Molecular and Cellular Biology, March 1999, p. 2142-2154, Vol. 19, No. 3
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Pseudouridine Mapping in the Saccharomyces
cerevisiae Spliceosomal U Small Nuclear RNAs (snRNAs)
Reveals that Pseudouridine Synthase Pus1p Exhibits a Dual
Substrate Specificity for U2 snRNA and tRNA
Séverine
Massenet,1
Yuri
Motorin,2
Denis L. J.
Lafontaine,3
Eduard C.
Hurt,4
Henri
Grosjean,2 and
Christiane
Branlant1,*
Laboratoire de Maturation des ARN et
Enzymologie Moléculaire, UMR7567 CNRS-UHP, Faculté des
Sciences, 54506 Vandoeuvre-les-Nancy
Cédex,1 and Laboratoire
d'Enzymologie et Biochimie Structurales, UPR CNRS, 91198 Gif-sur-Yvette,2 France; Institute of
Cell and Molecular Biology, University of Edinburgh, Edinburgh EH9
3JR, United Kingdom3; and University of
Heidelberg, 69120 Heidelberg, Germany4
Received 24 August 1998/Returned for modification 5 October
1998/Accepted 30 November 1998
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ABSTRACT |
Pseudouridine (
) residues were localized in the
Saccharomyces cerevisiae spliceosomal U small nuclear RNAs
(UsnRNAs) by using the chemical mapping method. In contrast to
vertebrate UsnRNAs, S. cerevisiae UsnRNAs contain only a
few residues, which are located in segments involved in
intermolecular RNA-RNA or RNA-protein interactions. At these positions,
UsnRNAs are universally modified. When yeast mutants disrupted for one
of the several pseudouridine synthase genes (PUS1,
PUS2, PUS3, and PUS4) or depleted
in rRNA-pseudouridine synthase Cbf5p were tested for UsnRNA content, only the loss of the Pus1p activity was found to affect formation in spliceosomal UsnRNAs. Indeed, 44 formation
in U2 snRNA was abolished. By using purified Pus1p enzyme and in
vitro-produced U2 snRNA, Pus1p is shown here to catalyze
44 formation in the S. cerevisiae U2 snRNA. Thus, Pus1p is the first UsnRNA pseudouridine synthase characterized so
far which exhibits a dual substrate specificity, acting on both tRNAs
and U2 snRNA. As depletion of rRNA-pseudouridine synthase Cbf5p had no
effect on UsnRNA content, formation of residues in S. cerevisiae UsnRNAs is not dependent on the Cbf5p-snoRNA guided mechanism.
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INTRODUCTION |
Introns are universally present in
the nuclear genes transcribed by RNA polymerase II. Introns with GU and
AG terminal dinucleotides and some introns with AU and AC terminal
dinucleotides are removed by spliceosomal complexes containing the U1,
U2, U4, U5, and U6 small nuclear RNAs (UsnRNAs) (for reviews, see
references 54 and 59), the
remaining part of introns with AU and AC terminal dinucleotides being
excised by complexes containing the U11, U12, U4atac, U5, and U6atac
UsnRNAs (32, 79, 106, 105). In yeast cells, only introns
with GU and AG borders have been detected, and their excision is
catalyzed by ribonucleoprotein complexes containing UsnRNAs homologous
to the vertebrate U1, U2, U4, U5, and U6 snRNAs (for a review, see
reference 31). However, compared to their
counterparts in other eukaryotes, the Saccharomyces
cerevisiae spliceosomal UsnRNAs differ by their larger size. For
example, U2 snRNA is 1,175 nucleotides (nt) long in S. cerevisiae versus 187 nt in humans, and U1 snRNA is 568 nt long in
S. cerevisiae versus 164 nt in humans (for a review, see
reference 31).
In spite of this difference, the splicing machineries for the
elimination of the GU-AG type of introns, in both vertebrates and
S. cerevisiae, share several common properties. In
particular, UsnRNPs are assembled in the same sequential order
(17, 27; for a review, see reference
59), and the same kinds of bi- and multimolecular
RNA-RNA interactions are implicated. The picture that now emerges from
a large body of experiments in several laboratories is rather complex.
First, upon U1 snRNP association, the 5' extremity of U1 forms a
base-pair interaction with the intron 5' extremity (62, 94, 95,
96, 123). Then, the U2 snRNP is associated and a base-pair
interaction is formed between U2 and the intron branch-point sequence
(71, 72, 116, 124). A U4/U6 RNA duplex is present in the
U4/U6 snRNP (34, 86) and a tri-snRNP is generated by
association of the U4/U6 snRNP with the U5 snRNP (11). When
this tri-snRNP particle joins the prespliceosomal complex, several
conformational changes take place and the U1 snRNA interaction at the
5' end of the intron is replaced by a U6 snRNA interaction (41,
52, 91). The U4/U6 RNA duplex is disrupted and replaced by a
U2/U6 RNA duplex (20, 35, 53, 102, 117), and the terminal
loop I of U5 contacts the 3' extremity of the upstream exon (19,
65, 66, 67, 99, 118). These structural rearrangements are
required for the first trans-esterification step to occur.
Following this first step, other structural rearrangements take place
that reveal the catalytic activity for the second step of the reaction.
In particular, the highly conserved terminal loop I of U5 then
interacts with the two exon extremities for proper alignment and
ligation (65-67, 99). Although several proteins play an
essential role in spliceosome assembly and function (for reviews, see
references 45, 109, and 114), the
general idea is that some of the UsnRNAs, in particular U2 and U6, may
be directly involved in catalysis (for reviews, see references
18, 30, 40, 101).
The first determinations of UsnRNA sequences were made at the RNA
level, and several posttranscriptional modifications were identified.
This analysis was done on U1, U2, U4, U5, and U6 snRNAs from HeLa,
chicken, mouse (13, 14, 33, 42, 47, 48), rat hepatoma (for a
review, see reference 81), Drosophila
melanogaster (63), and plant (for a review, reference
98) cells. Then, for a long period of time, UsnRNA
sequences were deduced essentially from the corresponding gene
sequences so that posttranscriptional modifications were only
investigated for a limited number of UsnRNAs: the Physarum
polycephalum U1 and U5 snRNAs (63, 103) and, more recently, the Schizosaccharomyces pombe U1, U2, U4, U5, and
U6 snRNAs (28).
Except for the cap and cap-related modifications, the two most
frequently found posttranscriptional modifications at internal positions of UsnRNAs are methylation at the 2'-O position of
ribose and isomerization of uridine to pseudouridine (). Only a few base methylations (m5C, m6A, and
m2G) were detected (for a review, see reference
55). Since residues and
2'-O-methylated residues stabilize RNA double helices (for reviews, see references 2, 6, and
21), the functional importance of these modified
nucleotides in UsnRNAs may be, at least in part, linked to the
necessity to form base-pair interactions between RNA molecules at one
or the other steps of the splicing process. Furthermore, in the case of
residues, the presence of an additional free NH group at position 3 of the ring, as compared to uridine, generates the possibility to form
an additional hydrogen bond with RNA or proteins. It is noteworthy that
the modified residues of spliceosomal UsnRNAs are clustered in the
segments involved in intermolecular interactions, and several of these modifications are conserved in all of the species that were studied so
far (103; for a review, see reference
55). This is the case for one of the two residues located in the U1 region that base pairs with the intron, for
the two residues present in the U2 region, which interacts with the
branch site, and for the numerous posttranscriptional modifications of
the U5 snRNA terminal loop I (28, 103).
The number of posttranscriptionally modified nucleotides present in the
interacting regions of U6 and U2 snRNAs, supposed to form at least a
part of the spliceosome active site, is rather impressive in vertebrate
species. All of these observations strongly suggest an important role
of UsnRNA posttranscriptional modifications in spliceosome assembly and
function. An experimental evidence for a role of posttranscriptional
modifications in splicing was obtained for the human U2 snRNA (93,
120). Indeed, whereas fully active U2 snRNPs were obtained upon
in vitro reconstitution with HeLa cell U2 snRNP proteins and the
authentic human U2 snRNA, the in vitro-produced human U2 snRNA lacking
all of the posttranscriptional modifications failed to form functional
splicing complexes (93). Replacement of the authentic
Xenopus laevis U2 snRNA by chimeric U2 snRNAs, in which some
sequences are from cellular-derived U2 and others are from in
vitro-transcribed U2, demonstrated that the essential
posttranscriptional modifications of the vertebrate U2 snRNA are
restricted to the 27-nt 5' terminus (120).
The biogenesis of in U1, U2, U4, U5, and U6 snRNAs from HeLa cells
have been the subject of several reports (121;
reference 122 and references therein; for a review,
see reference 76). Using in vitro-transcribed snRNAs
and nuclear or S100 extracts from HeLa cells, the existence of multiple
RNA-pseudouridine synthase activities that specifically recognize U1,
U2, and U5 snRNAs was demonstrated (73-75, 77). However, to
date, none of the implicated RNA-pseudouridine synthases has been
identified, nor was their precise specificity elucidated.
The splicing machineries of HeLa cells and S. cerevisiae are
the two most extensively studied, with respect to understanding how the
spliceosome is assembled and how it functions. However, in the case of
S. cerevisiae snRNAs, due to the low amounts of spliceosomal
UsnRNAs and their unusual lengths, no internal nucleotide modifications
have been identified so far. We started such a study by investigating
the presence of residues in the S. cerevisiae full-length U4, U5, and U6 snRNAs and in the regions of the
S. cerevisiae U1 and U2 snRNAs that have a counterpart with
modified residues in the vertebrate U1 and U2 snRNAs. We also looked
for the pseudouridine synthases that may catalyze the formation of the
identified residues. Based on in vitro experiments, a case of
dual-specificity was already described for an E. coli
RNA-pseudouridine synthase (the RluAp enzyme that catalyzes the
site-specific formation of at position 32 of tRNA anticodon and at
position 746 of 23 S rRNA) (115). We therefore asked whether
some of the already characterized yeast pseudouridine synthases, which
act on tRNAs or rRNAs, can also modify UsnRNAs. To this end, we
performed the mapping of the residues in UsnRNAs extracted from
yeast strains carrying separate disruptions of the genes coding
for the already-characterized RNA-pseudouridine synthases Pus1p,
Pus3p, and Pus4p acting on tRNAs (10, 51, 60, 97); the
putative Pus2p enzyme, whose substrate has not been identified so far
(97); and Cbf5p acting on rRNA complexed with snoRNA guides
(50).
In this study, we report the mapping of residues in the S. cerevisiae spliceosomal UsnRNAs and demonstrate that one of the previously identified tRNA-pseudouridine synthases (Pus1p) is directly
implicated in the pseudouridylation of U2 snRNA in vivo.
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MATERIALS AND METHODS |
Yeast strains and growth conditions.
The following S. cerevisiae strains were used in this study: S. cerevisiae FL100 (ATCC 28383) (49); S. cerevisiae strains carrying disruptions in the PUS1,
PUS2, and PUS3 genes that were described
previously (51, 97); an S. cerevisiae strain with a disrupted PUS4 gene that was kindly provided by R. Planta
(University of Amsterdam) (10); and an S. cerevisiae strain carrying a deletion in the PUS1 gene
transformed with a plasmid expressing an active recombinant protein
ProtA-Pus1p (pUN100-PUS1) (97). All of these S. cerevisiae strains were grown at 30°C on YPD liquid
medium (1% [wt/vol] yeast extract, 1% [wt/vol] Bacto Peptone, and
2% [wt/vol] glucose). The essential gene CBF5 was fused
on the chromosome to a GAL-repressible promoter
(50). Transcription driven from GAL-regulated
promoters is strongly repressed when strains are grown on glucose
medium, allowing the effects of depletion of essential proteins to be
monitored. For depletion of Cbf5p, cells growing exponentially in
permissive conditions (2% galactose, 2% sucrose, and 2% raffinose
minimal medium) at 30°C were harvested by centrifugation, washed, and
resuspended in 2% glucose minimal medium. During growth, cells were
diluted with prewarmed medium and constantly maintained in exponential
phase. For the experiment described in Fig. 4, two independently
isolated GAL::cbf5 strains (YDL521-1 and YDL521-3)
(50) were used. RNA was extracted from these strains after
transfer to nonpermissive conditions for up to 70 h. At this time
point of transfer, formation in rRNA is strongly inhibited and no
H+ACA snoRNA were detected (50).
Preparation of RNA from S. cerevisiae.
The soluble RNA
fraction (containing mainly tRNAs and snRNAs) from wild-type, disrupted
yeast strains and the GAL::cbf5 strain was
prepared as follow. Cells grown on YPD liquid medium until the late
stationary phase were harvested by centrifugation and resuspended in
twice their volume of lysis buffer containing 50 mM Tris-HCl (pH 7.5),
10 mM MgCl2, 100 mM KCl, 0.1 mM EDTA, 10% glycerol, and 10 mM 
-mercaptoethanol. The suspension was frozen in dry ice and passed
through a French Press at about 3,000 lb/in2. The
homogenate obtained was centrifuged for 10 min at 10,000 × g at 4°C. The supernatant was further centrifuged in a
high-speed centrifuge TL100 (Beckman) for 2 h at 80,000 rpm and
4°C. The resulting S100 extract was successively treated by equal
volumes of phenol, phenol-chloroform (1:1), and chloroform-isoamyl
alcohol (24:1). The extracted RNA was ethanol precipitated and used for further analysis by reverse transcription or Northern hybridization.
In vitro transcription of snRNA genes.
Plasmids containing
the S. cerevisiae U1, U2, U4, U5, and U6 snRNA coding
sequences under the control of a T7 promoter were kindly provided by P. Fabrizio. Synthetic U1, U2, U4, U5, and U6 snRNAs were prepared by in
vitro transcription of PvuII-linearized pT7U1 plasmid,
XhoI-linearized pT7U2 plasmid, StyI-linearized pT7U4 plasmid, DraI-linearized pT7U5 plasmid, and
DraI-linearized pT7U6 plasmid, respectively (23,
57).
Synthesis of transcripts was carried out in 30 µl of buffer
containing 40 mM Tris-HCl (pH 8.1), 20 mM MgCl2, 5 mM
dithiothreitol (DTT), 1 mM spermidine, 0.01% Triton X-100, 80 mg of
polyethylene glycol 8000 per ml, 2 µg of the linearized plasmid, 4 mM
concentrations of each ribonucleoside triphosphate, 19 U of RNase Guard
(Pharmacia), and 138 U of T7 RNA polymerase (Pharmacia). After 1 h
of incubation at 37°C, the template DNA was digested by using 7.5 U
of RNase-free DNase I (Pharmacia) for 30 min at 37°C. After phenol
extraction and ethanol precipitation, the RNA was dissolved in 100 µl
of sterile water.
Localization of residues in S. cerevisiae UsnRNAs
and 26S rRNA by primer extension analysis.
Total RNA (10 µg)
from the wild-type or mutant S. cerevisiae strains was used
for reverse transcription. The CMCT
[N-cyclohexyl-N'-(2-morpholinoethyl)-carbodiimid metho-p-toluolsulfonate] modification protocol was adapted
from Bakin and Ofengand (8) with the following
modifications: the CMCT treatment was performed for 2, 10, or 20 min;
the treatment in bicarbonate buffer at pH 10.4 was done for 3 h;
and all precipitations were done by using 0.3 M sodium acetate buffer
(pH 5.3). The hydrazine reaction was performed essentially as described
by Peattie (78).
Positions of CMCT and hydrazine modifications were identified by primer
extension analysis with AMV reverse transcriptase (RT; Life Sciences)
as described by Mougin et al. (61). The oligonucleotides
complementary to the following regions of UsnRNAs and 26S rRNA were
used as primers for reverse transcription: U1 (nt 57 to 72), U2 (nt 104 to 126), U4 (nt 68 to 90 and nt 134 to 160), U5 (nt 159 to 182), U6 (nt
93 to 112), and 26S rRNA (nt 1144 to 1163). Oligonucleotides were 5'
end labeled with [
-32P]ATP (3,000 Ci/mmol) and T4
polynucleotide kinase (90).
In vivo analysis of rp51A pre-mRNA and pre-U3 snoRNA
splicing.
The yield of rp51A pre-mRNA in the absence of an active
PUS1 gene was evaluated by primer extension analysis. Primer
extension analysis on the U1 snRNA was used as a control. The
oligonucleotide primer complementary to the rp51A pre-mRNA and its two
splicing products were described by Teem and Rosbash (107).
The oligonucleotide primer used for U1 snRNA was that described above
for residue identification. Primer extension analysis was done in
the conditions described by Mougin et al. (61). For
quantitative cDNA synthesis, the labeled primers were always added in
excess, 8 ng per assay. At the end of the incubation period, the
elongation mixtures were treated with 20 µg of RNase A per ml for 30 min at 37°C and analyzed by electrophoresis on a 5% sequencing gel.
To verify that the amount of synthesized cDNAs was proportional to the
amount of rp51A mRNAs in the total RNA extract, the experiments on the
pus1
strain were made in triplicate by using
10, 20, and 50 µg of total RNA. The linearity of the 32P
amount in cDNA bands versus the total RNA amount used as the template
was verified by PhosphorImager measurement. For the wild-type strain,
10 and 50 µg of total RNA were used for rp51A mRNA quantification, and for the U1 snRNA control assays, 5 and 15 µg of total RNA were
used. The amounts of synthesized U1 and rp51A cDNAs, in each assay,
were estimated by PhosphorImager measurement. Based on the values
obtained, the relative yields of rp51A mRNAs versus U1 snRNA were
established for the wild-type and pus1 strains.
The efficiency of pre-U3 snoRNA splicing in the absence or the presence
of an active PUS1 gene was analyzed by Northern blot analysis. A 5'-end 32P-labeled oligonucleotide
complementary to the S. cerevisiae U3 snoRNA (nt 1 to 16)
was used as the probe. Total RNA (10 µg) from the wild-type and the
pus1 disrupted strains (prepared as described
above) was fractionated on a 5% polyacrylamide gel. In vitro
transcripts (10 ng) corresponding to the spliced and unspliced pre-U3
snoRNAs were used as controls. The plasmid pVs51:snR17A (92)
was used to produce the U3A snoRNA transcript, while the pre-U3 snoRNA
transcript was obtained by using the construct described by Mougin et
al. (61). Total RNA (10 µg) from the JH84 S. cerevisiae strain (37) transformed by the pU3U14ds5'
plasmid (61) was also applied on the gel. The total RNA
fractions from the JH84 strain were prepared as described by
Méreau et al. (58). Plasmid pU3U14ds5' contains a U3
snoRNA gene carrying mutations that lead to an accumulation of
unspliced pre-U3 snoRNA and of a degraded form of the pre-U3 snoRNA in
vivo (24).
In vitro pseudouridine formation in yeast U2 snRNA
transcripts.
Two micrograms of S. cerevisiae U2
transcript dissolved in 9 µl of buffer (100 mM Tris-HCl buffer [pH
8.0] containing 100 mM ammonium acetate, 5 mM MgCl2, 2 mM
DTT, and 0.1 mM EDTA) was heated for 3 min at 80°C and cooled down to
37°C. The purified Pus1p enzyme (2.5 µg), prepared from the
recombinant E. coli strain (97) as described by
Motorin et al. (60), was added, and the reaction was
performed for 30 min at 37°C. After incubation, the modified
transcript was phenol extracted and ethanol precipitated. The presence
of pseudouridine residues was analyzed by the CMCT-RT technique as
described above.
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RESULTS |
Identification of residues in S. cerevisiae
UsnRNAs.
Two independent approaches were used for mapping residues in the S. cerevisiae spliceosomal UsnRNAs. The
first approach was based on the CMCT-RT technique developed by Bakin
and Ofengand (8). This method depends on the efficient
chemical reaction of U and residues in RNA with CMCT (very strong
for U residues, less strong for residues). Upon alkaline treatment
with bicarbonate buffer at pH 10.4, the bulky CMC group linked to the U
residues can be selectively hydrolyzed, while it remains bound to the
residues. Stops of reverse transcription at CMCT-modified allow localization of residues by primer extension analysis. Guanosine residues also react with CMCT but less efficiently than do U and .
Moreover, the CMC groups bound to G residues are easily removed by the
alkaline treatment.
The second complementary approach was based on the observation that (and also m5U) residues are resistant to hydrazine
treatment under conditions developed for chemical sequencing of RNA
(15, 78). Thus, with this analysis, the absence of
reactivity indicates the presence of one of these two
posttranscriptional modifications. The absence of hydrazine reactivity
can be detected directly by observing the cleavage pattern of purified
3'-end-labeled RNA after aniline treatment or indirectly, as described
above, by primer extension analysis with RT.
In both methods, primer extension was performed on total,
unfractionated yeast RNA prepared as described in Materials and Methods. Oligonucleotide primers allowed to explore different regions
of the yeast UsnRNA molecules. For the long U1 (568 nt in length) and
U2 snRNAs (1,175 nt), only the 5'-terminal regions (positions 1 to 50 of U1 and positions 1 to 100 of U2) were analyzed. These regions were
chosen taking into account the already localized modified nucleotides
in the U1 and U2 snRNAs of vertebrates, plants (reviewed in references
81 and 98), and S. pombe (28) (Fig. 1A and
2A). Indeed, vertebrate U1 snRNA contains
five modified nucleotides, four of which are found, respectively, at
positions 1 (Am), 2 (Um), 5 (), and 6 (), and the fifth one,
located at position 70, is a 2'-O-methylated adenosine
residue (for a review, see reference 81). Likewise,
the 5'-terminal 100-nt region of rat hepatoma U2 snRNA contains all of
the posttranscriptional modifications that were found in this snRNA (12 , 9 2'-O-methylated, and 1 m6Am residues)
(84). For the shorter U4 (160 nt), U5S (179 nt), U5L (214 nt), and U6 (112 nt) snRNAs, only a short 3'-terminal region was not
explored due to the constraint of primer extension analysis: the 30 nt
at the 3' end of the U4 snRNA, the 61 and 26 nt at the 3' extremity of
the U5L and U5S, respectively, and the 23 nt at the 3' end of the U6
snRNA.
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FIG. 1.
Localization of residues in S. cerevisiae
U1 snRNA. (A) Schematic representation of the secondary structure of
vertebrate U1 snRNA (12, 62). The residues are boxed,
and the 2'-O-methylated residues are also indicated (for a
review, see reference 55). The thick line shows the
region of rat hepatoma U1 snRNA that corresponds to the analyzed region
of S. cerevisiae U1 snRNA. The residues that were
conserved in S. cerevisiae U1 snRNA are indicated by stars.
(B) Primer extension analysis of the S. cerevisiae U1 snRNA
modified by CMCT in a total RNA fraction for 2, 10, and 20 min (lanes
2, 3, and 4, respectively). Experimental conditions were as described
in Materials and Methods. In lanes 3 and 4, the CMCT-modified RNA was
subjected to an alkaline treatment at pH 10.4 as described in Materials
and Methods. A control extension experiment was made without CMCT
treatment (lane 1). The two reverse-transcription stops, corresponding
to residues 5 and 6, are indicated by
arrows on the left of panel B. U1 snRNA in a total RNA mixture was also
treated by hydrazine under the conditions described in Materials and
Methods (lane 6). A control extension experiment was made in absence of
hydrazine (lane 5). The absence of hydrazine reactivity at positions 5 and 6 indicates the presence of a residue at these positions. Lanes
U, G, C, and A correspond to the RNA sequencing ladder. Nucleotide
positions, starting from the 5'-terminal nucleotide bound to the cap
structure, are indicated on the right. (C) Nucleotide sequence of the
analyzed region of the S. cerevisiae U1 snRNA. The
oligonucleotide used as the primer for reverse transcription is
indicated by a horizontal arrow. The two detected residues are
boxed. The secondary structure was taken from Kretzner et al.
(46).
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FIG. 2.
Localization of residues in S. cerevisiae
U2 snRNA. (A) Rat hepatoma U2 snRNA, folded according to the U2 snRNA
secondary structure model of Ares and Igel (4). The residues are boxed, the 2'-O-methylated residues and
base-methylated residues are indicated (for a review, see reference
81). The thick line shows the region of rat hepatoma
U2 snRNA that corresponds to the analyzed region of S. cerevisiae U2 snRNA. The residues that are conserved in the
S. cerevisiae U2 snRNA are marked by stars. (B) Primer
extension analysis of the S. cerevisiae U2 snRNA modified by
CMCT (lanes 2, 3, 4, and 1 [for the control]). The conditions are the
same as those for Fig. 1. The alkaline-resistant RT stops in lanes 3 and 4 revealed the presence of residues at positions 35, 42, and
44. The nucleotide sequence (3) and the secondary structure
(4, 38) of the analyzed region of S. cerevisiae
U2 snRNA are shown in panel C. The position of the primer
oligonucleotide is shown by the horizontal arrow. The identified residues are boxed.
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Only a few residues are found in the S. cerevisiae UsnRNAs.
The primer extension analysis of
U1, U2, U4, U5, and U6 snRNAs modified by CMCT was used to map the
pseudouridine residues. Incubation of the RNAs with CMCT was performed
in each case for 2, 10, or 20 min, followed or not (control experiment)
by alkaline treatment at pH 10.4. The cleavage patterns upon hydrazine
treatment were also analyzed in each case. Both approaches gave
essentially the same conclusions. Representative examples of primer
extension patterns are shown.
Figure 1B illustrates the analysis of the S. cerevisiae U1
snRNA modified by hydrazine or CMCT. As described for vertebrate UsnRNAs (Fig. 1A and 3B) (12,
83), two residues are found at positions 5 and 6 (Fig. 1B and
C and 3A). Only one of these two residues was detected in S. pombe (28). Analysis of the 5'-terminal region of
S. cerevisiae U2 snRNA by CMCT (Fig. 2B) and hydrazine
modification (data not shown) revealed the presence of three residues, respectively, at positions 35, 42, and 44 (Fig. 2C and 3A).
Three residues were found at the same positions in the rat hepatoma
(Fig. 2A and 3B) and the S. pombe U2 snRNAs, but additional
residues were also detected in these two RNAs (Fig. 3B) (28,
84). Only one residue was detected in the S. cerevisiae U5 snRNAs (Fig. 4C). It
corresponds to one of the two phylogenetically highly conserved residue found in the U5 snRNA terminal loop I (Fig. 3B)
(103). At the other conserved pseudouridylation site of this
terminal loop, the uridine residue is replaced by a cytidine residue in
S. cerevisiae (Fig. 3A). The same situation was found for
S. pombe (28). As found for U4 and U6 snRNAs from
S. pombe (28), no residues were detected in
the examined regions of U4 and U6 snRNAs (data not shown), while in the
vertebrates, three residues were detected in both U4 (47,
82) and U6 snRNAs (Fig. 3B) (33). Hence, altogether only 6 residues were detected in the S. cerevisiae
spliceosomal UsnRNAs (Fig. 3A), compared to 9 in the UsnRNAs from
S. pombe (28) and 23 in the UsnRNAs from rat
hepatoma (for a review, see reference 81).
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FIG. 3.
RNA-RNA interactions in the S. cerevisiae
spliceosomes (A) and in the GU-AG spliceosomes of higher eukaryotes
(B). The interaction between the 5' and 3' splice sites and branch-site
(BS) consensus sequences with U1 and U2 snRNAs are shown in scheme I of
panels A and B. UsnRNA-UsnRNA and UsnRNA-pre-mRNA interactions at the
catalytic center of the spliceosome are shown in scheme II of panels A
and B. Helices Ia, Ib, II, and III between U2 and U6 snRNAs are
represented, as well as the base-pairing interaction between U2 snRNA
and the branch-site sequence. The interaction between U6 snRNA and the
UGU trinucleotide, close to the 5' splice site, is indicated by
overlined residues joined by an arrow; the interaction between the
terminal loop I of U5 snRNA and the exon extremities is also shown (for
a review of all of these interactions, see reference
54). The residues are boxed, and the base and
ribose methylations are indicated in boldface (this study; for a
review, see reference 55). Nucleotide positions,
starting from the 5' extremity of each UsnRNA, are indicated.
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FIG. 4.
UsnRNA and rRNA pseudouridylation pattern in yeast
mutant strains. Mapping of residues in U2 (A), U1 (B), and U5 (C)
snRNAs by the CMCT-RT method, was performed as indicated in Fig. 1. The
total RNAs used were extracted from the wild-type S. cerevisiae (WT) and from strains carrying a disruption in one of
the PUS1, PUS2, PUS3, or
PUS4 genes or from GAL::cbf5 strain
(cbf5) grown as described in Materials and
Methods. In the case of U2 snRNA (last row of panel A), an additional
analysis was performed with total RNA extracted from the
pus1 strain transformed with plasmid
pUN100-PUS1 containing a wild-type PUS1 gene.
Lanes 1, 2, 3, and 4 correspond to the CMCT analysis according to the
legend of Fig. 1. U, G, C, and A is the sequencing ladder. To minimize
the figure size, only lanes 2 and 3 are shown for strains that show no
variation as compared to wild type. The detected residues are
indicated by arrows. The control experiment showing the absence of residues in the 26S rRNA domain II (positions 1010 to 1140) from the
GAL::cbf5 strain is shown in panel D. For the
wild-type and the GAL::cbf5
(cbf5) strains, residues in this 26S
region were mapped by CMCT as described in Materials and Methods. To
minimize the figure size, only the portion of 26S rRNA containing the
two residues 1109 and 1123 in the wild-type strain are shown.
|
|
Disruption of the PUS1 gene results in the absence of
44 in U2 snRNA.
Based on sequence homology with
known E. coli tRNA-pseudouridine synthases, several
potential RNA-pseudouridine synthases were identified in the S. cerevisiae genome (44). Three genes (PUS1,
PUS3, and PUS4) were shown to code for
tRNA-pseudouridine synthases (respectively, Pus1p, Pus3p, and Pus4p
[10, 51, 60, 97]), and a fourth one (CBF5)
was shown to be involved in pseudouridine formation in rRNA (protein
Cbf5p [50]). The target RNA for a putative
pseudouridine synthase Pus2p has not yet been determined
(97).
Total RNA was extracted from S. cerevisiae strains disrupted
for one of the nonessential PUS1, PUS2,
PUS3, or PUS4 genes. Depletion of the Cbf5p
enzyme was achieved in a GAL::cbf5 conditional strain after transfer to nonpermissive conditions for 70 h
(50; see Materials and Methods). The pseudouridine
residues in UsnRNAs were mapped by the CMCT-RT method. Since the
previous results showed that only U1, U2, and U5 snRNAs contain residues in S. cerevisiae, the analysis was limited to these
three snRNAs.
The results of the mapping analysis indicate that only the disruption
of the PUS1 gene affects formation in the spliceosomal UsnRNAs (Fig. 4). Conversion of U into residues in U1, U2, and U5
UsnRNAs was unaffected by Cbf5p depletion under conditions where formation in pre-rRNA was strongly inhibited. This is illustrated by
the analysis of the 26S rRNA segment (positions 1010 to 1140) that we
performed together with the UsnRNA analysis (Fig. 4D) (50).
Compared to a wild-type strain (WT), the pus1
strain differed by the disappearance of 44 in U2 snRNA
(Fig. 4A, compare lanes 3 and 4 [WT] to lanes 3 and 4 [pus1]). No apparent change at the other
positions (35 and 42) in U2 snRNA (Fig. 4A), as well as at positions 5 and 6 of U1 snRNA (Fig. 4B) and position 99 in U5 snRNA (Fig. 4C), was detected.
Pus1p catalyzes the pseudouridylation of U44 in U2
snRNA in vivo and in vitro.
To verify that Pus1p directly
catalyzes formation at position 44 of U2 snRNA, the
pus1 disrupted strain was transformed with
plasmid pUN100-PUS1 (97) containing a wild-type
PUS1 gene. As shown in Fig. 4A (lanes 2 and 3 pus1 + pUN100-PUS1), formation
at position 44 of U2 snRNA was completely restored in the transformed
yeast cells.
The capacity of the yeast Pus1p enzyme to catalyze U to conversion
at position 44 in U2 snRNA was also tested in vitro. To this end, we
used a recombinant Pus1p enzyme purified from E. coli
(60) and an in vitro-produced T7 transcript of the S. cerevisiae U2 snRNA. The results of CMCT mapping demonstrate the efficient formation of 44 in the U2 snRNA transcript and
show that only this residue is modified in vitro (Fig.
5).
View larger version (36K):
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|
FIG. 5.
In vitro pseudouridylation of U2 snRNA transcript by
using recombinant Pus1p pseudouridine synthase. After incubation of the
transcript with the purified Pus1p enzyme (as described in Materials
and Methods), the phenol-extracted RNA was analyzed by the CMCT-RT
method (lanes 1, 2, 3, and 4) as described in the legend to Fig. 1. The
strong alkaline-resistant RT stop at position 44 is indicated by an
arrow. Lanes U, G, C, and A correspond to the sequencing ladder.
|
|
The absence of 44 in U2 snRNA does not influence
pre-mRNA and pre-U3 snoRNA splicing.
Although no apparent growth
defect was found for the PUS1 gene deletion (97),
it was interesting to test whether the absence of a at position 44 in U2 snRNA could affect the efficiency of pre-mRNA splicing. We tested
this possibility on the rp51A pre-mRNA, the precursor for the mRNA of
the S. cerevisiae rp51A ribosomal protein (87).
To this end, using primer-extension analysis in conditions allowing
quantification of the RNA template, we compared the relative yields of
rp51A mRNAs and pre-mRNA in total RNA extracted from the wild-type and
the pus1 strains grown until mid-exponential
phase. U1 snRNA, which was not spliced in S. cerevisiae, was
used as an internal control. In both strains, no rp51A pre-mRNA was
accumulated (not shown). Only the two cDNA products corresponding to
the two rp51A mRNAs previously described (1, 107) were
detected (Fig. 6A). As shown in Fig. 6,
only a very slight decrease of the rp51A mRNA concentrations in total
RNA was observed in the absence of residue 44 in U2
snRNA. Based on the rp51A mRNA/U1 snRNA ratio, estimated by
PhosphorImager measurement, the rp51A mRNA concentration in total RNA
was only reduced by 10% in the absence of residue 44 in
U2 snRNA. The observed difference is at the limit of the accuracy of
mRNA quantification by primer extension analysis.
View larger version (45K):
[in this window]
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|
FIG. 6.
No marked effect of the PUS1 gene deletion on
rp51A pre-mRNA and pre-U3 snoRNA splicing. In panel A, total RNA
extracted from wild-type (WT) and the pus1
strains were analyzed by primer extension analysis under the conditions
described in Materials and Methods that allow rp51A pre-mRNA and mRNA
quantification. The pus1 strain primer
extension analyses with the rp51A primer were performed on 10 µg
(lane 5), 20 µg (lane 6), or 50 µg (lane 7) of total RNA, and for
the wild-type strain the experiments were performed with 10 (lane 8) or
50 µg (lane 9) of total RNA, respectively. Control extension
experiments with the U1 primer were performed with 5 µg (lanes 1 and
3) or 15 µg (lanes 2 and 4) of total RNA. The cDNA fractionation was
performed on a 5% sequencing gel; only the portions of the gel
corresponding to the two expected rp51A mRNA extension products are
shown. The cDNA amounts in the U1 and rp51A bands of gel were estimated
by PhosphorImager measurement. In panel B, total RNA extracted from the
wild-type and the disrupted pus1 strains was
analyzed by Southern blot hybridization by using a labeled
oligonucleotide complementary to the yeast U3 snoRNA from position 1 to
16 (92). In vitro transcripts corresponding to the pre-U3
snoRNA and the U3 snoRNA, respectively, were used as controls (the two
lanes on the left), as well as the total RNA extracted from a
pU3U16ds5' strain that shows the accumulation of unspliced and degraded
pre-U3 snoRNA (24). The 32P amounts in the U3
signals obtained for the wild-type and pus1
strains were compared by PhosphorImager analysis.
|
|
Since the S. cerevisiae U3 snoRNA is produced from a
precursor RNA that is spliced in a spliceosome and since the
branch-point sequence of the U3 snRNA intron shows a substitution at
the 5' extremity compared to the consensus branch-site sequence
(64), we tested whether splicing of this substrate may be
more dramatically alterated by the absence of a residue at position
44 of U2 snRNA. For this purpose, Northern blot analysis was performed
with total RNA extracted from the wild-type and the
pus1 strains (Fig. 6B). An S. cerevisiae strain carrying a mutant U3 snoRNA gene that produces a
pre-U3 snoRNA with a splicing defect (plasmid pU3U14ds5')
(61) was used as a control. In this strain, the pre-U3
snoRNA and its main degradation product accumulate (24). As
shown in Fig. 6B, the level of mature U3 snoRNA was very slightly
decreased in the absence of 44 in U2 snRNA. However, here again it was at the limit of the accuracy of this kind of experiment. Furthermore, no accumulation of the U3 snoRNA precursor was
detected. Hence, at least for the two pre-RNAs tested, the presence of
a residue at position 44 of U2 snRNA did not show a strong effect
on splicing efficiency. As no precursor accumulation was detected, the
slight differences observed were perhaps not due to a splicing defect
but to differences in RNA stability in the
pus1 strain.
| |
DISCUSSION |
S. cerevisiae spliceosomal UsnRNAs contain a few residues located at sites of RNA-RNA or RNA-protein interactions.
We detected only six residues in the studied regions of S. cerevisiae UsnRNAs. This is significantly lower than the 23 and 20 residues found in the corresponding parts of rat hepatoma and plant
UsnRNAs, respectively (for a review, see reference
55). A low number of residues in RNAs seems to
be a general feature of yeasts, as only nine residues were detected
in the S. pombe spliceosomal UsnRNAs (28), and a
low level of residues was also observed for rRNAs and tRNAs in
yeasts (7, 9, 16, 100).
Despite the absence of phenotype when there was a lack of formation
at position 44 of the S. cerevisiae U2 snRNA and the very
low effect that we detected on the level of rp51A mRNAs and U3 snoRNA,
which are among the very few S. cerevisiae RNAs
processed in a spliceosome, it is noteworthy that the six residues
that we detected in S. cerevisiae UsnRNAs are
evolutionarilly conserved. Furthermore, they are all located in
or very close to the UsnRNA segments involved in intermolecular RNA-RNA
interactions within the spliceosomes (Fig. 3A). Altogether, this
suggests that at least some of them may have a functional importance.
In U1 snRNA, the two residues detected are located in the segment
that base pairs with the 5' extremity of introns. Posttranscriptional
modifications at position 5 and 6 of the U1 snRNA are nearly universal.
Two residues are found at these positions in vertebrates and
insects (Fig. 3B), in plants a m residue is present at position 5 and a Um residue is found at position 6. Surprisingly, only position 5 shows a posttranscriptional modification in S. pombe
(28). In the S. cerevisiae U1 snRNA-intron
interaction, residue 5 of U1 snRNA faces residue
U4 of the intron (Fig. 3A). The presence of a U residue at
position 4 of yeast introns is required for the interaction with U6
snRNA in the active conformation of the spliceosome (Fig. 3A) (41,
52, 91), and the conversion of the
5-U4 pair into a canonical Watson-Crick pair
in the U1 snRNA-intron interaction results in a 50% increase of the
cell doubling time (96). In this context, formation at
position 5 of U1 snRNA may be of functional importance.
Among the 12 residues detected in the rat hepatoma U2 snRNA (Fig.
2A and 3B), only 3 are conserved in the S. cerevisiae U2
snRNA (Fig. 2C and 3A). None are found in the 27-nt 5'-terminal segment, whose modification at the posttranscriptional level was found
to be essential for vertebrate U2 snRNA function (120). However, residue 35 may be of high functional
importance, since it is involved in one of the two canonical base pairs
that bulge out the A residue responsible for the nucleophilic attack in
the first step of the splicing reaction. Helix stabilization by the presence of a -A pair (reviewed in references 2,
6, and 21) may be the reason for the
universal conservation of a residue at this position. In addition,
since it was shown for vertebrates that the branch-point bulged
structure is recognized by proteins (26, 80; for a
review, see reference 85), residue 35
may also be involved in this recognition. The presence of a second
-A pair in the vertebrate U2 snRNA-branch site interaction (Fig. 3B)
may be needed to compensate for the high degree of degeneracy of the
vertebrate branch-site sequence (for reviews, see references 39 and 89).
Using in vitro splicing assays, the effect of base substitutions on
splicing efficiency was tested for almost all residues of the
5'-terminal region of the S. cerevisiae U2 snRNA
(56). Mutations at position 35 resulted in a strong decrease
in the splicing efficiency. Pascolo and Séraphin (72)
tested the effect of compensatory mutations in the branch-site sequence
and its U2 snRNA recognition element in vivo. However, the data
obtained for the U2 35-branch site A5 pair
are not sufficient to determine whether the presence of a residue
at position 35 is required for high splicing efficiency.
The S. cerevisiae Prp5, Prp9, Prp11, Prp21, and Cus1
proteins, which are homologous to proteins from the human splicing
factors SF3a and SF3b, associate with the S. cerevisiae U2
snRNA region from position 40 to 87 (36, 88, 110, 111, 119).
This region contains the residues 42 and 44. In addition, the
segments from positions 42 to 46 in the S. cerevisiae U2
snRNA and from positions 42 to 49 in the vertebrate U2 snRNA were found
to form a base-pair interaction with U6 snRNA (Fig. 3). Such
interaction delineates helix III, which is needed for active
spliceosome formation in HeLa cells (102). In S. cerevisiae, no growth defect was detected for base substitution at
positions 42 of U2 snRNA (119). This argues against an
essential role of the U-to- conversion at position 42. Mutations at
position 44 strongly affected growth (119). However, based
on the absence of phenotype after deletion of the PUS1 gene
(reference 97 and this study), the defect was not related to the absence of a U-to- conversion at this position. Indeed, a proposed explanation of the defect was that the replacement of U44 (in fact, 44) by an A or a G residue
favors an alternative conformation of U2 snRNA which impairs active
spliceosome formation (119).
The residue at position 99 in the 5'-terminal loop of U5 snRNA is
at the border of the segment that interacts with the exon extremities.
Crystallographic and nuclear magnetic resonance studies of the yeast
tRNAAsp and tRNAGln showed an essential role
for 32 and 38 residues in the anticodon loop for maintaining the conformation required for proper anticodon recognition (5, 21, 22, 112, 113). As referred to this model, it may be that the U5 snRNA 99 favors a
conformation of the U5 snRNA 5'-terminal loop, which facilitates the
correct alignment of exons. In connection with this hypothesis, it
should be noticed that mutations affecting the 5'-terminal loop of
S. cerevisiae U5 snRNA block splicing after the first step
of the reaction (68).
In conclusion, based upon available genetic data and the present work,
four of the six residues detected in the S. cerevisiae spliceosomal UsnRNAs belong to RNA segments involved in intermolecular interactions and may be of high functional importance. The other two
are not essential taken individually. However, their conservation from
yeasts to humans suggests that they may provide some selective advantage, which is difficult to test in laboratory conditions.
Among several characterized yeast pseudouridine synthases, only the
Pus1p tRNA-pseudouridine synthase acts on spliceosomal UsnRNAs.
In
yeast tRNAs, residues are found at 15 different locations, and at
least five or six distinct enzymes are required for complete
pseudouridylation of tRNAs. Only three of them, Pus1p (60),
Pus3p (51), and Pus4p (10) have been
characterized. The S. cerevisiae 17S and 26S rRNAs contain,
respectively, 13 and 30 residues (16, 69, 70). The
recent discovery of the snoRNA-guided mechanism of eukaryotic rRNA
pseudouridylation has allowed to assign the Cbf5p (in yeast) and NAP57
(in higher eukaryotic) enzymes as the ones which act on the rRNA-snoRNP
complex (25, 50). The S. cerevisiae pseudouridine
synthases responsible for U isomerization in UsnRNAs have not been
investigated so far. Studies of UsnRNA-specific pseudouridine synthases
have been restricted to human cells. The results obtained revealed the
presence of several distinct pseudouridine synthases; however, none of
them was identified or cloned (73-75, 77, 121, 122).
Since no decrease of the level of residues was observed in UsnRNAs
upon Cbf5p protein depletion, whereas synthesis in rRNA was
strongly affected, our results strongly suggest that the Cbf5p enzyme
is not involved in the pseudouridylation of UsnRNAs in S. cerevisiae. This implies that the U-to- conversion in the S. cerevisiae spliceosomal UsnRNAs is not based on the
snoRNA guide mechanism involving the Cbf5p enzyme (50). This
is in contrast to the recently reported mechanism of
2'-O-methylation of the vertebrate U6 snRNA (43,
108). Our results, obtained for yeasts, do not rule out the
possibility that some pseudouridylation in the vertebrate U6 snRNA is
generated by the snoRNA-guided mechanism. The nonimplication of Cbf5p
in S. cerevisiae spliceosomal UsnRNA pseudouridylation may
simply be due to the absence in S. cerevisiae U6 snRNA of an
appropriate U residue that can be modified by the Cbf5p-snoRNA system.
A larger number of residues are present in the vertebrate U6 snRNA
(33), and some of them may be generated by a snoRNA-guided mechanism.
Two of the characterized S. cerevisiae pseudouridine
synthases were found to act on tRNAs: Pus3p catalyzes the U
isomerization at positions 38 and 39 in tRNAs (51), and
Pus4p catalyzes the isomerization at position 55 (10). Our
data show that these enzymes are not involved in the modification of
UsnRNAs. Both of them are highly dependent on the global tRNA
three-dimensional structure (10, 51), which probably
explains their absence of reactivity on UsnRNAs. In contrast, Pus1p
catalyzes formation at eight different sites in various tRNAs
(positions 26 to 28, 34 to 36, 65, and 67) (60).
Pseudouridine formation at the anticodon positions 34, 35, and 36 depends on the presence of an intron in tRNA, but it does not require
the intact three-dimensional tRNA architecture (97, 104).
These results obtained with tRNA substrates allowed the authors of
these studies to conclude that Pus1p recognizes only a limited
structural domain in RNA. The results presented here demonstrate that
Pus1p is also capable of modifying, both in vivo and in vitro, one of
the uridine residues (U44) in U2 snRNA. Evidently, this
enzyme shows a dual specificity for both tRNA and snRNA.
The only well-documented case of a pseudouridine synthase with
substrate dual specificity concerns the E. coli
pseudouridine synthase RluAp. This enzyme catalyzes U-to- conversion
at position 32 in several tRNAs and at position 746 in 23S rRNA
(115). This dual specificity towards tRNA and rRNA was
observed in vitro with synthetic RNA transcripts. In this case, the
dual specificity was attributed to the recognition of a consensus
sequence (UUNAAAA, where N is any of the four nucleotides) that is
present in both the tRNA anticodon loop and in the loop of 23S rRNA
bearing residue U746. Similarly, the E. coli
tRNA-U54-methyltransferase catalyzes the in vitro
formation of m5U54 in tRNA and
m5U788 in a 16S rRNA fragment produced by in
vitro transcription (29). However, no m5U
residue has been found in naturally occurring E. coli rRNA, attesting that in vitro assays do not necessarily reflect the in vivo situation.
How does Pus1p act on substrates with different architectures? From the
present results, we can conclude that Pus1p does not require an
external guide RNA for the formation of 44 in U2 snRNA, since we obtained 44 formation in vitro by using an RNA
transcript and the purified enzyme. Previous results on tRNA
modification suggest that Pus1p requires a double-stranded RNA portion
for binding, while the target uridine should be present in a rather flexible RNA structure (internal loop or even single-strand)
(60). The target nucleotide in U2 snRNA is in a
single-stranded region, which was confirmed by secondary-structure
probing on the U2 snRNA transcript (data not shown), and no common
sequence element was found for Pus1p target sites in tRNAs and in U2
snRNA. To identify the determinants required for U-to- conversion at
position 44 by the Pus1p enzyme, a mutational analysis of the U2 snRNA
target site is underway.
The presence of numerous and 2'-O-methylated residues in
eukaryotic tRNAs, rRNAs, and UsnRNAs raises the important question of
how many enzymes are required to account for all of these
posttranscriptional modifications. To minimize the number of required
enzymes, the cell seems to use two main strategies: (i) the involvement
of guide RNAs conferring different specificities to a unique enzymatic machinery and (ii) the utilization of a unique multisite-specific enzyme that allows the formation of posttranscriptional modifications at different locations in a given type of RNA, as well as in different RNA substrates, and this is exemplified by our observation with the
Pus1p enzyme.
However, the observation that Pus1p catalyzes only one of the residues detected in the S. cerevisiae UsnRNAs is in
agreement with the previous observation for vertebrate UsnRNAs
showing the involvement of several pseudouridine synthases
(73-75). Other putative pseudouridine synthase genes are
present in the S. cerevisiae genome, and we have initiated
systematic gene disruption experiments in order to identify the enzymes
responsible for the formation of the five other residues that were
detected in this study.
| |
ACKNOWLEDGMENTS |
This work was supported by laboratory funds from the
Ministère de la Recherche et de l'Enseignement Supérieur,
the CNRS, specific research grants from the CNRS (Programme Physique et Chimie du Vivant 1997) and the Action de Recherche sur le Cancer. S. Massenet is a predoctoral fellow supported by a fellowship from the
Ministère de la Recherche et de l'Enseignement Supérieur. Y. Motorin is the recipient of an Associated Researcher position at the
CNRS (Poste Rouge). D. L. J. Lafontaine was the recipient of
a fellowship from the European Commission.
The plasmids containing yeast UsnRNA genes were kindly provided by P. Fabrizio (Institut für Molekularbiologie and Tumorforschung, Marburg, Germany). We also thank R. Planta (University of Amsterdam, Amsterdam, The Netherlands) for providing the yeast strain with a
disrupted PUS4 gene and G. Simos for providing the
PUS1, PUS2, and PUS3-disrupted
strains. D. Tollervey (University of Edinburgh, Edinburgh, United
Kingdom) is thanked for the GAL::cbf5
RNA preparation, prepared in his laboratory. J. Ugolini is thanked for
technical assistance. A. Mougin is acknowledged for useful advice at
the beginning of this work. We also thank J.-P. Waller (CNRS,
Gif-sur-Yvette, France) for critical reading of the manuscript and for
useful comments.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratoire de
Maturation des ARN et Enzymologie Moléculaire, UMR7567 CNRS-UHP
Nancy I, Faculté des Sciences, BP 239, 54506 Vandoeuvre-les-Nancy
Cédex, France. Phone: 33-3-83-91-20-92. Fax: 33-3-83-91-20-93. E-mail: cbranlant{at}scbim.u-nancy.fr.
| |
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Abstract
Introduction
