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J. Biol. Chem., Vol. 277, Issue 23, 20477-20482, June 7, 2002
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From the Department of Molecular Sciences, University of Tennessee,
Memphis, Tennessee 38120
Received for publication, January 29, 2002, and in revised form, March 4, 2002
The Tor1/2p signal transduction pathway regulates
nitrogen catabolite repression (NCR)-sensitive (GAP1,
GAT1, DAL5) and retrograde (CIT2,
DLD3, IDH1/2) gene expression by controlling
intracellular localization of the transcription activators, Gln3p and
Gat1p, and Rtg1p and Rtg3p, respectively. The accepted pathway for this regulation is NH3 or excess nitrogen The GATA family of transcription factors are conserved from yeast
to man. The Saccharomyces cerevisiae family consists of at
least eight members, each possessing a homologous zinc-finger motif,
CX2CN17-20CX2C,
which binds to a sequence containing GATA at its core. Two of the
best-studied GATA factors, Gln3p and Gat1p, activate transcription of
many genes including those whose expression is Nitrogen
Catabolite Repression
(NCR)1-sensitive (1-4, 6, 7,
32).
Yeast cells face environments of widely varying nitrogen sources and,
like most microorganisms, transport, accumulate, and utilize good
nitrogen sources in preference to poor ones. NCR is the physiological
mechanism for achieving this selectivity and is the preeminent control
exerted over nitrogen catabolic gene expression in yeast. In excess
nitrogen (e.g. glutamine, ammonia), transcription of genes
encoding proteins needed to transport and degrade poor sources
(e.g. proline, allantoin) is low, i.e. "repressed." On the other hand, when nitrogen is limiting,
transcription of these genes increases, i.e. is
"derepressed" (1, 2).
Recently, our understanding of NCR-sensitive expression has greatly
increased. Ure2p negatively regulates the ability of Gln3p and Gat1p to
function (8, 9). When cells are grown in excess nitrogen, Gln3p and
Gat1p are not bound to their target promoter sequences thus making
these GATAs available, in some instances, to serve as surrogate TATA
elements (10). This behavior correlates with green fluorescent
protein-Gln3p and green fluorescent protein-Gat1p being nuclear when
NCR-sensitive expression is high and cytoplasmic when low (10).
A major breakthrough in our understanding of the mechanism of NCR
derives from reports that rapamycin, an immunosuppressant macroclide,
which inhibits the Tor1/2 proteins, induces NCR-sensitive expression
(11-14). Tor1, a non-essential protein, facilitates translational
initiation and G1 to S-phase progression (15). Tor2p is
essential and functions as does Tor1p but additionally participates in
actin cytoskeleton reorganization and other functions as well (16-18).
In cells growing in rich medium, Gln3p (and in some laboratories Ure2p
as well) is hyperphosphorylated, forms a complex with Ure2p, and is
localized to the cytoplasm (11-14). Inhibition of Torp activity with
rapamycin or by limiting nitrogen results in dephosphorylation of
Gln3p, decreased Ure2p-Gln3p complex formation, and nuclear
localization of Gln3p (11-14).
Mks1p, a recent addition to the NCR regulatory network, has been
identified three different ways. MKS1 (multicopy
compensator of a kinase suppression) was first
isolated as a gene whose products function downstream of protein kinase
A (19). Second, MKS1 was found to be identical to
LYS80, at first thought to encode a repressor of the lysine
biosynthetic genes (20) but later found to down-regulate the
More recently, genomic analyses led Shamji et al. to agree
that Mks1p is a positive regulator of rapamycin-induced,
Gln3p-dependent gene expression and a positive regulator of
Rtg1/3p-dependent retrograde gene expression (7). The
retrograde regulon consists of genes, including CIT2,
IDH1/2, and DLD3, whose expression is stimulated
by damage to mitochondria and reduced in cells grown with glutamate as
the sole nitrogen source (26, 27). Komeili et al. also
reported that retrograde gene expression is rapamycin-induced and
correlates with the quality of the nitrogen source provided, being
lowest with preferred nitrogen sources thereby linking carbon and
nitrogen regulation (28). They also, in agreement with Sekito et
al., demonstrated that Rtg1/3p intracellular
localization correlates with the level of retrograde expression, being
nuclear when it is high and cytoplasmic when low (27).
Several observations, however, raise questions about our current
understanding of the role of Mks1p in Tor1/2p signal transduction and
NCR-sensitive and retrograde gene expression. (i) Mks1p, a proposed
negative regulator of Ure2p, doesn't play a role in Ure2p dephosphorylation, i.e. Ure2p dephosphorylation occurs
normally in an mks1 mutant (7). (ii) Tap42p is
phosphorylated by Tor1/2p (29), and a mutant allele,
tap42-11, has been isolated in which Tap42 has lost its
ability to respond to rapamycin addition. As a result,
rapamycin-induction of processes downstream of Tap42p, e.g.
Gln3p-dephosphorylation, are lost in the mutant as well (11). Surprisingly, however, rapamycin-induced Ure2p dephosphorylation occurs
normally in the tap42-11 mutant (7). (iii) In most genetic backgrounds, glutamine and ammonia are more strongly repressive nitrogen sources than urea or glutamate (30). Yet in the measurements of Komeili et al., CIT2 expression occurs at the
same high level with ammonia and urea as the nitrogen source and is
severely reduced when glutamine or glutamate is provided instead (28).
In other words, CIT2 expression doesn't correlate with the
quality of nitrogen source.
Paradoxical observations such as these prompted us to reinvestigate the
relation of nitrogen quality to retrograde gene expression and the role
of Mks1p as a positive regulator of Rtg1/3p-dependent transcription and negative regulator of Ure2p. Here we show that: (i)
retrograde gene expression is controlled not by the quality of the
nitrogen source, but the product to which it is degraded, (ii) Mks1p is
not a positive but a strong negative regulator of retrograde gene
expression, and (iii) Mks1p does not significantly or directly
influence NCR-sensitive, GATA-mediated gene expression.
Strains and Media--
We used strains M970
(MATalys5/MAT RNA Isolation and Northern Blot Analyses--
Total RNA
preparation and Northern blot analyses were performed as described (10)
with the exception that the breaking buffer contained 0.5 M
Tris base and diethoxydiformate was not added and 9 µg of total RNA
were loaded per lane. Radiolabeled PCR products, using primers
CIT2 (5'-TCAGGGAACAATATCAACAC-3',
5'-CTGTTCTAATAGAACATCGC-3'); IDH1
(5'-CTGGTAACAATCAAGGTTCA-3', 5'-CTTCTTTATGATCTGTTTGC-3'); IDH2 (5'-GAACCTGAATTACCTTGGTAG-3',
5'-GACAAAGATAGGGCTAACATC-3'); DLD3
(5'-GTGCCAAAATGCTCCTCAAT-3', 5'-TCTTCTGGAGCTTGAGAGTT-3'); GAT1 (5'-GTTCTGTTCATCGCATGTGCA-3',
5'-GTATTATTGGCGATGCTGGGA-3'); GAP1
(5'-TGCCCAAACTCCATTGAAGC-3', 5'-AATCTCCCACGGGGAATACA-3'); DAL5
(5'-AGATTTCCACTAGTTCAGCGG-3', 5'-CCTACCAATTCAACAGCACCT-3'); MKS1 (5'-ACCCCAGAGCGATTGAATTT-3', 5'-TCTTCATCATCTTCAGCG-3');
LYS1 (5'-ATGGCTGCCGTCACATTACAT-3',
5'-TTGGCAGCAAAGAAGGCAA-3'); and H3
(5'-AAGCAAACAGCAAGAAAGTC3-', 5'-CCTTCTTTTGGATAGTGACA3-') were used as probes.
Mks1p-regulated Retrograde Gene Expression Does Not Correlate with
the Quality of the Nitrogen Source but the Product of Its
Degradation--
Komeili et al. concluded that rapamycin
signaling links nitrogen quality to the activity and nuclear
localization of retrograde transcription factors Rtg1/3p (31). Urea or
ammonia as the nitrogen source elicited high retrograde gene
expression, whereas glutamate and glutamine yielded low expression
(28). However, for most strains, urea and glutamate are poorer nitrogen
sources than ammonia and glutamine (30), arguing against the quality of
the nitrogen source being the important determinant. There is, however,
a physiologically significant correlation in the data of Komeili
et al. It is the product of the degraded nitrogen source.
Retrograde gene expression was high in both nitrogen sources that
yielded ammonia as the degradative product and low in those yielding
glutamate (28). To test this hypothesis, we measured gene expression in
cells provided with a spectrum of nitrogen sources ranging from poor to
good, some being degraded to ammonia and others to glutamate (Fig.
1). Expression of GAP1 and
GAT1 was used as the control to monitor NCR, i.e.
quality of the nitrogen source, while CIT2 and
DLD3 expression were the reporters for retrograde gene
expression.
Proline and allantoin, both poor nitrogen sources, support high level
GAP1 expression (Fig. 1C, lanes
A and B). Glutamate and urea behave similarly,
i.e. support high GAP1 expression
(lanes C and D). Ammonia and
glutamine, in contrast, are good nitrogen sources for this strain and
strongly repress GAP1 expression (lanes E and
F). The NCR-sensitive GAT1 expression profile is
similar to that of GAP1 (Fig. 1D).
CIT2 and DLD3 expression profiles differ from
those of GAP1 and GAT1, being higher with
allantoin, urea, and ammonia than with proline or glutamate (Fig. 1,
A and B). Allantoin and urea are degraded to
ammonia, while proline is degraded to glutamate. The results with
ammonia and glutamine are similarly correlated but more complex.
Ammonia elicits less CIT2 expression than urea but more than
glutamine or glutamate (Fig. 1A, lanes C-F).
Ammonia is transported and assimilated faster than urea, which accounts
for ammonia being repressive, while urea is not. Ammonia and urea
assimilation occurs predominantly through the formation of glutamate,
hence intracellular glutamate is higher with ammonia as the nitrogen
source than with urea. Therefore, the CIT2 results are not
surprising because CIT2 and DLD3 expression is
highly repressed by glutamate (26-28). By this reasoning, glutamine assimilation, which yields equimolar amounts of glutamate and ammonia,
should support less CIT2 and DLD3 expression than
ammonia alone even though ammonia and glutamine are equally repressive nitrogen sources, and that is what occurs (compare lanes
E and F). These data suggest the degradative
product rather than ability to elicit NCR controls CIT2 and
DLD3 expression.
Mks1p Is a Negative Regulator of Retrograde Gene Expression--
A
substantial regulatory network has developed around Mks1p and its
relation to NCR-sensitive gene expression (7, 22, 24). Schreiber's
laboratory, using genomic analyses, reported that Mks1p transmits a
signal from Tap42p to Rtg1/3p via the pathway rapamycin
To determine whether failure to down-regulate retrograde gene
expression adversely affects the cell, we grew wild type and mks1 NCR-sensitive Gene Expression Is Not Affected in a
mks1
A possible explanation of our failure to observe differences in
NCR-sensitive gene expression between wild type and mks1
To rectify Mks1p data with that derived from lys80 mutants
of Feller et al., we compared LYS1
expression in wild type and mks1 Rapamycin Induction of CIT2 Is Independent of Mks1p
Regulation--
According to the Schreiber model, rapamycin Four observations suggest that revisions are needed in the current
model of Tor1/2p signal transduction, retrograde, and NCR-sensitive gene regulation. We find that: (i) Mks1p does not directly control NCR-sensitive gene expression, (ii) Mks1p is a strong negative regulator of retrograde gene expression, (iii) nitrogen catabolic and
carbon retrograde gene expression are not linked by good
versus poor nitrogen sources but by the product of
nitrogen source degradation, i.e. compounds degraded to
ammonia do not down-regulate retrograde expression, whereas those
degraded to glutamate do, and (iv) Mks1p-mediated repression of
retrograde gene expression is dissociable from that exerted by the
Tor1/2p-mediated pathway.
Retrograde control regulates the amount of Differences between our conclusions and accepted models of
NCR-sensitive and retrograde expression prompt an attempt to rectify the observations. Mks1p was concluded to be a positive regulator of
retrograde expression from transcriptome analyses in which the ratios
of CIT2 and DLD3 expression in treated
versus untreated wild type cells (+7.1 and +6.4,
respectively) decreased (+1.0 and Komeili et al. report that the quality of a nitrogen source
determines whether it will stimulate or inhibit retrograde gene expression, i.e. "preferred" nitrogen sources (glutamine
and glutamate) down-regulate it (28). In contrast, we conclude that the
significant feature is not nitrogen source quality but the product of
degradation. Differences in interpretation derive from the S288c strain
background they used and how one classifies various nitrogen sources.
Ammonia is not a highly repressive nitrogen source in an S288c genetic background. Although the precise reason for this diminished repression has not been directly identified, it is an idiosyncrasy of this specific nitrogen source because other sources, e.g.
asparagine or glutamine, elicit similarly repressive responses in both
S288c and The third difference concerns whether Mks1p transmits the Tor1/2p
signal of excess nitrogen to the retrograde genes. Here, the conclusion
depends upon the data considered. mks1 The last, and by far most challenging, observations to rectify derive
from the USA uptake experiments (22). There is no doubt that
overexpression of MKS1 suppresses NCR-sensitivity of DAL5 expression (22), but this can occur in two different
ways: (i) Mks1p can negatively regulate Ure2p function, the prevailing view or (ii) Mks1p can diminish the ability of ammonia to bring about
NCR. We suggest the latter best accounts for all of the data. We show
that Mks1p is a strong negative regulator of CIT2 expression, which extends the earlier report that The most difficult incongruity to explain is the heterologous
DAL5-lacZ expression data obtained by Edskes et
al., Pierce et al., and in our
laboratory (Ref. 22 and 24, respectively). The former researchers find
that DAL5-lacZ expression decreases 70-fold in an
mks1 We thank Dr. Reed Wickner for very generously
providing strains, Tim Higgins for preparing the artwork, and the
University of Tennessee Yeast Group for suggestions to improve
the manuscript.
*
This work was supported by National Institutes of Health
Grant GM-35642.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, March 28, 2002, DOI 10.1074/jbc.M200962200
2
T. G. Cooper, submitted for review.
The abbreviations used are:
NCR, nitrogen
catabolite repression;
USA, ureidosuccinate.
Mks1p Is Required for Negative Regulation of Retrograde Gene
Expression in Saccharomyces cerevisiae but Does Not Affect
Nitrogen Catabolite Repression-sensitive Gene Expression*
ABSTRACT
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
Mks1p Ure2p
Gln3p 
DAL5, and rapamycin or limiting nitrogen Torp Tap42 Mks1p Rtg1/3p CIT2,
respectively. In current models, Mks1p positively regulates both Gln3p
(and DAL5 expression) and Rtg1/3p (and CIT2 expression). Here, in contrast, we show the following. (i) Mks1p is a
strong negative regulator of CIT2 expression and does not effect NCR-sensitive expression of DAL5 or
GAP1. (ii) Retrograde carbon and NCR-sensitive nitrogen
metabolism are not linked by the quality of the nitrogen source,
i.e. its ability to elicit NCR, but by the product of its
catabolism, i.e. glutamate or ammonia. (iii) In some
instances, we can dissociate rapamycin-induced CIT2 expression from Mks1p function, i.e. rapamycin does not
suppress Mks1p-mediated down-regulation of CIT2 expression.
These findings suggest that currently accepted models of Tor1/2p signal
transduction pathway regulation require revision.
INTRODUCTION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
ketoglutarate pool and several tricarboxylic acid cycle enzyme activities (21). The last identification of MKS1 was as a high copy suppressor of the NCR-sensitivity of ureidosuccinate (USA) uptake (22). USA, the first unique intermediate in uracil biosynthesis, can fulfill the auxotrophic requirement generated by a
ura2 mutation with proline, but not ammonia, as a nitrogen source (8, 9). Nitrogen source restriction derives from USA permease
(encoded by NCR-sensitive DAL5) production being repressed
by ammonia (8, 9, 23). A ura2 transformant, containing
approximately the 3' half of MKS1 on a high copy vector, can
use USA to cover the ura2 auxotrophy even with ammonia as the nitrogen source (22). Because ure2 is epistatic to
mks1, which in turn is epistatic to rtg2, the
regulatory circuit, NH3 Rtg2p Mks1p Ure2p Gln3p DAL5, was proposed (22, 24). Mks1p is also
required for conversion of Ure2p to its prion form [Ure3p]
(25).
MATERIALS AND METHODS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
lys2), YHE677 (MATa/MAT
mks1
::G418/mks1::G418
ura3/+), YHE815 (MAT ura2
leu2::hisG trp1::hisG (cross 83, spore 2a)), and
YHE823-1b (MAT ura2 leu2::hisG trp1::hisG
mks1::G418 (cross 83, spore 1b)). Strains
were grown at 30 °C to mid-log phase (A600 nm = 0.50-0.55) in Wickerham's minimal medium (31) containing 2%
glucose and the indicated nitrogen sources. Rapamycin (Sigma) (stock
solution, 1 mg/ml in 10% Tween 20 plus 90% ethanol) was added to
cultures, where indicated, to yield a final concentration of 0.3 µg/ml. Wickerham's solid medium containing 2% glucose and 0.1% of
either L-glutamic acid, L-glutamine, urea,
ammonium sulfate, or asparagine, 0.2% L-proline, or 0.2%
allantoin was used to evaluate growth. Plates were incubated at
30 °C for 3 days.
-Galactosidase Assays--
Strains, transformed with
DAL5-lacZ pRR29, were grown in 2% glucose yeast nitrogen base medium
with 0.1% proline or glutamine as the nitrogen source. Uracil (20 mg/liter), leucine (120 mg/liter), and tryptophan (20 mg/liter) were
added to provide for auxotrophic requirements. -galactosidase assays
were performed as described (5).
RESULTS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
View larger version (40K):
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Fig. 1.
Effects of various nitrogen sources on
NCR-sensitive and retrograde gene expression. Wild type (M970)
cells were grown in Wickerham's minimal medium containing 0.2%
L-proline (PRO), 0.2% allantoin
(ALL), or 0.1% L-glutamic acid
(GLU), urea, ammonium sulfate
(+NH4), or
L-glutamine (GLN) as the nitrogen source.
Northern blots were hybridized with radiolabeled CIT2
(A), DLD3 (B) GAP1
(C), or GAT1 (D) probes. Histone
(H3) was used as a control to assess loading and
transfer.
Torp Tap42 Mks1p Rtg1/3p retrograde (CIT2) gene
expression. In their model, Mks1p positively regulates Rtg1/3p (7). In
light of data in Fig. 1, we reinvestigated
Rtg1/3p-dependent expression in wild type and
mks1 strains, measuring CIT2 expression in
cells provided with proline, ammonia, or glutamine as the nitrogen source (Fig. 2A,
lanes A and G, C and
I, E and K). CIT2 is
expressed at undetectable levels in wild type cells with proline and
low levels with ammonia or glutamine as the nitrogen source
(lanes A, C, and
E). With all three nitrogen sources, CIT2
expression increases dramatically in the mks1
(lanes G, I, and
K). Therefore, in contrast to the conclusions of Schreiber
and co-workers (7), we find that Mks1p is a strong negative regulator
of CIT2 expression. To ensure that the observations with
CIT2 are not gene-specific but reflect retrograde expression
per se, we performed similar experiments with
DLD3, IDH1, and IDH2, all genes used
in earlier analyses by Komeili et al. and Shamji et
al. (Refs. 28 and 7, respectively). Expression of all three genes
is low to undetectable in wild type proline-grown cells and greatly
increases in the mks1 (Figs.
3C and 4, A and
B, lanes A and G). Mks1p
negative regulation of retrograde gene expression is not restricted to the use of proline as a nitrogen source. It also occurs with both ammonia and glutamine (Figs. 2-4,
lanes C, E, I,
and K). Changes between wild type and
mks1 were less dramatic because of the greater basal
level of retrograde gene expression with these nitrogen sources.
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Fig. 2.
Effects of mks1 and
rapamycin on CIT2 and GAP1, or lysine
on LYS1 expression. Northern blot analyses of RNA
from Wild type (W.T., M970) and mks1 (YHE677) strains
grown in minimal medium with either 0.1% L-proline
(PRO), 0.5% ammonium sulfate
(+NH4), or 0.1%
L-glutamine (GLN) as the sole nitrogen source
with (+RAP) or without rapamycin treatment. Blots were
hybridized with radiolabeled CIT2 (A) or
GAP1 (B) probes. When lysine (66 mg/liter) was
added to the medium, histidine (20 mg/liter) was also added to prevent
basic amino acid imbalance.
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Fig. 3.
Effects of mks1 and
rapamycin on DAL5, GAT1, and
DLD3 expression. Experiments were performed as in
Fig. 2. Northern blots were hybridized with radiolabeled
DAL5 (A), GAT1 (B), or
DLD3 (C) probes.
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Fig. 4.
Effects of mks1 and
rapamycin on IDH1, IDH2, and
MKS1 expression. Experiments were performed as in
Fig. 2. Northern blots were hybridized with radiolabeled
IDH1 (A), IDH2 (B), or
MKS1 (C) probes. Histone (H3) was used
as control to assess loadings.
strains on minimal glucose medium with a range of
nitrogen sources. There was little if any effect of deleting
MKS1 when the nitrogen source, irrespective of its quality,
provided is degraded to ammonia (Fig. 5,
right panel, allantoin, urea, asparagine). However,
mks1 cells grow more slowly than wild type when the nitrogen source is degraded to glutamate (Fig. 5, left
panels), arguing that excess retrograde gene expression is
detrimental in the presence of glutamate.
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Fig. 5.
Growth of wild type (W. T., M970)
and mks1 (YHE677) strains on various nitrogen
sources. W.T., cells were streaked onto yeast
extract/peptone/dextrose or Wickerham's minimal medium plates
containing 0.2% L-proline, 0.2% allantoin, or 0.1%
L-glutamic acid, urea, L-glutamine,
L-asparagine, or ammonium sulfate as the sole nitrogen
source. Plates were incubated at 30 °C for 3 days.
--
Significant differences between our views of Mks1p and
those of Shamji et al., Edskes et
al., and Pierce et al. prompted us to further query the
conclusion that Mks1p is a negative regulator of Ure2p (7, 22, 24). If
Mks1p is a negative regulator of Ure2p, it would be a positive
regulator of Gln3p, Gat1p, and NCR-sensitive gene expression (22).
Therefore, we compared the NCR sensitivity of GAP1
expression in wild type and mks1 strains. GAP1
expression is equally NCR-sensitive in the two strains; we see no
evidence of the Mks1p-dependent GAP1 expression
predicted by existing models (Fig. 2B, compare
lanes A, C, and
E with G, I, and
K). To ensure that the observations were not
GAP1-specific but reflected NCR-sensitive expression
per se, we additionally assayed DAL5 and
GAT1 expression and -galactosidase production supported
by a DAL5-lacZ fusion plasmid. The DAL5
expression profile is similar to that of GAP1,
i.e. there is no demonstrable Mks1p dependence of expression
or alteration of NCR sensitivity in the mks1 relative to
wild type. The GAT1 expression profile differs little from
that of DAL5, except that its NCR sensitivity is greater in
the mks1 than wild type (Fig. 3B). NCR
sensitivity is similarly unaltered when measured with a
-galactosidase assay. Wild type (YHE815) produced 28,276 and 949 units in proline versus glutamine medium, respectively,
compared with 8,951 and 210 for mks1 YHE823-1b. These
data argue against Mks1p having a role in NCR-sensitive gene expression.
strains might have been due to previously unnoticed
nitrogen-dependent modulation of MKS1 expression or a
defect in the mks1 construction. Therefore, we measured
MKS1 expression in wild type and mutant cells. It is
affected by neither nitrogen source nor rapamycin-treatment of wild
type cells (Fig. 4C, lanes A-F).
MKS1 mRNA could not be detected in the
mks1 (Fig. 4C, lanes
G-L); the same was true when the autoradiogram was heavily
overexposed or the blot analyzed with a phosphorimaging device (data
not shown).
strains. Ramos
et al. and Feller et al. report saccharopine dehydrogenase (encoded by LYS1) activity is 3-5-fold higher
in a lys80 mutant than wild type growing in minimal ammonia + lysine medium (20, 21). We confirm their enzymatic data;
LYS1 expression increases in an mks1 strain
relative to wild type (Fig. 2C).
Torp
Tap42 Mks1p Rtg1/3p retrograde gene expression (7).
That model posits Mks1p to be a positive regulator of Rtg1/3p,
connecting retrograde transcription to the upper portions of the Torp
pathway. Our evidence demonstrating Mks1p negatively, rather than
positively, regulates CIT2 expression calls this model into
question and prompted us to query the extent to which Mks1p mediates
Tor1/2p control of CIT2 expression. We assayed retrograde
and NCR-sensitive gene expression in wild type and mks1
strains treated with rapamycin. Higher concentrations of rapamycin than
used by some investigators do not induce CIT2 expression in
the wild type with proline as the nitrogen source even though they
strongly induce DAL5 expression as previously reported by
other laboratories (7, 12, 14) (Fig. 2, lanes A
and B). Rapamycin does induce CIT2 expression with ammonia or glutamine as the nitrogen source (Fig. 2,
lanes C-F), but in neither case does deletion of
MKS1 affect expression (Fig. 2, lanes
I-J). In contrast, deletion of MKS1 dramatically increases CIT2 expression in proline-grown cells even though
rapamycin cannot. DLD3, IDH1, and IDH2
expression responded similarly, but here rapamycin, in contrast to the
Schreiber model, was slightly inhibitory in the mks1
strain regardless of the nitrogen source (Figs. 3C and 4).
At least with proline as the nitrogen source, the effects of rapamycin
treatment and MKS1 deletion are clearly separable and
suggest that Mks1p is unlikely to be a direct participant in
rapamycin-induced CIT2 expression.
DISCUSSION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-ketoglutarate available
for ammonia assimilation into glutamate as manifested by
down-regulation of retrograde gene expression with glutamate as the
nitrogen source. Mks1p mediates this down-regulation as evidenced by
the dramatic phenotype of mks1 mutants. While glutamate is
the predominant regulator, ammonia may also play a role because CIT2 expression is greater with glutamine (which is degraded
to ammonia and glutamate) than glutamate as the nitrogen source. Whether a direct link exists between Tor1/2p and Mks1p is questionable because the effects of rapamycin can be completely dissociated from
Mks1p function with proline as the nitrogen source. The question cannot
be answered for ammonia or glutamine because although CIT2 expression increases upon rapamycin treatment in wild type, it is
already high in untreated mks1 cells and in some cases
decreases on treatment with rapamycin. Mks1p affects NCR-sensitive
expression only indirectly via -ketoglutarate production and
hence the rate of ammonia assimilation. To us, the function of Mks1p
remains unknown. If Mks1p is a direct participant in control of
CIT2 expression, it most likely does so by controlling
nuclear access of Rtg1/3p, probably by regulating the phosphorylation
state of these transcription factors. Consistent with this suggestion,
Pierce et al. have shown that: (i) Mks1p is localized to the
cytoplasm and (ii) an mks1 mutation is epistatic to one at
rtg2; hence Mks1p functions between Rtg2p and the
transcription factors Rtg1/3p that are required for activation of
CIT2 expression (24). We have confirmed the conclusions of
Pierce et al. concerning the mks1-rtg2 epistasis relationships using Northern blot analyses of GAP1,
DAL5, and CIT2 gene expression (data not shown).
1.2, respectively) in
mks1 cells (7). However, ratios can be ambiguous. The
ratio of CIT2 expression in Fig. 2A,
lanes D and J is close to one but much
greater if lanes C and D are compared.
This appears to concur with the Shamji et al. conclusion (7)
even though the opposite is true when all of the data can be analyzed.
1278b. Based on the data Komeili et al.
observed, ammonia was not classified as a good nitrogen source (28). It
was rather grouped with urea, a nitrogen source widely reported to
elicit little NCR. This grouping may have diverted attention away from a correlation involving the end product of degradation, thereby leading
them to conclude that nitrogen source quality was the important
determinant. According to the conclusions of Komeili et al.,
both proline and allantoin should support high
CIT2 expression because both are poor nitrogen sources. This
expectation, however, isn't supported experimentally (Fig. 1).
, but not rapamycin-treatment, increases CIT2 expression in proline
medium. With ammonia or glutamine, rapamycin induces CIT2
expression in the wild type. This increase cannot be concluded to occur
in the mks1, however, because CIT2 expression
is already high and in some cases decreases upon treating mutant cells
with rapamycin (Fig. 2). At least three interpretations immediately
come to mind: (i) Mks1p and rapamycin belong to different regulatory
pathways as far as CIT2 expression is concerned, (ii) Mks1p
belongs to the Tor1/2p pathway and the differences are quantitative, or
(iii) additional, unknown factors exist that function differentially, one set when Tor1/2p are active and another when they inactive, e.g. with proline as nitrogen source.
-ketoglutarate increases in lys80/mks1 mutants along with citrate synthase,
aconitase, and isocitrate dehydrogenase activities (21). We suggest
that overproduction of Mks1p excessively down-regulates CIT2
expression and hence citrate synthase production needed to synthesize
-ketoglutarate. The resulting limitation of -ketoglutarate
decreases the rate of ammonia assimilation to glutamate thereby
decreasing its ability to elicit NCR. This permits sufficient
DAL5/UREP expression to meet the requirements of the
selection scheme. This explanation also accounts for the recent report
that DAL5-lacZ expression increases in an rtg2 (24).
Because Rtg2p is required for nuclear localization of the retrograde
transcriptional activators, Rtg1/3p, its loss would result in
diminished CIT2 expression just as occurs with
overexpression of MKS1 (26-28).
relative to wild type cells growing in proline medium, whereas we see only a small (2.5-fold) decrease, which is not
substantiated by our Northern blot data. Further, the NCR sensitivity
of the -galactosidase production we measure is not significantly
different in wild type and mks1 cells. These differences may be an example of heterologous gene expression failing to mirror steady state mRNA data.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed. Tel.: 901-448-6179;
Fax: 901-448-3244; E-mail: tcooper@utmem.edu.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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