![[Feedback]](/icons/banner/feedbackACT.gif)
![[For Subscribers]](/icons/banner/subscriberACT.gif)
![[Archive]](/icons/banner/archiveACT.gif)
![[Search]](/icons/banner/searchACT.gif)
![[Contents]](/icons/banner/tocACT.gif)
Previous Article | Next Article 
Molecular and Cellular Biology, April 2000, p. 2926-2932, Vol. 20, No. 8
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Functionally Significant Secondary Structure of the
Simian Virus 40 Late Polyadenylation Signal
Holly
Hans and
James C.
Alwine*
Department of Microbiology, Microbiology and
Virology Graduate Program, School of Medicine, University of
Pennsylvania, Philadelphia, Pennsylvania 19104-6142
Received 29 October 1999/Returned for modification 24 November
1999/Accepted 10 January 2000
 |
ABSTRACT |
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 V1, while the
G-rich element is primarily single stranded. The U-rich element closest
to AAUAAA contains four distinct RNase
V1-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.
| |
INTRODUCTION |
Polyadenylation is the process by
which the 3' ends of most mammalian mRNAs are formed. In a tightly
coupled set of reactions the precursor RNA is endonucleolytically
cleaved at a specific site. Next, approximately 250 adenosine residues
are polymerized to the cleaved end, forming the poly(A) tail of the
final mRNA. It has been clearly established that a poly(A) tail is
essential for the survival, transport, stability, and translation of
most mRNAs (reviewed in references 8, 32, and
42 to 44).
The elements of the polyadenylation signal in the precursor RNA define
the site of polyadenylation through specific binding with a
complex of proteins which orchestrate cleavage and polyadenylation. The
central, nearly invariant, element of mammalian polyadenylation signals
is the AAUAAA sequence, which is the binding site for the cleavage and polyadenylation specificity factor (CPSF)
(19). AAUAAA is located 11 to 25 nucleotides
upstream of the actual cleavage and polyadenylation site. In addition,
it is now well established that sequence elements located 14 to 70 nucleotides downstream of AAUAAA greatly increase the
efficiency of utilization of the polyadenylation signal (4, 9, 14,
15, 23, 24, 25, 31, 33, 34, 45, 46, 49). Comparison of the
downstream elements (DSEs) of many polyadenylation signals has not
provided a clear consensus sequence other than various lengths (6 to 20 nucleotides) of GU- or U-rich sequences. However, the position of the
DSE relative to the AAUAAA sequence appears to be important, since the DSE is the binding site for the cleavage-stimulatory factor
(CStF) (38), which interacts with CPSF bound at AAUAAA to form a stable polyadenylation complex. Interestingly, the site of polyadenylation and DSE of the human T-cell leukemia virus type 1 polyadenylation signal, which is relatively efficient, are located more
than 200 nucleotides downstream of AAUAAA. However, a large
stem-loop secondary structure brings the DSE into an optimal position
(i.e., 14 to 70 nucleotides away) relative to AAUAAA (1, 3A).
Many mammalian polyadenylation signals appear to conform to the simple
structure of an AAUAAA and a GU- or U-rich DSE. However, a
growing number of polyadenylation signals have been shown to contain
additional efficiency elements located upstream of AAUAAA. These upstream elements (USEs) were originally studied in viral polyadenylation signals, such as the polyadenylation signals of the
simian virus 40 (SV40) late genes (7, 36), human
immunodeficiency virus (HIV) (6, 13, 40, 41), the adenovirus
major late region (12), cauliflower mosaic virus
(35), and ground squirrel hepatitis virus (29,
30). More recently, USEs have been found in some cellular genes
as well (5, 27). Our studies of the SV40 late
polyadenylation signal (LPA signal) suggest that the USEs impart
characteristics which provide efficiency, or special levels of control,
to the polyadenylation signal. For example, mutation of the LPA signal
USEs reduces polyadenylation efficiency by 75 to 85% both in vivo and
in vitro (7, 36).
Few generalizations can be made about USEs. Among the USEs which have
been studied, no definitive characteristics have been noted. However,
functional upstream motifs in the LPA signal and the HIV
polyadenylation signal have been characterized (36, 40, 41).
In HIV these motifs appear to be involved in the formation of a
secondary structure which aids CPSF recruitment to the HIV type 1 polyadenylation signal (16).
The LPA signal is a very efficient polyadenylation signal which
contains a more complex structure than most. As shown in Fig. 1, it contains both USEs and DSEs. In
addition, the downstream region is more unusual in that it contains
three defined elements, two U-rich elements (DSE-U and DSE-U') (Fig. 1)
(9, 33, 34) and a G-rich region (DSE-G) (Fig. 1) (3,
28) in between. The DSE closest to AAUAAA (DSE-U)
contains the site for CStF binding. The G-rich region has been shown to
interact with a protein of the hnRNP H family, which increases
polyadenylation efficiency (2, 3, 28). The other downstream
U-rich DSE (DSE-U') can bind hnRNP C proteins (45, 46) and
functions as a DSE under certain conditions. Specifically, in an in
vitro polyadenylation reaction with a substrate representing the entire
LPA signal, deletion or mutation of DSE-U' had little effect on
polyadenylation efficiency (our unpublished observations). However, if
the LPA signal is combined with a splicing cassette, such that a
coupled splicing and polyadenylation substrate is formed, mutation of DSE-U' causes diminished polyadenylation and splicing, suggesting that
the element may function under conditions of coupled polyadenylation and splicing (10).
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 1.
SV40 LPA signal. (A) Features of the SV40 LPA signal.
AAUAAA and the cleavage site (An) are shown along with the
three USEs (USE1 to -3; blue boxes) and the three DSEs (DSE-U [orange
box], a predominantly U-rich element just downstream of the cleavage
site; DSE-G [green box], a G-rich region downstream of DSE-U; and
DSE-U' [purple box], a second U-rich element further downstream). The
numbering above the diagram indicates the SV40 nucleotide numbering.
(B) Summary of nuclease structure analyses of the LPA signal. Regions
sensitive to the double-strand-specific RNase V1 are
indicated in red, and regions sensitive to the single-strand-specific
RNase T1 or PhyM are indicated in blue. The white box and
asterisks indicate regions which appeared to be inaccessible to the
nucleases in the structural analyses (see the text). Note that the
diagram does not continue as far upstream as does the structural
analysis shown in Fig. 2. (C) Sequence of the region downstream of the
cleavage site. The approximate regions of the three DSEs are shown;
DSE-U is in orange letters, DSE-G is in green italic letters, and
DSE-U' is in purple letters. Regions of the double-stranded structures
SR1 to SR4 identified in this study are shown as black bars. The
locations of the various linker substitution mutations used in these
studies are indicated (see the text).
|
|
The USEs of the LPA signal consist of three regions with sequences
similar to the sequence AUUUGURA (36). We have
previously shown that the U1A protein interacts with the LPA signal and
that the USEs are necessary for efficient U1A binding (21).
Our data suggest that the interaction of U1A protein may facilitate
polyadenylation complex formation or be involved in the coupling of
polyadenylation and splicing (22).
The existence of secondary structures in human T-cell leukemia virus
type 1 (1, 3A) and HIV polyadenylation signals (11,
16) has been mentioned above. In addition, secondary structures
have been suggested to be significant in the functions of several other
polyadenylation signals, including those of the equine infectious
anemia virus (18), the bovine growth hormone gene
(17), the adenovirus L4 gene (37), the human CD59
gene (39), and the murine immunoglobulin M secretory gene
(27a). Given these findings and the complexity of the LPA
signal, we have used nuclease structure analysis techniques to analyze
the secondary structure in the LPA signal. We find that the LPA signal forms a functionally significant secondary structure. Much of the
region upstream of AAUAAA is sensitive to
single-strand-specific nucleases. The downstream region has both
double- and single-stranded characteristics. Both U-rich DSEs are
predominately sensitive to the double-strand-specific nuclease RNase
V1, while the G-rich element is primarily single stranded.
We find that the U-rich element closest to AAUAAA contains
four distinct RNase V1-sensitive regions. Mutational
analyses indicate that the ability to form downstream double-stranded
regions correlates with efficient in vitro cleavage. We discuss the
possibility that a secondary structure downstream of AAUAAA
may be important for the function of polyadenylation signals in general.
| |
MATERIALS AND METHODS |
Plasmids and substrate RNAs.
Substrate RNAs containing the
LPA signal were produced by in vitro transcription using T7 RNA
polymerase and the plasmid templates described below. RNAs were
synthesized either unlabeled or labeled internally with
[32P]UTP. Unlabeled RNAs were transcribed either with
(for 3'-end labeling) or without (for 5'-end labeling) a 5' cap
structure. RNAs were then dephosphorylated using calf intestinal
alkaline phosphatase. After calf intestinal alkaline phosphatase
inactivation, the RNAs were extracted with phenol-chloroform and
precipitated with ethanol. 5'-end labeling was performed using
[
-32P]ATP and polynucleotide kinase, while 3'-end
labeling was accomplished using 32P-pCp and T4 RNA ligase
(20). All RNAs were gel isolated by separating the
full-length RNAs from smaller transcripts on 5% polyacrylamide-8 M
urea gels. The full-length transcripts were eluted from gel slices by
overnight incubation in 20 mM Tris HCl (pH 7.5)-400 mM NaCl-0.1%
sodium dodecyl sulfate (SDS). The eluted RNAs were phenol extracted and
ethanol precipitated.
The plasmid templates for the substrate RNAs included the following.
(i) pUPAS (7, 36) encodes the wild-type LPA signal between
nucleotides 2533 and 2770 inserted into the polylinker of pGEM2. All of
the plasmids used for in vitro transcription were linearized at a
DraI site at the end of the downstream region of the LPA
signal (SV40 nucleotide 2731). (ii) pPAS (7, 36) is similar
to pUPAS except that an XbaI linker has been inserted 5' of
AAUAAA and an XhoII linker has been inserted 3'
of AAUAAA. These sites were used along with the restriction
sites found in the polylinker to create the following constructions:
pUM123, which was constructed by inserting linkers to substitute for
the sequences containing the three USEs (36), and pdlUSEs,
which lacks the sequence upstream of AAUAAA and was created
by removing the XbaI-to-XbaI fragment from pPAS
and inserting it into the pGEM2 vector.
A set of linker substitution mutants with mutations through the
downstream region, mutants DM2 to DM4 (10) and mutants aD2, bD2, and abD2, was constructed with pUPAS by using previously described
PCR-based linker scanning mutagenesis techniques (36, 47,
48). The positions of their mutations are shown in Fig. 1C. The
wild-type nucleotides were replaced with the following sequences:
5'...CGCGGGAGGTACC...3' (DM2), 5...GGTACC...3'
(DM3), 5'...ATAGGTACC...3' (DM4),
5'...GGTACC...3' (aD2), 5'...GGTACC...3' (bD2),
and a construction that combines the aD2 and bD2 mutations (abD2). In
all cases, the wild-type sequences were exactly replaced with either a
KpnI linker or a KpnI linker plus additional sequences.
In vitro polyadenylation cleavage assays.
Substrate RNAs
were synthesized by in vitro transcription and internally labeled with
[32P]UTP as described above. Labeled RNAs
(105 cpm) were incubated in a final volume of 25 µl
containing 64 µg of HeLa nuclear extract (26), 250 µM
ATP, 1 mM cordycepin, 250 mM phosphocreatine, and 6.5 µl of 10%
polyvinyl alcohol. The cleavage reaction mixtures were incubated at
30°C for 30 min. Reactions were stopped by the addition of a
high-concentration salt-SDS buffer (20 mM Tris HCl [pH 7.5], 400 mM
NaCl, 0.1% SDS), and RNAs were purified by phenol-chloroform
extraction and then ethanol precipitation. RNA products were
fractionated on a 5% acrylamide-8 M urea gel and visualized by
autoradiography. Products were quantitated using a Molecular Dynamics
Storm PhosphorImager.
RNA sequencing and structure analysis.
RNAs, either 3' or 5'
end labeled, were analyzed by both sequencing and structure-probing
reactions which were modified from previously established procedures
(20). Prior to all reactions, the RNAs were thawed slowly
and then incubated at 37°C for 15 min.
RNAs were sequenced by incubating 104 cpm of RNA in RNA
sequencing buffer (7 M urea, 0.025% xylene cyanol, 0.025% bromphenol blue, 20 mM sodium citrate [pH 5], 1 mM EDTA) in the presence of
7.5 × 10
2 U of RNase T1 or 3 U of RNase
PhyM for 15 min at 50°C in a final volume of 4 µl. Nonspecific RNA
degradation was determined by incubating the RNAs with RNA sequencing
buffer for 15 min at 50°C. RNA ladders were formed by partial
hydrolysis of RNAs using 1 M NaHCO3, pH 9.2, for 5 min at
90°C.
Structural analyses of RNAs were performed by incubating RNA substrates
in standard structure-probing buffer (10 mM Tris HCl [pH 7], 10 mM
MgCl2, 100 mM KCl) with various RNases (7.5 × 103 U of RNase T1, 1.5 U of RNase PhyM, or
1.5 × 103 U of RNase V1) for 20 min at
37°C in a final volume of 4 µl.
Immediately following all analyses, the reactions were stopped by
adding an equal volume of 2× sequencing gel loading solution (9 M
urea, 0.05% xylene cyanol, 0.05% bromphenol blue, 10% glycerol) and
quick freezing in dry ice-ethanol. Prior to electrophoretic analysis,
samples were heated at 80°C for 1 min. The samples were separated on
prerun 10% polyacrylamide-7 M urea gels.
| |
RESULTS |
Secondary-structure analysis of the wild-type SV40 LPA signal.
We made use of RNase sequencing and structure analysis techniques to
determine the RNA secondary structure of the LPA signal. The
RNases used included RNase T1, which cleaves at
single-stranded G residues; RNase PhyM, which cleaves at
single-stranded A and U residues; and RNase V1, which
cleaves double-stranded RNA with no nucleotide specificity.
The wild-type LPA signal RNA substrate analyzed consists of SV40
nucleotides 2531 to 2731 (Fig. 1A), which contain all the characterized
elements (see the introduction) known to be needed for efficient
cleavage and polyadenylation both in vitro and in vivo (7, 10,
36). To obtain both sequence and structure data from the entire
LPA signal, the RNA substrates were 32P labeled at either
the 5' or the 3' end. The substrates were then treated with RNases
using (i) high-temperature, denaturing conditions for sequence analysis
or (ii) lower-temperature, native conditions for structure analysis
(see Materials and Methods). Figures 2
(region upstream of AAUAAA) and 3 (region
downstream of AAUAAA) show examples of data upon which we based
our structural conclusions. The overall structural conclusions
are based on the consensus results of numerous structure analysis
experiments, the data from which were examined by several individuals
in the laboratory in order to obtain unbiased interpretations.
View larger version (75K):
[in this window]
[in a new window]
|
FIG. 2.
RNase sequencing and structure analyses of the region
upstream of AAUAAA. Sequencing and structure analysis
reactions were carried out with a substrate in which the wild-type LPA
signal was labeled at its 5' end with 32P as described in
Materials and Methods. The labeling of the lanes indicates the
nucleotide(s) (G or AU) being analyzed and whether the analysis is for
sequence (Seq.) or structure (Struct.). The lane marked Struct. ds
reflects results of the structural analysis using RNase V1,
which is specific for double-stranded RNA with no nucleotide
preference. The lane marked Ladder contains the oligonucleotide ladder
generated by alkaline hydrolysis of the substrate RNA. The panel on the
left shows the mock-digested sample (lane Mock), an additional
hydrolysis ladder, and the results of repeated sequencing analyses,
which provided for better analysis of the structural data. The
positions of single-stranded (SS) and double-stranded (DS) regions are
indicated on the right as well as the positions of the three USEs,
USE1, USE2, and USE3. The asterisks indicate G nucleotides which were
not well cleaved by either RNase T1 or V1 in
the structure analyses (see the text).
|
|
View larger version (56K):
[in this window]
[in a new window]
|
FIG. 3.
RNase sequencing and structure analyses of the region
downstream of AAUAAA. Sequencing and structure analysis
reactions were carried out with an RNA substrate in which the wild-type
LPA signal was labeled at its 3' end with 32P as described
in Materials and Methods. The lanes indicate the nucleotide(s) (G or
AU) being analyzed and whether the analysis is for sequence (Seq.) or
structure (Struct.). The lane marked Struct. ds shows the results of
the structural analysis using RNase V1, which is specific
for double-stranded RNA with no nucleotide preference. The lane marked
Ladder contains the oligonucleotide ladder generated by alkaline
hydrolysis of the substrate RNA. The lane marked Mock contains the
mock-digested sample. The panel on the left provides additional
sequence and structural analyses to show reproducibility. The locations
of AAUAAA, the cleavage site (An), DSE-U, DSE-G, and part of
DSE-U' are indicated at the left of the panels. The positions of
single-stranded (SS) and double-stranded (DS) regions as well as the
positions of the four prominent double-stranded regions, SR1 to SR4
(see the text), are indicated at the right of the panels. It should be
noted that the sample used in the Struct. ssAU lane was overly digested
with RNase PhyM, which resulted in low levels of cleavage at A's and
U's in the double-stranded regions SR1 to SR4.
|
|
As indicated in Figures 2 and 3, our data suggested that regions both
upstream and downstream of AAUAAA contained single- and
double-stranded characteristics as indicated by specific nuclease sensitivity. Figure 1B shows a graphic summary of the data indicating the RNase T1- and PhyM-sensitive regions (single strand
specific) in blue and the RNase V1-sensitive regions
(double strand specific) in red. The data suggest that the upstream
region (Fig. 1B and 2) is predominantly sensitive to
single-strand-specific nucleases but that the region downstream of
AAUAAA is significantly more sensitive to the
double-strand-specific nuclease (Fig. 1B and 3).
Structure of the regions upstream of AAUAAA.
A more detailed
examination of the data for the upstream region (Fig. 1B and 2) shows
that USE1, the upstream element closest to the AAUAAA (Fig.
1), was consistently sensitive to the single-strand-specific nucleases
and resistant to RNase V1. This element is very AU rich, and its single-stranded nature can be seen by the prominent RNase PhyM
cleavages. Previous linker substitution mutational analysis (36) to examine the individual effects of the three USEs
indicated that USE1 has the most significant effect on
polyadenylation efficiency. Thus, the marked single-stranded
characteristic of USE1 may be functionally significant. Interestingly,
it was difficult to determine the structures of USE2 and USE3. The
asterisks in Fig. 1B and 2 indicate specific examples of G's which
were cleaved by RNase T1 in the sequencing reactions but
failed to be cleaved by either RNase T1 or RNase
V1 in the structure analysis. This result indicates that
there are structural features in the RNA which protect these nucleotides from access by the relatively large nucleases. Please note
that the results of our sequencing and structure analyses in Fig. 2
extend further upstream than is diagrammed in Fig. 1B.
Structure of the regions downstream of AAUAAA.
As
mentioned above, a significant portion of the downstream region is
sensitive to the double-strand-specific nuclease RNase V1.
A distinct pattern of four double-stranded regions can be seen. These
are denoted structural regions 1, 2, 3, and 4 (SR1 to -4) (Fig. 3). The
positions of these regions with respect to those of the three DSEs
(DSE-U, DSE-G, and DSE-U') and the nucleotide sequence of the
downstream region are shown in Fig. 1C. The first U-rich DSE (DSE-U)
(Fig. 1C), nearest AAUAAA, is predominantly double stranded,
whereas the G-rich DSE (DSE-G) is single stranded. The final U-rich DSE
(DSE-U') is again within a double-stranded region as indicated by RNase
V1 sensitivity (note that the RNase V1
sensitivity of DSE-U' is not shown in Fig. 3). Figure 3 and results of
additional structural analyses (not shown) suggest that the structure
of AAUAAA is predominantly single stranded; however, the
first two A's of AAUAAA consistently show sensitivity to
RNase V1.
Integrity of the downstream structure during mutation of the
upstream region.
We next asked whether the formation of the four
downstream double-stranded regions, SR1 to SR4, was dependent on the
presence of the upstream region. Figure 4
shows the structures of SR1 to SR4 as analyzed with RNase
V1. It is clear that the wild-type structure of the region
(lane WT) changed very little either by the deletion of all sequences
upstream of AAUAAA (lane 
US Seq.), or by specific linker
substitution mutagenesis of the three USEs (lane UM123). Thus, the
formation of the downstream SRs, SR1 to SR4, is independent of upstream
sequences.
View larger version (56K):
[in this window]
[in a new window]
|
FIG. 4.
Integrity of SR1 to SR4 during mutation of the upstream
region. The RNase V1 sensitivity of the prominent
downstream double-stranded regions SR1 to SR4 was analyzed using
substrates in which the wild-type LPA signal RNA was labeled at its 3'
end with 32P (lane WT) and two mutants in which (i) the
entire region upstream of AAUAAA was deleted (lane US
Seq.) or (ii) the three USEs were mutated by specific linker
substitution mutagenesis (lane UM123).
|
|
Correlation of function with the formation of the downstream
double-stranded structure.
To determine the functional
significance of the downstream double-stranded regions (SR1 to -4), we
examined several linker substitution mutations in the downstream
region. Each mutation was examined for its effect on structure, which
was correlated with its effect on in vitro polyadenylation efficiency.
The mutations tested are shown in Fig. 1C, where the exact bases
substituted are indicated by boxes (mutants DM2 to -4) or lines
(mutants aD2 and bD2). The mutant sequences substituted in each case
are described in Materials and Methods.
The wild-type and mutant LPA signal substrates were assayed in in vitro
polyadenylation cleavage reactions. The efficiency of cleavage for each
substrate was determined and compared to that of the wild type, which
was set at 100%. These experiments were repeated at least three times,
resulting in a standard error of less than 5%. The results are shown
in the boxes at the bottom of Fig. 5,
below the RNase V1 structural analysis of the downstream region of each substrate.
View larger version (55K):
[in this window]
[in a new window]
|
FIG. 5.
Correlation of downstream structure with in vitro
cleavage efficiency. The RNase V1 sensitivity of the
downstream region, particularly SR1 to SR4, was analyzed using
32P-3'-end-labeled substrates representing the wild-type
LPA signal (WT) and the LPA signal containing linker substitution
mutants in the downstream region (DM2, DM3, DM4, aD2, bD2, and abD2).
The locations of these mutations in the LPA signal are shown in Fig.
1C. The results of three WT structure analyses are provided to
demonstrate reproducibility. The boxes at the bottom show the
percentage of cleavage by each of the substrates as measured in an in
vitro cleavage reaction by using a HeLa cell extract (see Materials and
Methods). The wild-type cleavage activity is set at 100%, and the
standard error of the analyses is ±5%.
|
|
We show three different analyses of the wild-type LPA signal to
indicate the consistency of detection of the RNase
V1-sensitive regions SR1 to SR4. Mutant DM3, which had
very little effect on in vitro cleavage (92% of the wild-type level),
primarily had mutated nucleotides in the RNase V1-sensitive
region SR4 (Fig. 1C). These mutations affected the structure in SR4
(Fig. 5), but the RNase V1-sensitive structure remained in
SR1, -2, and -3, although it appeared reduced in intensity compared to
that of the wild type, suggesting that it may not be as stable. In
addition, the position of the V1 sensitivity of SR3 is
shifted 2 to 4 nucleotides downstream. The fact that this mutation had
little effect on function suggests that (i) the residual RNase
V1-sensitive regions are sufficient for cleavage and (ii)
the SR4 region is not essential for efficient cleavage of the LPA signal.
Mutant DM2 markedly lowered cleavage efficiency to 30% of that of the
wild type. Its mutations also altered a significant number of
nucleotides in DSE-U, affecting nucleotides in SR2 and SR3 (Fig. 1C).
The mutations completely eliminated RNase V1 sensitivity in
SR3 and altered that of SR2; however, RNase V1 sensitivity remained in SR1 and -4. The deleterious effect of the mutations in DM2
on function, coupled with the disruption of SR3 and possibly SR2,
suggests that these double-stranded regions may be significant for cleavage.
Mutants DM4 and bD2 can be considered together since they overlap,
altering bases in DSE-G. Importantly, these mutations affect sequences
which are predominately single stranded by nuclease analysis. No
nucleotides within SR1 to SR4 were mutated. Both mutations were
functionally quite deleterious (producing levels 23 and 38% of that of
the wild type, respectively), and despite their location each
eliminated RNase V1 sensitivity throughout SR2, SR3, and
SR4. These data again show that disruption of the secondary structure
in SR3, and possibly SR2, correlates with loss of cleavage efficiency.
The mutations in aD2 affected fewer bases in DSE-U than did those in
DM2, and it had only a moderate effect on function (72% of wild-type
cleavage). The nucleotides mutated included some in SR3 (Fig. 1C), and
the double-stranded nature of SR3 was disrupted. However, a new region
with a double-stranded structure appeared 2 to 4 nucleotides further
downstream of the wild-type position of SR3 (Fig. 5). Thus, structure
at or near the position of SR3 (relative to AAUAAA) again
correlates with function. Further, the observation that this mutation
had little effect on cleavage suggests that the ability to form a
secondary structure at or near the position of SR3 may be more
significant than the actual nucleotide sequence.
This idea is supported by mutant abD2, which combines the mutations in
aD2 and bD2 in the same RNA substrate. This mutant substrate was
efficiently processed (88% of wild-type cleavage), indicating that the
deleterious effect of the mutations in bD2 on cleavage efficiency is
compensated for by aD2's mutations. In addition, the double-stranded
region introduced near SR3 by mutant aD2 was again present. Further,
the double-stranded region near SR3 was the only significant RNase
V1-sensitive region in the abD2 substrate other than
SR1 (which was present to some extent in all of the mutants).
Hence, the ability of the mutations in aD2 to form this SR3-like
structure appears to have compensated for the deleterious effects of
the mutations in bD2. These results argue that double-stranded
structure at or near the position of SR3 (relative to AAUAAA)
is important for function.
| |
DISCUSSION |
In this report we have described RNA secondary structure as a
functional feature of the LPA signal. In the introduction we noted a
number of examples where the secondary structure of a polyadenylation
signal appears to play a role in function. Many of these examples were
based on a computer-predicted structure with minimal experimental
conformation. We have provided experimental characterization of the
secondary structure, concluding that the upstream region is
predominantly single stranded and that the downstream region contains
functionally significant double-stranded regions. We have not presented
a diagram of a base-paired secondary structure, since attempts to
generate such structures using available programs have resulted in
either structures which do not completely correspond to the nuclease
sensitivity data or structures which are thermodynamically unfavorable
when the programs are forced to consider the nuclease sensitivity data.
Our nuclease sensitivity analysis provides a first approximation of the
solution structure of the LPA signal in the absence of proteins.
Although our data suggest that this structure correlates with function,
there are clearly many additional aspects of the structure which are
yet to be determined as discussed below.
The upstream region.
Our data indicate that the region
upstream of AAUAAA is predominantly sensitive to
single-strand-specific nucleases, suggesting a relatively large region
of linear, nonstructured RNA. USE1, the USE closest to AAUAAA,
is clearly single stranded; this is the USE with the greatest
effect on polyadenylation efficiency. However, the structures of USE2
and -3 were difficult to determine because these regions were
relatively resistant to both single- and double-strand-specific
nucleases. This result is interesting, since it suggests a higher-order
structure in which the nucleotides in the region of USE2 and -3 are
folded such that they are not accessible to the comparatively large nucleases.
The downstream region.
The downstream region's predominant
characteristics are the double-stranded SRs, SR1 to SR4, within the
U-rich DSE closest to AAUAAA (DSE-U), followed by the
starkly single-stranded region encompassing the majority of the G-rich
DSE (DSE-G). Our data show that the structures formed in SR1 to SR4 are
solely a property of the downstream region, since mutation or deletion
of sequences upstream of AAUAAA had no effect on the
formation of SR1 to SR4.
Our data strongly suggest that the double-stranded nature of SR3 is
functionally significant. The most compelling evidence for this came
from mutant aD2, which altered nucleotides within SR3 but reconstituted
an alternate RNase V1-sensitive region within 2 to 4 nucleotides of the wild-type position of SR3 relative to that of
AAUAAA. It should be reiterated that this alternate
structure contains none of the wild-type bases normally found in this
region but that the mutant functions at more than 70% of the wild-type level of cleavage. This observation suggests that structure at this
position in the polyadenylation signal is more significant than exact
sequence. The significance of SR1 in the function of the LPA signal
cannot be predicted from our data since none of the mutants tested
disrupted its RNase V1 sensitivity.
Mutations in DM4 and bD2, within DSE-G, provided surprising
results. Each dramatically eliminated the
double-stranded character of SR2, SR3, and SR4. In
addition, these mutations had the greatest negative effect on in vitro
cleavage. One could argue that the loss of in vitro cleavage is simply
due to mutation of the G-rich element, which is a binding site for an
hnRNP H family member (known also as DSEF-1) previously shown to be
significant for LPA signal function (2, 3, 28). However,
using mutant abD2 (the combination of mutants aD2 and bD2), we have
shown that the loss of in vitro cleavage mediated by mutant bD2 can be
overcome by the formation of an alternate double-stranded structure
near the position of SR3 by mutant aD2 (discussed above). These data suggest that the functional defect of mutant bD2 is not simply the
mutation of the hnRNP H site but that it is, at least in part, the
result of the mutations' disruption of the double-stranded structure
in the SR3 region. The wild-type region SR3 begins at a position 35 nucleotides downstream of AAUAAA. Our data suggest that such
a structure, at a position between 35 and 39 nucleotides downstream of
AAUAAA, is important for the functioning of the polyadenylation signal. Further, our data suggest that the structure in
this region is more functionally significant than the sequence.
Downstream secondary structure as a general characteristic of
polyadenylation signals.
Our data indicate the functional
significance of the secondary structure in the downstream region of the
LPA signal. However, the specific mechanism requiring this secondary
structure for function is yet to be identified. The sequences
encompassing SR1 to SR4 contain the site for CStF binding. It is
possible that the secondary structure aids the CStF interaction.
Indeed, the downstream secondary structure in the murine immunoglobulin
M gene polyadenylation signal may affect polyadenylation complex formation (27a).
It is intriguing to consider that RNA structure in the downstream
region may perform a catalytic role in the cleavage process. In this
regard it should be noted that, although the cleavage factors of the
polyadenylation complex have been examined, no nucleolytic activity has
yet been noted. Hence, it is possible that the combination of protein
and structure in the substrate RNA provides the cleavage activity.
How general is the feature of secondary structure in the downstream
regions of polyadenylation signals? Clearly not enough polyadenylation
signals have been examined to answer this question. However, it is well
established that the DSEs of most mammalian polyadenylation signals
consist of a region (8 to 12 or more nucleotides) which is GU or U
rich. Due to the multiple ways G's and U's can base pair in RNA, a
GU- or U-rich region would provide the most versatility in forming
base-paired regions with surrounding sequences. In the LPA signal, a
very efficient polyadenylation signal, the downstream structure was
stable enough to be examined in solution. However, in a simpler
polyadenylation signal, the needed secondary structure in the DSE may
form transiently or coordinately with the binding of polyadenylation
factors. Indeed the initial structure, or the structure determined in
solution, may be altered by the binding of proteins. Thus, we suggest
that stable or transient formation of secondary structure involving the
DSE may be an important feature of mammalian polyadenylation signals.
| |
ACKNOWLEDGMENTS |
We thank the members of the Alwine laboratory for aid in and
discussion of the experiments.
H.H. was supported by NIH training grant 5-T32-AI 07325. This work was
supported by NIH grant GM45773 provided to J.C.A. by the Public Health Service.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 314 Biomedical
Research Building, 421 Curie Blvd., School of Medicine, University of Pennsylvania, Philadelphia, PA 19104-6142. Phone: (215) 898-3256. Fax:
(215) 573-3888. E-mail: alwine{at}mail.med.upenn.edu.
| |
REFERENCES |
| 1.
|
Ahmed, Y. F.,
G. M. Gilmartin,
S. M. Hanly,
J. R. Nevins, and W. C. Greene.
1991.
The HTLV-I rex response element mediates a novel form of mRNA polyadenylation.
Cell
64:727-737[CrossRef][Medline].
|
| 2.
|
Bagga, P. S.,
G. K. Arhin, and J. Wilusz.
1998.
DSEF-1 is a member of the hnRNP H family of RNA-binding proteins and stimulates pre-mRNA cleavage and polyadenylation in vitro.
Nucleic Acids Res.
26:5343-5350[Abstract/Free Full Text].
|
| 3.
|
Bagga, P. S.,
L. P. Ford,
F. Chen, and J. Wilusz.
1995.
The G-rich auxiliary downstream element has distinct sequence and position requirements and mediates efficient 3' end pre-mRNA processing through a trans-factor.
Nucleic Acids Res.
23:1625-1631[Abstract/Free Full Text].
|
| 3a.
|
Bar-Shira, A.,
A. Panet, and A. Honigman.
1991.
An RNA secondary structure juxtaposes two remote genetic signals for human T-cell leukemia virus type I RNA 3'-end processing.
J. Virol.
65:5165-5173[Abstract/Free Full Text].
|
| 4.
|
Bhat, B. M., and W. S. M. Wold.
1985.
ATTAAA as well as downstream sequences are required for RNA 3'-end formation in the E3 complex transcription unit of adenovirus.
Mol. Cell. Biol.
5:3183-3193[Abstract/Free Full Text].
|
| 5.
|
Brackenridge, S.,
H. L. Ashe,
M. Giacca, and N. J. Proudfoot.
1997.
Transcription and polyadenylation in a short human intergenic region.
Nucleic Acids Res.
25:2326-2335[Abstract/Free Full Text].
|
| 6.
|
Brown, P. H.,
L. S. Tiley, and B. R. Cullen.
1991.
Efficient polyadenylation with the human immunodeficiency virus type I long terminal repeat requires flanking U3-specific sequences.
J. Virol.
65:3340-3343[Abstract/Free Full Text].
|
| 7.
|
Carswell, S., and J. C. Alwine.
1989.
Efficiency of utilization of the simian virus 40 late polyadenylation site: effects of upstream sequences.
Mol. Cell. Biol.
9:4248-4258[Abstract/Free Full Text].
|
| 8.
|
Colgan, D. F., and J. L. Manley.
1997.
Mechanism and regulation of mRNA polyadenylation.
Genes Dev.
11:2755-2766[Free Full Text].
|
| 9.
|
Conway, L., and M. Wickens.
1985.
A sequence downstream of AAUAAA is required for formation of simian virus 40 late mRNA 3' termini in frog oocytes.
Proc. Natl. Acad. Sci. USA
82:3949-3953[Abstract/Free Full Text].
|
| 10.
|
Cooke, C.,
H. Hans, and J. C. Alwine.
1999.
Utilization of splicing elements and polyadenylation elements in the coupling of polyadenylation and last intron removal.
Mol. Cell. Biol.
19:4971-4979[Abstract/Free Full Text].
|
| 11.
|
Das, A. T.,
B. Klaver, and B. Berkhout.
1999.
A hairpin structure in the R region of the human immunodeficiency virus type 1 RNA genome is instrumental in polyadenylation site selection.
J. Virol.
73:81-91[Abstract/Free Full Text].
|
| 12.
|
DeZazzo, J. D., and M. J. Imperiale.
1989.
Sequences upstream of AAUAAA influence poly(A) site selection in a complex transcription unit.
Mol. Cell. Biol.
9:4951-4961[Abstract/Free Full Text].
|
| 13.
|
DeZazzo, J. D.,
J. E. Kilpatrick, and M. J. Imperiale.
1991.
Involvement of long terminal repeat U3 sequences overlapping the transcription control region in human immunodeficiency virus type I mRNA 3' end formation.
Mol. Cell. Biol.
11:1624-1630[Abstract/Free Full Text].
|
| 14.
|
Gil, A., and N. J. Proudfoot.
1987.
Position-dependent sequence elements downstream of AAUAAA are required for efficient rabbit  -globin mRNA formation.
Cell
49:399-406[CrossRef][Medline].
|
| 15.
|
Gil, A., and N. J. Proudfoot.
1984.
A sequence downstream of AAUAAA is required for rabbit -globin mTNS 3'-end formation.
Nature
312:473-474[CrossRef][Medline].
|
| 16.
|
Gilmartin, G. M.,
E. S. Fleming, and J. Oetjen.
1992.
Activation of HIV-1 pre-mRNA 3' processing in vitro requires both an upstream element and TAR.
EMBO J.
11:4419-4428[Medline].
|
| 17.
|
Gimmi, E. R.,
M. E. Reff, and I. C. Deckman.
1989.
Alterations in the pre-mRNA topology of the bovine growth hormone polyadenylation region decrease poly(A) site efficiency.
Nucleic Acids Res.
17:6983-6998[Abstract/Free Full Text].
|
| 18.
|
Graveley, B. R., and G. M. Gilmartin.
1996.
A common mechanism for the enhancement of mRNA 3' processing by U3 sequences in two distantly related lentiviruses.
J. Virol.
70:1612-1617[Abstract].
|
| 19.
|
Keller, W.,
S. Bienroth,
K. M. Lang, and G. Christofori.
1991.
Cleavage and polyadenylation factor CPF specifically interacts with the pre-mRNA 3' processing AAUAAA.
EMBO J.
10:4241-4249[Medline].
|
| 20.
|
Knapp, G.
1989.
Enzymatic approaches to probing of RNA secondary and tertiary structure.
Methods Enzymol.
180:192-212[Medline].
|
| 21.
|
Lutz, C., and J. C. Alwine.
1994.
Direct interaction of the U1snRNP-A protein with the upstream efficiency element of the SV40 late polyadenylation signal.
Genes Dev.
8:576-586[Abstract/Free Full Text].
|
| 22.
|
Lutz, C. S.,
K. G. Murthy,
N. Schek,
J. L. Manley, and J. C. Alwine.
1996.
Interaction between the U1snRNP-A protein and the 160 kD subunit of cleavage-polyadenylation specificity factor increases polyadenylation efficiency in vitro.
Genes Dev.
10:325-337[Abstract/Free Full Text].
|
| 23.
|
McDevitt, M. A.,
R. P. Hart,
W. W. Wong, and J. R. Nevins.
1986.
Sequences capable of restoring poly(A) site function define two distinct downstream elements.
EMBO J.
5:2907-2913[Medline].
|
| 24.
|
McDevitt, M. A.,
M. J. Imperiale,
H. Ali, and J. R. Nevins.
1984.
Requirement of a downstream sequence for generation of a poly(A) addition site.
Cell
37:992-999.
|
| 25.
|
McLauchlan, J.,
D. Gaffney,
J. L. Whitton, and J. B. Clements.
1985.
The consensus sequence YGTGTTYY located downstream from the AATAAA signal is required for efficient formation of mRNA 3' termini.
Nucleic Acids Res.
13:1347-1368[Abstract/Free Full Text].
|
| 26.
|
Moore, C. L.
1990.
Preparation of mammalian extracts active in polyadenylation.
Methods Enzymol.
181:49-74[Medline].
|
| 27.
|
Moreira, A.,
M. Wollerton,
J. Monks, and N. J. Proudfoot.
1995.
Upstream sequence elements enhance poly(A) site efficiency of the C2 complement gene and are phylogentically conserved.
EMBO J.
14:3809-3819[Medline].
|
| 27a.
|
Phillips, C.,
C. B. Kyriakopoulou, and A. Virtanen.
1999.
Identification of a stem-loop structure important for polyadenylation at the murine IgM secertory poly(A) site.
Nucleic Acids Res.
27:429-438[Abstract/Free Full Text].
|
| 28.
|
Qian, Z., and J. Wilusz.
1991.
An RNA-binding protein specifically interacts with a functionally important domain of the downstream element of the simian virus 40 late polyadenylation signal.
Mol. Cell. Biol.
11:5312-5320[Abstract/Free Full Text].
|
| 29.
|
Russnak, R.
1991.
Regulation of polyadenylation in hepatitis B viruses: stimulation by the upstream activating signal PS1 is orientation-dependent, distance-dependent, and additive.
Nucleic Acids Res.
19:6449-6456[Abstract/Free Full Text].
|
| 30.
|
Russnak, R., and D. Ganem.
1990.
Sequences 5' to the polyadenylation signal mediate differential poly(A) site use in hepatitis B viruses.
Genes Dev.
4:764-776[Abstract/Free Full Text].
|
| 31.
|
Ryner, L. C.,
Y. Takagaki, and J. L. Manley.
1989.
Sequences downstream of AAUAAA signals affect pre-mRNA cleavage and polyadenylation in vitro both directly and indirectly.
Mol. Cell. Biol.
9:1759-1771[Abstract/Free Full Text].
|
| 32.
|
Sachs, A., and E. Wahle.
1993.
Poly(A) tail metabolism and function in eucaryotes.
J. Biol. Chem.
268:22955-22958[Free Full Text].
|
| 33.
|
Sadofsky, M., and J. C. Alwine.
1984.
Sequences on the 3'-side of hexanucleotide AAUAAA affect efficiency of cleavage at the polydenylation site.
Mol. Cell. Biol.
4:1460-1468[Abstract/Free Full Text].
|
| 34.
|
Sadofsky, M.,
S. Connelly,
J. L. Manley, and J. C. Alwine.
1985.
Identification of a sequence element on the 3' side of AAUAAA which is necessary for simian virus 40 late mRNA 3'-end processing.
Mol. Cell. Biol.
5:2713-2719[Abstract/Free Full Text].
|
| 35.
|
Sanfacon, H.,
P. Brodmann, and T. Hohn.
1991.
A dissection of the cauliflower mosaic virus polyadenylation signal.
Genes Dev.
5:141-149[Abstract/Free Full Text].
|
| 36.
|
Schek, N.,
C. Cooke, and J. C. Alwine.
1992.
Definition of the upstream efficiency element of the simian virus 40 late polyadenylation signal using in vitro cleavage and polyadenylation analyses.
Mol. Cell. Biol.
12:5386-5393[Abstract/Free Full Text].
|
| 37.
|
Sittler, A.,
H. Gallinaro, and M. Jacob.
1995.
The secondary structure of the adenovirus-2 L4 polyadenylation domain: evidence for a hairpin structure exposing the AAUAAA signal in the loop.
J. Mol. Biol.
248:525-540[CrossRef][Medline].
|
| 38.
|
Takagaki, Y., and J. L. Manley.
1997.
RNA recognition by the human polyadenylation factor CstF.
Mol. Cell. Biol.
17:3907-3914[Abstract].
|
| 39.
|
Tone, M.,
L. A. Walsh, and H. Waldmann.
1992.
Gene structure of human CD59 and demonstration that discrete mRNAs are generated by alternative polyadenylation.
J. Mol. Biol.
227:971-976[CrossRef][Medline].
|
| 40.
|
Valsamakis, A.,
N. Schek, and J. C. Alwine.
1992.
Elements upstream of the AAUAAA within the human immunodeficiency virus polyadenylation signal are required for efficient polyadenylation in vitro.
Mol. Cell. Biol.
12:3699-3705[Abstract/Free Full Text].
|
| 41.
|
Valsamakis, A.,
S. Zeichner,
S. Carswell, and J. C. Alwine.
1991.
The human immunodeficiency virus type 1 polyadenylation signal: a 3'-LTR element upstream of the AAUAAA necessary for efficient polyadenylation.
Proc. Natl. Acad. Sci. USA
88:2108-2112[Abstract/Free Full Text].
|
| 42.
|
Wahle, E., and W. Keller.
1992.
The biochemistry of 3'-end cleavage and polyadenylation of messenger RNA precursors.
Annu. Rev. Biochem.
61:419-440[Medline].
|
| 43.
|
Wahle, E., and W. Keller.
1996.
The biochemistry of polyadenylation.
Trends Biochem. Sci.
27:247-250.
|
| 44.
|
Wickens, M.
1990.
How the messenger got its tail: addition of poly(A) in the nucleus.
Trends Biochem. Sci.
15:277-281[CrossRef][Medline].
|
| 45.
|
Wilusz, J.,
D. I. Feig, and T. Shenk.
1988.
The C proteins of heterogeneous nuclear ribonucleoprotein complexes interact with RNA sequences downstream of polyadenylation cleavage sites.
Mol. Cell. Biol.
8:4477-4483[Abstract/Free Full Text].
|
| 46.
|
Wilusz, J., and T. Shenk.
1990.
A uridylate tract mediates efficient heterogeneous nuclear ribonucleoprotein C protein-RNA cross-linking and functionally substitutes for the downstream element of the polyadenylation signal.
Mol. Cell. Biol.
10:6397-6407[Abstract/Free Full Text].
|
| 47.
|
Zaret, K. S.,
J. Lin, and C. M. DePersio.
1990.
Site-directed mutagenesis reveals a liver transcription factor essential for the albumin transcriptional enhancer.
Proc. Natl. Acad. Sci. USA
87:5469-5473[Abstract/Free Full Text].
|
| 48.
|
Zeichner, S. L.,
J. Y. H. Kim, and J. C. Alwine.
1991.
Linker scanning mutational analysis of the transcriptional activity of the human immunodeficiency virus type 1 long terminal repeat.
J. Virol.
65:2436-2444[Abstract/Free Full Text].
|
| 49.
|
Zhang, F., and C. N. Cole.
1987.
Identification of a complex associated with processing and polyadenylation in vitro of herpes simplex virus type 1 thymidine kinase precursor RNA.
Mol. Cell. Biol.
7:3277-3286[Abstract/Free Full Text].
|
Molecular and Cellular Biology, April 2000, p. 2926-2932, Vol. 20, No. 8
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Qiu, J., Cheng, F., Pintel, D.
(2007). Distance-Dependent Processing of Adeno-Associated Virus Type 5 RNA Is Controlled by 5' Exon Definition. J. Virol.
81: 7974-7984
[Abstract]
[Full Text]
-
Peterson, M. L., Bingham, G. L., Cowan, C.
(2006). Multiple features contribute to the use of the immunoglobulin m secretion-specific poly(a) signal but are not required for developmental regulation.. Mol. Cell. Biol.
26: 6762-6771
[Abstract]
[Full Text]
-
Oberg, D., Fay, J., Lambkin, H., Schwartz, S.
(2005). A Downstream Polyadenylation Element in Human Papillomavirus Type 16 L2 Encodes Multiple GGG Motifs and Interacts with hnRNP H. J. Virol.
79: 9254-9269
[Abstract]
[Full Text]
-
Wu, C., Alwine, J. C.
(2004). Secondary Structure as a Functional Feature in the Downstream Region of Mammalian Polyadenylation Signals. Mol. Cell. Biol.
24: 2789-2796
[Abstract]
[Full Text]
-
Perkins, K. D., Gregonis, J., Borge, S., Rice, S. A.
(2003). Transactivation of a Viral Target Gene by Herpes Simplex Virus ICP27 Is Posttranscriptional and Does Not Require the Endogenous Promoter or Polyadenylation Site. J. Virol.
77: 9872-9884
[Abstract]
[Full Text]
-
Zarudnaya, M. I., Kolomiets, I. M., Potyahaylo, A. L., Hovorun, D. M.
(2003). Downstream elements of mammalian pre-mRNA polyadenylation signals: primary, secondary and higher-order structures. Nucleic Acids Res
31: 1375-1386
[Abstract]
[Full Text]
-
Orozco, I. J., Kim, S. J., Martinson, H. G.
(2002). The Poly(A) Signal, without the Assistance of Any Downstream Element, Directs RNA Polymerase II to Pause in Vivo and Then to Release Stochastically from the Template. J. Biol. Chem.
277: 42899-42911
[Abstract]
[Full Text]
-
Aissouni, Y., Perez, C., Calmels, B., Benech, P. D.
(2002). The Cleavage/Polyadenylation Activity Triggered by a U-rich Motif Sequence Is Differently Required Depending on the Poly(A) Site Location at Either the First or Last 3'-Terminal Exon of the 2'-5' Oligo(A) Synthetase Gene. J. Biol. Chem.
277: 35808-35814
[Abstract]
[Full Text]
-
Cooke, C., Alwine, J. C.
(2002). Characterization of Specific Protein-RNA Complexes Associated with the Coupling of Polyadenylation and Last-Intron Removal. Mol. Cell. Biol.
22: 4579-4586
[Abstract]
[Full Text]
-
Arhin, G. K., Boots, M., Bagga, P. S., Milcarek, C., Wilusz, J.
(2002). Downstream sequence elements with different affinities for the hnRNP H/H' protein influence the processing efficiency of mammalian polyadenylation signals. Nucleic Acids Res
30: 1842-1850
[Abstract]
[Full Text]
Top
Abstract
Introduction
