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Molecular and Cellular Biology, March 2000, p. 2176-2185, Vol. 20, No. 6
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Functional Cus1p Is Found with Hsh155p in a Multiprotein Splicing
Factor Associated with U2 snRNA
Michelle Haynes
Pauling,1
David S.
McPheeters,2 and
Manuel
Ares Jr.1,*
Department of Biology and the Center for Molecular Biology
of RNA, Sinsheimer Laboratories, University of California, Santa
Cruz, Santa Cruz, California 95064,1 and
Department of Biochemistry and the Center for RNA Molecular
Biology, Case Western Reserve University, School of Medicine,
Cleveland, Ohio 441062
Received 27 July 1999/Returned for modification 9 September
1999/Accepted 17 December 1999
 |
ABSTRACT |
To explore the dynamics of snRNP structure and function, we
have studied Cus1p, identified as a suppressor of U2 snRNA
mutations in budding yeast. Cus1p is homologous to human SAP145, a
protein present in the 17S form of the human U2 snRNP. Here, we
define the Cus1p amino acids required for function in yeast. The
segment of Cus1p required for binding to Hsh49p, a homolog of human
SAP49, is contained within an essential region of Cus1p. Antibodies
against Cus1p coimmunoprecipitate U2 snRNA, as well as Hsh155p, a
protein homologous to human SAP155. Biochemical fractionation of
splicing extracts and reconstitution of heat-inactivated splicing
extracts from strains carrying a temperature-sensitive allele of
CUS1 indicate that Cus1p and Hsh155p reside in a
functional, high-salt-stable complex that is salt-dissociable from U2
snRNA. We propose that Cus1p, Hsh49p, and Hsh155p exist in a stable
protein complex which can exchange with a core U2 snRNP and which
is necessary for U2 snRNP function in prespliceosome assembly. The
Cus1p complex shares functional as well as structural similarities with
human SF3b.
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INTRODUCTION |
Pre-mRNA splicing is catalyzed by a
large ribonucleoprotein complex called the spliceosome. Several RNA
molecules and many proteins are essential for splicing, assisting in
spliceosome assembly, spliceosome activation, and conformational
rearrangements before the actual transesterification reactions occur.
An ordered assembly pathway for the construction of the spliceosome,
including numerous points at which ATP hydrolysis is required, provide
a rich sequence of biochemical events that is carried along in part by
the action of splicing proteins (for reviews, see references 29 and 39).
Proteins that act during splicing have been identified by both
biochemical and genetic means. In mammalian systems, splicing proteins
have operationally been classified as small nuclear ribonucleoprotein particle (snRNP) proteins (that remain associated with a particular snRNA during biochemical fractionation) or splicing factors (that are transiently associated with snRNAs) (29, 39). Upon
closer inspection, a number of splicing proteins cannot be classified by this simple operational distinction. For example, two multimeric protein factors required for prespliceosome assembly in mammalian cell
extracts, SF3a and SF3b, can be separated from snRNAs and purified
as discrete protein complexes that function in prespliceosome assembly
(13, 28). Surprisingly, SF3a and SF3b subunits comprise seven of the nine salt-dissociable proteins identified in the 17S form
of the U2 snRNP, the form that is recruited to the pre-mRNA during
spliceosome assembly (8, 12, 30). The SF3a and SF3b proteins
are also found in preparations of assembled spliceosomes, and most can
be cross-linked to regions near the pre-mRNA branch point within the
assembled spliceosome (10, 20, 38). The SF3a polypeptides
are SAP61, SAP62, and SAP114, and the four known SF3b polypeptides are
SAP49 SAP130, SAP145, and SAP155 (reviewed in reference
29). Thus, SF3a and SF3b are protein complexes with
biochemical characteristics of splicing factors but which associate
specifically with the free U2 snRNP under splicing conditions and
remain as part of the spliceosome after U2 snRNP has been recruited. The SF3b proteins are also associated with the minor spliceosome, which has the U12 snRNP in place of U2 snRNP
(44).
In contrast, Saccharomyces cerevisiae splicing factors have
been discovered mainly through genetic approaches but have led independently to a similar set of proteins (29, 39). For
example, PRP9 and PRP11 were identified among
Hartwell's original temperature-sensitive mutations (originally called
RNA9 and RNA11 [24]), and
PRP21 was identified as a suppressor of prp9-1
(17), as well as in a search for temperature-sensitive
splicing mutations (4, 40). The products of these three
genes are similar to human SF3a subunits: Prp21p corresponds to SAP114,
Prp9p corresponds to SAP61, and Prp11p corresponds to SAP62 (29,
39). Identification of yeast proteins similar to human SF3b
subunits has occurred more recently, aided by the completion of the
yeast genome. Cus1p was identified genetically by its ability to
suppress U2 snRNA mutations and is similar to human SAP145
(19, 43). Hsh49p is an essential yeast protein homologous to
SAP49 (26). A yeast protein similar to SAP155, which we
refer to here as Hsh155p, has been identified (18, 37, 41).
Rse1p is a conserved protein associated with the U2 snRNP
(16) and is structurally related to human SAP130 (16,
18). The sequence similarities between the yeast proteins and
their mammalian counterparts, as well as several examples of parallel
protein-protein interactions (26, 29), have led to the
hypothesis that these proteins function in a similar fashion in both
yeast and mammals. Although numerous protein-protein interactions (18), phosphorylation events (41), and
protein-RNA cross-links (19) have been described, exactly
how human SF3b promotes spliceosome assembly and splicing remains mysterious.
In this study, we focus on Cus1p and provide evidence that the minimum
portion of Cus1p required for viability in yeast contains the region of
significant homology to human SAP145. The part of Cus1p required for
binding to Hsh49p is contained within this essential conserved region
but does not include the amino acid altered in the U2 suppressor
protein Cus1-54p. Cus1p is physically associated with a fraction of U2
snRNA in splicing extracts and is efficiently associated with
Hsh155p, the yeast protein similar to SAP155. Pre-mRNA becomes
detectably associated with Cus1p before the first step of splicing and
remains associated through the second step. Biochemical complementation
studies using heat-inactivated splicing extracts from a cus1
temperature-sensitive mutant demonstrate that Cus1p functions as part
of a protein complex which includes Hsh155p. This Cus1p complex
dissociates from the U2 snRNP in a salt-sensitive fashion. These
experiments reveal significant functional similarities between the
Cus1p complex and human SF3b and suggest that the roles of these
proteins in the function of the branch point binding snRNPs are
similar in the yeast and human major and minor spliceosomes.
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MATERIALS AND METHODS |
Plasmid constructs.
All recombinant DNA manipulations were
carried out as described previously (6). Yeast manipulations
were also carried out in accordance with standard techniques
(21). To create the CUS1 deletion series clones,
an NdeI site was generated at the Cus1p start codon by
site-directed mutagenesis (31) to make pRS314-CUS1Nde. Oligonucleotides containing NdeI (N termini) or
XhoI (C termini) restriction sites were used to produce
deletions of CUS1 with start and stop codons at the desired
positions by PCR. These plasmids were transformed into a
cus1::HIS3 knockout strain carrying wild-type CUS1 on a URA3 plasmid (43).
Transformants that arose on synthetic complete dextrose medium
(SCD)-His-Trp plates were replica plated onto 5-fluoroorotic acid
(5-FOA)-Trp-His to check viability at different temperatures.
Temperature-sensitive cus1 allele.
A fragment
spanning the open reading frame of CUS1 was amplified by
mutagenic PCR (14). The PCR product was cotransformed into
the cus1::HIS3 knockout strain along with a gapped
linear fragment carrying pRS314-CUS1 without a coding region, in order that functional pRS314-CUS1 could only be regenerated by incorporation of a mutagenized copy of the CUS1 coding region.
Transformants were replica plated onto 5-FOA to select for cells that
had lost the URA3 plasmid. Cells that grew on 5-FOA were
replica plated at different temperatures. DNA was recovered from
colonies unable to grow at 34°C, and temperature-sensitive phenotypes
were verified by retransformation and testing for temperature-sensitive
in vitro splicing defects. One plasmid, designated cus1-3,
carries 14 mutations in the CUS1 coding region that predict
10 amino acid substitutions (see Fig. 1A).
Two-hybrid assay.
The pACT2-CUS1 fusion plasmid, the
pAS2-HSH49 fusion plasmid, and the URA3 control plasmids
were as described previously (26). Deletions of
CUS1 within the pACT2-CUS1 plasmid were made by utilization of restriction sites that maintained the open reading frame of the
fusion. Pairs of constructs were cotransformed into yeast strain Y190
(7, 23). Multiple transformants from each pairwise combination of plasmids were streaked on a grid, grown and overlaid with 0.5% agarose-0.5 M NaPO4 (pH 7.0)-0.1% sodium
dodecyl sulfate (SDS)-2% dimethyl formamide-0.2% (wt/vol) X-Gal
(5-bromo-4-chloro-3-indolyl-
-D-galactopyranoside), and
incubated at 37°C.
Protein-protein interactions.
Regions of Cus1p that
interacted with Hsh49p in two-hybrid assays were cloned into pET24b
(Novagen). Expression of these Cus1p fragments in Escherichia
coli BL21 was confirmed by Western blot analysis (22).
pGEX2t-Hsh49p was subcloned as previously described (26).
The proteins were extracted after induction and incubation at 30°C
for 3 h as previously described (26). Expression of glutathione S-transferase (GST)-Hsh49p and GST was checked
by Western blot analysis utilizing anti-GST monoclonal antibody (gift from Santa Cruz Biotechnology). The in vitro protein-protein
interaction assay was performed essentially as described previously
(26).
Protein purification and polyclonal antibody production.
The
CUS1 coding sequence was amplified with an NdeI
site at the start codon and cloned into pET24b to produce an untagged protein. The plasmid was transformed into the E. coli strain
BL21, and colonies were screened for optimal protein production.
Cultures were grown to an A595 of 0.6 and
induced with 10 mM IPTG
(isopropyl--D-thiogalactopyranoside) for 3 h at
37°C. Cells were pelleted by centrifugation and resuspended in 0.1 volume of HK100 (0.05 M HEPES [pH 7.5], 100 mM KCl) buffer. Triton-X
(to 0.1%) and lysozyme (to 0.1 mg/ml) were added, and the mixture was
incubated at 30°C for 20 min, put on ice, sonicated, and centrifuged
at 10,000 rpm for 10 min at 4°C in a Sorvall SS-34 rotor. The lysate
was loaded onto cation-exchange resin Bio-Rex70 (Bio-Rad), washed with
5 column volumes of HK100 and then 2 volumes of HK400 (0.05 M HEPES
[pH 7.5], 400 mM KCl), and eluted with HK700 (0.05 M HEPES [pH
7.5], 700 mM KCl). Approximately 90% purification was achieved with
this protocol. Protein was concentrated with Centriprep30s (Amicon) and
loaded onto a 10% denaturing Tris-glycine acrylamide gel. Side strips
of the gel were stained with Coomassie blue dye to locate the protein.
The strip of gel containing Cus1p was cut out, and protein was
electroeluted and injected into a rabbit (22). Polyclonal
anti-Cus1p antibody was affinity purified by binding rabbit serum to
denatured recombinant Cus1p on nitrocellulose strips, washing, and
eluting bound antibody with glycine (22). The antibody was
determined to be specific for Cus1p through detection of recombinant
Cus1p, native yeast Cus1p, and Cus1p-His6 in whole-cell extracts of yeast by Western blotting (data not shown).
Immunoprecipitation and Western blotting.
Immunoprecipitation experiments were performed essentially as described
before (42). Protein A-Sepharose was preswollen in HK150
(0.05 M HEPES [pH 7.5], 150 mM KCl) or HK200 (0.05 M HEPES [pH
7.5], 200 mM KCl) buffer overnight at 4°C, and 400 µl of a 50%
slurry was incubated with preimmune serum or anti-Cus1p serum for
3 h at 4°C. Beads were washed three times with HK150 with 5-min
incubations on ice between washes. Aliquots of 50% slurry (40 µl)
were incubated with 100 µl of yeast splicing extract or yeast protein
preparation (6) and incubated at 4°C for at least 3 h. Beads were collected and washed three times in HK150 as described
above. Proteins were eluted by suspension in 20 µl of SDS loading dye
and separated on SDS-10% polyacrylamide gels.
Western blots (22) were blocked in 3% bovine serum albumin
in Tris-buffered saline-Tween (TBST) for 30 min at room temperature, probed with primary antibody in the same solution for 1 h at room temperature and washed in TBST for 30 min, and then secondary antibody
was added for 1 h at room temperature. Blots were washed in TBST,
and proteins were visualized with 5-bromo-4-chloro-3-indolyl phosphate-nitroblue tetrazolium (NBT-BCIP). Anti-Cus1p antibody was
used at a dilution of 1:10,000 for detection of Cus1p. Monoclonal antibody 9E10 directed against the myc epitope (gift from Santa Cruz
Biotechnology) was used at a dilution of 1:2,000 for detection of
Hsh155-Mycp.
Immunoprecipitated snRNA was isolated by the addition of 200 µl
of RNA elution buffer (0.3 M Na acetate [pH 5.2], 0.2% SDS,
1 mM
EDTA, 10 µg of proteinase K/ml) to the beads and incubation
at 65°C
for 10 min, followed by phenol extraction and ethanol
precipitation.
Primer extension was performed as described previously
(
45)
with oligonucleotides complementary to U1, U2, U4, U5,
and U6
snRNAs.
Association of Cus1p with pre-mRNA was evaluated by
coimmunoprecipitation of pre-mRNA with anti-Cus1p antibody. Splicing
reaction
mixtures were incubated for 20 min at 23°C and added to
protein
A-Sepharose prebound to anti-Cus1p antibodies or preimmune
serum
from the same rabbit as described previously (
42).
Splicing extract preparation, splicing, and complex
formation.
Extract preparation was performed as previously
described (43). Strains were grown at 26°C until
saturation, diluted to an A600 of 0.05, and
grown to an A600 of 2.8 to 3.5. Splicing assays
(43) and oligonucleotide ablation (33, 42) were
performed as previously described.
Fractionation of yeast splicing extracts.
Chromatography of
splicing extracts on a Superose6 gel filtration column (Pharmacia) was
done as follows: 500 µl of splicing extract was run through a Spin-X
100 column to remove aggregated proteins. This filtrate was passed over
the Superose6 column with a flow rate of 0.2 ml of buffer D150 or D500
(buffer D with 150 or 500 mM KCl) per ml, with collection volumes of
0.5 ml. Fractions were concentrated to 200 µl with Microcon10
centrifugal concentrators (Amicon). Even-numbered fractions were
assayed for Cus1p and Hsh155-mycp by gel electrophoresis and Western
blotting. To test for Cus1p activity, an aliquot of splicing extract
from the temperature-sensitive cus1-3 strain was heat
inactivated at 36°C for 1 h and placed on ice. Then, 2 µl of
each fraction was added to 2 µl of heat-inactivated cus1-3
extract in a 10-µl splicing reaction volume and incubated for 30 min
at room temperature. Extracts were derived from wild-type strain HI227
(43), the cus1-3 strain described above, and a derivative of strain EJ101 (27) carrying Hsh155-mycp, the
product of an allele of HSH155 (also called ySAP155) with 13 C-terminal copies of the myc tag. This last strain was constructed by
the PCR tagging method of Longtine et al. (32).
| |
RESULTS |
Essential Cus1p amino acids correspond to those shared among
Cus1/SAP145 family members.
Cus1p is similar to SAP145 from humans
(19, 43), as well as proteins predicted from cDNAs derived
from Caenorhabditis elegans and Arabidopsis
thaliana (Fig. 1A). The region
of homology between the yeast and metazoan proteins comprises
approximately 200 amino acids and is about 43% identical and 65%
similar at positions shared by all. To explore the relationship between
this structural conservation and the functional requirement for Cus1p in growth and splicing (43), we defined the region of
CUS1 required for viability in yeast. A series of partial
CUS1 deletions was tested for their ability to rescue a
lethal cus1::HIS3 knockout allele (Fig. 1A and data not
shown). Whereas an N-terminal deletion to amino acid 121 rescues a
lethal CUS1 disruption, further deletion to position 171 does not. Deletion of the carboxy-terminal 40 amino acids (to residue
392) rescues the cus1::HIS3 disruption, but deletion
past residue 368 is lethal. Nearly half of the last 59 residues of
Cus1p are acidic (23 are E or D) (Fig. 1A). The nonlethal deletion to
position 392 removes 12 of these. The lethal deletion to position 368 removes additional glutamate residues that are shared among all family
members (Fig. 1A). Therefore, the elements of Cus1p required for normal
growth are contained within amino acids 121 to 392 and correspond to
the most highly conserved region of Cus1p. We conclude that the
conserved elements of Cus1p structure are required for function in
yeast and likely in metazoans as well.
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FIG. 1.
Structure and function of Cus1p. (A) Alignment
of Cus1p amino acid sequence with those of Cus1p/SAP145 family members
from metazoans. Scere, yeast Cus1p; Celeg, C. elegans
(GenBank accession no. AAB69931); Hsapi, human SAP145 (Swissprot
accession no. Q13435) (19); Athal, Arabidopsis
(EMBL accession no. CAB36810). Black boxes indicate identity; grey
boxes indicate similarity. Searches used BLAST (3), and
alignment was performed by CLUSTALW (25). Positions of the
smallest viable deletions (+) and the largest lethal deletions ( ) are
indicated below the yeast sequence. An asterisk marks the position of
the Cus1-54p suppressor mutation E181K. Letters below the yeast
sequence indicate predicted amino acid substitutions in the
cus1-3 allele. The Hsh49p interaction domain is indicated
between positions 229 and 311. (B) An 82-amino-acid region of Cus1p is
necessary for the interaction with Hsh49p in the two-hybrid system.
Amino-terminal deletions of Cus1p to amino acid 229 (229-437) can
interact with Hsh49p, although the deletions produce a dominant
negative growth defect (asterisk). Carboxy-terminal deletions to amino
acid 311 (1-311) also support an interaction. Interaction is
indicated by blue color (shown as dark shading on the figure)
accumulating on the yeast patches after application of X-Gal. The
229-311 region of Cus1p alone is unable to support this interaction in
this system (229-311). None of the constructs interacted with the
Ura3p control. See panel A for position of the deletion end points. (C)
Cus1p and a Cus1p fragment containing amino acids 171 to 311 bind
Hsh49p. Pulldown studies were performed with GST or GST-Hsh49p and
either recombinant Cus1p or a region of Cus1p containing the amino
acids between positions 117 and 311. Recombinant extracts were mixed in
a pairwise manner and then purified with glutathione agarose.
Associated proteins were eluted with reduced glutathione, run on a 10%
polyacrylamide gel, transferred, and blotted with anti-Cus1p antibody.
Pairwise combinations are as follows: lane 1, GST plus pET24b (empty
vector); lane 2, GST plus Cus1p; lane 3, GST plus Cus1p amino acids 171 to 311 (aa171-311); lane 4, GST-Hsh49p plus pET24b; lane 5, GST-Hsh49p plus Cus1p; lane 6, GST-Hsh49p plus Cus1p aa171-311. See
panel A for position of the deletion end points.
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A distinct region of Cus1p is required for the interaction with
Hsh49p.
Full-length Cus1p binds Hsh49p both in vivo and in vitro
(26). To map the region of Cus1p required for the
interaction with Hsh49p, we used the two-hybrid system (7, 11,
34) and verified our findings by an in vitro protein binding
assay (see below). GAL4-DNA binding domain-Hsh49p fusion protein was
expressed with different segments of CUS1 fused to the GAL4
activation domain in yeast carrying a GAL-regulated lacZ
gene, and -galactosidase activity was assayed on plates (Fig. 1B).
The derivatives containing amino acids 1 to 311 or 229 to 437 of Cus1p
are sufficient for the interaction with Hsh49p (Fig. 1B; region marked
on Fig. 1A), suggesting that the 82 amino acids between positions 229 and 311 represent the Hsh49p interaction domain of Cus1p. Although
neither construct expressed separately or with other constructs
produced a growth defect, the specific pair of two-hybrid plasmids
expressing the GAL4 DNA binding domain-full-length
HSH49 fusion and the GAL4 activation domain fused
to amino acids 229 to 437 of Cus1p demonstrated a severe dominant
negative growth defect (and produced strong lacZ reporter
expression) (Fig. 1B). The construct containing only amino acids 229 to
311 failed to support the two-hybrid interaction with Hsh49p,
suggesting that either the Hsh49p interaction region of Cus1p requires
the support of other Cus1p elements or that this particular fusion
protein is unstable or incorrectly folded. The region of Cus1p altered
in the Cus1-54p suppressor protein (position 181) is not required for
interaction with Hsh49p (Fig. 1B), suggesting that the mechanism of
suppression does not directly involve changes in association of these
subunits with each other.
To confirm that the two-hybrid results reflect physical interactions,
we tested the ability of recombinant derivatives of
Cus1p to bind a
GST-Hsh49p protein in vitro. Since expression
of a Cus1p fragment
representing residues 229 to 311 was not detectable
in
E. coli, we used a slightly larger segment spanning residues
171 to
311 (Fig.
1A). Association of Cus1p with Hsh49p was assessed
by binding
to glutathione agarose loaded with either control GST
(Fig.
1C, left)
or the GST-Hsh49p fusion (Fig.
1C, right) and
detected by Western
blotting of bound material probed with an
anti-Cus1p antibody (see
Materials and Methods). Proteins representing
full-length Cus1p (lanes
2 and 6) or the Cus1p region spanning
residues 171 to 311 (lanes 3 and
7) were not detected when incubated
with GST (lanes 1 to 3) but were
readily detected after incubation
with GST-Hsh49p (lanes 6 and 7). This
demonstrates that the region
of Cus1p containing amino acids 171 to 311 is sufficient for the
interaction with Hsh49p, and we conclude that
this region contains
the Cus1p element required for binding to Hsh49p.
This region
is conserved in the metazoan members of the Cus1/SAP145
family
(Fig.
1A), suggesting that the structure of the interface
between
these two subunits is conserved. In Hsh49, this interaction
involves
predominantly the first of two RNA recognition motifs
(
26).
A fraction of U2 snRNA is bound to Cus1p in splicing
extracts.
As a suppressor of a cold-sensitive U2 snRNA
mutation, Cus1p has clear functional association with U2 RNA. To
determine whether Cus1p is physically associated with U2 or other
snRNAs, yeast extracts were immunoprecipitated with anti-Cus1p
antibody and examined for the presence of snRNAs by primer
extension (Fig. 2A). Only a fraction of
U2 snRNA is associated with Cus1p in splicing extracts (Fig. 2A,
lane 3), and the association is specific, since preimmune serum did not
precipitate U2 snRNA (lane 2). The amount of U2 snRNA in the
precipitate is less than 10% of that present in the extract, even
though the antibody recovers >90% of the input Cus1p as determined by
Western blotting of the immunosupernatant (data not shown). This
indicates that only a fraction of total U2 snRNA is
immunoprecipitable with Cus1p antibody at 150 mM KCl. Anti-Cus1p
antibody also reproducibly precipitates small amounts of U1, U5, and U6
that are not recovered in the preimmune control (compare lanes 2 and
3). This is consistent with the presence of endogenous spliceosomal
complexes in the extract and the fact that anti-Cus1p recognizes the
spliceosome (see below).
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FIG. 2.
Anti-Cus1p antibody coimmunoprecipitates U2 snRNA,
Hsh155p, and the intermediates and products of splicing. (A) Anti-Cus1p
antibody coimmunoprecipitates U2 snRNA. Splicing extracts were
incubated with prebound anti-Cus1p serum or preimmune serum. Bound RNA
was washed and eluted. Primer extension analysis with primers
complementary to U1, U2, U5, and U6 snRNAs was performed. Lane 1, total RNA; lane 2, preimmune serum; lane 3, anti-Cus1p; lane 4, end-filled Sau3A fragments of pUC13 as markers. Extension
products from the U snRNAs are indicated at the left. (B)
Anti-Cus1p antibodies specifically coimmunoprecipitate Hsh155p, the
yeast homologue of the human SF3b subunit SAP155. Yeast splicing
extract was made from a strain with Hsh155p tagged with the myc
epitope. Extract was incubated with protein A-Sepharose-bound
anti-Cus1p serum or preimmune serum and washed, and associated proteins
were removed and loaded on a 10% polyacrylamide gel, transferred, and
blotted with monoclonal anti-myc antibody. Lane 1, total extract (20%
of input for lanes 2 and 3); lane 2, anti-Cus1p antibody; lane 3, preimmune serum; lane 4, protein markers. (C) Anti-Cus1p antibodies
coimmunoprecipitate pre-mRNA substrate, intermediates, and products of
splicing. Splicing reaction mixtures were incubated either with (lane
4) or without (lanes 1 to 3 and 5) preincubation of extract with a U2
snRNA-complementary oligonucleotide. Reaction mixtures were
immunoprecipitated with anti-Cus1p serum (lanes 3 and 4), preimmune
serum (lane 2), or anti-hemagglutinin antibody (lane 5). Bound RNA was
then extracted and run on a 6% denaturing acrylamide gel. Lane 1 contains RNA from 20% of the input used in the immunoprecipitations
for the other lanes.
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To determine whether the number of Cus1p molecules might be limiting
for the immunoprecipitation of U2 snRNA, we used Western
blotting
and known amounts of recombinant Cus1p to estimate the
number of Cus1p
molecules per yeast cell (data not shown). This
analysis indicates that
there are approximately 2,000 molecules
of Cus1p per cell. To estimate
the number of U2 snRNA molecules
in the cell, we compared the ratio
of a U2 snRNA primer extension
product from a known number of cells
to a known amount of a synthetic
(T7) mutant U2 snRNA able to
produce a different primer extension
product (C121U
[
5]). This indicates that there are approximately
500 molecules of U2 snRNA in a yeast cell, a number that is consistent
with a previous general estimate of snRNA content by Northern
blotting (
35). Given this, we can at least conclude that
limiting
Cus1p does not explain the inefficient precipitation of U2
snRNA.
We suggest that the specific interaction between Cus1p and
U2
snRNA may be restricted to a functional subset of molecules,
their
association may be salt labile, or
both.
A substantial fraction of Hsh155p is associated with Cus1p in
splicing extracts.
Identification of a yeast homolog of SAP155
(37, 41) prompted us to ask whether this protein is
associated with Cus1p. Although called ySAP155 or ySAP110 by other
workers, the designation SAP is in use for other yeast genes not
involved in splicing. We refer to this gene as HSH155 (for
human SAP homolog 155). The gene is essential (18); however,
a strain carrying an HSH155 gene with 13 C-terminal copies
of the myc epitope is viable, and splicing extracts made from the
tagged strain are active (data not shown).
To determine whether Hsh155p is associated with Cus1p, we
immunoprecipitated splicing extracts from the strain carrying the
HSH155-myc gene with anti-Cus1p antibody and evaluated the
presence
of tagged Hsh155p by Western blotting with anti-Myc antibody
(Fig.
2B). To evaluate the fraction of myc-tagged Hsh155p associated
with Cus1p, we used an aliquot of the total extract equivalent
to 20%
of that used for the immunoprecipitation (lane 1). Comparison
of this
signal to that observed in the anti-Cus1p immunoprecipitate
(lane 2)
indicates that more than half and possibly all of the
input myc-tagged
Hsh155p is immunoprecipitated by the anti-Cus1p
antibody. Because a
much larger fraction of input Hsh155-myc protein
than U2 RNA is
associated with Cus1p, it seems likely that the
interaction between the
proteins does not require U2 RNA. The
interaction is specific, since
immunoprecipitation with preimmune
serum did not result in
coimmunoprecipitation of Hsh155-mycp (Fig.
2B, lane 3). The association
of Cus1p with Hsh155p (Fig.
2B),
together with the interaction between
Cus1p and Hsh49p (Fig.
1B
and C) (
26), significantly extends
the parallels in subunit
composition between the yeast and mammalian
SF3b
complexes.
Cus1p is associated with intermediates and products of
splicing.
To explore the association of Cus1p with the pre-mRNA
during splicing, we immunoprecipitated splicing reaction mixtures
containing radiolabeled pre-mRNA (Fig. 2C). Cus1p is associated with
the pre-mRNA substrate, the splicing intermediates (free exon 1 and lariat intermediate), and the splicing products (spliced exons and
lariat intron), as demonstrated by the coimmunoprecipitation of these
RNAs with Cus1p (Fig. 2C, lane 3). This association is specific, since
immunoprecipitation with preimmune serum (Fig. 2C, lane 2) or
antihemagglutinin antibody (Fig. 2C, lane 5) did not efficiently
precipitate pre-mRNA or any intermediates or products of splicing.
Oligonucleotide ablation of U2 snRNA in the splicing reactions
prior to immunoprecipitation demonstrated that interaction of Cus1p
with pre-mRNA is dependent upon the presence of U2 snRNA (Fig. 2C,
lane 4). These data indicate that Cus1p is accessible to the antibody
in spliceosomes at various stages of the splicing reaction. The
immunoprecipitation of intermediates and products of splicing by
anti-Cus1p antibodies is in contrast to similar experiments with Prp9p,
Prp11p, and Prp21p. These homologs of mammalian SF3a components have
been demonstrated to coimmunoprecipitate only pre-mRNA and have been
considered to be destabilized or lost from the spliceosome or shielded
from antibodies before the first step of splicing (1, 2, 4, 36,
42).
Splicing in heat-inactivated temperature-sensitive Cus1p extracts
can be rescued by extracts depleted of U2 snRNA.
To explore
the biochemical role of Cus1p in splicing, we began to develop assays
that depend on Cus1p function. Extracts made after repression of Cus1p
expression using a GAL:CUS1 gene do not support splicing
complex formation in vitro, and a small but reproducible rescue of
prespliceosome formation occurs after addition of partially purified
Cus1p-containing fractions from yeast extracts (43). Because
splicing is poorly reconstituted in a genetically depleted Cus1p
extract, we were concerned that secondary effects of CUS1
repression might hinder efforts to reconstitute Cus1p activity. To
circumvent this difficulty, we isolated temperature-sensitive Cus1p
mutants and made splicing extracts that could be heat inactivated (Fig.
3). Preheating of extracts derived from
one temperature-sensitive mutant, the cus1-3 mutant,
specifically inactivated splicing (Fig. 3A, lane 4; see Fig. 1A for
sequence changes in the cus1-3 mutant) and prespliceosome
formation (Fig. 3B, lane 4). Commitment complexes (Fig. 3B) still
appear in the heated mutant extracts, consistent with a role for Cus1p
after commitment complex formation but before or during prespliceosome
formation (43).
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FIG. 3.
Heat-treated cus1-3 extract is blocked in
prespliceosomeformation and splicing. (A) The cus1-3 extract
is temperature sensitive for splicing. cus1-3 or wild-type
(CUS1) extracts were preincubated at 22 or 36°C for 1 h and then incubated with radiolabeled actin pre-mRNA at 22°C for 20 min. RNA was extracted and run on a 6% denaturing acrylamide gel. Lane
1, wild-type extract treated at 22°C; lane 2, wild-type extract
treated at 36°C; lane 3, cus1-3 extract treated at 22°C;
lane 4, cus1-3 extract treated at 36°C. (B) The
cus1-3 extract is temperature sensitive for prespliceosome
formation. Reactions were set up as described for panel A, incubated,
and loaded onto a nondenaturing 3.5% acrylamide-0.5% agarose gel.
Lane 1, wild-type extract treated at 22°C; lane 2, wild-type extract
treated at 36°C; lane 3, cus1-3 extract treated at 22°C;
lane 4, cus1-3 extract treated at 36°C. CC, commitment
complexes.
|
|
The addition of recombinant Cus1p alone does not rescue splicing or
prespliceosome formation in the heat-inactivated
cus1-3 extract (data not shown). This suggests that execution of Cus1p
function requires additional factors, for example, the other yeast
SF3b-like proteins, which may not freely diffuse from inactivated
cus1-3p-containing mutant complexes. To determine whether the
addition
of wild-type Cus1p in some form could rescue heat-inactivated
cus1-3 extracts, we prepared wild-type extracts depleted of
functional
U2 snRNA by oligonucleotide-directed RNase H digestion
of U2 RNA
(Fig.
4). Such extracts do not
splice (Fig.
4, lane 6) because
they lack intact U2 snRNA
(
33); however, they can reconstitute
splicing when mixed
with heat-inactivated
cus1-3 extracts (lane
3).
Complementation is not efficient, as indicated by the reduced
levels of
the lariat product and lariat-exon 2 intermediate migrating
more slowly
than the pre-mRNA substrate. This inefficiency may
be due to a loss or
dilution of a general splicing factor or to
the formation of denatured
Cus1p that may inhibit splicing, because
the same low efficiency is
observed with wild-type extracts treated
with an irrelevant
oligonucleotide (mock treated) (Fig.
4, lane
4). Despite this, extracts
containing disintegrated U2 snRNPs
retain significant Cus1p
activity that can exchange with that
of the intact U2 snRNA from
the
cus1-3 extract. Together with
the efficient association
of Hsh155p with Cus1p (Fig.
2), this
result suggests that yeast Cus1p
activity exists in a complex
with Hsh155p that can exchange with U2
snRNA under splicing conditions.
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|
FIG. 4.
Reconstitution of splicing in heat-inactivated
cus1-3 extracts does not require U2 snRNA. Splicing in
heat-inactivated cus1-3 extracts alone or with the addition
of wild-type (CUS1) extracts depleted of U2 RNA by
oligonucleotide-RNase H depletion is shown. Lane 1, cus1-3
extract treated at 22°C; lane 2, cus1-3 extract treated at
36°C; lane 3, cus1-3 extract treated at 36°C plus
U2-depleted wild-type extract; lane 4, cus1-3 extract
treated at 36°C plus mock-depleted wild-type extract; lane 5, untreated wild-type extract; lane 6, U2-depleted wild-type extract;
lane 7, mock-depleted wild-type extract.
|
|
Cus1p complementing activity is associated with Hsh155p and U2
snRNA under splicing conditions.
To study the properties of
the factor that complements Cus1p function in vitro, we fractionated
splicing extracts derived from the Hsh155-myc-tagged strain by gel
exclusion fast protein liquid chromatography in a buffer containing 150 mM KCl (Fig. 5). Fractions were added to heat-inactivated
cus1-3 splicing extract and assayed for complementation of
splicing (Fig. 5A). Most of the rescuing
activity chromatographed as a broad peak (Fig. 5A, lanes 5 to 8), with
an apparent native molecular mass of 669 kDa to 2 MDa as estimated by
comparing its Kav determined from the elution
volume with the values obtained for several globular protein calibration standards and by the known upper limit of separation for
the Superose6 column (2 MDa). Western blot analysis of these fractions
using the anti-Cus1p antibody demonstrates that they contain Cus1p
(Fig. 5B, fractions 18 to 24). These same fractions were also blotted
and probed with the anti-myc antibody in order to detect Hsh155-mycp
(Fig. 5B). Hsh155-mycp was also found in the fractions that
reconstitute splicing (fractions 18 to 24). The Cus1p antibody is
barely able to detect the protein at the levels we recover from the
column fractions (data not shown), and only peak fractions have
detectable levels of protein. The level of Cus1p in the weakly
complementing fractions of Fig. 5 (28 and 30) is
below the level of detection of the antibody. The anti-myc antibody
that recognizes epitope tag at the C terminus of Hsh155-mycp is much
more sensitive, so some side fractions may appear to contain 155 but
not Cus1p. Fraction 16 is problematic, because it appears to contain
aggregated protein, including nucleases and proteases that
differentially influence the recovery and analysis of RNA and tagged
protein in different experiments (data not shown). RNA was extracted
from the fractions and assayed by primer extension for the presence of
U2, which is also present in fractions where the reconstituting
activity is found (Fig. 5B, lanes 18 to 26). Given the large size of
this complex, and the identity of components found in these fractions,
it seems possible that the rescuing factor in this experiment is the U2
snRNP itself.
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FIG. 5.
Rescue of heat-treated cus1-3 extracts by
large complexes containing U2 RNA, Cus1p, and Hsh155p under low-salt
conditions. (A) Fractionation of Cus1p activity at 150 mM KCl.
Hsh155p-myc extract was separated over a Superose6 sizing column in the
presence of 150 mM KCl, added to heat-inactivated cus1-3
extracts, and assayed for splicing. Lane 1, pre-mRNA substrate; lane 2, wild-type extract; lane 3, cus1-3 extract at 22°C; lane 4, cus1-3 extract at 36°C; lanes 5 to 14, heat-inactivated
cus1-3 extract incubated with fractionated Hsh155p-Myc
extract from even-numbered fractions; lane 15, markers. (B) Profiles of
U2 snRNA, Cus1p, and Hsh155p in Hsh155p-myc extract fractionated at
150 mM KCl. RNA was extracted from even-numbered fractions and used in
primer extension analysis with an oligonucleotide complementary to U2
snRNA. Cus1p and Hsh155p in Hsh155p-myc extract fractionated at 150 mM KCl were detected by using even-numbered fractions loaded onto 10%
acrylamide gels, transferred, and blotted with anti-Cus1p antibodies or
anti-myc antibodies.
|
|
Cus1p-complementing activity remains associated with Hsh155p but
not U2 snRNA under high-salt conditions.
Although most of the
complementing activity migrates as a large complex in 150 mM KCl, in
some experiments a small amount of complementing activity could be
observed in fractions 28 to 30 (Fig. 5A, lanes 11 and 12). This
activity is very weak and migrates with an apparent mass of between 232 and 669 kDa. Although not present in sufficient amounts to be
detectable on Western blots by our anti-Cus1p antibody, the more avid
anti-myc monoclonal antibody detects small amounts of Hsh155-mycp in
these fractions. To test the idea that these fractions represent
Cus1p-containing complexes that dissociate from U2 snRNP, and to
evaluate the salt sensitivity of the association of the Cus1p complex
with U2 RNA, splicing extracts from the Hsh155-mycp strain were
fractionated in the presence of 500 mM KCl (Fig.
6). Under these conditions, the majority
of the complementing activity is present in fractions 26 to 30, but
splicing is inefficient. (The mRNA product and exon 1 intermediates are
obscured. Refer to lariat intermediate and product.) This activity has
an apparent mass of 232 to 669 kDa (Fig. 6A, lanes 9 to 14), similar to
the very minor peak observed under low-salt conditions. This value is
larger than that expected for Cus1p alone (50 kDa), providing
biochemical evidence for a salt-resistant complex containing Cus1p
activity. Indeed, Western blot analysis of these fractions shows that
Cus1p and Hsh155-mycp fractionate with the reconstituting activity
(Fig. 6B, fractions 24 to 30). Because the amounts of Cus1p in the peak
fractions are near the detection limit of our anti-Cus1p antibody,
quantitation of the Cus1p signal is not reliable. Furthermore, because
the anti-myc antibody is much more sensitive, the signals arising from
the two proteins cannot be compared directly. Because of this, we can
only qualitatively assign Cus1p to a subset of fractions containing
Hsh155-mycp, and in every case all fractions that contain abundant
Hsh155-mycp also contain Cus1p. Although this suggests that the two
proteins are together in a single complex, it is formally possible that
they are each in different complexes that comigrate on the column.
Analysis of the RNA in these fractions shows that most of the U2
snRNA still migrates in the larger fractions (Fig. 6B, fractions 18 to 24), consistent with the very large mass of yeast U2 snRNA (387 kDa) plus additional proteins (15). This result indicates
that in 500 mM KCl, the cus1-3p-complementing activity is no longer
associated with the bulk of U2 snRNA. We conclude that increasing
the salt concentration from 0.15 to 0.5 M releases a functional protein
complex containing Cus1p and Hsh155p from a larger complex that may
represent a form of the U2 snRNP.
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FIG. 6.
Rescue of heat-treated cus1-3 extracts by
smaller complexes containing Cus1p and Hsh155p under high-salt
conditions. (A) Rescue of splicing in heat-inactivated splicing
extracts by sizing fractions separated at 500 mM KCl. Hsh155p-myc
extract was separated over a Superose6 sizing column in the presence of
500 mM KCl, added to heat-inactivated cus1-3 extracts, and
assayed for splicing. Lane 1, pre-mRNA; lane 2, wild-type extract; lane
3, cus1-3 extract at 22°C; lane 4, cus1-3
extract at 36°C; lanes 5 to 14, heat-inactivated cus1-3
extract incubated with fractionated Hsh155p-myc extract from
even-numbered fractions; lane 15, markers. (B) Profiles of U2
snRNA, Cus1p, and Hsh155p in Hsh155p-myc extract fractionated at
500 mM KCl. RNA was extracted from even-numbered fractions and used in
primer extension analysis with an oligonucleotide complementary to U2
snRNA. Cus1p and Hsh155p in Hsh155p-myc extract fractionated at 500 mM KCl were detected by using even-numbered fractions loaded onto 10%
acrylamide gels, transferred, and blotted with anti-Cus1p antibodies or
anti-Myc antibodies.
|
|
| |
DISCUSSION |
Understanding snRNP function will require knowing how
snRNP proteins and splicing factors interact with RNA during
spliceosome assembly and splicing. Building on the identification of
the splicing factor Cus1p in a U2 RNA suppressor screen
(43), we found that the most widely conserved parts of Cus1p
are those essential for function in yeast (Fig. 1A). An 82-amino-acid
region within the essential part of Cus1p is sufficient for binding to
another evolutionarily conserved splicing factor, Hsh49p (Fig. 1B).
Anti-Cus1p antibodies coimmunoprecipitate U2 snRNA as well as
pre-mRNA and the intermediates and products of the splicing reaction,
demonstrating that Cus1p is present in the spliceosome and accessible
to antibodies throughout the splicing process (Fig. 2A and C). A new
interaction between Cus1p and Hsh155p, the homolog of human SAP155
(Fig. 2B), establishes an important functional parallel between the
structurally similar yeast and human proteins. Gel exclusion
chromatography of splicing extracts under different ionic conditions
shows that functional Cus1p-complementing activity contains both Cus1p
and Hsh155p, suggesting that rescue is mediated by a Cus1p complex that
also contains Hsh155p (Fig. 5 and 6). Considering the binding between Hsh49p and Cus1p (Fig. 1B and C) (26), and the association
of Cus1p with Hsh155p (Fig. 2B), we conclude that a complex of yeast proteins similar to mammalian SF3b is required for the association of
the U2 snRNP with the assembling spliceosome (Fig.
7). The dynamic salt-sensitive behavior
of this protein complex with respect to its association with U2
snRNA also seems similar to that observed for mammalian SF3b
(8, 12), suggesting that the underlying features of the
splicing apparatus that lead to this phenomenon are conserved as well.
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FIG. 7.
A model for salt-labile interaction of Cus1p-containing
complexes (ySF3b) during activation of the U2 snRNP for intron
recognition and spliceosome assembly in yeast. I, IIa, and IIb,
conserved stem-loops of U2 snRNA; Sm, core Sm protein complex of
the snRNP. Other individual proteins are named by their gene names,
followed by a lowercase p. Proteins that remain associated with U2 in
high salt are described in reference 15.
|
|
Cus1p function in splicing.
Cus1p was identified as a
suppressor of U2 snRNA mutations in yeast. A glutamate at position
181 in the wild-type protein is changed to a lysine, somehow
accelerating the rate of prespliceosome formation at low temperature in
extracts containing mutant U2 RNA (43). Extracts made from
strains in which the expression of Cus1p is repressed have been
difficult to complement; however, extracts made from the
temperature-sensitive cus1-3 strain could be heat
inactivated (Fig. 3) and complemented with splicing extract fractions
of different types (Fig. 4 to 6). The defect in the heat-inactivated
temperature-sensitive extracts (failure to form prespliceosomes) (Fig.
3) is the same as that observed in the genetically depleted extract
(43), and thus both results indicate that the earliest
function of Cus1p in the splicing pathway is at the step of U2
snRNP addition to the commitment complex to form the
prespliceosome. Since Cus1p remains associated with the spliceosome
throughout splicing (Fig. 2), there could be additional functions of
Cus1p at later steps of splicing.
Cus1p binds the pre-mRNA substrate in active splicing extracts, and
this binding is dependent on intact U2 snRNA (Fig.
2).
This argues
that Cus1p does not act by binding to the pre-mRNA
before it becomes
associated with U2, although the possibilities
that Cus1p binds
pre-mRNA in an unstable fashion and that U2 snRNP
is required to
stabilize that interaction cannot strictly be ruled
out. Based on gel
exclusion chromatography in high-salt conditions,
the protein that
rescues heat-inactivated
cus1-3 splicing extracts
is much
larger than the 50 kDa expected for monomeric Cus1p, a
result
consistent with the expectation that Cus1p is a subunit
of a protein
complex. Since other yeast U2 snRNP proteins remain
associated with
U2 snRNA in up to 0.3 M KCl (
15), it seems likely
that
the Cus1p complex dissociates under high-salt conditions
from a core U2
snRNP containing the high-salt-stable proteins
and reassociates at
lower ionic strengths in order to participate
in spliceosome assembly
(Fig.
7). Precisely how Cus1p helps U2
snRNP assemble into the
complex and especially how the Cus1-54p
suppressor protein enables
mutant U2 RNA to participate in this
reaction at a normally
nonpermissive temperature remain to be
determined.
Other proteins in the Cus1p complex.
Cus1p interacts with a
number of other proteins. Hsh49p binds Cus1p in vitro, through the
first RNA recognition motif of Hsh49p (26), and through
amino acids 229 to 311 of Cus1p (Fig. 1). Although we have not provided
direct evidence that Hsh49 is present in the fractions that rescue
heat-inactivated cus1-3 extracts in vitro, the robust nature
of the protein-protein interaction suggests that binding of these two
proteins to each other is important for their function, and in both
proteins the minimum binding domain includes essential amino acids.
Thus, Hsh49p is a likely component of the functional Cus1p complex.
Anti-Cus1p antibodies coimmunoprecipitate nearly all of the tagged
Hsh155p present in splicing extracts (Fig.
2B), indicating
that most if
not all of Hsh155p is bound directly or indirectly
to Cus1p, at least
at 150 mM NaCl. All rescuing fractions contain
both Cus1p and Hsh155p
(Fig.
5 and
6), consistent with the coimmunoprecipitation.
Taken
together, the coimmunoprecipitation and cofractionation
results support
the interpretation that Hsh155p is part of the
Cus1p complex (Fig.
7).
Because we have not yet shown that we
can coimmunoprecipitate Cus1p and
Hsh155-mycp from the complementing
fractions of the 0.5 M KCl
fractionation, we cannot discern whether
the two proteins are together
in a single complex or in two different,
similarly sized complexes.
Future work will address the composition
of the functional Cus1p
complex in these fractions with respect
to the presence and direct
physical association of Hsh155p, Rse1p,
and Hsh49p with Cus1p and each
other. Since the human homologues
of these three yeast proteins form
part of the SF3b complex in
mammals, we propose that the Cus1p complex
we observe (Fig.
5 and
6) is equivalent to yeast SF3b. The yeast
splicing factor
Rse1p is equivalent to mammalian SAP130, the fourth
subunit of
mammalian SF3b (
16,
18,
44). Rse1p is associated
with U2
snRNA in a salt-sensitive fashion and is required for
prespliceosome
formation, properties expected of a yeast SF3b subunit
(
16).
The sum total of the predicted masses of the proposed
yeast SF3b
subunits Cus1p, Hsh49p, Hsh155p, and Rse1p is about 336 kDa,
a
value consistent with the migration of cus1-3p-complementing activity
by gel exclusion chromatography in 0.5 M KCl (Fig.
6). The limited
resolution of the analysis thus far does not allow us to determine
whether other proteins are also present in the functional Cus1p
complex.
Relationship of the Cus1p complex to mammalian SF3b.
The
splicing factor SF3b binds to 12S U2 snRNP to create the 15S U2
snRNP, which is then competent to bind the SF3a complex to create
the 17S U2 snRNP, the form that participates in spliceosome assembly (8, 12, 30). Human SF3b (hSF3b)
contains four major proteins: SAP155, SAP130, SAP145, and SAP49
(29). The corresponding proteins of ySF3b are Hsh155p,
Rse1p, Cus1p, and Hsh49p (references 16, 19, 26, 29, 37,
41, and 43 and present study). Similarity
in the amino acid sequences between the corresponding human and yeast
proteins varies for the different subunits and ranges from 50 to 25%
identity and 70 to 40% similarity, indicating that some of the
subunits are more constrained than others to maintain the function of
the complex. The human 17S U2 snRNP forms under low-salt conditions
and contains nine additional proteins that the high-salt-stable 12S U2
snRNP lacks, and four of these represent the SF3b complex
(8). In yeast extracts, complexes containing at least Cus1p,
Hsh155p, and U2 snRNA (Fig. 2) or Rse1p and U2 snRNA
(16) are detectable under low (150 mM)-salt conditions,
whereas under high-salt conditions, the U2 RNA cannot be detected.
Furthermore, the functional Cus1p complex migrates away from U2
snRNA on gel exclusion columns under high-salt conditions (Fig. 6)
but must depend on U2 snRNA to participate in spliceosome assembly
(Fig. 2) during active splicing in reconstituted extracts (Fig. 6).
Thus, the association of SF3b with U2 snRNA is salt labile in both
systems. Once assembled into spliceosomes, the hSF3b proteins remain
near the pre-mRNA sequences until after the second catalytic step
of splicing, as assayed by cross-linking (9, 19, 38). In
yeast, Cus1p remains bound to pre-mRNA until after the second
step, as assayed by coimmunoprecipitation of substrate RNA (Fig. 2C).
Cross-linking of Hsh155p to sequences near the branch site of a yeast
pre-mRNA is also observed following prespliceosome formation (D. S. McPheeters and P. Muhlenkamp, unpublished data). Thus, in both
systems, the SF3b subunits appear to become integral components of the
spliceosome once the U2 snRNP is recruited to the branch point.
Salt sensitivity may seem simply a convenient phenomenon by which to
categorize the behavior of protein factors; however,
its conservation
in two diverse systems may betray a deeper biological
significance. A
specific association between factors that can
be broken by raising the
salt slightly above physiological levels
may indicate that the
association itself may be physiologically
dynamic. If such an
association can be controlled by small shifts
in ionic strength, then
it may be controlled physiologically by
protein modification, for
example, phosphorylation. If there is
a functional reason for
controlling the association of SF3b with
U2 snRNP, it is
sufficiently important to have been conserved
in evolution. Future
experiments to address how and why the association
of SF3b with U2
snRNP may be controlled are
needed.
| |
ACKNOWLEDGMENTS |
We thank Haller Igel for sequencing the cus1-3 allele.
We also thank Rhonda Perriman for helpful technical suggestions and Rhonda Perriman and Marc Spingola for critical comments on the manuscript.
This work was supported by a Department of Education Graduate
Fellowship to M.H.P. and by National Institutes of Health grants GM40478 (to M.A.) and GM52310 (to D.S.M.).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Center for
Molecular Biology of RNA, Sinsheimer Laboratories, University of
California, Santa Cruz, Santa Cruz, CA 95064. Phone: (831) 459-4628. Fax: (831) 459-3737. E-mail: ares{at}biology.ucsc.edu.
| |
REFERENCES |
| 1.
|
Abovich, N.,
P. Legrain, and M. Rosbash.
1990.
The yeast PRP6 gene encodes a U4/U6 small nuclear ribonucleoprotein particle (snRNP) protein, and the PRP9 gene encodes a protein required for U2 snRNP binding.
Mol. Cell. Biol.
10:6417-6425[Abstract/Free Full Text].
|
| 2.
|
Abovich, N.,
X. C. Liao, and M. Rosbash.
1994.
The yeast MUD2 protein: an interaction with PRP11 defines a bridge between commitment complexes and U2 snRNP addition.
Genes Dev.
8:843-854[Abstract/Free Full Text].
|
| 3.
|
Altschul, S. F.,
W. Gish,
W. Miller,
E. W. Myers, and D. J. Lipman.
1990.
Basic local alignment search tool.
J. Mol. Biol.
215:403-410[CrossRef][Medline].
|
| 4.
|
Arenas, J. E., and J. N. Abelson.
1993.
The Saccharomyces cerevisiae PRP21 gene product is an integral component of the prespliceosome.
Proc. Natl. Acad. Sci. USA
90:6771-6775[Abstract/Free Full Text].
|
| 5.
|
Ares, M., Jr., and A. H. Igel.
1990.
Lethal and temperature-sensitive mutations and their suppressors identify an essential structural element in U2 small nuclear RNA.
Genes Dev.
4:2132-2145[Abstract/Free Full Text].
|
| 6.
|
Ausubel, F. M.,
R. Brent,
R. E. Kingston,
D. D. Moore,
J. G. Seidman,
J. A. Smith, and K. Struhl.
1987.
Current protocols in molecular biology.
John Wiley & Sons, Inc., New York, N.Y.
|
| 7.
|
Bai, C., and S. J. Elledge.
1996.
Gene identification using the yeast two-hybrid system.
Methods Enzymol.
273:331-347[CrossRef][Medline].
|
| 8.
|
Behrens, S. E.,
K. Tyc,
B. Kastner,
J. Reichelt, and R. Luhrmann.
1993.
Small nuclear ribonucleoprotein (RNP) U2 contains numerous additional proteins and has a bipartite RNP structure under splicing conditions.
Mol. Cell. Biol.
13:307-319[Abstract/Free Full Text].
|
| 9.
|
Bennett, M.,
S. Michaud,
J. Kingston, and R. Reed.
1992.
Protein components specifically associated with prespliceosome and spliceosome complexes.
Genes Dev.
6:1986-2000[Abstract/Free Full Text].
|
| 10.
|
Bennett, M.,
S. Pinol-Roma,
D. Staknis,
G. Dreyfuss, and R. Reed.
1992.
Differential binding of heterogeneous nuclear ribonucleoproteins to mRNA precursors prior to spliceosome assembly in vitro.
Mol. Cell. Biol.
12:3165-3175[Abstract/Free Full Text].
|
| 11.
|
Brent, R., and R. L. Finley, Jr.
1997.
Understanding gene and allele function with two-hybrid methods.
Annu. Rev. Genet.
31:663-704[CrossRef][Medline].
|
| 12.
|
Brosi, R.,
K. Groning,
S. E. Behrens,
R. Luhrmann, and A. Kramer.
1993.
Interaction of mammalian splicing factor SF3a with U2 snRNP and relation of its 60-kD subunit to yeast PRP9.
Science
262:102-105[Abstract/Free Full Text].
|
| 13.
|
Brosi, R.,
H. P. Hauri, and A. Kramer.
1993.
Separation of splicing factor SF3 into two components and purification of SF3a activity.
J. Biol. Chem.
268:17640-17646[Abstract/Free Full Text].
|
| 14.
|
Cadwell, R. C., and G. F. Joyce.
1994.
Mutagenic PCR.
PCR Methods Appl.
3:S136-S140[Medline].
|
| 15.
|
Caspary, F., and B. Seraphin.
1998.
The yeast U2A'/U2B complex is required for pre-spliceosome formation.
EMBO J.
17:6348-6358[CrossRef][Medline].
|
| 16.
|
Caspary, F.,
A. Shevchenko,
M. Wilm, and B. Seraphin.
1999.
Partial purification of the yeast U2 snRNP reveals a novel yeast pre-mRNA splicing factor required for pre-spliceosome assembly.
EMBO J.
18:3463-3474[CrossRef][Medline].
|
| 17.
|
Chapon, C., and P. Legrain.
1992.
A novel gene, spp91-1, suppresses the splicing defect and the pre-mRNA nuclear export in the prp9-1 mutant.
EMBO J.
11:3279-3288[Medline].
|
| 18.
|
Das, B. K.,
L. Xia,
L. Palandjian,
O. Gozani,
Y. Chyung, and R. Reed.
1999.
Characterization of a protein complex containing spliceosomal proteins SAPs 49, 130, 145, and 155.
Mol. Cell. Biol.
19:6796-6802[Abstract/Free Full Text].
|
| 19.
|
Gozani, O.,
R. Feld, and R. Reed.
1996.
Evidence that sequence-independent binding of highly conserved U2 snRNP proteins upstream of the branch site is required for assembly of spliceosomal complex A.
Genes Dev.
10:233-243[Abstract/Free Full Text].
|
| 20.
|
Gozani, O.,
J. G. Patton, and R. Reed.
1994.
A novel set of spliceosome-associated proteins and the essential splicing factor PSF bind stably to pre-mRNA prior to catalytic step II of the splicing reaction.
EMBO J.
13:3356-3367[Medline].
|
| 21.
|
Guthrie, C., and G. Fink.
1991.
Guide to yeast genetics and molecular biology.
Academic Press, Inc., San Diego, Calif.
|
| 22.
|
Harlow, E., and D. Lane.
1988.
Antibodies: a laboratory manual.
Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
|
| 23.
|
Harper, J. W.,
G. R. Adami,
N. Wei,
K. Keyomarsi, and S. J. Elledge.
1993.
The p21 Cdk-interacting protein Cip1 is a potent inhibitor of G1 cyclin-dependent kinases.
Cell
75:805-816[CrossRef][Medline].
|
| 24.
|
Hartwell, L. H.
1967.
Macromolecule synthesis in temperature-sensitive mutants of yeast.
J. Bacteriol.
93:1662-1670[Abstract/Free Full Text].
|
| 25.
|
Higgins, D. G.,
J. D. Thompson, and T. J. Gibson.
1996.
Using CLUSTAL for multiple sequence alignments.
Methods Enzymol.
266:383-402[Medline].
|
| 26.
|
Igel, H.,
S. Wells,
R. Perriman, and M. Ares, Jr.
1998.
Conservation of structure and subunit interactions in yeast homologues of splicing factor 3b (SF3b) subunits.
RNA
4:1-10[Abstract].
|
| 27.
|
Jones, E. W.
1991.
Tackling the protease problem in Saccharomyces cerevisiae.
Methods Enzymol.
194:428-453[Medline].
|
| 28.
|
Kramer, A.
1988.
Presplicing complex formation requires two proteins and U2 snRNP.
Genes Dev.
2:1155-1167[Abstract/Free Full Text].
|
| 29.
|
Kramer, A.
1996.
The structure and function of proteins involved in mammalian pre-mRNA splicing.
Annu. Rev. Biochem.
65:367-409[CrossRef][Medline].
|
| 30.
|
Kramer, A.,
P. Gruter,
K. Groning, and B. Kastner.
1999.
Combined biochemical and electron microscopic analyses reveal the architecture of the mammalian U2 snRNP.
J. Cell. Biol.
145:1355-1368[Abstract/Free Full Text].
|
| 31.
|
Kunkel, T. A.,
K. Bebenek, and J. McClary.
1991.
Efficient site-directed mutagenesis using uracil-containing DNA.
Methods Enzymol.
204:125-139[Medline].
|
| 32.
|
Longtine, M. S.,
A. R. McKenzie,
D. J. Demarini,
N. G. Shah,
A. Wach,
A. Brachat,
P. Philippsen, and J. R. Pringle.
1998.
Additional modules for versatile and economical PCR-based gene deletion and modification in Saccharomyces cerevisiae.
Yeast
14:953-961[CrossRef][Medline].
|
| 33.
|
McPheeters, D. S.,
P. Fabrizio, and J. Abelson.
1989.
In vitro reconstitution of functional yeast U2 snRNPs.
Genes Dev.
3:2124-2136[Abstract/Free Full Text].
|
| 34.
|
Phizicky, E. M., and S. Fields.
1995.
Protein-protein interactions: methods for detection and analysis.
Microbiol. Rev.
59:94-123[Abstract/Free Full Text].
|
| 35.
|
Riedel, N.,
J. A. Wise,
H. Swerdlow,
A. Mak, and C. Guthrie.
1986.
Small nuclear RNAs from Saccharomyces cerevisiae: unexpected diversity in abundance, size, and molecular complexity.
Proc. Natl. Acad. Sci. USA
83:8097-8101[Abstract/Free Full Text].
|
| 36.
|
Ruby, S. W.,
T. H. Chang, and J. Abelson.
1993.
Four yeast spliceosomal proteins (PRP5, PRP9, PRP11, and PRP21) interact to promote U2 snRNP binding to pre-mRNA.
Genes Dev.
7:1909-1925[Abstract/Free Full Text].
|
| 37.
|
Schmidt-Zachmann, M. S.,
S. Knecht, and A. Kramer.
1998.
Molecular characterization of a novel, widespread nuclear protein that colocalizes with spliceosome components.
Mol. Biol. Cell
9:143-160[Abstract/Free Full Text].
|
| 38.
|
Staknis, D., and R. Reed.
1994.
Direct interactions between pre-mRNA and six U2 small nuclear ribonucleoproteins during spliceosome assembly.
Mol. Cell. Biol.
14:2994-3005[Abstract/Free Full Text].
|
| 39.
|
Staley, J. P., and C. Guthrie.
1998.
Mechanical devices of the spliceosome: motors, clocks, springs, and things.
Cell
92:315-326[CrossRef][Medline].
|
| 40.
|
Vijayraghavan, U.,
M. Company, and J. Abelson.
1989.
Isolation and characterization of pre-mRNA splicing mutants of Saccharomyces cerevisiae.
Genes Dev.
3:1206-1216[Abstract/Free Full Text].
|
| 41.
|
Wang, C.,
K. Chua,
W. Seghezzi,
E. Lees,
O. Gozani, and R. Reed.
1998.
Phosphorylation of spliceosomal protein SAP 155 coupled with splicing catalysis.
Genes Dev.
12:1409-1414[Abstract/Free Full Text].
|
| 42.
|
Wells, S. E., and M. Ares, Jr.
1994.
Interactions between highly conserved U2 small nuclear RNA structures and Prp5p, Prp9p, Prp11p, and Prp21p proteins are required to ensure integrity of the U2 small nuclear ribonucleoprotein in Saccharomyces cerevisiae.
Mol. Cell. Biol.
14:6337-6349[Abstract/Free Full Text].
|
| 43.
|
Wells, S. E.,
M. Neville,
M. Haynes,
J. Wang,
H. Igel, and M. Ares, Jr.
1996.
CUS1, a suppressor of cold-sensitive U2 snRNA mutations, is a novel yeast splicing factor homologous to human SAP 145.
Genes Dev.
10:220-232[Abstract/Free Full Text].
|
| 44.
|
Will, C. L.,
C. Schneider,
R. Reed, and R. Luhrmann.
1999.
Identification of both shared and distinct proteins in the major and minor spliceosomes.
Science
284:2003-2005[Abstract/Free Full Text].
|
| 45.
|
Yan, D.,
R. Perriman,
H. Igel,
K. J. Howe,
M. Neville, and M. Ares, Jr.
1998.
CUS2, a yeast homolog of human Tat-SF1, rescues function of misfolded U2 through an unusual RNA recognition motif.
Mol. Cell. Biol.
18:5000-5009[Abstract/Free Full Text].
|
Molecular and Cellular Biology, March 2000, p. 2176-2185, Vol. 20, No. 6
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
