyadenylation site, and (ii) the 20-nucleotide GU-rich sequence immediately downstream from the poly(A) site. It has been postulated that the folding of RNA into a secondary structure juxtaposes the AAUAAA sequence, in a noncontiguous manner, to within 14 nucleotides of the polyadenylation site. To test this hypothesis, we introduced deletions and point mutations within the U3 and R regions of the LTR. RNA 3'-end processing occurred efficiently at the authentic HTLV-I poly(A) site after deletion of the sequences predicted to form the secondary structure. Thus, the genetic analysis supports the hypothesis that folding of the HTLV-I RNA in the U3 and R regions juxtaposes the AAUAAA sequence and the poly(A) site to the correct functional distance. This unique arrangement of RNA-processing signals is also found in the related retroviruses HTLV-II and bovine leukemia virus.