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Molecular and Cellular Biology, July 2000, p. 4591-4603, Vol. 20, No. 13
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Upf1p Control of Nonsense mRNA Translation Is
Regulated by Nmd2p and Upf3p
Alan B.
Maderazo,
Feng
He,
David A.
Mangus, and
Allan
Jacobson*
Department of Molecular Genetics and
Microbiology, University of Massachusetts Medical School,
Worcester, Massachusetts 01655-0122
Received 20 October 1999/Returned for modification 18 January
2000/Accepted 4 April 2000
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ABSTRACT |
Upf1p, Nmd2p, and Upf3p regulate the degradation of yeast mRNAs
that contain premature translation termination codons. These proteins
also appear to regulate the fidelity of termination, allowing
translational suppression in their absence. Here, we have devised a
novel quantitative assay for translational suppression, based on a
nonsense allele of the CAN1 gene (can1-100),
and used it to determine the regulatory roles of the
UPF/NMD gene products. Deletion of UPF1,
NMD2, or UPF3 stabilized the
can1-100 transcript and promoted can1-100
nonsense suppression. Changes in mRNA levels were not the basis of
suppression, however, since deletion of DCP1 or
XRN1 or high-copy-number can1-100 expression in
wild-type cells caused an increase in mRNA abundance similar to
that obtained in upf/nmd cells but did not result in
comparable suppression. can1-100 suppression was highest in
cells harboring a deletion of UPF1, and overexpression of
UPF1 in cells with individual or multiple
upf/nmd mutations lowered the level of nonsense suppression without affecting the abundance of the can1-100 mRNA.
Our findings indicate that Nmd2p and Upf3p regulate Upf1p activity and
that Upf1p plays a critical role in promoting termination fidelity that
is independent of its role in regulating mRNA decay.
Consistent with these relationships, Upf1p, Nmd2p, and Upf3p were shown
to be present at 1,600, 160, and 80 molecules per cell,
levels that underscored the importance of Upf1p but minimized
the likelihood that these proteins were associated with
all ribosomes or that they functioned as a stoichiometric complex.
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INTRODUCTION |
The pathways of gene expression
include intricate mechanisms that safeguard against the accumulation of
aberrant transcripts and proteins (6, 13, 14, 19, 30, 62).
In addition to their protective functions, these pathways also
contribute additional regulatory facility and complexity
(57). The phenomenon of nonsense-mediated mRNA decay
(NMD) exemplifies such mechanisms. NMD minimizes the synthesis of
truncated polypeptides by eliminating mRNAs containing premature
nonsense codons within their protein coding regions (19, 29, 39,
45, 46, 49, 51). NMD also provides the cell with a pathway for
the selective degradation of a subset of mRNAs whose coding regions
could be considered "normal" (37, 57).
In the yeast Saccharomyces cerevisiae, the rapid degradation
of nonsense-containing mRNAs proceeds from
deadenylation-independent removal of the 5' cap by the decapping enzyme
Dcp1p to 5'
3' digestion of the remainder of the mRNA by the
exoribonuclease Xrn1p (4, 5, 17, 27, 33, 40). Three
additional factors are also essential for NMD in yeast: Upf1p, Nmd2p
(Upf2p), and Upf3p (7, 20, 22, 34, 35). Mutations in the
UPF1, NMD2, or UPF3 genes lead to the
stabilization of mRNAs containing premature nonsense codons without
affecting the rates of decay of most wild-type mRNAs. Since single
or multiple mutations within UPF1, NMD2, or UPF3 yield similar decay phenotypes, all three gene products
have been considered to be functionally related and to act in a
common pathway (22). Substantial support for this conclusion
has been derived from protein-protein interaction analyses
(11, 22).
A more detailed understanding of the functions of Upf1p, Nmd2p, and
Upf3p has been sought in several ways. Consistent with their roles in
responding to aberrant translation, all three proteins have been shown
to localize to the cytoplasm and to associate with polyribosomes
(3, 38, 46). Upf1p is a 109-kDa protein that contains two
putative zinc finger domains near its amino terminus and harbors seven
motifs characteristic of RNA-DNA helicase superfamily I (1,
31). In vitro studies demonstrated that purified Upf1p has the
ability to bind nucleic acids and that its ATPase and helicase
activities are dependent upon nucleic acid binding (10, 60).
Upf1p interacts with the polypeptide release factors Sup35p and Sup45p
(11) and utilizes the same N-terminal zinc finger region for
Nmd2p interaction, intramolecular interaction, and homodimerization (F. He and A. Jacobson, unpublished data). Little is known about the
biochemical activities of the 127-kDa Nmd2p and 45-kDa Upf3p polypeptides.
The involvement of the UPF/NMD genes in regulating the
stability of mRNAs containing premature nonsense codons and the
interactions of Upf1p with Nmd2p, Upf3p, Sup35p, and Sup45p suggest
that UPF1, NMD2, and UPF3 may all be
regulators of translation termination and/or fidelity. Consistent with
this notion are experiments which indicate that deletion of these genes
leads to nonsense suppression (36, 58), allosuppression
(9), and enhancement of programmed ribosomal frameshifting
(8, 52). To investigate further the possible regulatory
roles of Upf1p, Nmd2p, and Upf3p, we devised an assay that
quantitatively monitors the effects of upf/nmd mutations on
suppression of the can1-100 nonsense allele. Deletion of the genes encoding each of these factors was found to stabilize the can1-100 transcript and promote nonsense suppression.
Strains harboring a deletion of UPF1 showed the highest
levels of suppression, and overexpression of UPF1 in
upf/nmd strains lowered the levels of nonsense suppression
significantly without altering the steady-state levels of the
can1-100 mRNA. These data and determinations of the
abundance of all three factors indicate that Upf1p plays a critical
role in regulating the efficiency of translation termination and that
Nmd2p and Upf3p, in turn, regulate Upf1p activity.
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MATERIALS AND METHODS |
Strains, plasmids, and general methods.
The isogenic yeast
strains used in this study are listed in Table
1. Preparation of standard yeast media
and cell culturing were done as described by Rose et al.
(50). Transformation of yeast strains was done by the rapid
method described by Soni et al. (55). DNA manipulations were
performed according to standard techniques (53). All PCR
amplifications were performed with Taq DNA polymerase
(61) and confirmed, where appropriate, by DNA sequencing
using the method described by Sanger et al. (54). The
can1-100 allele (28), characterized in this study
by DNA sequencing (see Results), was recreated in a
YEp24-CAN1 high-copy-number plasmid and a
pRIP-CAN1 single-copy plasmid by PCR mutagenesis. CAN1 containing sequences that comprised a 3'
triple-hemagglutinin (HA) epitope tag was obtained from Duane Jenness.
The 3'-HA-tagged can1-100 allele was constructed by
inserting a SalI-EagI HA-containing fragment into
the YEp24-can1-100 plasmid digested with the same enzymes.
Plasmid DNAs were prepared from Escherichia coli DH5
RNA extraction and Northern blot analysis.
RNA was isolated
using the hot phenol method as described by Herrick et al.
(24). Aliquots (20 µg) of each RNA sample were analyzed by
Northern blotting using radiolabeled probes prepared by random priming
(12). mRNA steady-state levels were determined by
quantitating Northern blots with a Bio-Rad Molecular Imager. The DNA
probes used to detect specific transcripts included CYH2 (a
600-bp EcoRI-HindIII fragment from
pGEM4Z-CYH2 which hybridizes to both the pre-mRNA and the mRNA)
(24), CAN1 (a 1-kb
EcoRI-SalI fragment from YEp24-CAN1),
and SCR1 (a 400-bp fragment amplified from yeast
genomic DNA using oligonucleotides SCR1-1
[5'-AGGCTGTAATGGCTTTCTGGTGGGATGGGA-3'] and SCR1-2
[5'-GATATGTGCTATCCCGGCCGCCTCCATCAC-3']).
Immunoprecipitation of capped mRNAs was performed as
described by Muhlrad et al. (40) using polyclonal
anti-m7G antibodies generously provided by Elsebet Lund.
Protein gels, Western blots, and antibodies.
Sodium dodecyl
sulfate-polyacrylamide gel electrophoresis was performed as described
by Laemmli (32). Gels were electroblotted to Immobilon-P
membranes (Millipore) under conditions recommended by the manufacturer.
The binding conditions used for antibodies were as described by Harlow
and Lane (18). Detection was enhanced by chemiluminescence
with an ECL kit from Amersham Corp. Western blots were quantitated by
densitometry or by Fluor-S (Bio-Rad) scanning of films exposed for
different lengths of time. The anti-HA antibody (12CA5) used for
Western blotting was obtained from Boehringer Mannheim Biochemicals.
Purification of recombinant GST-Upf1p and GST-Nmd2p.
Extraction steps were carried out at between 0 and 4°C. All buffers
included 0.1 mM dithiothreitol (DTT), 1 mM phenylmethylsulfonyl fluoride, and the protease inhibitors bestatin (0.35 µg/ml),
pepstatin (0.4 µg/ml), leupeptin (0.5 µg/ml), and benzamidine (20 µg/ml). Cell pellets were resuspended in 4 volumes of T(50) buffer
(30 mM Tris-HCl [pH 7.9] 2 mM EDTA, 5% glycerol, 10 mM
MgCl2, 50 mM KCl) per g of cell wet weight and lysed with a
French press (cell pressure, 20,000 lb/in2). Lysates were
cleared by centrifugation at 30,000 × g. The pellet was resuspended in denaturing buffer (6 M urea, 50 mM Tris-HCl [pH
7.9], 1 mM EDTA, 8 mM DTT), vortexed vigorously, homogenized with a B
pestle, and centrifuged at 30,000 × g. Chromatography steps were carried out at room temperature. The supernatant was dialyzed against a buffer containing 50 mM Tris-HCl [pH 7.9], 1 mM
EDTA, 1 mM DTT, and 20% glycerol. Extracts were bound in batches to
glutathione-agarose (Sigma) previously equilibrated in T(50) buffer.
After binding for 10 min on a platform shaker, the resin was washed
three times with the same buffer. The resin was then transferred to a
small column, and the protein was eluted with 10 column volumes of
T(50) buffer containing 10 mM glutathione (Sigma). The purity of the
protein was assessed by sodium dodecyl sulfate-polyacrylamide
electrophoresis and staining with Coomassie blue R-250. Glutathione
S-transferase (GST)-Upf1p (residues 876 to 971) was greater
than 99% pure and was the only protein detected, while GST-Nmd2p was
greater than 90% pure, with the majority of the contamination coming
from proteolysis.
Quantitation of mRNA decay factors.
The relative
abundance of Upf1p, Nmd2p, and Upf3p was determined by comparing the
Western blot band intensities of the factors present in crude cell
extracts to those of specific standards. For Upf1p, purified
recombinant GST-Upf1p (residues 876 to 971) was used as a standard; for
Nmd2p, purified recombinant Nmd2p was used as a standard; and for
Upf3p, cells bearing an HA-NMD2 allele were used as a
standard. For Western blotting, aliquots of crude cell extracts
equivalent to 1 ml of cells at an optical density at 600 nm
(OD600) of 0.2 were loaded onto polyacrylamide gels. The
number of cells in each aliquot was determined by serially diluting and
plating the cultures.
can1-100 nonsense suppression assay.
Multiple
independent isolates of yeast strains to be assayed were grown in
selective liquid media to mid-log phase (OD600 = 0.5 to 0.7). Samples from these cultures were serially diluted (1:10) four
times, and aliquots (10 µl) of the four dilutions were spotted on
SC-arg plates containing 0 to 500 µg of canavanine per ml. The final
aliquots, used as the principal indicators of canavanine sensitivity,
each contained approximately 100 cells. Growth on plates, monitored
after incubation at 30°C for 2 days, yielded reproducible results for
each strain.
Arginine uptake assay.
The arginine uptake assay was adopted
from that previously described by Opekarova and Kubin (43).
Yeast cultures were grown to mid-log phase (OD600 = 0.5 to 0.7) at 30°C in SC-arg medium and then supplemented with 50 mM
L-arginine containing 5 µCi of L-[3H]arginine (Amersham). Aliquots of the
cultures were then removed at specific intervals, diluted in 2 ml of
100 mM LiCl, filtered on GF/C filters (Whatman), and washed with 2 ml
of water. Radioactive arginine associated with each filter was
determined by scintillation counting.
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RESULTS |
The can1-100 transcript is a substrate for NMD.
To
address the roles of UPF1, NMD2, and
UPF3 in translation termination, we devised a quantitative
assay for nonsense suppression, i.e., readthrough of a premature
termination codon. This assay exploited the yeast CAN1 gene,
which encodes a high-affinity permease (Can1p) responsible for the
transport of arginine into cells (26). Previous studies
indicated that a can1 allele, can1-100, was
attributable to a nonsense mutation because it could be suppressed in
strains containing an ochre suppressor tRNA (28). We
confirmed this conclusion by sequence analysis of the
can1-100 allele, identifying a single A-to-T mutation that
results in the substitution of a lysine codon at position 47 of the
CAN1 coding region with a UAA codon (data not shown).
The occurrence of a premature termination codon in the
can1-100 mRNA led us to predict that it would be a
substrate for NMD.
To test this possibility, single deletions of
UPF1,
NMD2, or
UPF3 were constructed
in yeast strains that harbored the
can1-100 allele,
and the
effects of these mutations on the abundance of the
can1-100 transcript were examined. Northern analyses
of mRNA steady-state
levels demonstrated that the
can1-100 transcript was approximately
fourfold more abundant
in
upf/nmd cells than in the isogenic
UPF/NMD strain (Fig.
1A). Likewise, deletion of
genes encoding general
factors involved in mRNA decay (i.e.,
DCP1 and
XRN1) also promoted
a fourfold increase
in
can1-100 transcript abundance (Fig.
1A).
These
differences in mRNA abundance were consistent with the respective
differences in the rates of decay of the
CAN1 and
can1-100 mRNAs
in wild-type cells (half-lives of 8 and 2 min, respectively; data
not shown). As a control for the experiments
shown in Fig.
1A,
the abundance of an endogenous substrate of the NMD
pathway (
19)
was monitored. As expected, this experiment
showed that the
CYH2 pre-mRNA was barely detectable in
wild-type cells and was abundant
in all of the mutants. These
results indicate that the
can1-100 mRNA requires Upf1p,
Nmd2p, Upf3p, Dcp1p, and Xrn1p for its degradation
and that it is thus
a typical substrate for NMD.
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FIG. 1.
Deletion of UPF1, NMD2, or
UPF3 stabilizes the can1-100 transcript and
promotes nonsense suppression. (A) Deletion mutants that inactivate NMD
stabilize the can1-100 transcript. Total RNA isolated from
yeast strains with the indicated UPF/NMD genotypes was
analyzed by Northern blotting with DNA probes that detected the
can1-100 and CYH2 transcripts. WT,
wild type. (B) Deletion of UPF1, NMD2, or
UPF3 leads to a canavanine-sensitive phenotype. Aliquots (10 µl) of each of four 1:10 dilutions of liquid cultures of each yeast
strain were spotted on SC-arg plates containing either 0 or 100 µg of
canavanine per ml ( Canavanine or + Canavanine, respectively)
and grown at 30°C for 2 days. (C) Deletion of DCP1 or
XRN1 does not suppress the can1-100 mutation.
Aliquots of serial 1:10 dilutions of each yeast strain were spotted on
plates without or with canavanine as in panel B. Because these two
mutants had slow doubling times, growth comparable to that of wild-type
cells was obtained by maintaining the xm1 strain at
30°C for 3 days and the dcp1 strain at 30°C for 4 days.
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Quantitative assay for nonsense suppression.
Mutations in the
UPF1, NMD2, or UPF3 genes have been
found to lead not only to increased abundance of substrate mRNAs
but also to suppression of certain nonsense alleles, including
leu2-2 and tyr7-1 (36, 58). To
investigate nonsense suppression of the can1-100 allele, we
took advantage of the observation that canavanine, a toxic arginine
analog, is also transported into cells via Can1p (15).
can1-100 cells are thus phenotypically canavanine resistant,
and sensitivity to canavanine is indicative of can1-100 suppression.
Figure
1B illustrates the canavanine resistance of
can1-100
cells and demonstrates that deletion of
UPF1,
NMD2, or
UPF3 results
in a canavanine-sensitive
phenotype when these cells are grown
on media containing 100 µg of
canavanine per ml. Although deletion
of
DCP1 and
XRN1 led to
can1-100 mRNA stabilization
comparable
to that seen in
upf1,
nmd2, or
upf3 mutants (Fig.
1A), strains
with the former deletions
did not exhibit canavanine sensitivity
(Fig.
1C). These results
indicate that deletion of any of the
UPF/NMD genes allows
for suppression of the
can1-100 nonsense
mutation and that
increased mRNA abundance alone is not sufficient
to promote
suppression (see
below).
To quantitate the extent of nonsense suppression in the different
mutant strains, they were grown on plates containing increasing
amounts
of canavanine, and the concentration at which each strain
exhibited a
canavanine-sensitive phenotype was determined. In
this assay,
canavanine sensitivity is defined as the minimum concentration
of
canavanine required to kill all cells at the end point of a
serial
dilution, i.e., approximately 100 cells. These experiments
demonstrated
that deletion of
UPF1,
NMD2, or
UPF3
promoted different
extents of
can1-100 suppression. For
example, Fig.
2A shows that
40 µg of
canavanine per ml was sufficient to kill
upf1 cells
but
was only partially toxic to comparable numbers of
nmd2 or
upf3 cells. Similar assays consistently demonstrated that
the
highest levels of nonsense suppression occurred in
upf1 cells,
which exhibited 12-fold greater sensitivity
to canavanine than
the isogenic wild-type strain (Fig.
2B). Suppression
was found
to be lower in
nmd2 and
upf3
cells, which exhibited 1.5-fold
less sensitivity than
upf1 cells (Fig.
2). Although the canavanine
sensitivities of the
nmd2 and
upf3 strains
were almost identical,
subtle differences were detected which indicated
that the
nmd2 mutation was a slightly more effective
suppressor than the
upf3 mutation (Fig.
2).
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FIG. 2.
Deletion of UPF1 promotes higher levels of
can1-100 nonsense suppression than deletion of
NMD2 or UPF3. (A) Growth of yeast strains with
different UPF/NMD genotypes on SC-arg plates containing
either 0 or 40 µg of canavanine (can.) per ml. Cells were grown for 2 days at 30°C. WT, wild type. (B) Canavanine sensitivities
of different yeast strains. Suppression assays analogous to those shown
in panel A were used to determine the minimum concentration of
canavanine required to kill approximately 100 cells of the respective
yeast strains (Can. Sensitivity) after 2 days of growth at 30°C.
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Accumulation of functional Can1p correlates with nonsense
suppression of can1-100.
To ensure that the respective
differences in canavanine sensitivity reflected comparable changes in
the extent of synthesis of functional Can1p, arginine permease
activities were determined by monitoring the rate of uptake of
[3H]arginine in wild-type and mutant cells. Consistent
with the suppression assays of Fig. 1 and 2, these experiments
demonstrated that deletion of UPF1, NMD2, or
UPF3 allowed for enhanced transport of arginine (Fig.
3A).
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FIG. 3.
Accumulation of functional Can1p correlates with
nonsense suppression of can1-100. (A) 3H-labeled
arginine uptake in yeast strains with the indicated UPF/NMD
and CAN1 genotypes. The control yeast strain harboring the
CAN1 allele is PLY148 (36). WT, wild
type. Error bars indicate standard deviations. (B) Western analysis of
Can1p levels. Lysates of yeast strains with the indicated
UPF/NMD genotypes and bearing either CAN1 or
can1-100 plasmids were analyzed by Western blotting with
HA-specific antibodies. The lower panel is a longer exposure of the
same blot shown in the upper panel.
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To test whether increased suppression and transport activity reflected
enhanced synthesis of full-length Can1p, the expression
of an HA
epitope-tagged allele of
can1-100 was monitored by Western
blotting. As a control, we showed that all strains containing
the
can1-100-HA plasmid exhibited suppression phenotypes
identical
to those of strains containing the same plasmid lacking the
triple-HA
tag (data not shown). Figure
3B shows that Can1p-HA was
barely
detectable in wild-type cells (lower panel, lane 3) but
increased
approximately 10-fold in abundance in
upf1,
nmd2, and
upf3 cells (compare lane 3 to
lanes 4 to 6). Suppression of
can1-100 yielded Can1p levels
that were approximately 20-fold lower than
those obtained from
expression of the wild-type
CAN1 gene, a result
consistent
with the high rate of arginine transport in
CAN1 cells
(Fig.
3A) and the sensitivity of the same cells to 0.7 µg of canavanine
per
ml (data not shown). Quantitation of the blot shown in Fig.
3B also
provided an estimate of the reduction in
CAN1 expression
caused by the premature termination codon. Since the levels of
Can1p in
lanes 1 and 3 of Fig.
3B differ by approximately 10-fold
and the sample
in lane 1 is a 20-fold dilution, premature termination
of
CAN1 translation caused a 200-fold reduction in Can1p
synthesis.
The data in Fig.
3B also demonstrate that Can1p accumulation
and
the results of the plate assay for canavanine sensitivity
approximate
a linear relationship. This conclusion is drawn from the
observations
that wild-type cells harboring the
CAN1 gene,
wild-type cells
harboring
can1-100, and
upf1
cells harboring
can1-100 are sensitive
to 0.7, 300, and 25 µg of canavanine per ml, respectively, and
accumulate 200-, 1-, and
10-fold relative units of Can1p (Fig.
2B and
3B and data not
shown).
can1-100 nonsense suppression by mutations in
UPF1, NMD2, or UPF3 is only
partially attributable to increases in mRNA abundance.
Since
the can1-100 mRNA was stabilized in upf1,
nmd2, and upf3 mutants (Fig. 1),
suppression might be attributable to a constant but low rate of
"leaky" termination that becomes functionally significant as
mRNA levels increase. To directly address the contribution of
mRNA abundance to the suppression phenotypes, the
can1-100 allele was subcloned into single-copy and
high-copy-number plasmids that were then introduced into cells that
were wild type for NMD and already harbored a genomic copy of the
can1-100 allele. Levels of the can1-100 mRNA
were then measured by Northern analysis (Fig. 4A and
B), and the respective suppression
phenotypes (i.e., canavanine sensitivities) of the different strains
were determined (Fig. 4C). Wild-type cells expressing an additional
copy of can1-100 (YCp can1-100) showed a slight
(1.4-fold) increase in can1-100 mRNA levels (Fig. 4A and
B), but this increase did not alter the suppression phenotype of
wild-type cells containing either single-copy or high-copy-number
vectors without inserts (Fig. 4C, compare WT-YCp
can1-100 with WT-YEp; also, data not shown).
Wild-type cells transformed with the high-copy-number plasmid
containing the can1-100 allele showed a 12-fold increase in
can1-100 mRNA abundance compared to the same cells
containing only the vector (Fig. 4A and B, compare WT-YEp
can1-100 with WT-YEp). Accompanying this
increase in mRNA levels was a sixfold increase in sensitivity to
canavanine (Fig. 4C).
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FIG. 4.
can1-100 nonsense suppression is only
partially attributable to increased mRNA abundance. (A) Northern
analysis of can1-100 mRNA levels. RNA isolated from
yeast strains with the indicated genotypes was analyzed by Northern
blotting with probes specific for can1-100 mRNA and
SCR1 RNA (the latter to serve as an internal loading
control). Each of the indicated strains contained either a
high-copy-number can1-100 plasmid (YEp can1-100),
a single-copy can1-100 plasmid (YCp can1-100), or
an empty vector as a control (YEp). WT, wild type. (B)
can1-100 steady-state mRNA levels. Data from the blot in
panel A were quantitated by phosphorimaging, standardized to
SCR1 RNA levels, and normalized to data for the
upf1 strain. (C) Canavanine sensitivities of strains
harboring single-copy or high-copy-number plasmids. Suppression assays
analogous to those shown in Fig. 2 were used to define the canavanine
(Can.) sensitivities of cells with different UPF/NMD
genotypes.
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The same phenomena were exhibited when this experiment was repeated
with
upf1,
nmd2, and
upf3
mutants. All strains expressing
an additional copy of the
can1-100 allele exhibited modest increases
in
can1-100 mRNA levels (15 to 50%; Fig.
4A and B) but
showed
approximately threefold increases in their respective levels of
suppression (Fig.
4C, compare YCp
can1-100 with YEp for all
three
mutants). When the
can1-100 allele was expressed in
these mutants
from the high-copy-number plasmid, there was a 10-fold
increase
in the abundance of its mRNA (Fig.
4A and B) and a
comparable
increase in the level of nonsense suppression (Fig.
4C).
These
results indicate that increased mRNA abundance contributes to
nonsense suppression but is not its sole determinant. This conclusion
is illustrated further by direct comparisons of mRNA levels and
extents of suppression in mutant and wild-type cells. For example,
UPF/NMD wild-type cells overexpressing
can1-100
(
WT-YEp
can1-100)
had two- to threefold higher
levels of
can1-100 mRNA than any
of the
upf/nmd mutant cells (Fig.
4A and B), yet the level of
suppression in the
WT-YEp
can1-100 strain was
still lower than
that in any of the mutants (Fig.
4C).
Additional support for the notion that increased mRNA abundance is
not sufficient for
can1-100 nonsense suppression is the
finding that single deletions of
UPF1,
NMD2,
UPF3,
DCP1, or
XRN1 were found to
stabilize
can1-100 mRNA to comparable levels
(approximately
fourfold; Fig.
1A), yet there were substantial
differences in
the canavanine sensitivities of the respective strains
(Fig.
1B
and C and 2B). Collectively, the data in Fig.
1 to
4 provide
strong
support for the notion that the
UPF/NMD genes
regulate not only
the rates of decay of nonsense-containing mRNAs
but also their
efficiencies of
translation.
Different efficiencies of suppression are not attributable to
changes in the fraction of capped can1-100 mRNA.
Recent experiments have indicated that deletions of UPF1,
NMD2, or UPF3 inhibit the decay of
nonsense-containing mRNAs prior to the decapping step; i.e., such
deletions increase the steady-state ratio of capped to uncapped
mRNAs (He and Jacobson, unpublished). Since the upf/nmd
mutations affected the efficiency of translational suppression (see
above), we considered the possibility that this effect, in turn,
reflected substantial alterations in the relative percentages of capped
can1-100 mRNA in wild-type and mutant cells. Immunoprecipitation experiments with anti-cap antibodies were used to
examine the 5' cap status of the can1-100 mRNA and a
control (ADH1) mRNA in wild-type, upf1,
nmd2, and upf3 strains. In both wild-type
and mutant cells, the ADH1 mRNA was predominantly capped
(Fig. 5). However, the
can1-100 mRNA was predominantly uncapped in wild-type
cells, and deletion of UPF1, NMD2, or
UPF3 led to a slight increase in the percentage of capped
molecules (Fig. 5). These changes in the ratios of capped to uncapped
can1-100 mRNAs do not correlate with the suppression
data of Fig. 1 to 4 and indicate that variations in suppression
efficiencies must reflect events unrelated to mRNA cap status. This
conclusion is underscored by experiments indicating that
dcp1 and xm1, two mutations that have
negligible effects on can1-100 suppression (Fig. 1), lead to
the accumulation of mRNAs that are predominantly capped or
uncapped, respectively (4, 27, 40; also data not
shown).
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FIG. 5.
Suppression phenotypes are not a consequence of changes
in the relative fractions of capped can1-100 mRNA. (A)
Northern analysis of mRNAs fractionated by 5'-cap
immunoprecipitation. Total RNA from yeast strains with the indicated
UPF/NMD genotypes was separated into capped and uncapped
fractions by use of polyclonal anti-m7G antibodies and
analyzed by Northern blotting with DNA probes for either the
ADH1 mRNA or the can1-100 mRNA. I, input
RNA; S, RNA in the supernatant fraction (represents the uncapped
fraction); P, RNA in the pellet fraction (represents the capped
fraction). WT, wild type. (B) Relative amounts of capped and
uncapped can1-100 and ADH1 transcripts. RNA in
the S and P fractions of panel A was quantitated by phosphorimaging,
and the relative percentages of capped and uncapped transcripts were
determined by calculating the fraction each sample represented of its
respective total (S + P).
|
|
The relative distributions of capped and uncapped
can1-100
mRNA species differed not only from that observed for the
ADH1 mRNA but also from that seen with
nonsense-containing
PGK1,
MER2,
and
CYH2 transcripts (
41; He and Jacobson,
unpublished). This
finding was unexpected and may reflect the
possibility that, for
some mRNAs, decapping is not immediately
followed by exonucleolytic
digestion. This conclusion is supported by
experiments showing
that at least one other NMD substrate, the
his4-38 mRNA, behaves
similarly (He and Jacobson,
unpublished) and that uncapped mRNAs
accumulate in a
temperature-sensitive eukaryotic initiation factor
5A mutant
(
63).
Epistatic relationships of Upf1p, Nmd2p, and Upf3p in
nonsense suppression.
Since the different upf/nmd
mutations showed small but highly reproducible differences in the
extents of can1-100 suppression that they promoted (Fig.
2B), we were able to exploit those differences to determine
epistatic relationships of Upf1p, Nmd2p, and Upf3p. To resolve
epistatic relationships, mutants containing double deletions of the
UPF1, NMD2, or UPF3 genes were
constructed and assayed for their sensitivity to canavanine. Analyses
of these mutants demonstrated that any strain harboring a deletion of
UPF1 exhibited the highest levels of suppression (i.e.,
sensitivity to 25-µg/ml of canavanine) and, conversely, that strains
harboring a wild-type UPF1 gene showed lower levels of
suppression (i.e., sensitivity to 35 µg of canavanine per ml). As
shown in Fig. 2, double deletion of UPF1 and either
NMD2 or UPF3 resulted in a suppression phenotype
identical to that caused by upf1 alone. This result
indicates that combining an nmd2 or upf3
mutation with upf1 does not have an additive effect on
nonsense suppression and that the upf1 phenotype
supersedes the nmd2 and upf3 phenotypes. Of
the double mutants, the nmd2 upf3 mutant showed the
lowest level of suppression, displaying a phenotype like that of an
nmd2 strain (compare nmd2 upf3 to
nmd2 in Fig. 2A). These results indicate that Upf1p is
epistatic to Nmd2p and Upf3p and suggest a role for Upf1p in affecting
the efficiency of premature translation termination.
While the suppression phenotypes of the double mutants suggested
relatively straightforward epistatic relationships, the phenotype
of
the triple mutant, lacking
UPF1,
NMD2, and
UPF3, was somewhat
surprising. This mutant showed a lower
level of suppression than
any of the
upf/nmd mutants tested
(sensitivity to 50 µg of canavanine
per ml; Fig.
2), demonstrating
that the efficiency of translation
termination is greater in the
absence of all three
UPF/NMD gene
products than in the
presence of any one of them. This result
suggests either the existence
of an alternate mechanism of termination
fidelity that functions in the
absence of the
UPF/NMD gene products
or that the presence of
one of the
UPF/NMD factors without the
other two acts
dominantly to prevent proper
termination.
Overexpression of UPF1 decreases the efficiency of
nonsense suppression without altering can1-100 mRNA
levels.
As an additional approach to characterizing the
functional relationships of Upf1p, Nmd2p, and Upf3p, these gene
products were overexpressed in all of the upf/nmd mutant
backgrounds, and the resulting effects on nonsense suppression
were examined. Overexpression was accomplished by
cloning UPF1, NMD2, or UPF3 under the
control of the strong ADH1 promoter on a
high-copy-number plasmid (22). Expression of the
UPF/NMD genes from these constructs was found to increase
the accumulation of the respective proteins at least 10-fold (data not
shown). As controls for these experiments, we utilized mutant strains
transformed with only the high-copy-number vector. The presence of this
plasmid did not alter the suppression phenotypes of any of the mutant
strains (compare Table 2 [YEp column]
with Fig. 2B).
Overexpression of
UPF1 in all of the single, double,
and triple mutant strains (not including the
upf1
control) was found
to lower suppression levels two- to threefold (Table
2, compare
YEp and YEp-
UPF1 columns). These results are
consistent with the
notion that Upf1p can, by itself, enhance
termination fidelity
and also implicate a regulatory role for
Nmd2p and Upf3p, since
Upf1p can lower suppression in the absence of
either of the other
proteins. Overexpressing
UPF3
complemented its own deletion, had
no effect on any other single or
double mutation, and did not
change the phenotype of the triple mutant.
The latter phenomenon,
however, could be considered to reflect a modest
increase in canavanine
resistance over that observed in a
upf1
nmd2 strain (Table
2).
Overexpression of
NMD2 had
comparable effects, except that, in
upf3 cells, it also
enhanced suppression to a level comparable
to that obtained in
upf1 cells (Table
2). This result suggests
that Nmd2p may
be a negative regulator of the activity of Upf1p
or is capable of
simply titrating available
Upf1p.
Since the overexpression of
UPF1 altered the suppression
phenotypes of all of the mutants, we investigated whether these effects
might be caused by restoration of the rapid rate of decay of the
can1-100 transcript. To this end, steady-state levels of the
can1-100 mRNA were examined in
upf/nmd
mutants overexpressing
UPF1. As
expected, overexpression of
UPF1 in the
upf1 strain restored
NMD to
wild-type levels, resulting in a fourfold decrease in
can1-100 mRNA levels (Fig.
6, compare
upf1-YEp to
upf1-YEp-
UPF1). Accompanying
this restoration
of decay function was the restoration of the
wild-type suppression
phenotype (Table
2). In all of the other
upf/nmd mutant
strains,
UPF1 overexpression did not significantly
alter
can1-100 mRNA levels compared to those seen in the
starting
mutant strains that contained the vector only (Fig.
6).
Additionally,
overexpression of
NMD2 or
UPF3 in
any of the mutant backgrounds
had no effect on steady-state
can1-100 mRNA levels, other than
those involving direct
complementation of the respective single
deletions (data not shown).
These results demonstrate that changes
in the suppression phenotype
caused by overexpression of
UPF1 are not attributable to
changes in
can1-100 mRNA levels. These
observations are
consistent with the proposed role of Upf1p in
controlling the
efficiency of translation termination, provide
further support for a
regulatory function for Nmd2p and Upf3p,
and comprise additional
evidence for the separation of the activities
of Upf1p in mRNA
decay and translation (
11,
58,
59).
View larger version (49K):
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|
FIG. 6.
Overexpression of UPF1 in upf/nmd
mutant strains does not affect can1-100 mRNA abundance.
(A) Northern analysis of can1-100 mRNA levels. Total RNA
isolated from yeast strains with the indicated genotypes was analyzed
by Northern blotting as described in the legend to Fig. 4. Each of the
mutant strains contained either a high-copy-number UPF1
plasmid (YEp-UPF1) or an empty vector as a control (YEp).
(B) Quantitation of can1-100 steady-state mRNA levels.
can1-100 mRNA levels were determined, standardized to
SCR1 RNA, and normalized to data for the upf1
strain as described in the legend to Fig. 4.
|
|
Upf1p is considerably more abundant than Nmd2p or Upf3p but is not
stoichiometric with ribosomes.
The suppression analyses described
above indicated that Upf1p was a critical regulator of termination
fidelity and that Nmd2p and Upf3p regulated the activity of Upf1p.
These putative regulatory relationships are consistent with the results
of previous protein-protein interaction analyses (11, 21, 22,
58) but raise the question as to whether these interactions occur
as part of a stoichiometric complex or are more transient events. To
address this issue further, we determined the cellular abundance of
each of these factors. Western blotting was used to compare the amounts
of epitope-tagged Upf1p and Nmd2p in a fixed number of cells with those
present in purified samples of each of the two proteins. Relative
levels of Nmd2p and Upf3p in crude extracts were determined by
comparing the relative Western blot intensities of the two proteins
when each harbored the same epitope tag. Using this approach, Upf1p was
found to be the most abundant of the three factors, with approximately 1,600 molecules of Upf1p/cell (Table 3).
Nmd2p was found to be 10-fold less abundant than Upf1p (160 molecules
of Nmd2p/cell), and Upf3p was found to be the least abundant of the NMD
factors (80 molecules of Upf3p/cell) (Table 3). These experiments
indicate that the cellular concentrations of Upf1p, Nmd2p, and Upf3p
differ greatly and do not approach the cellular levels of ribosomes, release factors, or the major cellular exonuclease, Xrn1p
(23) (Table 3). These data are, however, consistent with the
putative role of Upf1p as a regulator of termination fidelity, as well as the implied roles of Nmd2p and Upf3p as regulators of Upf1p.
| |
DISCUSSION |
Suppression of the can1-100 nonsense allele is enhanced
by upf1, nmd2, and upf3
mutations.
The UPF1, NMD2, and
UPF3 genes regulate NMD (7, 20, 22, 34-36, 45).
Mutations in any of these genes generally promote the stabilization of
nonsense-containing mRNAs by reducing the rate at which the
recognition of a premature termination codon by the translation
apparatus triggers mRNA decapping (He and Jacobson, unpublished).
These effects of upf/nmd mutations on mRNA stability and
parallel enhancing effects on nonsense suppression (9, 36, 58,
59) and programmed ribosomal frameshifting (8, 52)
suggested a regulatory role in translation termination and/or fidelity
for Upf1p, Nmd2p, and Upf3p. Strong support for this conclusion was
obtained from experiments demonstrating interactions between Upf1p and
the polypeptide release factors Sup35p and Sup45p (11).
To characterize further the roles of the
UPF/NMD gene
products in translation termination, we developed an assay that
examined
the effects of
upf/nmd mutations on suppression of
the
can1-100 allele. A single A
T mutation in this allele
leads to the synthesis
of a transcript in which codon 47 has been
changed to UAA. As
a consequence, the
can1-100 mRNA is a
substrate for NMD. Mutations
in
UPF1,
NMD2, or
UPF3 not only stabilized the
can1-100 transcript
but also promoted its suppression. Quantitative measurement of
the
extent of
can1-100 suppression by these mutations was
achieved
by varying the canavanine concentration of the growth media
and
determining the specific concentration that effectively killed
diluted samples of the respective mutants. Since the degree of
suppression (i.e., enhanced canavanine sensitivity) was found
to
correlate with the level and activity of Can1p in the cells,
we
conclude that the
can1-100 system provides a reliable assay
for nonsense suppression. Further support for the reliability
of this
assay was provided by experiments showing that the qualitative
aspects
of
can1-100 suppression were comparable to those obtained
in
independent assays with the
leu2-1 (UAA) and
tyr7-1 (UAG) nonsense
alleles (data not
shown).
We initially investigated the effects of single deletions of
UPF1,
NMD2, and
UPF3 on
can1-100 nonsense suppression. Individual
deletions of each
of these genes were shown to have comparable
stabilizing effects on the
can1-100 mRNA but to produce differential
effects on
suppression. Strains harboring the
upf1 mutation
consistently
showed a higher level of nonsense suppression than strains
harboring
either the
nmd2 or the
upf3
mutation. We inferred from this
observation that Upf1p might play a
more direct role in regulating
the translation of nonsense-containing
mRNAs than the other two
factors; further experimentation appears
to have substantiated
this conclusion (see
below).
can1-100 nonsense suppression: a loss in termination
fidelity?
Mutations in the UPF/NMD genes have
previously been shown to promote the suppression of leu2,
tyr7, met8, and his4 nonsense alleles
(7, 36, 58, 59). Since these mutations invariably led to
increases in the levels of the corresponding mRNAs (35, 36) but failed to generate evidence for an effect on the
readthrough of premature stop codons, it was initially concluded
that suppression was due solely to the combination of enhanced mRNA
abundance and an inherent rate of readthrough that was sufficient
to generate the minimal amount of protein required for function of the
respective genes (36, 47). However, the experiments of Weng
et al. (58, 59) suggested that an alternative explanation
was more likely. They generated a large set of upf1 alleles
and identified several in which the effects on mRNA decay and
translational suppression could be separated. More specifically, they
identified two significant classes of upf1 alleles: (i)
those which, when expressed at a high copy number, inactivated mRNA
decay but failed to allow suppression (e.g., DE572AA) (58)
and (ii) those which, when expressed in a single copy, promoted normal
mRNA decay but allowed suppression to occur (e.g., C84S)
(59). The phenotypes of these mutants indicated that
suppression was unlikely to be caused solely by changes in mRNA
levels and established the notion that Upf1p could regulate both
mRNA decay and translation. Since upf1 mutations had no
effect on polysome profiles (19, 35) and since Upf1p was
known to be of relatively low abundance, it was considered likely that
the translational effects were targeted not to general initiation or
elongation but rather to the premature termination event.
On the basis of the results of Weng et al. (
58,
59), we
anticipated that the suppression of
can1-100 by
upf/nmd mutations
would also be attributable to more than
simple increases in mRNA
levels. This assumption was substantiated
by several new lines
of experimentation which demonstrated that
(i)
xrn1- and
dcp1-mediated
increases in
can1-100 mRNA abundance, to levels comparable to
those
obtained in
upf/nmd mutant cells, did not promote canavanine
sensitivity; (ii) high-copy-number expression of the
can1-100 allele in wild-type cells, leading to
can1-100 mRNA levels which
exceeded those obtained in
upf/nmd mutant cells 2- to 3-fold,
was less effective in
promoting canavanine sensitivity than single
upf1,
nmd2, or
upf3 mutations; (iii) when
UPF1 was overexpressed,
large changes in the extent of
nonsense suppression could be attained
without significant alterations
in
can1-100 mRNA abundance; (iv)
in
upf/nmd
mutant cells harboring an additional copy of the
can1-100 allele, 2- to 3-fold increases in canavanine sensitivity were
obtained
when levels of the corresponding mRNA increased only
50% or less;
and (v) high-copy-number expression of the
can1-100 allele
led to 3- to 4-fold higher levels of the corresponding
mRNA in
upf/nmd mutant cells than in wild-type cells but to 16-
to
25-fold higher levels of suppression. Interestingly, the observation
that the canavanine sensitivity of wild-type cells increased at
all in
response to enhanced abundance of the
can1-100 mRNA
indicates
that mRNA abundance contributes to suppression and that
the premature
termination codon in the
can1-100 mRNA
must be leaky. The latter
conclusion is substantiated by the
identification of small amounts
of full-length Can1p in wild-type cells
harboring the
can1-100 allele (Fig.
3B).
Given that the premature termination codon in the
can1-100
allele has an intrinsic, albeit low, rate of readthrough, two
explanations
for the mechanism of suppression appear plausible. In the
first,
translation initiation of the
can1-100 mRNA is
somehow increased,
and in the second, the efficiency of the premature
termination
event is decreased. While there is no evidence supporting
global
effects on translation initiation by
upf/nmd mutants
(
19,
35),
inactivation of the NMD pathway has been shown to
promote a modest
increase in the translational efficiency of
nonsense-containing
mRNAs (
42). Moreover, recent studies
have demonstrated that
the
upf1,
nmd2, and
upf3 mutations alter the distributions
of capped and
uncapped transcripts (He and Jacobson, unpublished).
Therefore,
suppression by deletion of
UPF1,
NMD2, or
UPF3 could,
in principle, have been caused by subtle
increases in the translational
efficiency of
can1-100
mRNA, possibly because of changes in its
extent of capping.
However, since deletion of
UPF1,
NMD2, or
UPF3 produced differential effects on the amounts of capped
and uncapped
can1-100 mRNAs (Fig.
5) that did not
correlate with their respective
suppression phenotypes, it is unlikely
that suppression is dependent
on changes in the fraction of capped
can1-100 mRNA. We therefore
consider it likely that
suppression caused by deletion of
UPF1,
NMD2, or
UPF3 is due either to a loss in termination fidelity
at the
premature nonsense codon or to additional rounds of translational
initiation on an mRNA with an inherent, low rate of leaky
termination.
The demonstration of interactions between Upf1p and the
polypeptide
release factors (
11) suggests that the former
model is more
likely.
Upf1p plays a central role in regulating nonsense suppression.
The finding that deletion of UPF1 resulted in a greater
extent of suppression than deletion of NMD2 or
UPF3 either implicates Upf1p as the most critical of the
three factors for the maintenance of termination fidelity or suggests
that Upf1p and either Nmd2p (i.e., as in the upf3 strain)
or Upf3p (i.e., as in the nmd2 strain) may enhance
termination fidelity cooperatively. To distinguish between these
possibilities, strains harboring double mutations were constructed, and
nonsense suppression by these strains was monitored. Any double mutant
harboring a deletion of UPF1 showed the highest levels of
suppression and, alternatively, the nmd2 upf3 mutant (the only double mutant expressing
UPF1) showed lower suppression levels. Therefore, the
suppression phenotype mediated by the deletion of UPF1
supersedes an additional mutation of NMD2 or
UPF3, suggesting that, of the three proteins, Upf1p is the central factor involved in regulating the translational efficiency of
nonsense-containing mRNAs. This conclusion was significantly reinforced by analyses of the consequences of UPF1
overexpression (see below). Interestingly, since deletion of both
NMD2 and UPF3 does not have an additive effect on
suppression, it appears that Nmd2p and Upf3p may act in concert, as
opposed to independently, to regulate Upf1p activity.
Deletion of all three
UPF/NMD genes resulted in
significantly lower levels of suppression than that seen in any of the
other
mutants tested. This result was surprising, since this mutant
was
expected to exhibit a phenotype characteristic of
upf1
strains.
Since deletion of the genes encoding all three factors
enhances
termination efficiency, either an alternate fidelity pathway
may
function in the absence of the
UPF/NMD-mediated
mechanism or any
one of the
UPF/NMD factors without the
other two may act in a
dominant-negative
manner.
Overexpression of UPF1 restores termination fidelity
without affecting mRNA decay.
As noted above, Weng et
al. (58, 59) showed that specific upf1
alleles could separate the translation and turnover
functions of Upf1p, i.e., some alleles resulted in normal mRNA
decay but impaired termination fidelity, whereas others resulted
in the opposite phenotype. Curiously, these phenotypes are not
reproduced in the can1-100 system. Strains with
upf1 alleles shown to result in normal decay but impaired
fidelity (e.g., C84S) behaved like the wild-type strain in the
can1-100 system, and strains with alleles resulting in
inactive mRNA decay but functional fidelity (e.g., DE572AA) behaved
just like upf1 strains (data not shown). However, we have
been able to obtain independent evidence for the separation of the two
putative functions of Upf1p. In analyses of the effects of
overexpression of each of the UPF/NMD genes in the different
mutant backgrounds, we observed that high-copy-number expression of
UPF1 led to substantial decreases in can1-100
nonsense suppression without having any significant effect on
can1-100 mRNA levels. This finding underscores the
existence of a separate translational role for Upf1p, reinforces the
notion of Upf1p as the preeminent of the three factors in regulating
termination fidelity, and implies a regulatory function for Nmd2p and
Upf3p (since the overexpression of Upf1p has the ability to enhance fidelity even in the absence of Nmd2p or Upf3p).
The overexpression of
NMD2 in a
upf3 strain
enhanced nonsense suppression to an extent comparable to that observed
in strains
harboring only a
UPF1 deletion. This result
suggests that Nmd2p
may negatively regulate the activity of Upf1p, such
that an excess
of this negative regulator renders Upf1p inactive.
Alternatively,
since Nmd2p and Upf1p interact (
21,
22), the
overexpression
of
NMD2 may simply sequester Upf1p molecules
and prevent their
proper functioning by hindering additional
interactions. The latter
hypothesis leaves open the possibility that
Nmd2p and Upf3p are
actually activators of Upf1p activity, a model
consistent with
the decreases in suppression observed when
UPF1 was overexpressed.
If Nmd2p and Upf3p are indeed such
activators, then the results
of their respective overexpression would
indicate that high levels
of either factor alone are not sufficient to
promote such
activation.
Cellular concentrations of Upf1p, Nmd2p, and Upf3p are consistent
with their apparent regulatory interactions.
Earlier studies
recognized that the UPF/NMD factors were relatively low in
abundance (3, 37, 46), but their actual cellular
concentrations were not determined previously. Here, using Western
blotting of crude cell extracts and purified proteins as standards, we
found approximately 1,600, 160, and 80 molecules of Upf1p, Nmd2p, and
Upf3p per cell, respectively. The abundance of these factors is
consistent with the proposed central role of Upf1p in regulating
termination fidelity, as well as with the hypothesis that Nmd2p and
Upf3p regulate the activity of Upf1p. Although Upf1p, Nmd2p, and Upf3p
have all been shown to be interacting proteins that associate with
polyribosomes (3, 20-22, 38, 46, 58, 59), these data make
it unlikely that these proteins exist in a stable complex or that they
associate with all ribosomes. Rather, their interactions and ribosome
association must be transient, with the latter limited to ribosomes
recognizing newly synthesized mRNAs or their termination codons. An
association with ribosomes actively recognizing termination codons
would be consistent with recent studies demonstrating that Upf1p
interacts with the peptide release factors Sup35p and Sup45p
(11).
Possible functions of Upf1p, Nmd2p, and Upf3p in translation
termination.
Taken together, the findings presented are consistent
with Upf1p playing an important role in regulating the efficiency of translation termination, with Nmd2p and Upf3p serving as codependent activators of Upf1p function (Fig. 7).
The importance of UPF1 is highlighted by the observations
that deletion of UPF1 results in the highest levels of
suppression, overexpression of UPF1 can restore termination
fidelity, and Upf1p is the most abundant of the three proteins involved
in NMD. Further, homologs of Upf1p have been identified in other
organisms, including Caenorhabditis elegans (44,
49) and humans (2, 48), indicating evolutionary conservation of this factor. It is possible that the role of Upf1p in
translation termination simply involves stimulation of the activity of
the peptide release factors (K. Czaplinski et al., submitted for
publication), such that efficient release allows for enhanced fidelity.
Alternatively, Upf1p may play a more elaborate role in termination,
including the regulation of ribosome release and recycling and the
stimulation of decapping concurrent with premature nonsense codon
recognition. Experiments to be described elsewhere suggest that these
activities are also within the realm of Upf1p (R. Ganesan, F. He, and
A. Jacobson, unpublished data; He and Jacobson, unpublished).
View larger version (39K):
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FIG. 7.
Model for functional relationships of Upf1p, Nmd2p, and
Upf3p in translation termination. Upf1p is depicted as a positive
regulator of the efficiency of translation termination mediated by
Sup35p and Sup45p. The activity of Upf1p is postulated to be dependent
on the function of both Nmd2p and Upf3p. Regulation of Upf1p by Upf3p
and Nmd2p is postulated to occur as a consequence of either the
combined or the sequential action of Upf3p and Nmd2p. The left and
right complexes depict translation termination with and without
nonsense decay factors, respectively, with the breadth of the large
arrows indicating the relative efficiencies of the two events. E, P,
and A represent the exit, peptidyl, and aminoacyl sites on the ribosome
(dark gray ovals).
|
|
| |
ACKNOWLEDGMENTS |
This work was supported by a grant (GM27757) to A. J. from the National Institutes of Health, a predoctoral NRSA
fellowship (GM18043) to A.B.M. from the National Institutes of
Health, and a postdoctoral fellowship to D.A.M. from The Medical
Foundation/Charles A. King Trust.
We thank Elsebet Lund for anti-cap antibodies, Duane Jenness for
CAN1-HA and for teaching us about the potential value of a
CAN1-based assay, and members of the Jacobson laboratory for their helpful editorial comments and occasional moral support.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Genetics and Microbiology, University of Massachusetts
Medical School, 55 Lake Ave. North, Worcester, MA 01655-0122. Phone:
(508) 856-2442. Fax: (508) 856-5920. E-mail:
Allan.Jacobson{at}umassmed.edu.
| |
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Molecular and Cellular Biology, July 2000, p. 4591-4603, Vol. 20, No. 13
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Abstract
Introduction
