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Previous Article | Next Article 
Molecular and Cellular Biology, February 2001, p. 1011-1023, Vol. 21, No. 4
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.4.1011-1023.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Splicing Factor Slt11p and Its Involvement in Formation of
U2/U6 Helix II in Activation of the Yeast Spliceosome
Deming
Xu and
James D.
Friesen*
Banting and Best Department of Medical
Research and Department of Molecular and Medical Genetics,
University of Toronto, Toronto, Ontario, Canada M5G 1L6
Received 29 September 2000/Returned for modification 31 October
2000/Accepted 22 November 2000
 |
ABSTRACT |
Slt11p is a new splicing factor identified on the basis of
synthetic lethality with a mutation in the 5' end of U2 snRNA, a region
that is involved in intermolecular U2/U6 helix II interaction. Slt11p
is required for spliceosome assembly. Our genetic results suggest that
Slt11p is involved in the base-pairing interaction of U2/U6 helix II in
vivo. We showed that the recombinant protein binds to RNAs with some
degree of structural specificity. Slt11p also anneals RNA and binds to
the resulting duplexes, which contain two separated helical regions.
These RNA structures are reminiscent of U2/U6 helix II, which is formed
concomitantly with U4/U6 stem II, and suggest that Slt11p facilitates
the cooperative formation of helix II in association with stem II in
the spliceosome. We show that Slt11p and Slu7p, a second-step factor,
interact with each other both in vivo and in vitro and that the binding
of Slu7p to Slt11p impairs the RNA-binding activity of the latter.
These results suggest that the function of Slt11p is regulated by Slu7p in the spliceosome.
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INTRODUCTION |
Pre-mRNA splicing proceeds in a
large RNA-protein complex, the spliceosome. During assembly,
activation, and remodeling of the spliceosome, protein factors play
essential roles in establishment, maintenance, regulation, and
coordination of a series of dynamic RNA-RNA interactions which are
directly involved in recognition of splice sites and formation of RNA
structures that are important for the two-step splicing reaction
(13, 30). Among these factors, RNA-binding proteins and
RNA-dependent ATPases/RNA helicases (DEXD/H proteins) have been
demonstrated or implicated in several RNA conformational changes in the
splicing pathway (30). In yeasts, recognition of the 5'
splice site (5'-SS) is mediated directly through its base-pairing
interaction with U1 small nuclear RNA (snRNA) in the formation of
commitment complexes (29). The highly conserved branch
point site (BPS) is first recognized by an RNA-binding protein, BBP
(1). BBP is also involved in direct interactions with
Prp40p, a component of U1 small nuclear ribonucleoprotein particle
(snRNP) bound at the 5'-SS, and Mud2p, another RNA-binding protein
bound to the polypyrimidine tract which is important for the selection
of the 3'-SS. The BPS is then recognized through direct base-pairing
interaction with a region in U2 snRNA (25). One component
of the U2 snRNP, Prp11p, interacts with Mud2p (2). These
protein-protein interactions provide a temporal and spatial framework
for a cross-intron coordination of different RNA-RNA interactions
(1). The function of Prp5p (a DEAD protein) has been
associated with the recognition of BPS sequence by U2 snRNA (22).
Formation of the prespliceosome (containing U1 and U2 snRNPs) is
followed immediately by recruitment of the preformed tri-snRNP consisting of U4/U6.U5, in which U4 and U6 snRNAs are complexed through
extensive base-pairing interactions (stems I and II) (18). A series of conformational RNA changes is triggered through
displacement of U1 snRNA by U6 snRNA at the 5'-SS. Another DEAD
protein, Prp28p, facilitates this process (31).
Recognition of the 5'-SS involves a highly conserved ACAGAGA
sequence in U6 snRNA (18). The relative position of
this motif with respect to U4/U6 stem I is critical to the recognition
of the 5'-SS (15). Prp8p also exerts its function at this
step (14, 15). Other RNA conformational changes during
activation of the spliceosome include disruption of the U4/U6 duplex
and formation of intermolecular U2/U6 interactions and an
intramolecular Brow stem, near the 3' end of U6 snRNA. Some of these
RNA interactions presuppose the disruption of U4/U6 duplex, since
regions in U6 snRNA that form U2/U6 helix I and the Brow stem are
initially paired with U4 snRNA in U4/U6 stems I and II, respectively.
Formation of U2/U6 helix Ia brings the BPS (recognized by a sequence in
U2 snRNA immediately adjacent to helix Ia) close to the vicinity of the
5'-SS, which is recognized by the ACAGAGA sequence in U6 snRNA, also
adjacent to helix Ia (see reference 18 for a review). Two
RNA-dependent ATPases, Slt22p (or Brr2p), a large DEIH protein
(21, 37), and Prp2p, a DEAH protein (33), are
involved in spliceosomal activation prior to the first step. While the
RNA target of Prp2p is not yet clear, Slt22p has been implicated in
disruption of U2/U6 helix II (37) and U4/U6 duplex
(26).
Following the first step, the spliceosome undergoes remodeling in order
to form RNA structures that are important for the second splicing step.
Loop 1 of U5 snRNA is important for tethering the two exons
(23). However, a number of trans- and
cis-acting factors are involved in the selection and
recognition of the 3'-SS (34). RNA structures important
for the second step usually involve noncanonical tertiary interactions
(9, 17, 19). Two DEAH proteins, Prp16p (7)
and Prp22p (28), are required for the second splicing step.
The U2/U6 helix II interaction, between the 5' end of U2 snRNA and the
3' end of U6 snRNA, is highly conserved (18). In yeast an
11-nucleotide (nt) substitution in U2 snRNA that disrupts the proposed
helix II interaction confers mild growth defects (10).
This 11-nt substitution in U2 snRNA (see Fig. 2A) was used as the
starting mutation in a genetic screen for additional splicing mutants
that are synthetically lethal with it (38). This screen
yielded two new factors, Slt11p, an RNA-binding protein, and Slt22p, an
RNA-dependent ATPase (37), and a number of previously characterized factors, Slt15p (or Prp17p), Slt16p (or Smd3p), Slt17p
(or Slu7p), and Slt21p (or Prp8p) (38). In this study, we
characterized the function of Slt11p in pre-mRNA splicing. We provide
both genetic and biochemical data that Slt11p is involved in the RNA
base-pairing interaction of U2/U6 helix II and that Slt11p interacts
with Slu7p, a factor that is required for the recognition of the 3'-SS
(5). Our results indicate that the RNA-annealing and
-binding activities of Slt11p, which forms a dimer, facilitate the
formation of U2/U6 helix II in association with U4/U6 stem II. We
suggest that U2/U6 helix II plays a regulatory role in activation of
the spliceosome. Furthermore, the effects of Slu7p on Slt11p suggest
that the RNA-binding activity of the latter is regulated in
spliceosomal activation.
| |
MATERIALS AND METHODS |
Genetic manipulation of yeast and tests of synthetic lethality
and genetic suppression.
All yeast strains were derived from
W303-1A and -1B (Mata or Mat
ade2-1 his3-11,15 leu2-3,112
trp1-1 ura3-1 can1-100). Procedures for manipulation of yeast have been described by Adams et
al. (3). A yeast strain containing chromosomal deletions of both U2 and U6 genes (see Fig. 3C) was described previously (38). A strain with a chromosomal deletion of
SLT11 was constructed by replacing the entire open reading
frame (ORF) with the yeast HIS3 gene. A yeast strain
containing chromosomal deletion of U2 and U6 snRNA genes and
SLT11 (see Fig. 3C) was constructed as described elsewhere
(38). In all experiments, synthetic complete media were
used. The plasmid shuffling method was used to test phenotypic defects
of and genetic interactions between U2 and U6 snRNA mutations in
SLT11 and 
slt11 backgrounds (see Fig. 3C). These strains were transformed with plasmids carrying U2 and U6 snRNA
genes. The resultant transformants were grown on medium containing
uracil prior to being transferred to 5-fluoroorotic acid (5-FOA)
medium at 25 and 30°C. Yeast cells which were resistant to 5-FOA were
then tested for additional phenotypic defects. Genetic interaction
between slt11 and slu7-1 and
slt17/slu7-100 was tested as described
by Xu et al. (38).
In vitro splicing assays and nondenaturing gel electrophoresis of
spliceosome assembly.
Preparation of whole-cell yeast splicing
extracts and in vitro splicing assays were performed as described
previously (37). Synthetic
32P-labeled yeast pre-actin RNA was used in these
assays and spliceosome assembly. Splicing complexes were analyzed by
nondenaturing gel electrophoresis as described by Cheng and Abelson
(8) and Tarn et al. (32), with modifications
(37).
Site-directed mutagenesis.
Quick-change site-directed
mutagenesis (Stratagene) was used to construct 5-nt, 4-nt, and
substitution mutations in both U2 (U2-, -
, and -
) and U6
(U6-E, -F, -G, and -H) snRNA genes (see Fig. 3B). The 9-nt-substitution
mutants of both U2 (U2-) and U6 (U6-EF) (see Fig. 3B) mutations
were constructed based on U2- and U6-E, respectively.
Expression and purification of His-Slt11p and GST-Slu7p.
The
ORF of Slt11p was cloned in pET16b (Novagen). The bacterial host cell
BL21(DE3) was used to produce His6-Slt11p.
Recombinant protein was found to be soluble and was thus purified using
Ni2+-affinity chromatography with
nickel-nitrilotriacetic acid resin (Qiagen). To construct glutathione
S-transferase (GST)-Slu7p fusion protein expression
vectors, the entire SLU7 ORF was cloned in pGEX-4T-1
(Pharmacia Biotech). The host XL1-Blue cells (Stratagene) were
transformed with the GST-Slu7p constructs and pGEX-4T-1. GST-Slu7p
protein (soluble) and GST were purified using chromatography affinity
with glutathione Sepharose 4B (Pharmacia Biotech). RNase A and DNase I
were added to both His6-Slt11p and GST-Slu7p
samples prior to affinity chromatography to remove nucleic acids. All the purified proteins were dialyzed against 1× ACB (10 mM HEPES [pH
7.6], 100 mM NaCl, 1 mM EDTA, 1 mM dithiothreitol, and 10% [vol/vol] glycerol). The His6-Slt11p was used
to produce rabbit antibodies at Comparative Animal Study Center of
University of Toronto.
RNA-binding assay.
T7 templates for various RNA substrates
were constructed by annealing two DNA oligonucleotides containing the
promoter sequence of T7 RNA polymerase. Synthetic
32P-labeled RNA substrates were made from these
DNA templates using T7 RNA polymerase with
[-32P]UTP. Both labeled and unlabeled
substrates were gel purified. The RNA-binding assay was performed in a
solution containing 1× ACB and 0.1% Triton in a final volume of 10 µl. Appropriate amounts (5 to 100 ng) of
His6-Slt11p were mixed with
32P-labeled RNA (approximately 1 fmol, with
different amounts of unlabeled RNA, if applicable), and the mixtures
were kept at 25°C for 20 min and transferred to ice for another 20 min. The protein-RNA mixtures were then loaded directly on
nondenaturing gels (4% acrylamide-bisacrylamide [60:1], 0.5×
Tris-borate-EDTA [pH 7.5]) and run (in 0.5× Tris-borate-EDTA and 5 µM -mercaptoethanol) for 2 h at 150 V at 4°C.
Glycerol gradient sedimentation.
A total of 100 µg of
His6-Slt11p was layered onto a 10-to-40%
glycerol step (5% increments) gradient (in 1× ACB) which was subsequently centrifuged at 46,000 rpm for 16 h in an SW50 Ti rotor (Beckman). Fractions (approximately 100 µl each) from the gradients were collected and analyzed by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) followed by
blotting with rabbit anti-Slt11p antibodies and mouse anti-rabbit
immunoglobulin G conjugated to horseradish peroxidase using an
enhanced chemiluminescence kit (Kirkegaard & Perry
Laboratories). For size standards, parallel gradients were run on
samples containing bovine serum albumin (BSA) (68 kDa), albumin (45 kDa), and cytochrome c (12.5 kDa).
RNA-annealing assay.
Approximately 1 fmol of
32P-labeled RNA was mixed with various amounts of
unlabeled RNA and various amounts of
His6-Slt11p in a final volume of 10 µl (1×
ACB), followed by 20 min of incubation at 25°C; 5 ng of proteinase K
(with 0.1% SDS, final concentration) was then added to the mixture and
incubated for another 15 min (after complete digestion of
His6-Slt11p, as determined by immunoblotting [data not shown]). The resulting mixtures were immediately loaded on
nondenaturing gels (6%; see above) and run for 2.5 h at 200 V at
4°C.
Affinity chromatography.
Recombinant GST-Slu7p and GST were
incubated (for 60 min) with 200 µl of glutathione Sepharose 4B (50%
slurry, equilibrated with 1× ACB containing 100 mM NaCl [1×
ACB-100]) at final (ligand) concentrations of 1, 2, and 4 µg/µl
(for GST-Slu7p) and 4 µg/µl (for GST). Minicolumns were assembled
with proteins bound to the Sepharose. After one wash with 100 µl of
1× ACB-100), 100 µg of His6-Slt11 (mixed with
50 µg of BSA in 200 µl of 1× ACB-100) was applied to each column.
The flowthrough was collected. After washes with 500 µl of 1×
ACB-100, each column was eluted with 200 µl of 1× ACB with 500 mM
NaCl, followed by 200 µl of 1× ACB with 1,000 mM NaCl and 200 µl
of 1× ACB-100 with 1% SDS. Samples corresponding to 1% of the
loading sample, 5% of the flowthrough fraction, and 10% of eluates
were analyzed by SDS-PAGE followed by immunoblotting.
| |
RESULTS |
Slt11p is a new splicing factor involved in spliceosome
activation.
SLT11 (YBR065) was identified on
the basis of synthetic lethality with a mutation near the 5' end of the
U2 snRNA that disrupts U2/U6 helix II (38). The protein
can be divided into three regions (Fig.
1A). The N-terminal region (amino acids 1 to 150) contains two conserved zinc finger motifs that are found in
three other proteins from Schizosaccharomyces pombe (cwf5),
Caenorhabditis elegans, and Arabidopsis thaliana
and several expressed sequence tags in the databases (Fig. 1B and data
not shown). The cwf5 protein was identified on the basis of its
association with a large complex that is involved in cell cycle control
and pre-mRNA splicing (20). Slt11p contains two regions
which are reminiscent of the RNA-binding domains (RBDs) of a class of
RNA-binding proteins (6). However, the two putative RBDs
of Slt11p contain divergent RNP1 and RNP2 subdomains that show homology
to each other and to Yra1p (Fig. 1C), which possesses RNA-annealing
activity (24). SLT11 was also identified as
ECM2, which, in its mutant form, confers hypersensitivity to
Calcofluor white, an indication of defects in cell surface biosynthesis
and architecture (16). However, it is unclear whether its
effect on the functions of extracellular matrix is direct or indirect.
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FIG. 1.
Slt11p protein sequence and motifs. (A) Schematic of
Slt11p and related proteins from S. pombe cwf5
(AL023592), C. elegans (Z69384), A.
thaliana (AC004561), and S.
cerevisiae Yra1p (U72633). (B) Alignment of the Slt11p
zinc fingers with other proteins with similar motifs. Dots indicate
conserved cysteine residues. (C) Alignment of the two potential RBDs in
Slt11p with the RBD in Yra1p. The RNP core and other structural motifs
are shown according to the work of Burd and Dreyfuss (6).
In panels B and C, the conservation at a particular position among the
aligned proteins is indicated by grey shading.
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SLT11 is not essential for cell viability at 
30°C.
However, a chromosomal deletion of the entire ORF (slt11)
confers temperature-sensitive growth at 
33°C (data not
shown). Although a splicing extract made from slt11 cells
was active at 25°C, the overall splicing activity was significantly
impaired (Fig. 2A, lanes 4 to 6),
suggesting that Slt11p is required for maximum efficiency of splicing.
The slt11 extract was completely inactive at 30°C
(Fig. 2A, lanes 8 and 10). Spliceosome assembly at 30°C was assessed
using native gel electrophoresis as described by Cheng and Abelson
(8). Spliceosome assembly in the wild-type extract was
largely consistent with kinetics described in references 8
and 32: complex B was detected in the initial stage of
assembly (Fig. 2B, lane 1), followed by transient appearance of
complexes A2-1 and A1 (Fig. 2B, lanes 2 and 3). After 10 min of
incubation, accumulation of active spliceosome (i.e., complex A2-2,
which ran with a mobility similar to that of complex A2-1
[8]) was observed (Fig. 2B, lane 4). The
slt11 extract was defective in spliceosome assembly at
30°C: assembly of complex B was delayed, and complex A1 was not
detected (Fig. 2B, lanes 5 to 8). The complex that accumulated after 10 min of incubation was likely A2-1 (Fig. 2B, lane 8). Similar results
were observed with the wild-type extract at 25°C, whereas minimum
formation of complex A1, in addition to A2-2, was detected in the
slt11 extract (data not shown). The transition from
complex A2-1 (containing all five spliceosomal snRNAs) to complex A1
(functional spliceosome, containing U2, U5, and U6 snRNAs) represents
activation of the spliceosome (32). Our preliminary results suggest that Slt11p is required for spliceosome assembly, in
particular, activation of the spliceosome.
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FIG. 2.
Slt11p is a splicing factor. (A) In vitro splicing assay
of yeast pre-actin RNA with wild type (lanes 1 to 3, 7, and 9) and
slt11 (lanes 4 to 6, 8, and 10) at 25°C (lanes 1 to
6), 30°C (lanes 7 and 8) and 33°C (lanes 9 and 10) for the
indicated incubation times. (B) Spliceosome assembly in wild-type
(lanes 1 to 4) and slt11 (lanes 6 to 8) extracts at
30°C and schematic of spliceosome assembly and snRNA content (based
on data in reference 32). (C) Rescue of splicing activity
of slt11 extract by recombinant Slt11p. Increasing
amounts of His6-Slt11p (1, 10, and 100 ng [lanes 2, 3, and
4, respectively]) were added to a slt11 extract
(lane 1), which was preincubated for 10 min at 25°C prior to a
splicing reaction at 30°C. Note that the lariat intron ran very close
to precursor RNA in this gel.
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Recombinant His6-Slt11p was produced in
Escherichia coli and purified by Ni2+
affinity chromatography (data not shown). When added to the
slt11 extract, the recombinant protein was able to rescue
the splicing activity at 30°C (Fig. 2C, lanes 2 to 4), suggesting
that the defect associated with the slt11 extract can be
attributed solely to genetic depletion of Slt11p and that the
recombinant protein is functionally competent.
Slt11 is involved in the RNA base-pairing interaction of U2/U6
helix II in vivo.
We showed previously that
slt11-1 is synthetically lethal with mutations in
the helix II region of both U2 and U6 snRNAs (38). A
genetic approach was used to explore the role of SLT11 in
the helix II interaction (Fig. 3). The
effects on growth of partial disruption of helix II by substitutions of
5 nt (U2- and U6-E) and 4 nt (U2- and U6-F) in both snRNAs (Fig.
3B) were tested in SLT11 and slt11 yeast
strains (Fig. 3C). None of these helix II mutations was found to confer
temperature-sensitive or cold-sensitive defects by itself in the
SLT11 background (Fig. 3D, panels R1/C1, R1/C2, R1/C3,
R3/C1, and R5/C1; also data not shown). However, when tested in the
slt11 background, each conferred synthetic lethality
(Fig. 3D, panels R2/C2, R2/C3, R4/C1, and R6/C1 [partial lethality]),
whereas a 3-nt substitution in a region outside helix II in U2 snRNA
(U2-) showed no such lethality (Fig. 3D, panel R2/C5). In the
slt11 background the synthetic lethality of both U6-E and
U6-F was suppressed fully by U2- and U2-, respectively (Fig. 3D,
R4/C2 and R6/C3); both combinations restored the helix II base-pairing
interaction. This genetic complementation is allele specific; i.e., the
other two combinations, U6-E-U2- and U6-F-U2-, remained lethal
in the slt11 background (Fig. 3D, panels R4/C3 and R6/C2,
). The control mutation, U2-, was unable to complement U6-E (Fig.
3D, panel R4/C5) but partially suppressed U2-F (Fig. 3D, panel R6/C5);
this is probably due to extension of helix II by 3 bp in U2 (GGA) and
U6 (UUU) (Fig. 3D, panel R6/C5). The suggestion that Slt11p is
involved in the helix II base-pairing interaction was supported further
by the observation that none of the combinations of U2-, -, and
- with U6-E and -F mutations in the SLT11 background conferred detectable growth defects (Fig. 3D, panels R3/C2, R3/C3, R5/C2, and R5/C3).
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FIG. 3.
Slt11p is involved in U2/U6 helix II interaction in
vivo. (A) Inter- and intramolecular RNA interactions in the yeast
spliceosome. Two conserved intron elements, the 5'-SS and the BPS (BPS
int.), are recognized by U6 and U2 snRNAs, respectively. Both snRNAs
can form two intermolecular base-pairing interactions (helices I and
II) and an intramolecular interaction (Brow stem). (B) Substitution
mutations in the helix II regions of U2 and U6 snRNAs. U2- is a
control mutation. (C) Yeast strains with a double deletion of U2 and U6
genes (top) and a triple deletion of U2, U6 and SLT11
genes (bottom) used in genetic tests. Since SLT11 is not
essential at 30°C, the maintenance plasmid for both strains
contains only wild-type U2 and U6 genes. (D) Genetic interactions
between U2 and U6 snRNA mutations in SLT11 (rows 1, 3, and 5) and slt11 (rows 2, 4, and 6) backgrounds.
Panels a and b show 2-day growth (at 30 and 37°C, respectively) of
the strain with the combination of U2 and U6 snRNA mutations in the
SLT11 background on selective medium in the absence of
the maintenance plasmid. Panels c and d show 2-day growth on
5-FOA-containing medium (at 25 and 30°C, respectively) of the strain
with the combination of U2 and U6 snRNA mutations in the
slt11 background. WT, wild type.
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When U2- and U2- mutations were combined, the resulting 9-nt
substitution, U2-, conferred a growth defect in the
SLT11 strain at 37 and 16°C (10) (Fig. 3D,
panel R1/C4) and was synthetically lethal with slt11
(Fig. 3D, panel R2/C4). The synthetic lethality was suppressed by U6-E
(Fig. 3D, panel R4/C4), although not by U6-F (Fig. 3D, panel R6/C4).
The corresponding mutation in U6 snRNA, U6-EF, in contrast, conferred
lethality by itself (10). This phenotypic asymmetry is due
to an additional intramolecular RNA-RNA interaction in which the helix
II region of U6 snRNA is involved (unpublished observations). We note
that of four combinations in which helix II is partially disrupted by 4 bp, i.e., U2--U6-wt (Fig. 3D, panel R2/C3), U2-wt-U6-F (panel
R6/C1), U2--U6-E (panel R4/C4), and U2--U6-F (panel R6/C5),
three (all but the first) resulted in partial synthetic lethality with
slt11. This indicates that the remaining RNA base-pairing
interaction in these three cases may be sufficient, to various extents,
to maintain the helix II interaction in the absence of Slt11p.
Slt11p binds to RNA in vitro.
The genetic results (Fig. 3D)
suggest that Slt11p is involved in the base-pairing interaction of
U2/U6 helix II. We tested binding of the recombinant Slt11p to a
synthetic RNA that corresponds to U2/U6 helix II (RNA-A) (Fig.
4A) but were unable to detect any
significant binding activity by gel mobility shift (data not shown).
Instead, we found that Slt11p binds to a synthetic RNA that contains
two separate stems (Fig. 4B, lanes 2 to 4, and data not shown). These
results suggested that Slt11p does not bind to helix II per se but that
it binds to helix II in the presence of another stem or helix.
We tested this hypothesis with an array of RNAs in which components of
U2/U6 helix II and U4/U6 stem II were contained either in a single
covalently linked molecule or in separate molecules (Fig. 4A).
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FIG. 4.
RNA-binding activities of Slt11p. (A) Summary of
RNA-binding activities of Slt11p to different synthetic RNAs. Shown on
the top is the base-pairing interaction between the 3' end of U6 snRNA
with the 5'-end regions of U2 and U4 (underlined) snRNAs. The U2/U6
helix II-corresponding interaction is indicated by a grey box and U4/U6
stem II is indicated by an open box. All the synthetic RNAs were made
according to the sequence shown on the top, and potential secondary
structures are drawn on the basis of primary sequence. The 5' end is
indicated by a dot. ++, binding; +/-, weak binding;  , no binding. (B)
RNA-binding activities of Slt11p to RNA-KQ, -N, -Q, -K, and -S. Three
amounts (5, 10, and 20 ng) of Slt11p were tested for binding to
32P-labeled RNA (approximately 1 fmol). In the absence of
Slt11p, all native RNAs ran as two bands in a nondenaturing gel. They
likely represent different RNA conformations. The asterisk in lane 9 indicates a small portion of RNA-Q with a different conformation
resulting from repeated freezing and thawing.
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RNA-KQ (Fig. 4A) contains sequences derived from the 5' end of U2 snRNA
(nt 1 to 24), the 5' end of U4 snRNA (nt 1 to 15), and the 3' end of U6
snRNA (nt 66 to 112), thus corresponding to U2/U6 helix II and U4/U6
stem II (separated by an unpaired region). Binding of
[32P]RNA-KQ to Slt11p was observed (Fig. 4B,
lanes 1 to 4). This binding was competed efficiently by unlabeled
cognate RNA (data not shown). When base pairing was introduced in the
central region that separated the two helical elements (Fig. 4B)
(RNA-N), Slt11p binding was almost entirely abolished (Fig. 4B, lanes 5 to 8). However, the individual introduction of 9-nt substitutions into the U2- or U6-corresponding portions of the chimeric RNA (e.g., RNA-MQ)
(Fig. 4A) had a relatively small effect in reducing the binding of
Slt11p (data not shown). For further characterization of the RNA
requirements for Slt11p recognition and binding, RNA-KQ was divided
into several constituent components (Fig. 4A). Neither RNA-Q nor
-K, corresponding to the individual U6 and U2/U4 portions of RNA-KQ,
respectively, bound to Slt11p sufficiently to be detected by gel shift
(Fig. 4B, lanes 9 to 16). On the other hand, Slt11p bound nearly as
well to RNA-S (corresponding to U4/U6 stem II and to the 3' end of U6
snRNA) (Fig. 4B, lanes 17 to 20). Slt11p did not bind to RNA-U
(corresponding to the 5' end of U2 snRNA) (data not shown). The U4/U6
stem II portion of RNA-KQ and the U2/U6 helix II portion (RNA-H and -A,
respectively) (Fig. 4A) alone also failed to bind to Slt11p (data not shown).
Although Slt11p contains domains that are characteristic of RNA-binding
proteins (Fig. 1C), it does not bind to RNA nondiscriminatingly. Slt11p
does not bind to RNA-N, -Q, -K, -U, -H, and -A (Fig. 4A), some of which
may form single helices (RNA-A and H). It binds strongly to RNAs that
contain two helical regions (RNA-KQ) (Fig. 4A) or one helical region
with another unpaired sequences (RNA-MQ and -S) (Fig. 4A). Although the
identity of nucleotides in the helical region(s) is not important for
Slt11p binding (unpublished observations), the region that separates
two helices seems to be important for Slt11p binding (Fig. 4B, lanes 5 to 8). These results suggest some degree of (structural) specificity
for the RNA-binding activity of Slt11p. It is possible that Slt11p
binds to helix II in the context of another helical element, i.e.,
U4/U6 stem II (Fig. 5A).
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FIG. 5.
RNA-annealing activities of Slt11p. (A) Schematic of the
U2/U6 helix II interaction in association with U4/U6 stem II in
spliceosome assembly. (Top) While the 5'-SS and the BPS are recognized
by conserved elements in U6 (black box) and U2 (grey box) snRNAs, the
5' end of U2 snRNA can interact with the 3' end of U6 snRNA, forming
helix II, prior to the disruption of U4/U6 stem II. (Bottom)
Concomitant formation of U2/U6 helix II and U4/U6 stem II. (B)
Schematic of RNA-annealing assay. Slt11p was first mixed with
32P-labeled RNA (black) and unlabeled RNA (grey) and kept
at 25°C for 20 min; then proteinase K was added, and incubation was
continued for another 15 min. The resulting RNA duplex was then
resolved on a nondenaturing gel. (C) Annealing of RNA-Q-RNA-K duplex.
[32P]RNA-Q was mixed with increasing amounts of unlabeled
RNA-K in the presence or absence of Slt11p in the annealing assay. The
two controls were [32P]RNA-Q alone and mixed with Slt11p.
Increasing amounts of unlabeled RNA-K were mixed with
[32P]RNA-Q in the thermal annealing reaction
(65°C for15 min  42°C for15 min 25°C) (lanes 8 to 11). The
RNA sequences and potential base pairing are shown at the bottom. (D)
Competition of annealing activities. Increasing amounts of unlabeled
RNA-R and -Q or excess amounts of yeast tRNA (t) or control RNA
(transcribed from pBluescript) (p) were added to the annealing assay
(with [32P]RNA-Q, RNA-K and Slt11p) in the beginning.
Lanes 2 to 6, 20-min annealing assay with increasing amounts of Slt11p;
lane 1, [32P]RNA-Q alone.
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Slt11p promotes efficient annealing of cRNAs in vitro.
During
spliceosome assembly, U4 and U6 snRNAs are recruited into the
prespliceosome as a duplex. It is thus unlikely that U4/U6 stem II is
formed de novo in the spliceosome. However, U2 snRNA binds to the BPS
independently of U4/U6 stem II. It is possible that U2/U6 helix II may
form prior to disruption of U4/U6 stem II (Fig. 5A). One possible role
for Slt11p, as suggested by genetic suppression (Fig. 3) and in vitro
RNA binding (Fig. 4), is to facilitate the efficient formation of helix
II in association with U4/U6 stem II. We determined if Slt11p is able
to anneal cRNAs that contain these two elements.
The two RNAs used in the annealing assay, K and Q, can form two
intermolecular helical structures corresponding to U2/U6 helix II and
U4/U6 stem II (Fig. 4A). In this assay,
[32P]RNA-Q was mixed with unlabeled RNA-K and
Slt11p. Proteinase K was added following 20 min of incubation to remove
Slt11p. The formation of RNA duplexes was determined by nondenaturing
gel electrophoresis (Fig. 5B). When increasing amounts of RNA-K were mixed with [32P]RNA-Q in the presence of 20 ng
of Slt11p, efficient annealing was observed (Fig. 5C, lanes 3 to 6).
Although a small amount of spontaneous annealing was observed at a K/Q
ratio of 4:1 (Fig. 5C, lane 7), at a K/Q ratio of 2:1, in the presence
of Slt11p, more than 95% of [32P]RNA-Q was
converted to the Q-K duplex (Fig. 5C, lane 5). This annealing was
nearly complete within 5 min of incubation with Slt11p (data not
shown). The RNA annealing promoted by Slt11p was significantly more
efficient than thermal annealing (Fig. 3B, compare lanes 9 through 11 with lanes 3 through 6; also see Fig. 5D, lanes 3 to 6). This
RNA-annealing activity was confirmed by strong competition for
formation of the duplex by unlabeled cognate RNA-Q, mixed at the start
of the assay (Fig. 5D, lanes 10 to 12). RNA-R, which contains a 9-nt
substitution in the U2-corresponding region (Fig. 5D, lanes 7 to 9),
was a marginally poorer competitor than RNA-Q. Nonspecific RNAs did not
compete (Fig. 5D, lanes 13 and 14, and data not shown). Additional
experiments indicated that the RNA-annealing activity of Slt11p
requires a minimum of 11 consecutive base pairs and that this activity
is not sequence specific (unpublished observations).
We used four pairs of RNAs in various combinations. They represent
wild-type helix II (RNA-K-RNA-Q), disrupted helix II due to a 9-nt
substitution in either U2 snRNA (RNA-M-RNA-Q) or U6 snRNA
(RNA-K-RNA-R), and restored helix II (RNA-M-RNA-R) (Fig. 6A). The intermolecular
interaction corresponding to U4/U6 stem II in all four cases remained
intact. The presence of this interaction was preponderant on the
overall annealing activities of Slt11p (Fig. 6B, compare lanes 7 through 9 and lanes 13 through 15 with lanes 3 through 5 and lanes 17 through 19). When [32P]RNA-Q was mixed with
RNA-M, corresponding to disrupted U2/U6 helix II interaction caused by
the 9-nt substitution in U2 snRNA, the annealing efficiency was reduced
marginally (Fig. 6B, lanes 7 to 9). Furthermore, three complexes, a, b,
and c, were formed by Slt11p (Fig. 6B, lanes 7 to 9). These complexes
probably represent RNA-M-RNA-Q duplexes with different conformations.
They were largely eliminated when helix II-corresponding interaction
was restored (Fig. 6B, lanes 17 to 19). These results suggest that the
9-nt substitution in U2 snRNA not only disrupts the U2/U6 helix II interaction but also introduces a conformational change(s) into the
overall RNA structure(s) in vivo.
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FIG. 6.
Characterization of the RNA-annealing and -binding
activities of Slt11p. (A and D) Sequences and potential base-pairing of
synthetic RNAs used in panels B and C and panels E and F, respectively.
(B and E) Annealing of RNAs by Slt11p. Approximately 1 fmol of
32P-labeled RNAs was mixed with increasing amounts of
unlabeled RNA and 10 ng of Slt11p in the RNA-annealing assay (Fig. 5C).
The resulting RNA duplexes, after proteinase K digestion, were analyzed
in 6% nondenaturing gels. The controls include [32P]RNA
alone, with 10 ng of Slt11p, and with unlabeled RNAs in the absence of
Slt11p. a, b, and c (panel B, lanes 7 to 9) indicate the complexes
formed between RNA-Q and -M with altered configurations. In panel E, U'
indicates RNA-U with a different conformation and mobility. (C and F)
Binding of Slt11p to RNA duplexes formed in B and E, respectively. Approximately 1 fmol of
32P-labeled RNAs was mixed with increasing amounts of
unlabeled RNAs and 100 ng of Slt11p. The mixtures were first incubated
at 25°C for 20 min and kept on ice for another 20 min prior to
loading onto 4% nondenaturing gels. The controls include
[32P]RNAs with unlabeled RNAs only and with 100 ng of
Slt11p only. Note that RNA-K and -M ran as triplets and doublets,
respectively, on nondenaturing gels. The asterisk indicates a
protein-RNA-RNA ternary complex. In panel C, the arrow indicates an RNA
duplex (lanes 1 to 4) observed in lanes 3 to 6 in panel B. Similar
duplexes were not observed in lanes 7 to 9, 12 to 14, or 17 to 19, due
partially to smearing. The formation of the Slt11p-RNA-M-RNA-R
ternary complex is further indicated by the reduction of free RNA-M
(lanes 17 to 19).
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We sought to determine if Slt11p is able to bind to RNA duplexes that
resulted from its own RNA-annealing activity. Although neither RNA-K
nor RNA-Q bound individually to Slt11p (Fig. 4B, lanes 9 to 16), they
formed an RNA duplex in the presence of Slt11p (Fig. 6B, lanes 3 to 6).
When the labeled RNA-K or -M was mixed with unlabeled RNA-Q and Slt11p,
large amounts of labeled RNAs were trapped in the wells (Fig. 6C, lanes
2 to 4, 7 to 9, 12 to 14, and 17 to 19). This is likely due to
aggregation. However, formation of a possible protein-RNA-RNA
tripartite complex (at a relatively low efficiency) was observed when
[32P]RNA-K, RNA-Q, and Slt11p were mixed (Fig.
6C, lanes 2 to 4), since it did not occur in the absence of either
Slt11p (Fig. 6C, lane 1) or unlabeled RNA (Fig. 6C, lane 5). RNA
molecules in which the U2/U6 helix II-corresponding interaction was
disrupted, [32P]RNA-M and RNA-Q, were unable to
form this complex (Fig. 6C, lanes 7 to 9). Failure of RNA-M-RNA-Q and
Slt11p to form this ternary complex is likely due to the alternative
conformations introduced by the mutation in RNA-M (Fig. 6B, lanes 7 to
9). Consistent with this explanation, we observed that restoration of
the helix II-corresponding interaction in RNA-M-RNA-R duplex, which
eliminated complexes a and b (Fig. 6B, lanes 17 to 19), restored (at
least partially) the formation of stable RNA-M-RNA-R-Slt11p complex (Fig. 6C, lanes 17 to 19). On the other hand, when the helix
II-corresponding interaction was disrupted by mutation in the
U6-corresponding RNA (RNA-R), no stable tripartite complex was observed
(Fig. 6C, lanes 12 to 14).
We then tested another set of RNAs for the annealing activity of Slt11p
(Fig. 6D and E). RNA-S contained a helical element corresponding to
U4/U6 stem II and another region corresponding to the 3' end of U6
snRNA (Fig. 6D). When it was mixed with labeled RNA-U, corresponding to
the 5' end of U2 snRNA, in the presence of Slt11p, a stable duplex was
formed (Fig. 6E, lanes 3 to 5). However, when the helix
II-corresponding interaction was disrupted by the 9-nt substitution in
U6 snRNA (in RNA-T), such an RNA duplex was not detected (Fig. 6E,
lanes 7 to 9). These results indicate that Slt11p is able to form a
helical interaction (corresponding to U2/U6 helix II) in the presence
of another preformed helical element (corresponding to U4/U6 stem II).
Furthermore, a tripartite Slt11p-RNA-S-RNA-U complex was detected
when the two RNAs were present in comparable amounts (i.e., at an S/U
ratio of 1/1) (Fig. 6F, lane 3). At a higher S/U ratio, most of the
labeled RNA-U was trapped in the wells (Fig. 6F, lanes 4 and 5). This
aggregation might be caused by the binding of Slt11p to RNA-S (Fig. 4B,
lanes 18 to 20, Fig. 4B) and annealing of labeled RNA-U to excess RNA-S associated with Slt11p. However, when the helix II-corresponding interaction was disrupted, only a small amount of tripartite
Slt11p-RNA-T-RNA-U was detected in the presence of excess RNA-T
(unlabeled) (Fig. 6F, lanes 8 to 10). The RNA substrates shown in Fig.
6D can form two helical elements in a different configuration than
those shown in Fig. 6A. In both configurations, Slt11p is able to
anneal two RNAs and to bind (under the experimental conditions tested)
to the resulting duplex that contains two helical elements. The
integrity of both helical elements seems to be important for the
Slt11p-RNA interaction.
Slt11p forms a homodimer in the absence of RNA.
The formation
of Slt11p-RNA-RNA ternary complexes (Fig. 6C) that contain two
separated helical elements suggests that Slt11p may act as a dimer,
with each subunit interacting with one of the two elements. We used
glycerol gradient sedimentation to determine if the recombinant Slt11p
forms a dimer. We used a mixture of three proteins (BSA, albumin, and
cytochrome c) as molecular weight markers. Following
centrifugation, the sedimentation profile indicated that these proteins
are sufficiently separated to allow detection of an Slt11p dimer.
Slt11p was found in two locations of the gradient, most likely
representing, according to molecular weights, monomer (fractions 30 to
34) and dimer (fractions 20 to 22) forms (Fig. 7). We conclude that Slt11p forms a
homodimer in the absence of RNA. It is possible that in the
spliceosome, one subunit of Slt11p dimer binds to U4/U6 stem II, while
the other subunit (with its RNA annealing activity) promotes the
formation of U2/U6 helix II. The Slt11p dimer then binds to the
resulting U2/U6/U4 complex (see Discussion).
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FIG. 7.
Slt11p forms a homodimer in vitro in the absence of RNA.
An immunoblot of fractions from the glycerol gradient (10 to 40%)
sedimentation of Slt11p probed with rabbit anti-Slt11p antibodies is
shown.
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Slu7p interacts with Slt11p and impairs the RNA binding but not the
annealing activities of Slt11p.
We showed previously that the
original slt11-1 allele is synthetically lethal
with several factors involved in the second splicing step, including
Slu7p (38). Chromosomal deletion of SLT11 also
caused synthetic lethality with slu7-1 and
slt17/slu7-100 (data not shown). In
order to determine direct protein-protein interaction, GST-Slu7p was
produced in E. coli and purified (data not shown). We used
affinity chromatography to determine if Slt11p binds to Slu7p in the
absence of RNA (see Materials and Methods). While it was not detected
in the 0.5 M and 1.0 M NaCl eluates of the GST column (Fig.
8A, lanes 15 and 16), Slt11p, bound to GST-Slu7, was detected in these eluates of GST-Slu7p columns with ligand concentrations of 4 and 2 µg/µl (Fig. 8A, lanes 3, 4, 7, and
8). At a lower ligand concentration (1 µg/µl), most of the bound
Slt11p was eluted with 0.5 M NaCl (Fig. 8A, lanes 11 and 12). These
results demonstrate a direct Slt11p-Slu7p binding that is ligand
concentration dependent and susceptible to high salt concentrations.
Mutations in the Zn finger region of Slt11p that failed to complement
the synthetic lethality of slt11 with
slt17/slu7-100 did not bind to GST-Slu7p in vitro
(unpublished observations). These results suggest that the Slt11p-Slu7p
interaction is important for pre-mRNA splicing.
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FIG. 8.
Slt11p-Slu7p interaction and its effects on RNA-binding
and -annealing activities of Slt11p. (A) Protein-protein interaction
between Slt11p and Slu7p as determined by affinity chromatography.
Western blots of flowthrough (lanes 2, 6, 10, and 14), 0.5 M NaCl
(lanes 3, 7, 11, and 15), 1 M NaCl (lanes 4, 8, 12, and 16), and 1%
SDS (S, lanes 5, 9, 13, and 17) eluates of four minicolumns with the
indicated ligand concentrations were probed with rabbit anti-Slt11p
antibody. (B) Effects of Slu7p on the RNA-binding activity of Slt11p.
Approximately 1 fmol of [32P]RNA-KQ was mixed with
increasing amounts of Slt11p and incubated for 20 min at 25°C; 20 or
40 ng of GST-Slu7p and 20 ng of GST were then added to the mixture and
incubated for another 20 min. The mixtures were then loaded onto 4%
nondenaturing gels. The controls include [32P]RNA alone,
with 20 and 40 ng of GST-Slu7p, and with 20 ng of GST. (For binding of
Slt11p to RNA-KQ, see Fig. 4B, lanes 2 to 4.) (C) Effects of Slu7p on
the RNA-annealing activity of Slt11p. Twenty nanograms of Slt11p was
mixed with 20, 40, or 60 ng of GST-Slu7p and 20 ng of GST and incubated
for 20 min at 25°C. Approximately 1 fmol of [32P]RNA-Q
and 2 mol of RNA-K were then added, and the mixtures were incubated for
another 20 min, after which proteinase K was added for 15 min. The
mixtures were then loaded onto 6% nondenaturing gels. The controls
include [32P]RNA-Q alone, mixed with RNA-K only, or mixed
with RNA-K and 40 or 60 ng of GST-Slu7, 20 ng of GST, and 20 ng of
Slt11p.
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In order to probe the function of this direct protein-protein
interaction, we examined the effects of Slu7p on RNA-binding and
-annealing activities of Slt11p. Slt11p was first incubated with
[32P]RNA-KQ for 20 min, which resulted in
Slt11p binding to the RNA (Fig. 4B, lanes 2 to 4). Different amounts of
GST-Slu7p and GST were then added, and the mixture was incubated for
another 20 min. While GST had no discernible effect on the formation of
the Slt11p-RNA complex (Fig. 8B, lanes 8 to 10), GST-Slu7p almost completely abolished the protein-RNA complex (Fig. 8B, lanes 2 to 7),
suggesting that Slu7p is able to interact with RNA-bound Slt11p and
that this interaction impairs the binding of Slt11p to the RNA. Similar
results were observed when GST-Slu7p was mixed with Slt11p prior to
addition of RNA-KQ (data not shown). In contrast, when
[32P]RNA-Q and RNA-K were added to the
GST-Slu7p-Slt11p mixture (preincubated for 20 min), the annealing of
these two RNAs was not affected by the presence of GST-Slu7p (Fig. 8C,
lanes 8 to 10). The different effects of GST-Slu7p on Slt11p activities
suggest that RNA-annealing and -binding activities are two distinct
biochemical properties associated with different (i.e., monomer and
dimer) (Fig. 9) forms of Slt11p and that
Slu7p binds preferentially to one form of Slt11p that is active in
RNA-binding (see Discussion).
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FIG. 9.
Model for Slt11p function. Slt11p forms a homodimer in
the absence of RNA. One of the subunits recognizes and binds to U4/U6
stem II. The other subunit facilitates the formation of U2/U6 helix II
through its RNA-annealing function. The Slt11p dimer then binds to the
resulting RNA structures with both helix II and stem II to maintain
structural integrity. Stem II is divided by an unpaired bulge into two
parts, including the helix II-proximal part (U4 nt 1 to 11 with U6 nt
70 to 80), which consists of 11 bp. Helix II also contains 11 bp.
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DISCUSSION |
Slt11p, a new splicing factor, is involved in activation of the
spliceosome (Fig. 2). We have shown in this study that recombinant Slt11p binds to RNA (Fig. 4) and that it is able to anneal two RNAs
(Fig. 6B) and, in particular, to form a helical interaction in the
presence of another preformed helical element (Fig. 6E). The protein
can bind to the resulting duplexes if they contain two separated
helical regions (Fig. 6C and F). Furthermore, our genetic results
suggest that Slt11p is involved in the RNA base-pairing interaction of
U2/U6 helix II in vivo (Fig. 3). Taken together, these data suggest
that Slt11p acts in the spliceosome to facilitate the formation of
U2/U6 helix II in association with another helical element, likely
U4/U6 stem II (Fig. 9). This is supported further by the (structural)
requirements for Slt11p binding to RNAs (Fig. 4) and dimerization of
Slt11p (Fig. 7). We also demonstrated that Slt11p and Slu7p interact
with each other both in vivo and in vitro (Fig. 8A) and that Slu7p
exerts different effects on the RNA-binding and -annealing activities
of Slt11p (Fig. 8B and C). We suggest that the function of Slt11p is
regulated by Slu7p in the spliceosome.
The RNA-annealing and -binding activities of Slt11p are two
distinct biochemical properties.
Slt11p is able to anneal a wide
range of cRNAs (Fig. 6B and data not shown), provided that a minimum of
11 consecutive base pairs can be formed (likely to allow detection of
the resulting duplexes in nondenaturing gels). However, its RNA-binding
activity has some degree of (structural) specificity (Fig. 4A). It
requires one helical element (11 bp) and a second single-stranded
region (e.g., RNA-S) (Fig. 4) or helical region (e.g., RNA-KQ) (Fig. 4). Although Slt11p did not bind RNA-K and RNA-Q individually (Fig. 4B,
lanes 9 to 16), it was able to promote the efficient annealing of these
RNAs (Fig. 6B, lanes 3 to 5) and to bind (weakly, under the conditions
tested) to the resulting duplex (Fig. 6C, lanes 2 to 4). Similar
results were observed with another set of RNAs (Fig. 6D, E, and F). In
contrast, Slt11p was able to anneal RNA-M and -Q (resulting in RNA
duplexes with altered configurations(Fig. 6B, lanes 7 to 9) but failed
to bind stably to any of the duplexes (Fig. 6C, lanes 7 to 9). These
results suggest that the RNA-annealing and -binding activities of
Slt11p are two different biochemical properties with different
substrate requirements. It seems that the structural aspects (the
integrity of the two helical elements) (Fig. 6) of the RNA substrates
rather than sequence are the determining factor for the Slt11p-RNA
interactions. Our genetic results suggest the importance of RNA base
pairing rather than sequence per se for SLT11-mediated helix
II interaction in vivo (Fig. 3). Perhaps this is reflected in the lack
of strict specificity for Slt11p activities in vitro (Fig. 4 and 6).
However, it is possible that an additional factor(s) is required in
vivo to maintain the specific SLT11-U2/U6 helix II
interaction and that this factor(s) is absent in vitro.
Slt11p exists in two forms in the absence of RNA (Fig. 7). It is
plausible that the dimer form binds to RNAs with two helical elements
(Fig. 9). We note that the native U4/U6 stem II is divided into two
regions with a single bulge. The region close to the 3' end of U6 snRNA
consists of 11 bp. U2/U6 helix II also contains 11 bp (Fig. 9). It is
possible that the two subunits bind to each element in a similar or
identical fashion. We suggest that the RNA-binding activity of Slt11p
is attributed to its dimer form and the annealing activity to the
monomer (and, perhaps, each subunit of the dimer). The different
substrate specificities of these two activities can be explained as
follows. As an RNA-binding protein (Fig. 1), the Slt11p monomer is able
to anneal RNAs without strong specificity and to bind weakly to RNAs.
Strong and cooperative RNA binding is established when both subunits of
the dimer bind to two helical elements or one helical element along
with a single-stranded region. In particular, Slt11p is able to form,
at low efficiency, a tripartite complex with two RNAs that do not form
proper base pairing (Fig. 6F, lanes 8 to 10). This tolerance of
disrupted base-pairing interaction is consistent with cooperativity of
RNA-binding activity of Slt11p. The different effects of Slu7p on two
activities of Slt11p (Fig. 8B and C) are also consistent with the
interpretation that the RNA-binding and -annealing activities of Slt11p
are two distinct biochemical properties (see below). However, in order to dissect these two activities, it is necessary to test mutant Slt11p
proteins that fail to form dimers for their RNA-binding and -annealing activities.
Slt11p is involved in formation of U2/U6 helix II in association
with U4/U6 stem II.
During spliceosome assembly, after the
U4/U6-U5 tri-snRNP is recruited into the prespliceosome, the resulting
holospliceosome (corresponding to complex A2-1) (32) (Fig.
2B) undergoes a series of RNA conformational rearrangements. The switch
at the 5'-SS (31) is followed immediately by disruption of
U4/U6 stem I (15). The U6 portion of stem I is involved in
U2/U6 helix I interaction (18). The mutual exclusion of
U4/U6 stem I and U2/U6 helix I indicates that formation of the latter
must follow unwinding of the former. By the same reasoning, the Brow
stem forms following the disruption of U4/U6 stem II. On the other
hand, it is possible to form U4/U6 stem II and U2/U6 helix II
interactions concomitantly (Fig. 5A and 9). Our genetic study (Fig. 3)
suggests that Slt11p is involved in the base-pairing interaction of
U2/U6 helix II. The biochemical properties of recombinant Slt11p (see
above) suggest that the protein binds to an RNA that resembles
preformed U4/U6 stem II with the 3' end of U6 snRNA (RNA-S) (Fig. 4A
and B, lanes 18 to 20) and that anneals another short RNA
(corresponding to the 5' end of U2 snRNA, RNA-T) to this RNA (Fig. 6E,
lanes 3 to 5). The outcome of this process is reminiscent of formation
of U2/U6 helix II in association with (preformed) U4/U6 stem II (Fig. 9). We suggest that Slt11p acts as a dimer in the splicing process. During spliceosome assembly, one subunit of the Slt11p dimer may recognize U4/U6 stem II and anchor the dimer to the site of its action.
The RNA-annealing activity of the other subunit may facilitate the
formation of U2/U6 helix II. The dimer may then bind to the resulting
RNA structure (Fig. 9).
Our preliminary biochemical data also suggest that Slt11p (dimer) binds
to two separated helical elements cooperatively (Fig. 6F and
unpublished observations). The genetic data (Fig. 3) are consistent
with this notion of cooperativity. In the presence of Slt11p, most
mutations in the helix II regions of both U2 and U6 snRNAs confer no or
mild growth defects (Fig. 3) (10, 38). The only exceptions
are the 9-nt (U6-E+F) (Fig. 3B) and 11-nt substitutions in the helix II
region of U6 snRNA; these confer lethality by themselves
(10). This is due to disruption of helix II and an
intramolecular U6 interaction, in both of which the 3' end of U6 snRNA
is involved (unpublished observations). The tolerance of 4- and 5-nt
substitutions of both U2 and U6 snRNAs and a 9-nt substitution of U2
snRNA (Fig. 3) suggests that in the presence of a proper (i.e.,
wild-type) U4/U6 stem II, dimeric Slt11p is able to form an imperfect
U2/U6 helix II (in association with U4/U6 stem II) (Fig. 6F). Slt11p
can be viewed as an RNA chaperone that maintains the structural
integrity of RNA interactions, in addition to other activities. Its
function is not essential for viability at permissive temperatures but
is manifested when the integrity of the helix II interaction is
compromised. This is demonstrated by synthetic lethality of
slt11 with all these 4-nt and 5-nt substitution mutations
in both U2 and U6 snRNAs and by allele-specific and mutual genetic
suppression when helix II is restored (Fig. 3). However, it remains to
be determined if mutations in the stem II region of U4 snRNA interact
genetically with slt11 and mutations in the helix II
region of both U2 and U6 snRNAs.
Wassarman and Steitz (35) detected a psoralen-cross-linked
trimolecular U2/U4/U6 snRNA complex in HeLa cell nuclear extract. Two
forms of the U2/U6 helix II interaction were observed. The first occurs
in the relatively abundant snRNP complexes that sediment at >150S
(containing all five spliceosomal snRNAs) in the absence of pre-mRNA
substrate. This corresponds to the concomitant formation of the two
intermolecular interactions of U2/U6 helix II and U4/U6 stem II, as
suggested by Brow and Vidaver (4). The second form occurs
in the S100 fraction and is dependent on the splicing reaction (36), which corresponds to de novo formation of helix II
in the spliceosome assembly. It remains to be determined if helix II
forms with stem II in the absence of pre-mRNA substrate in yeast. If it
does, the existence of such a preassembled U2/U6/U4 snRNA complex (with
or without U5 snRNA) may indicate an alternative pathway for
spliceosome assembly in which the multi-snRNP complexes are recruited
into the commitment complex in a single step. A large native complex
containing all five snRNPs has been identified in yeast extracts in the
absence of pre-mRNA (26). Regardless of the physiological
relevance of this large complex to pre-mRNA splicing in vivo, the
concomitant formation of U2/U6 helix II and U4/U6 stem II is
topologically possible in the yeast spliceosome (Fig. 5A and 9). We
note that Prp24p, another RNA-binding protein, is involved in formation
of U4/U6 di-snRNP (11, 12, 27). Prp24p may also facilitate
the formation of U2/U6 helix II. If so, it may explain why Slt11p is
not essential at 30°C but is required, as an RNA chaperone (see
above), for maximum efficiency of splicing and spliceosomal activation
(Fig. 2).
Slu7p regulates the function of Slt11p in the spliceosome.
The
concomitant formation of helix II and stem II raises the question of
how they are unwound prior to the splicing reaction. Another factor
identified in our genetic screen, Slt22p (or Brr2p), has been
implicated in the unwinding of the U4/U6 duplex (26) and
U2/U6 helix II (reference 37 and unpublished
observations). Another question of concern is the dissociation of
Slt11p from stem II and helix II. Slu7p may be involved in regulating
this process.
Slu7p was identified in our genetic screen as Slt17p. Both
slu7-1 and
slt17/slu7-100 are synthetically
lethal with mutations in the helix II region of U2 snRNA
(38) and slt11 (see Results). The direct
protein-protein interactions between the Slt11p dimer and Slu7p (Fig.
8A) (unpublished observations) and the inhibitory effect of this on the
RNA-binding activity of Slt11p (Fig. 8B) suggest that one of the
functions of Slu7p is to dissociate the Slt11p dimer from stem II and
helix II. As discussed above, the RNA-annealing and -binding activities
of Slt11p might be attributed to the monomeric and dimeric forms of
Slt11p, respectively. If so, the inhibition of Slt11p RNA binding by
Slu7p is due to interaction with the dimer form of Slt11p, whereas the
RNA annealing activity of the Slt11p monomer is largely unaffected by
Slu7p. We have observed that mutant Slt11p proteins that fail to form
dimers also fail to bind the RNA substrates tested in this study. When tested, they do not interact with Slu7p in vitro (unpublished observations). These results are consistent with our interpretations. Although Slu7p is a second-step splicing factor (5), its
interaction with Slt11p may occur prior to the first step. If so, the
Slt11p dimer dissociates from helix II and stem II after Slu7p binds to
it during spliceosomal activation. The two RNA duplexes can then be
unwound by Slt22p. The Slt11p-Slu7p interaction may persist through
both steps of splicing. It is possible that Slt11p plays an additional
role(s) in both the first and second steps.
| |
ACKNOWLEDGMENTS |
We thank Michael Costanza, Quoc Hugnh, and Shou-Jiang Tang for
their technical assistance, B. Blencowe, D. Jansma, M. Kober, C. Köth, V. Lay, J. Li, A. MacMillan, and W. Rice for their advice and suggestions during the course of this study, and members of the
Friesen lab, present and past, for their support. D.X. thanks Peggy M. Pasternak and Yiming Xu for their support and stimulating discussion.
This research was supported by the National Cancer Institute of Canada
and the Medical Research Council of Canada.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Banting and Best
Department of Medical Research and Department of Molecular and Medical Genetics, University of Toronto, 112 College St., Toronto, Ontario, Canada M5G 1L6. Phone: (416) 946-3016. Fax: (416) 978-8528. E-mail: james.friesen{at}utoronto.ca.
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Molecular and Cellular Biology, February 2001, p. 1011-1023, Vol. 21, No. 4
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.4.1011-1023.2001
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Abstract
Introduction
