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Journal of Virology, August 2001, p. 7763-7768, Vol. 75, No. 16
Department of Biology, Johns Hopkins
University, Baltimore, Maryland 21218
Received 6 March 2001/Accepted 21 May 2001
Rous sarcoma virus RNA contains a negative regulator of splicing
(NRS) element that aids in maintenance of unspliced RNA. The NRS binds
U1 snRNA at a sequence that deviates from the 5' splice site consensus
by substitution of U's for A's at three positions: Retroviruses synthesize full-length,
viral RNAs that resemble cellular pre-mRNA substrates for splicing.
Unlike cellular pre-mRNAs, many of these full-length viral transcripts
are transported to the cytoplasm, where they are packaged into viral
particles or translated to produce gag and pol
gene products. Retroviruses also splice a fraction of their primary
transcripts to generate additional mRNA, including env mRNA
(reviewed in references 2 and 17).
The regulation of avian retroviral RNA splicing involves the use of
suboptimal 3' splice sites, an exonic splicing enhancer, and a negative
regulator of splicing (NRS) (1, 8, 14, 20, 21). The
230-nucleotide (nt) cis-acting NRS element is located within
the gag gene, about 300 nt downstream from the 5' splice
site and 4,000 nt from the env 3' splice site. Insertion of
the NRS into a cellular intron inhibits splicing from that site in an
orientation- and distance-dependent fashion (15). NRS-mediated inhibition of splicing involves the interaction of U1
snRNP with the 3' end of the NRS (7, 13). Mutations that interfere with U1 snRNA base-pairing impair NRS activity, and this
activity is partially rescued by a compensatory U1 snRNA mutant
(7). The U1 snRNP binding site in the NRS partially overlaps a consensus U11 snRNP binding site, and U11 snRNA has also
been shown to bind to the NRS (6). However, mutations specifically disrupting the U11 binding sequence did not inhibit NRS
activity, suggesting that U11 snRNP binding is not necessary for NRS
function (7, 13). The NRS appears to function as a
nonproductive 5' splice site decoy which competes with the authentic viral 5' splice site upstream for interaction with 3' splice sites (3, 5).
In the present study, we have carried out a detailed mutational
analysis of the 5' splice site-like sequence in the NRS. We asked
whether this sequence or its context was responsible for the failure of
splicing from this site. This study revealed that all three
nonconsensus U's are important for NRS activity. Point mutations at
any of these sites can either neutralize splicing suppression or
activate productive splicing at this NRS site.
NRS contains a decoy 5' splice site.
The Rous Sarcoma Virus
(RSV) NRS sequence contains a 5' splice site-like sequence near its 3'
end, and mutations in this region have been shown to impair NRS
activity (6, 7, 13, 15). The potential base-pairing
between the NRS and the 5' end of U1 snRNA includes positions
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.16.7763-7768.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Retroviral Splicing Suppressor Requires Three
Nonconsensus Uridines in a 5' Splice Site-Like Sequence
ABSTRACT
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2, +3, and +4.
All three of these U's are important for NRS-mediated splicing
suppression. Substitution of a single nonconsensus C or G at any of
these sites diminished NRS activity, whereas substitution of a single A
generated a preferred 5' splice site within the NRS.
TEXT
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1, +1,
+2, +5, and +6 of the 5' splice site consensus sequence
(AG/GURAGU), as shown in the alignment in Fig.
1C. In addition, the NRS sequence at
positions +7 and +8 is complementary to the first two encoded bases of
U1 snRNA, extending the potential base-pairing. However, nonconsensus
bases are observed at NRS positions 2, +3, and +4 of the decoy 5'
splice site. In all three nonconsensus positions, the viral sequence has a U instead of an A (or an R at +3). These U's could result in
potential interactions with a U or pseudouridine (
) in U1 snRNA. We
investigated the functional significance of these nonconsensus U's by
mutating each to the other three nucleotides.
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FIG. 1.
Nonconsensus U's in a 5' splice site-like sequence are
needed for NRS activity. (A) The 230-nt NRS sequence was inserted into
the myc intron of pRSVNeo-int at a site 336 nt downstream
from the 5' splice site and 632 nt upstream from the 3 splice site. A
riboprobe spanning the myc 5 splice site was used to detect
spliced (441 nt) and unspliced (602 nt) RNAs. SV40, simian virus 40. (B) RNase protection assay with the myc 5 splice site probe
of transcripts isolated from 293 cells transfected with wild-type (WT)
or mutant NRS sequences in pRSVNeo-int. (C) Potential base-pairing of
the NRS with U1 snRNA. The 5' splice site consensus sequence is shown
below the NRS sequence, and consensus bases present in the NRS are
underlined. NRS mutations are aligned with the wild-type (WT) sequence.
(D) Histogram of spliced myc RNA assayed by RNase protection
as in Fig. 2A. Error bars represent the standard deviation from the
mean for at least three independent transfection experiments.
Nonconsensus uridines in 5' splice site-like sequence are important for NRS activity. To assay the effect of NRS mutations on splicing in transfected cells, we inserted NRS mutants into the myc intron of a heterologous splicing construct, pRSVNeo-int (9), as shown in Fig. 1A. The constructs were transiently transfected into the human embryonic kidney 293 cell line. After total cellular RNA was isolated, splicing was assayed by RNase protection with a riboprobe spanning the myc 5' splice site (Fig. 1A), as previously described (7, 15). This probe allowed us to quantify the level of splicing at this site by comparison of the relative amounts of spliced (exonic) and unspliced protected fragments.
We first tested the effect of single point mutations in the NRS at positions2, +3, and +4 (nt 913, 917, and 918; Fig. 1C). The
substitution of A for U at any of these positions resulted in a
dramatic reduction in splicing from the myc 5' splice site (Fig. 1B, lanes 3 and 6, and Fig. 1D). Quantitation of the results revealed that U913A was 28% spliced, U917A was 8% spliced, and U918A
was 19% spliced at this site (Fig. 1D). In comparison, the construct
bearing the wild-type NRS was 45% spliced, and the construct lacking
an NRS spliced 81% of its RNA at the myc 5' splice site.
The substitution of either C or G for U had the opposite effect,
increasing splicing from the myc 5' splice site. The results were as follows: U913C, 79% spliced; U917C, 75% spliced; U913G, 56%
spliced; U917G, 63% spliced; U918C, 71% spliced; and U918G, 69%
spliced (Fig. 1D). Thus, single base changes at 2, +3, or +4 gave
similar results: mutations to an A decreased myc splicing, while changes to a C or G increased splicing at this site.
Mutations in U1 binding site sequence in NRS can activate splicing
within NRS.
We next investigated the possibility that some of
these NRS mutations had activated a cryptic 5' splice site sequence
within the NRS. RNA spliced from a 5' splice site within the NRS or in other regions of the intron would be indistinguishable from unspliced RNA with the myc 5' splice site probe. Therefore, a second
probe which spanned the NRS sequence and extended 70 nt downstream into the myc intron was used in RNase protection assays to
determine if cryptic splicing was occurring within this region (Fig.
2A).
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2, +3, or +4 all showed very high levels of splicing within
the NRS. This was represented by a new doublet band in the RNase
protection analyses (Fig. 2B, lanes 3 and 6). This spliced RNA
represented 77 and 78% of the RNA generated by constructs U917A and
U918A, respectively, and detected with the NRS probe (Fig. 2C).
Similarly, U913A appeared to be 83% spliced (Fig. 2C), and the double
point mutant UU917/918AA (7) yielded 88% spliced RNA with
this NRS-specific probe (data not shown).
The base changes from U to G at positions 917 and 918 also resulted in
splicing within the NRS at levels of 56 and 32%, respectively (Fig.
2B, lanes 5 and 8; Fig. 2D). The U917Gmutant is closer to the 5' splice
site consensus than the wild-type sequence. In contrast, no splicing
within the NRS was observed with U913G (Fig. 2C). The substitutions
from U to C at positions 2, +3, and +4 resulted in very little
splicing within the NRS (15, 10, and 12%, respectively; Fig. 2B, lanes
4 and 7; Fig. 2C).
Identification of splice sites within NRS.
The NRS probe used
in Fig. 2 allowed identification of cryptic splice sites within the NRS
or 70 nt downstream of it. To extend this analysis to include the
entire 1,200-nt intron containing the NRS, we performed reverse
transcription (RT)-PCR using primers in both myc exons.
Unspliced RNA would be expected to generate a 1,330-bp RT-PCR product,
and normally spliced myc RNA would yield a 139-bp product
(Fig. 3A). These were the only products generated from the wild-type NRS construct, confirming that no cryptic
splicing occurred (data not shown). In contrast, mutants UU917/918AA, U917A, U918A, and U913A generated a novel product of
684 bp and a reduced amount of the 139-bp spliced product (Fig. 3B and
data not shown). The UU917/918AA, U917A, and U918A mutants also
generated small amounts of a 389-bp product. Small amounts of the
684-bp product were also observed with U917G and U918G (data not
shown). In contrast, mutants U913C, U913G, and UU917/918CC did not
generate any of these novel RT-PCR products, yielding mainly the 139-bp
product, generated by splicing at the normal myc splice
sites (Fig. 3B).
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Competition between two splice sites.
The data presented above
suggested that alternative splicing was occurring with some of the NRS
mutants, with competition between the upstream myc 5' splice
site and an activated 5' splice site within the NRS. The experiments
shown in Fig. 1 used the myc donor probe and generated data
on splicing at this site only; the apparent "unspliced" RNA in this
assay includes any RNA spliced at a downstream site. In contrast, the
NRS probe data presented in Fig. 2 give the relative amount of RNA
spliced within the NRS or directly downstream of it; any RNA spliced at
the myc 5' splice site would not hybridize to this probe. To
give an overall picture of the distribution of the RNA species between
the alternatively spliced products and unspliced RNA, we analyzed the
data as shown in Fig. 4.
|
2, +3, and +4.
Analysis of a 5' splice site sequence data base (18; http://fruitfly.org/seq_tools/splice.html) did not reveal any examples of this NRS sequence (UG/GUUUGU) in a catalog of
more than 2,000 nonredundant human 5' splice sites, suggesting that this sequence may not be functional as a 5' splice site. Alternatively, there may be contextual problems that prevent splicing at this site.
To determine sequence requirements for NRS splicing suppression, we
have mutated each of the nonconsensus U's to the three other bases.
Surprisingly, mutation of any one of the U's to a C led to a nearly
normal splicing phenotype, abolishing the NRS splicing suppression.
When any of the U's was mutated to an A, the NRS site became the
preferred 5' splice site. Mutation of the +3 or +4 site to a G led to a
lower level of activation of this cryptic 5' splice site within
the NRS. Therefore, making any one of these three sites fit the
consensus led to splicing at this site in preference to the upstream 5'
splice site. It may be important that there is an ASF/SF2 binding site
within the NRS (12), located between the two alternative
5' splice sites (myc site and cryptic NRS site). This has
been shown to facilitate U1 snRNP binding to the NRS (13)
and may promote use of the downstream splice site (4).
It appears that U's specifically, rather than any nonconsensus base,
are important for NRS splicing inhibition. Each of the NRS nonconsensus
U's would oppose a U (2) or a (+3 and +4) in the U1 snRNA
sequence. U-U interactions have been observed in tRNA and found to be
more stable than most non-Watson-Crick base-pairing interactions,
including C-U (19). It is interesting that the yeast 5'
splice site consensus sequence also has a U at +4 (10),
which could interact with the in yeast U1 snRNA (11).
The U at +4 has also been found to be important for stable binding of
U1 snRNP in randomization-selection experiments (D. Libri, personal
communication). Alternatively, these U's may be important for binding
of another factor to the NRS. There is the potential for base-pairing
of 12 of 13 nt of U6 snRNA (nt 33 to 45) to this region of the NRS, and
the U's at +3 and +4 would stabilize this interaction.
In summary, the NRS is capable of interacting with several snRNPs.
Single point mutations in the NRS which improve the 5' splice site
consensus sequence make the NRS the preferred 5' splice site. We
propose that the NRS functions as a decoy 5' splice site and may
prevent cryptic as well as productive splicing in the virus (C. T. O'Sullivan, unpublished data). The NRS requires three nonconsensus
U's in the 5' splice site-like sequence to effectively maintain
unspliced RNA for export to the cytoplasm (16).
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ACKNOWLEDGMENTS |
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R. E. Paca and C. S. Hibbert contributed equally to this work.
This work was supported by Public Health Service research grant RO1 CA48746 from the National Cancer Institute. R.E.P. and C.O.S. were supported in part by NIH predoctoral training grant 52T32G07231.
We thank Raymond Fernalld for technical assistance and members of the Beemon laboratory for review of the manuscript.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Biology, Johns Hopkins University, 3400 N. Charles St., Baltimore, MD 21218. Phone: (410) 516-7289. Fax: (410) 516-7292. E-mail: KLB{at}JHU.edu.
Present address: NCI-Frederick Cancer Research and Development
Center, Frederick, MD 21702.
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Journal of Virology, August 2001, p. 7763-7768, Vol. 75, No. 16
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.16.7763-7768.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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