Functionally significant secondary structure of the simian virus 40 late polyadenylation signal

The structure of the highly efficient simian virus 40 late polyadenylation signal (LPA signal) is more complex than those of most known mammalian polyadenylation signals. It contains efficiency elements both upstream and downstream of the AAUAAA region, and the downstream region contains three defined elements (two U-rich elements and one G-rich element) instead of the single U- or GU-rich element found in most polyadenylation signals. Since many reports have indicated that the secondary structure in RNA may play a significant role in RNA processing, we have used nuclease structure analysis techniques to determine the secondary structure of the LPA signal. We find that the LPA signal has a functionally significant secondary structure. Much of the region upstream of AAUAAA is sensitive to single-strand-specific nucleases. The region downstream of AAUAAA has both double- and single-stranded characteristics. Both U-rich elements are predominately sensitive to the double-strand-specific nuclease RNase V(1), while the G-rich element is primarily single stranded. The U-rich element closest to AAUAAA contains four distinct RNase V(1)-sensitive regions, which we have designated structural region 1 (SR1), SR2, SR3, and SR4. Linker scanning mutants in the downstream region were analyzed both for structure and for function by in vitro cleavage analyses. These data show that the ability of the downstream region, particularly SR3, to form double-stranded structures correlates with efficient in vitro cleavage. We discuss the possibility that secondary structure downstream of the AAUAAA may be important for the functions of polyadenylation signals in general.     

Sequence and position requirements for uridylate-rich downstream elements of polyadenylation signals.

We have defined the positional and sequence requirements of U-rich downstream elements using a simian virus 40 late polyadenylation signal containing a substituted downstream region. A UUUUU element will significantly increase the efficiency of 3' end processing when placed between 6 and 25 bases downstream from the cleavage site. Positions in this interval closer than 15 bases from the cleavage site, however, were noticeably less efficient. Placement of the UUUUU element between +20 and +25 caused a partial shift in cleavage site usage to a CA motif at +4. Mutational analysis indicated that the sequence requirements at individual positions of the UUUUU element were somewhat flexible. Changing more than one base of the UUUUU sequence, however, severely diminished the ability of the element to mediate efficient 3' end processing. Finally, although hnRNP C proteins specifically interact with U-rich sequences, this protein--RNA interaction is not required for efficient in vitro polyadenylation.     

Spatial constraints on polyadenylation signal function

Efficient cleavage and polyadenylation of eukaryotic messenger RNAs require at least two signal elements: an AAUAAA or closely related sequence located 7-30 base pairs (bp) upstream of the site of processing, and a G/U- or U-rich sequence located 3' to the cleavage site. The herpes simplex virus type 1 thymidine kinase (tk) gene contains two copies of the AATAAA hexanucleotide and a GT-rich region. We have shown that the first AATAAA and the GT-rich region are essential for efficient processing, both in vivo and in vitro, whereas the second AATAAA does not appear to play any role in the formation of tk mRNA 3' ends. The failure of a signal containing only the second AATAAA and the GT-rich element to signal cleavage and polyadenylation suggested that these two elements might be too close together to constitute a functional polyadenylation signal. The experiments described in this report were directed at determining the effects on mRNA 3' end formation of alterations in spacing between signal elements. Wild-type tk contains 19 bp between these two elements. Constructs were made in which an AATAAA and the GT-rich region were separated by various distances ranging from 7 to 43 bp. The quantity and location of 3' ends of the tk mRNA produced by these constructs in Cos-1 cells were measured by S1 nuclease protection analysis. Signal efficiency was gradually reduced as the separation between the two signal elements was increased; with a separation of 43 bp, the signal functioned at approximately one-eighth the efficiency of the parental construction. Bringing the two signals closer together resulted in decreased signal efficiency; with a separation of 7 or 9 bp, no tk mRNA polyadenylated within the normal region was produced. Altering the sequences between these two elements without changing the distance had small effects on processing efficiency.     

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.     

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.     

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.     

Translational control by cytoplasmic polyadenylation during Xenopus oocyte maturation: characterization of cis and trans elements and regulation by cyclin/MPF.

The expression of certain maternal mRNAs during oocyte maturation is regulated by cytoplasmic polyadenylation. To understand this process, we have focused on a maternal mRNA from Xenopus termed G10. This mRNA is stored in the cytoplasm of stage 6 oocytes until maturation when the process of poly(A) elongation stimulates its translation. Deletion analysis of the 3' untranslated region of G10 RNA has revealed that two sequence elements, UUUUUUAU and AAUAAA were both necessary and sufficient for polyadenylation and polysomal recruitment. In this communication, we have defined the U-rich region that is optimal for polyadenylation as UUUUUUAUAAAG, henceforth referred to as the cytoplasmic polyadenylation element (CPE). We have also identified unique sequence requirements in the 3' terminus of the RNA that can modulate polyadenylation even in the presence of wild-type cis elements. A time course of cytoplasmic polyadenylation in vivo shows that it is an early event of maturation and that it requires protein synthesis within the first 15 min of exposure to progesterone. MPF and cyclin can both induce polyadenylation but, at least with respect to MPF, cannot obviate the requirement for protein synthesis. To identify factors that may be responsible for maturation-specific polyadenylation, we employed extracts from oocytes and unfertilized eggs, the latter of which correctly polyadenylates exogenously added RNA. UV crosslinking demonstrated that an 82 kd protein binds to the U-rich CPE in egg, but not oocyte, extracts. The data suggest that progesterone, either in addition to or through MPF/cyclin, induces the synthesis of a factor during very early maturation that stimulates polyadenylation.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.