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Mol Cell Biol, May 1998, p. 2514-2523, Vol. 18, No. 5
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Dynamic Regulation of Copper Uptake and
Detoxification Genes in Saccharomyces cerevisiae
Maria Marjorette O.
Peña,
Keith A.
Koch, and
Dennis J.
Thiele*
Department of Biological Chemistry, The
University of Michigan Medical School, Ann Arbor, Michigan 48109-0606
Received 22 October 1997/Returned for modification 18 December
1997/Accepted 16 February 1998
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ABSTRACT |
The essential yet toxic nature of copper demands tight regulation
of the copper homeostatic machinery to ensure that sufficient copper is
present in the cell to drive essential biochemical processes yet
prevent the accumulation to toxic levels. In Saccharomyces cerevisiae, the nutritional copper sensor Mac1p regulates the copper-dependent expression of the high affinity Cu(I) uptake genes
CTR1, CTR3, and FRE1, while the
toxic copper sensor Ace1p regulates the transcriptional activation of
the detoxification genes CUP1, CRS5, and
SOD1 in response to copper. In this study, we characterized
the tandem regulation of the copper uptake and detoxification pathways
in response to the chronic presence of elevated concentrations of
copper ions in the growth medium. Upon addition of CuSO4,
mRNA levels of CTR3 were rapidly reduced to eightfold the
original basal level whereas the Ace1p-mediated transcriptional
activation of CUP1 was rapid and potent but transient. CUP1 expression driven by an Ace1p DNA binding
domain-herpes simplex virus VP16 transactivation domain fusion was also
transient, demonstrating that this mode of regulation occurs via
modulation of the Ace1p copper-activated DNA binding domain. In vivo
dimethyl sulfate footprinting analysis of the CUP1 promoter
demonstrated transient occupation of the metal response elements by
Ace1p which paralleled CUP1 mRNA expression. Analysis of a
Mac1p mutant, refractile for copper-dependent repression of the Cu(I)
transport genes, showed an aberrant pattern of CUP1
expression and copper sensitivity. These studies (i) demonstrate that
the nutritional and toxic copper metalloregulatory transcription
factors Mac1p and Ace1p must sense and respond to copper ions in a
dynamic fashion to appropriately regulate copper ion homeostasis and
(ii) establish the requirement for a wild-type Mac1p for survival in
the presence of toxic copper levels.
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INTRODUCTION |
Copper (Cu) is an essential element
required by all living organisms; however, it is also highly toxic.
Copper functions as an important cofactor for a variety of enzymes that
are required for essential biochemical processes such as cytochrome
c oxidase, Cu,Zn superoxide dismutase, lysyl oxidase, and
dopamine-
-hydroxylase (32). On the other hand, Cu can
participate in Fenton-like reactions that can generate extremely
reactive hydroxyl radicals which cause cellular damage such as the
oxidation of proteins, cleavage of DNA and RNA molecules, and membrane
damage due to lipid peroxidation (18). Furthermore, Cu
toxicity can result from its improper incorporation into proteins. For
example, Cu has been shown in vitro to replace Zn in the zinc finger
DNA binding domain of the human estrogen receptor, rendering the
protein unable to bind to its target DNA sequences (36). It
is therefore important that organisms elaborate appropriate mechanisms
for uptake and detoxification, as well as possess cellular sensors to
ensure that sufficient Cu is present in the cell to drive the essential biochemical processes while preventing its accumulation to toxic levels. The importance of maintaining appropriate intracellular Cu
levels is underscored by the existence of two human genetic disorders
of Cu homeostasis, Menkes syndrome and Wilson's disease (2, 3,
43, 47). Proper regulation of the Cu homeostatic machinery
requires the ability of the Cu ion sensors to detect Cu and respond by
appropriately regulating the expression of Cu homeostasis genes in
order to maintain the delicate balance between essential and toxic
levels.
The baker's yeast Saccharomyces cerevisiae has been a
powerful model organism for elucidating the components of the Cu
homeostatic machinery and their mechanisms of action. Elegant genetic
screens have identified genes that are responsible for Cu uptake under nutritional conditions when essential levels of Cu ions are present in
the cell (10, 25), distribution to appropriate subcellular compartments (8, 15, 31, 49), and detoxification under toxic
conditions when Cu ions are present in excess (7, 40, 41,
45). At the nutritional level, Cu uptake into yeast cells is
mediated by two membrane-associated high-affinity Cu(I) transporters, encoded by CTR1 and CTR3 (10, 25), and
a cell surface Cu(II)/Fe(III) reductase, encoded by the FRE1
gene, which reduces Cu(II) to Cu(I) prior to uptake (14,
21). In the presence of excess Cu ions, when expression of the
high-affinity Cu(I) transporters is abolished, Cu ion uptake can
proceed through a putative low-affinity Cu ion uptake system. The
high-affinity Cu(I) transport genes CTR1, CTR3, and FRE1 are transcriptionally downregulated by Cu ions and
induced by Cu ion starvation. This Cu ion-dependent regulation requires a wild-type Mac1p Cu metalloregulatory transcription factor (CuMRTF) (15, 24, 29, 48). Regulation of these genes by Mac1p is highly specific for and exquisitely sensitive to Cu ions
(29). Deletion of the MAC1 gene results in Cu ion
starvation phenotypes similar to those associated with deletions in the
CTR1 and CTR3 genes, which can be corrected by
added Cu ions. In mac1
strains, transcription of
CTR1 and CTR3 is undetectable and the
FRE1 gene is transcribed at low levels. In addition, yeast
strains which possess a dominant MAC1up1 allele
exhibit high basal levels of CTR1, CTR3, and
FRE1 mRNAs, a lack of Cu-dependent repression of
CTR1 and CTR3 (29), and hypersensitivity to Cu ions (24). The mutations in Mac1p
that lead to a dominant MAC1up1 allele all map
to the first of two cysteine clusters found in the carboxyl-terminal
half of Mac1p (16, 24, 48, 56). Regulation by Mac1p requires
the Cu-responsive cis-acting elements (CuREs)
5'-TTTTGCTC-3' which are arranged either in tandem or inverted repeats in the promoters of the CTR1,
CTR3, and FRE1 genes (29, 48). In vivo
dimethyl sulfate (DMS) footprinting revealed that the CuREs are
occupied under Cu ion starvation conditions in which the Cu(I)
transport genes are expressed and unoccupied in the presence of
sufficient Cu ion concentrations when transcription of these genes is
inactivated. The CuREs are unoccupied in a mac1 deletion
strain, are constitutively occupied in a MAC1up1
strain (29), and have been demonstrated by electrophoretic mobility shift assays to bind Mac1p in vitro (48).
Excess levels of Cu ions are directly sensed by the S. cerevisiae CuMRTF Ace1p. Ace1p cooperatively binds Cu(I) to form a tetra-Cu cluster through specific cysteine residues within the amino-terminal DNA binding domain (13, 40). Copper binding leads to a conformational change in this domain that results in specific binding of monomeric Ace1p to the metal response elements (MREs) 5'-TCY(4-6)GCTG-3' (Y = pyrimidine) on the
promoters of genes that are involved in Cu ion detoxification and
protection against oxidative damage (53). These include
CUP1 (19) and CRS5 (7),
which encode small cysteine-rich metallothioneins that sequester Cu
ions and protect the cell from its toxic effects, and SOD1,
which encodes Cu,Zn superoxide dismutase (17). Both in vitro
and in vivo footprinting analyses have demonstrated that Cu-activated
Ace1p binds to four MREs on the CUP1 promoter (12, 23). In addition, Ace1p binds to single MREs on the
SOD1 and CRS5 promoters to modestly activate
transcription. The importance of Ace1p in Cu detoxification is
underscored by the observation that deletion of the ACE1
gene renders yeast strains extremely sensitive to Cu ion toxicity
(22). Interestingly, the Cu ion sensors Mac1p and Ace1p
share 50% identity only within the 40 amino-terminal amino acids which
contains 3 of the 11 conserved cysteine residues found in Ace1p and
Amt1p, the homologous CuMRTF in the opportunistic pathogenic yeast
Candida glabrata (55). This region binds Zn and
may be involved in minor groove binding to the MREs (27,
42).
In this study, we characterized the dynamic regulation of the Cu ion
uptake and detoxification pathways in the presence of elevated Cu ion
concentrations in the growth medium. Our results show that tandem
regulation by both the nutritional copper sensor, Mac1p, and the toxic
copper sensor, Ace1p, of the expression of their respective target
genes is required for survival of S. cerevisiae cells in the
presence of toxic levels of Cu ions. In addition to mediating the Cu
ion-dependent regulation of the high affinity Cu(I) uptake genes, a
wild-type Mac1p is also important for proper detoxification in the
absence of these genes.
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MATERIALS AND METHODS |
Growth conditions.
Yeast cells were maintained in YPD medium
(1% yeast extract, 2% Bacto Peptone, 2% dextrose) (38)
with or without the addition of CuSO4 or in the
corresponding dropout media for maintenance of yeast strains
transformed with plasmids. Liquid cultures were seeded to an optical
density of 0.4 and grown to exponential phase (optical density at 650 nm of 1.2 to 1.5) at 30°C and 400 rpm and then treated with the
indicated Cu concentrations for up to 2 h. Five-milliliter samples
were withdrawn from the Cu-treated cultures at the indicated time
points for analysis. Plasmids were constructed and maintained in
Escherichia coli DH5
F' cells, using standard techniques
(1).
Yeast strains and plasmids.
The yeast strains used in this
study are listed in Table 1. Strain
DTY205 is isogenic to DTY1 but contains the dominant
MAC1up1 allele and was a generous gift from
D. J. Kosman. To determine the role of the Ace1p carboxyl-terminal
activation domain in CUP1 expression, strains KKY1, MPY2,
and MPY3 were constructed as follows. Strain KKY1 was derived from SLY1
(29) by deletion of the chromosomal copy of the
ACE1 gene by using plasmid
pace1::hisG-URA3 (4). Disruption of
ACE1 was verified by testing the sensitivity of KKY1 on Cu
plates and by Southern blot analysis. Plasmid p316:ACE1 contains a
1.8-kb genomic fragment encompassing the complete ACE1 open
reading frame, 541 bp of the 5' flanking region, and 612 bp of the 3'
flanking region cloned into the HindIII site of pRS316. The 1.8-kb ACE1 genomic fragment was released from p316:ACE1
by digestion with EcoRI and SalI and mobilized
into the same restriction sites on the pRS303 integrating vector to
generate plasmid p303:ACE1. To generate a fusion gene between the Ace1p
DNA binding domain and the activation domain of the herpes simplex
virus transcriptional activator VP16 (5, 6), p316:ACE1 was
digested with BamHI and BglII, releasing a 937-bp
fragment containing the coding region for the amino-terminal DNA
binding domain of Ace1p and the 5' flanking region. An in-frame fusion
with the VP16 activation domain was constructed by cloning this
fragment into the BglII site of plasmid CRF3 which contains
the coding region for amino acids 402 to 479 of VP16, 119 bp of 3'
flanking region, and a 400-bp fragment containing the thymidine kinase
termination signal and polyadenylation site (a generous gift from
Steven Triezenberg). The ACE1-VP16 fusion gene was then
released by digesting the resulting plasmid with EcoRI and
SalI and mobilized into pRS303 to generate p303:ACVP.
Plasmids p303:ACE1 and p303:ACVP were digested at a unique
BsmI site on the HIS3 marker and transformed into
strain KKY1 for integration into the chromosome at the his3
locus to generate strains MPY2 and MPY3, respectively. Proper
integration of these plasmids into the genome was verified by Southern
blot analysis and by testing the resistance of the resulting strains to
Cu on synthetic complete medium (SC)-His plates. To evaluate the role
of MAC1 in Cu detoxification, strains MPY17 and MPY18 were
constructed. MPY17 was derived from SKY46, which contains a double
deletion of the high-affinity transport genes CTR1 and CTR3 (25), by PCR mutagenesis of the
URA3 marker in which 391 bp of the URA3 open
reading frame was replaced by the kanamycin resistance cassette
(44). MPY18 was derived from MPY17 by disruption of the
MAC1 allele, using the plasmid pmac1::URA3
(29). Disruption of the MAC1 gene was verified by
diagnostic PCR analysis. Plasmids pRSMAC1(HA) and
pRSMAC1up1(HA) contain a 2.5-kb genomic fragment of the
MAC1 gene and a 2.5-kb genomic fragment of
MAC1up1, both cloned into the SalI
and BamHI sites of the pRS313 vector (56). Both
genes were tagged with a single copy of the Haemophilus influenzae hemagglutinin protein epitope at the carboxyl terminus, giving rise to proteins functionally indistinguishable from the parental proteins. For RNase protection analyses, three plasmids were
constructed for making antisense RNA probes. Plasmid pSKCUP1 was
constructed by inserting a 149-bp EcoRI-BamHI
fragment of the CUP1 gene into the same sites of pBlueScript
SK. The antisense RNA hybridizes to the region between +31 and +179
downstream from the translational start codon of CUP1. To
generate pSKCTR3, a 181-bp fragment of the CTR3 gene was
amplified from strain DTY1 and cloned into the EcoRI and
BamHI sites of pBlueScript SK. This fragment hybridizes to
the region between +86 and +267 downstream from the translational start
codon of CTR3. The riboprobe derived from the plasmid
pKSACT1 (29) was used to probe ACT1 mRNA as an
internal control for normalization during quantitation of the RNase
protection products. For in vivo DMS footprinting, plasmid pRSCUP1/CYC1-lacZ, containing the CUP1 promoter
from 
390 up to the first base of the translation start codon fused to
a minimal CYC1 promoter and a reporter lacZ gene
(a generous gift from Nicholas Santoro), was used as a template for
sequencing.
[35S]cysteine labeling.
Exponential-phase
cultures of DTY1 cells were grown at 30°C in 100 ml of YPD medium to
exponential phase. The cells were incubated with 5 µCi of
[35S]cysteine (800 Ci/mmol; ICN Radiochemicals) per ml
for 30 min prior to the addition of 0.1 M CuSO4 to a final
concentration of 100 µM. Five-milliliter samples were withdrawn from
the cultures after Cu treatment. Proteins were extracted and analyzed
on 20% nondenaturing polyacrylamide gels and visualized by
fluorography as described previously (54).
In vivo DMS footprinting.
Log-phase cultures of DTY1 cells
were grown in 1.5 liters of YPD liquid medium and treated with 100 µM
CuSO4. After 0, 15, 30, and 60 min, 250-ml samples were
treated with 2% DMS for 5 min. In vivo DMS footprinting was performed
as previously described (57). Isolated genomic DNA samples
from cells that were treated or untreated with Cu or DMS were digested
with BspHI prior to G,A-specific cleavage with 1.0 N NaOH.
An oligonucleotide (5'-CCTCATATATGTGTATAGGTTTATACGG-3') which hybridizes to the CUP1 promoter at positions
310 to 282 with respect to the start site of transcription was used
for primer extension analysis and for dideoxy sequencing of the
pRSCUP1/CYC1-lacZ template.
Standard methods.
Total RNA was extracted by the hot phenol
method as previously described (28). RNase protection assays
were performed as described by Koch and Thiele (27).
Quantitation of the radioactive bands were performed with a
PhosphorImager SP and ImageQuant 3.3 software (Molecular Dynamics).
Quantitation from the PhosphorImager were plotted and analyzed by using
Kaleidagraph 3.02 (Synergy Software, Reading, Pa.). Proteins were
extracted as previously described (54) and quantitated by
using a Bio-Rad protein assay kit with bovine serum albumin as a
protein standard. Spectrophotometric measurements were performed on a
Beckman DU64 spectrophotometer. DNA isolation and PCRs were performed
by standard protocols (1). DNA sequencing was carried out
with a Sequenase kit as specified by the manufacturer (U.S.
Biochemical). Western blot analysis was performed by standard protocols
(1) and visualized with horseradish peroxidase-labeled goat
anti-rabbit immunoglobulin G (Bethesda Research Laboratories) and a
Renaissance chemiluminescence kit (Dupont NEN).
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RESULTS |
Transcriptional regulation of CUP1 and CTR3
in the chronic presence of Cu ions.
To study the interplay between
the Cu ion sensors Mac1p and Ace1p, which regulate the expression of
genes encoding components of the high-affinity Cu(I) uptake pathway and
the Cu ion detoxification pathway, respectively, yeast cells were
incubated with low and high Cu ion concentrations in the media.
Expression of the high-affinity Cu(I) transport gene CTR3
and the metallothionein gene CUP1 was analyzed over time by
RNase protection. In response to 1, 10, and 100 µM added Cu,
CTR3 mRNA levels were quickly reduced approximately fivefold
within 15 min of Cu treatment (Fig. 1A).
This loss of expression was followed by a slight and transient but
reproducible derepression and then subsequent repression to eightfold
less than the original basal level (Fig. 1B). Simultaneously, the
Ace1p-mediated transcriptional activation of CUP1 mRNA
expression was rapid and robust but transient. In response to 1, 10, and 100 µM Cu, maximum levels of CUP1 mRNA induction of
16-, 27-, and 36-fold, respectively, occurred within 30 min of Cu
treatment. This was followed by a precipitous reduction in
CUP1 mRNA levels within 60 min to approximately eightfold
the original basal level and remained at these levels throughout the
time course of the experiment (Fig. 1A and C). Therefore, in response
to the continued presence of Cu ions, the expression of CTR3
was extinguished whereas the CUP1 gene was strongly but
transiently activated.
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FIG. 1.
Expression of CTR3 and CUP1 in
response to 1, 10, and 100 µM CuSO4. (A)
Exponential-phase cultures of S. cerevisiae DTY1 were
treated with 1, 10, and 100 µM CuSO4. Five-milliliter
samples were taken after 0, 2, 5, 10, 15, 20, 25, 30, 45, 60, 75, 90,
and 120 min of Cu treatment. RNA extracted from each sample was
analyzed by RNase protection assays. Each reaction contained 30 µg of
total RNA. CTR3, CUP1, and ACT1 RNAs
are indicated by arrows. (B) Quantitation of CTR3 mRNA
expression in response to Cu. (C) Quantitation of CUP1 mRNA
expression in response to Cu. All values in panels B and C were
normalized against those for ACT1 mRNA as an internal
control.
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Steady-state Cup1p levels during Cu ion treatment.
The yeast
metallothionein encoded by CUP1 detoxifies Cu ions by
tightly sequestering seven atoms of Cu(I) through coordination with the
thiolate ligands of the abundant cysteine residues in the protein.
Since CUP1 mRNA levels were transiently elevated when cells
were grown in the continued presence of Cu ions, the levels of Cup1
protein were analyzed from cells treated with 100 µM Cu by
metabolically labeling yeast cells with [35S]cysteine.
Total soluble proteins were extracted from culture aliquots, analyzed
on a 20% nondenaturing polyacrylamide gel, and visualized by
fluorography (54). Figure 2
shows that although the levels of Cup1 protein increased with
increasing times of Cu treatment, these levels remained high throughout
the time course of the experiment. Therefore, while CUP1
mRNA levels were transiently induced, Cup1p remained at high
steady-state levels.
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FIG. 2.
Induction of Cup1p in response to 100 µM
CuSO4. Exponential-phase cultures of S. cerevisiae DTY1 were labeled with 5 µCi of
[35S]cysteine (800 Ci/mmol) per ml for 30 min and then
treated with 100 µM CuSO4. Five-milliliter samples were
taken at 0, 2, 5, 10, 15, 20, 25, 30, 45, 60, 75, 90, and 120 min of Cu
treatment. Total protein extracts were analyzed on a 20% nondenaturing
polyacrylamide gel. Each lane contains 30 µg of total protein. The
gel was fixed with 10% acetic acid and 30% methanol for 1 h,
fluorographed with En3Hance (Dupont), dried under vacuum,
and exposed to Kodak BioMax Film with an intensifying screen at
80°C.
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Ace1p occupation of MREs parallels transient CUP1
expression.
The Ace1p metalloregulatory transcription factor
rapidly activates CUP1 transcription in response to Cu ions
(40). The cooperative formation of a tetra-Cu cluster in the
amino-terminal Ace1p DNA binding domain, via cysteine thiolate
coordination, induces Ace1p to bind to two potent and two modestly
active MREs in the CUP1 promoter (23). We
postulated that inactivation of CUP1 expression, in the
chronic presence of Cu ions, could occur via several mechanisms. First,
it is possible that the half-life of CUP1 mRNA decreases at
the later time points. Second, it is possible that at the later time
points, Ace1p is degraded. Third, Ace1p could remain bound to the
CUP1 MREs but the carboxyl-terminal transactivation domain might be rendered inactive. Fourth, the activation and inactivation of
CUP1 transcription by Ace1p may simply reflect fluctuations in the amount of available intracellular Cu ions sufficient to maintain
Ace1p in an active configuration for DNA binding.
Since the estimated half-life of
CUP1 mRNA is approximately
12 to 16 min (
35a), the reduced levels of
CUP1
mRNA between 30
and 60 min may reflect the combined result of its
normal decay
and a reduced rate of transcription at these time points.
To test
the possibility that Ace1p is degraded at the later time
points,
DTY1 cells were incubated with 1, 10, and 100 µM Cu ions, and
total cellular proteins were extracted and analyzed by immunoblotting
with polyclonal antibodies raised against Ace1p expressed in and
purified from
E. coli. The results in Fig.
3 show that the levels
of Ace1p remained
constant throughout the time course of the experiment
at all Cu ion
concentrations. Therefore, the reduction in
CUP1 mRNA levels
at later time points was not the result of a Cu-dependent
degradation
of Ace1p. This finding is consistent with previous
observations that
ACE1 expression, at the level of steady-state
mRNA, is
constitutive and not affected by the presence or absence
of Cu ions
(
39).
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FIG. 3.
Western blot analysis of Ace1p levels during Cu ion
treatment. Exponential-phase cultures of S. cerevisiae DTY1
were treated with 1, 10, or 100 µM CuSO4. Five-milliliter
samples were taken after 0, 2, 5, 10, 15, 20, 25, 30, 45, 60, 75, and
90 min of Cu treatment. Thirty micrograms of total protein extract was
analyzed by immunoblotting with polyclonal antibodies raised against
purified recombinant Ace1p from E. coli (rACE1p).
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To test the role of the Ace1p transactivation domain in the
inactivation of
CUP1 expression, we constructed a chimeric
gene
in which the transactivation domain of the herpes simplex virus
VP16 protein was fused to the Ace1p amino-terminal DNA binding
domain.
This chimeric protein contains the amino-terminal 122
amino acids of
Ace1p, encompassing the minimal Cu-activated DNA
binding domain
(
22) fused to 78 amino acids (residues 401 to
479) from the
carboxyl-terminal activation domain of VP16 (
5,
6). The
ACE1-VP16 gene and, as a control, the wild-type
ACE1 gene were integrated in single copy at the chromosomal
his3 locus
in an
ace1 strain. Copper
resistance tests demonstrated that
the strain harboring the integrated
ACE1 gene was resistant to
2 mM CuSO
4, which was
indistinguishable from the result for parental
strain containing a
genomic copy of wild-type
ACE1. On the other
hand, the
strain harboring the integrated
ACE1-VP16 fusion gene
was
resistant only to 200 µM CuSO
4 (data not shown). Since a
strain
harboring only the Ace1p Cu-activated DNA binding domain, with
no transactivation domain, is resistant to only approximately
25 µM
CuSO
4 (
22), the VP16 activation domain
significantly activates
CUP1 expression, though not as
strongly as the natural Ace1p activation
domain. It is possible that
Ace1p-VP16 is present at lower levels
than Ace1p; however, it is also
possible that since VP16 is a
heterologous transactivator, it requires
other factors not present
in yeast or other cellular components that
may not function well
with the
CUP1 promoter for strong
activation of
CUP1 transcription,
and this might be
responsible for the lower level of activation
exhibited by this fusion
protein. Cells harboring the integrated
ACE1 and
ACE1-VP16 genes were incubated with 100 µM
CuSO
4, and
CTR3,
CUP1, and
ACT1 mRNA levels were analyzed by RNase protection
assays.
The results shown in Fig.
4 demonstrate
that, consistent
with the Cu ion resistance data, both Ace1p and
Ace1p-VP16 mediate
the induction with subsequent inactivation of
CUP1 expression
in response to Cu, although at different
magnitudes. Ace1p activates
CUP1 expression approximately
19-fold within 45 min, followed
by reduction to approximately 6-fold
above the original basal
level. The Ace1p-VP16 fusion protein modestly
(fourfold) activates
the expression of
CUP1, followed by
reduction to less than twofold
above the original basal level. These
results suggest that the
Ace1p carboxyl-terminal activation domain is
required for maximum
CUP1 induction in response to Cu.
Furthermore, the reduction in
CUP1 expression upon prolonged
exposure to Cu ions does not occur
specifically through the Ace1p
carboxyl-terminal transactivation
domain.
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FIG. 4.
Transcription of CTR3 and CUP1 by
ACE1-VP16 in response to 100 µM CuSO4.
Exponential-phase cultures of strains MPY2 and MPY3 harboring a
wild-type ACE1 gene and a gene fusion between the Ace1p DNA
binding domain and the VP16 activation domain integrated at the
his3 locus, respectively, were treated with 100 µM
CuSO4. Five-milliliter samples were taken after 0, 2, 5, 10, 15, 20, 25, 30, 45, 60, 75, 90, and 120 min of Cu treatment. Thirty
micrograms of total RNA was used in RNase protection experiments for
each sample, using ACT1 mRNA as an internal control.
CTR3, CUP1, and ACT1 RNase protection
products are indicated by arrows.
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The
CUP1 promoter harbors four MREs which have previously
been shown to be bound by Ace1p both in vitro and in vivo (
12,
23). The promoter proximal MREs (MREs 1 and 2) potently activate
CUP1 transcription in response to Cu ions, while the distal
MREs
(MREs 3 and 4) modestly contribute to the magnitude of Cu
ion-inducible
CUP1 activation (
23). To test the
hypothesis that the inactivation
of
CUP1 transcription in
response to prolonged treatment of cells
with Cu ions is mediated
through the regulation of Cu-dependent
Ace1p binding to MREs, the
occupancy of the
CUP1 MREs was monitored
over a time course
of Cu ion exposure by in vivo footprinting
with DMS. Log-phase cultures
of DTY1 cells were treated with 100
µM Cu; samples were taken after
0, 15, 30, and 60 min of Cu ion
treatment and incubated with 2% DMS to
assess the occupancy of
the MREs by Ace1p over time. The data in Fig.
5 show that before
treatment of cells
with Cu ions, the guanosine (G) residues within
the MREs that are
engaged in major groove contacts with Ace1p
(indicated by dots in Fig.
5A) were accessible to modification
by DMS. After 15 min of Cu ion
treatment, when
CUP1 expression
was strongly induced, the G
residues at positions
180,
165,
133,
132,
119,
107,
104,
and
103 were relatively inaccessible
to modification by DMS compared
to the zero time point. This is
consistent with occupation of the MREs
corresponding to these
positions (MREs 1 to 3) by Ace1p. Occupancy of
the MREs coincides
with the onset of
CUP1 mRNA synthesis as
shown in Fig.
1A. The
intensities of these bands after 15 and 30 min of
Cu treatment
suggest a 50% occupancy by Ace1p of the MREs at this Cu
concentration.
After 60 min, when
CUP1 mRNA levels were
strongly reduced, the
G residues were more accessible to modification
by DMS. The quantitation
shown in Fig.
5B shows the relative
accessibility of the G residues
at positions
107,
119, and
132
with respect to the start site
of
CUP1 transcription. These
residues fall within or immediately
adjacent to MREs 1 and 2, previously shown to be the most potent
MREs in the
CUP1
promoter (
23). On the other hand, the G residues
at
positions
104,
165,
180,
203, and
211 were more accessible
than after 15 and 30 min of Cu treatment but were not restored
to basal
levels (data not shown). This finding is consistent with
the
observation that at this time point,
CUP1 mRNA levels were
approximately eightfold above the basal level; thus, transcription
by
Ace1p is eightfold higher than in untreated cells. Based on
these
observations, the induction and subsequent reduction of
CUP1
mRNA levels in response to Cu ions are mediated in large
part through
the Cu-dependent DNA binding of Ace1p to the MREs.
Furthermore, the
observation of reduced Ace1p occupation of the
MREs at the later time
points suggests that the inactivation of
CUP1 expression is
likely due to inactivation of the Ace1p Cu
ion-dependent DNA binding
domain.
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FIG. 5.
In vivo DMS footprinting analysis of the CUP1
promoter. (A) Exponential-phase cultures of strain DTY1 were treated
with 100 µM Cu. After 0, 15, 30, and 60 min of Cu treatment, 250-ml
samples were taken and analyzed by in vivo DMS footprinting to assess
the occupancy of the MREs by Ace1p. The positions of MREs 1 through 4 are indicated schematically, and G residues within MREs are indicated
by dots. (B) Quantitation of the relative accessibility to DMS
modification of representative G residues from the proximal MRE (MRE 1)
closest to the CUP1 transcriptional start site. These values
were normalized against the bands at positions 212 and 243 with
respect to the transcriptional start site, whose intensities remained
constant throughout the time course of Cu ion treatment.
|
|
Effect of increasing Cu ion concentrations on CUP1
regulation.
Inactivation of the DNA binding activity of Ace1p
requires the removal of Cu ions from its DNA binding domain. To test
the possibility that inactivation of the Ace1p DNA binding occurs through sequestration by Cup1p of excess Cu ions, DTY1 cells were challenged with 1 and 5 mM Cu ions and the effect on CUP1
downregulation was examined by RNase protection analyses. Since these
Cu concentrations are at the threshold level of Cu resistance for this
strain, expression of CUP1 is required for its survival and
the excess Cu ions may surpass the chelation capacity of Cup1p. In
response to 1 mM Cu, the levels of CUP1 mRNA were quickly
induced 15-fold within 15 min, followed by downregulation to 4-fold
above the original basal level within 60 min and then a further 14-fold
induction within 2 h (Fig. 6). In
response to 5 mM Cu, the CUP1 mRNA levels were quickly
induced 15-fold within 15 min; however, the mRNA levels were not
significantly downregulated but were maintained at approximately 15- to
20-fold above the basal level for 2 h. Therefore, at toxic Cu ion
concentrations approaching the threshold for cell survival, transcription of the high-affinity Cu(I) transporters is extinguished, Cu uptake proceeds via the low-affinity uptake pathway, and
CUP1 transcription is no longer downregulated at the later
time points.
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|
FIG. 6.
Effect of increasing Cu ion concentration on
CUP1 regulation. Exponential-phase cultures of strain DTY1
were treated with 1 or 5 mM CuSO4. Five-milliliter samples
were taken after 0, 15, 30, 45, 60, 90, and 120 min of Cu treatment.
RNA was extracted from each sample and analyzed by RNase protection
assays. Each reaction contained 20 µg of total RNA. CUP1
and ACT1 mRNAs are indicated by arrows. Quantitation of
CUP1 mRNA is shown in the graph.
|
|
Role of the Cu(I) transporters in CUP1 regulation.
S. cerevisiae utilizes the products of the FRE1,
CTR1, and CTR3 genes to carry out high-affinity
Cu(I) transport. In contrast to the CUP1 gene, each of these
genes is transcriptionally activated by Cu ion starvation and
inactivated by Cu ion repletion (26). Both the
transcriptional activation and inactivation of these genes require
Mac1p (14, 24, 29, 48). Furthermore, the ability to properly
activate, via metallation, the Ace1p DNA binding domain depends on the
presence of functional yeast Cu(I) ion transport machinery (9,
25). The observations that CUP1 expression and Cu
ion-dependent Ace1p binding to the CUP1 MREs is transient and that expression of the high-affinity Cu(I) transport machinery is
inactivated under these conditions suggest a link between the proper
expression of the Cu ion transport and detoxification pathways. To test
the potential role of the high-affinity Cu(I) transport system in the
inactivation of CUP1 expression in response to Cu ions, a
strain carrying a dominant mutation in the MAC1 gene, MAC1up1, was used.
MAC1up1 strains are unable to properly sense
even high Cu ion concentrations and therefore express high constitutive
levels of mRNA from the FRE1, CTR1, and
CTR3 genes (14, 29, 48, 56). A
MAC1up1 strain (DTY205) was incubated in the
presence of 1, 10, or 100 µM CuSO4, and the levels of
CTR3, CUP1, and ACT1 mRNAs were
analyzed by RNase protection. The results shown in Fig.
7A,
and quantitated in Fig. 7B and C, show that although CTR3
transcription was transiently inactivated by Cu ions in the
MAC1up1 strain at all concentrations used,
CTR3 mRNA levels were eventually elevated to approximately
1.3-fold the original basal level upon prolonged exposure to Cu ions.
In response to 1 µM Cu, transcription of the CUP1 gene was
transiently induced as in the wild-type parental strain. However, at a
Cu ion concentration of 10 or 100 µM, CUP1 transcription
was sustained at approximately 15-fold above the original basal level
after the initial induction (Fig. 7). These results demonstrate that
sustained expression of the high-affinity Cu(I) ion transport machinery
also results in sustained transcription of CUP1.
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|
FIG. 7.
Expression of CTR3 and CUP1
in a MAC1up1 strain. (A) Exponential-phase
cultures of strain DTY205, which harbors the dominant
MAC1up1 allele, were treated with 1, 10, and 100 µM Cu. Five-milliliter samples were taken after 0, 2, 5, 10, 15, 20, 25, 30, 45, 60, 75, 90, and 120 min of Cu ion treatment and analyzed by
RNase protection assays. Thirty micrograms of total RNA was analyzed in
each reaction. The CTR3, CUP1, and
ACT1 RNase protection products are indicated by arrows. (B)
Quantitation of CTR3 expression in response to Cu. (C)
Quantitation of CUP1 expression in response to Cu. The
values shown in panels B and C were normalized against values for
ACT1 as an internal control.
|
|
One phenotype associated with
MAC1up1 strains is
hypersensitivity to Cu ion toxicity, even though, as demonstrated here,
CUP1 expression after prolonged exposure to at least 10 µM
Cu ions
(90 to 120 min) is much higher than in an isogenic
MAC1 wild-type
strain. This hypersensitivity may be a
consequence of the high
levels of Cu ion transport previously observed
(
24) due to the
constitutive expression of the Cu ion
transport genes. To assess
the effect of continued Cu uptake by the Cu
ion transporters on
the ability of a
MAC1up1
strain to detoxify Cu, strains harboring the
MAC1 or
MAC1up1 allele, with or without functional
CTR1 and
CTR3 genes, were
challenged with
increasing concentrations of Cu ions. Figure
8 shows that a strain harboring a
wild-type
MAC1 gene survived in
the presence of 2 mM
CuSO
4. Deletion of the
CTR1 and
CTR3
high-affinity
Cu(I) transport genes allowed these cells to grow slowly
in the
presence of a slightly higher Cu concentration of 2.5 mM (data
not shown), thus providing the cell with a slight added advantage
over
strains that have both
CTR1 and
CTR3. On the
other hand,
a strain harboring the dominant
MAC1up1 allele was sensitive to 400 µM Cu
whereas deletion of
CTR1 and
CTR3 allowed these
strains to grow in the presence of 400 µM Cu,
but not at higher
concentrations, providing only a limited advantage
over strains that
possessed both transporters. Thus, while continued
Cu ion uptake by
CTR1 and
CTR3 contribute to the increased Cu
sensitivity of a
MAC1up1 strain, the presence of
this allele may directly or indirectly
influence other cellular events
that can contribute to the Cu
sensitivity phenotype. These results
clearly show that although
deletion of the Cu ion transporters Ctr1p
and Ctr3p contribute
modestly to Cu resistance, the nutritional Cu
sensor Mac1p plays
a critical role in cell survival under toxic Cu
conditions.
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|
FIG. 8.
Copper sensitivity of MAC1 and
MAC1up1 strains. Yeast strains of the indicated
relevant genotypes were plated on SC-His medium containing increasing
concentrations of CuSO4. Strains DTY1 and DTY205 were
transformed with the pRS313 vector to allow growth on SC-His plates.
Both strains contain the CTR1 and CTR3 genes and
harbor a wild-type MAC1 and MAC1up1
alleles, respectively. MPY18 strains lack both high-affinity Cu
transport genes and harbor a chromosomal deletion of the
mac1 allele. These strains were transformed with a
plasmid expressing either the MAC1 or
MAC1up1 allele on a pRS313-based centromeric
vector. The MAC1 genes were both tagged with a single copy
of the hemagglutinin epitope at the 3' end of the open reading frame.
|
|
| |
DISCUSSION |
The essential yet toxic nature of Cu ions in biological systems
demands tight regulation of the expression of genes involved in Cu
homeostasis. Proper regulation is critical to dictate that appropriate
levels of Cu ions are present in cells at all times and under all
growth conditions. Consistent with this delicate regulation, the
proteins involved in Cu uptake, distribution, and detoxification are
regulated in response to Cu ions at the level of gene transcription,
posttranscriptional events, and protein trafficking (26).
The CTR3 gene, encoding a protein involved in high-affinity
Cu(I) transport, and the CUP1 gene, encoding the Cu ion
binding and detoxification metallothionein protein, are
transcriptionally regulated in opposite directions in response to
elevated Cu ion concentrations. Furthermore, although CTR3 is transcriptionally inactivated at very low Cu ion concentrations and
CUP1 is activated at high Cu ion concentrations, our results establish that there is a window of overlap between the nutritional and
toxic Cu ion sensing systems. Since at least two Cu-responsive regulatory circuits function in yeast, there must be a dynamic interplay between the Cu ion uptake and detoxification pathways and
their regulation by the Cu-responsive transcription factors Mac1p and
Ace1p.
Interestingly, we demonstrate that in the chronic presence of elevated
Cu ion concentrations, CUP1 mRNA levels are rapidly but
transiently activated, while expression of the CTR3 gene is inactivated. The analysis of Ace1p steady-state levels, the activity of
an Ace1p DNA binding domain-VP16 activation domain fusion protein, and
in vivo footprinting studies have clearly demonstrated that the
transient activation of CUP1 occurs via the modulation of Cu
ion-dependent Ace1p binding to the CUP1 promoter MREs.
Occupation of the CUP1 promoter MREs closely paralleled the
abundance of CUP1 mRNA levels. This correlation might
reflect fluctuations in the availability of intracellular Cu ions for
the activation of Ace1p DNA binding during the time course of the
experiment. Previous studies in mice showed that administration of
cadmium (Cd) transiently induced metallothionein-I gene (MT-I)
transcription in the liver and kidney, with maximum transcriptional
rates observed within 1 h and maximum mRNA levels observed within
4 h of Cd injection. MT-I mRNA levels are then reduced within
9 h; however, these levels never return to the constitutive basal
levels (11). In these studies, however, MT-I induction was
measured in response to a single injection of Cd rather than constant
exposure of the mice to extracellular Cd. In other studies using
Neurospora crassa, Cu treatment strongly induced Cu-MT mRNA
levels within 1 h followed by repression to basal levels within
8 h, while Cu-MT protein levels reach maximum levels within 3 h and remained at the same elevated levels over the time period
examined (17 h) (33). These results in other eukaryotic
systems correlate well with our direct analysis of the activity of a
yeast CuMRTF.
What might be the mechanisms by which CUP1 expression is
turned down, through inactivation of the Ace1p DNA binding function even in the continued presence of elevated Cu ion concentrations? One
mechanism might be through Cu ion efflux. Studies using BHK cell lines
showed transient expression of a -galactosidase reporter gene fused
to five MREs (MRE--Geo) in response to zinc, and this transient
expression was attributed to zinc efflux by ZnT-1 (33a, 35)
and sequestration of zinc into an endosomal/lysosomal compartment by
ZnT-2 (34), to prevent the accumulation of intracellular zinc to toxic levels. However, it is unlikely that the transient expression of CUP1 mRNA shown in our results is due to
extrusion of Cu ions from yeast cells. Previous studies have clearly
shown that over the same time course as our experiments, cells treated with elevated Cu levels in the media continue to accumulate Cu ions to
a level of saturation with increasing time of incubation, without any
evidence for efflux (30, 35b). In these studies, however, Cu
levels were measured as total cell-associated Cu; thus, although the
results preclude Cu efflux, they do not address the possibility of Cu
transport into the vacuole. Since our experiments demonstrate that Cup1
protein stably accumulates over the time course of these experiments,
one mechanism may be that Cup1p itself outcompetes Ace1p for available
Cu ions, either through competition for available free intracellular
copper or through the disassembly of the tetra-copper cluster in the
Ace1p DNA binding domain that is essential for an active DNA binding
configuration. It is interesting that proteins called Cu chaperones
which deliver Cu ions to specific intracellular targets that include
the secretory compartment, Cu,Zn superoxide dismutase, and the
mitochondria have been identified in yeast and human cells (8, 15,
31). Therefore, it is possible that Cu ion chaperones exist to
disassemble preformed Cu clusters or that the assembly reaction carried
out by a Cu-specific chaperone is also reversible. To date, no Cu ion
chaperones specific for assembly of the Cu cluster in Ace1p have been
reported. On the other hand, our results show that when cells were
treated with toxic levels of Cu (5 mM), CUP1 expression was
no longer downregulated, suggesting that as the intracellular Cu levels increase, the chelation capacity of Cup1p is saturated and excess Cu
becomes available to activate the DNA binding activity of Ace1p, resulting in the continued expression of CUP1 mRNA. Previous
studies have shown that apometallothioneins can sequester Zn from the zinc finger domains on transcription factors such as Sp1
(50) and TFIIIA (51), rendering them unable to
bind to target DNA sequences. In addition, it has been shown that
autoregulation of CUP1 transcription by Cup1p depends on its
ability to bind and detoxify Cu. Mutations in CUP1 that
prevented Cu ion binding also diminished its ability to autoregulate
its own transcription and detoxify Cu (46). Thus, increased
synthesis of Cup1p metallothionein in response to Cu ions in yeast
might sequester Cu from Ace1p, rendering it unable to bind to the MREs
on the CUP1 promoter, providing a mechanism for
autoregulating its own transcription. This mechanism for Cu
detoxification by Cup1p and autoregulation of its own transcription in
the continued presence of Cu in the media clearly requires that
additional Cu uptake by the high-affinity transporters be prevented.
Although CTR1 and CTR3 play critical roles in
high-affinity Cu ion transport, our data suggest that the proper
regulation of these transporter genes by Mac1p, even in the presence of
high Cu ion concentrations, is crucial for the normal transient
expression of CUP1. In a strain expressing a mutant allele
of the MAC1 gene which gives strong constitutive activation
of CTR1 and CTR3, CUP1 mRNA was
transcriptionally activated by Cu ions, but the mRNA levels persisted,
in contrast to the transient expression under the same conditions in
wild-type cells. These observations suggest that the disappearance of
the Ctr1p and Ctr3p transporters from the cell surface plays an
important role in limiting intracellular Cu ion levels that are
available to Ace1p.
The results presented here also clearly demonstrate that the Mac1p,
previously thought to function predominantly in sensing nutritional
levels of Cu ions, must function properly to allow cells to mount a
normal Cu detoxification response. The inability of Mac1p to properly
sense Cu ions, as exhibited by the Mac1up1 protein,
resulted in sustained expression of the CTR1 and
CTR3 genes and a concomitant hypersensitivity to Cu ions.
This background also gives rise to sustained expression of the
CUP1 gene, suggesting that Cu toxicity results from
continued Cu uptake that surpasses the chelation or
compartmentalization capacity of the cell. Consistent with this
possibility, deletion of the CTR1 and CTR3 genes
in the MAC1up1 strain partially restored Cu
resistance. Our results show, however, that continued Cu uptake by the
high-affinity Cu ion transporters contribute minimally to the Cu
hypersensitivity of a MAC1up1 strain since
removal of CTR1 and CTR3 in this strain allowed cells to survive in the presence of only 400 µM, while removal of
both genes in a wild-type MAC1 strain allowed this strain to grow in the presence of 2.5 mM Cu. This finding suggests that additional Mac1p target genes must be properly regulated for normal Cu
ion resistance. It is possible that, as in the case of the Zn
metalloregulatory factor Zap1p, which regulates the transcription of
both the high- and low-affinity zinc uptake genes in yeast (52), Mac1p regulates the expression of both the high- and
low-affinity Cu ion uptake genes and that a Mac1up1 protein
would result in dramatic overexpression of the low-affinity Cu ion
transport machinery. Additionally, Cu sensitivity in the MAC1up1 background could result from an
inability to properly regulate other genes encoding proteins that may
directly or indirectly protect cells from the toxic effects of Cu ions.
To date, these genes and genes encoding the low-affinity Cu ion uptake
machinery remain to be identified. The results presented here
underscore the importance of dynamic regulation of the Cu ion transport
pathway by the nutritional Cu sensor Mac1p, and the Cu detoxification pathway by the toxic Cu sensor Ace1p, to maintain appropriate intracellular Cu levels and for survival in the continued presence of
elevated Cu levels in the environment.
| |
ACKNOWLEDGMENTS |
We thank the members of the Thiele laboratory for stimulating
discussions and critical comments. We are grateful to Simon Labbé
for providing plasmids pSKCUP1, pSKCTR3, ura3::KanMX2, and
pKSACT1 and to Zhiwu Zhu for providing plasmids pRSMAC1(HA) and
pRSMAC1up1(HA).
This work was supported by National Institutes of Health (NIH) grant
RO1 GM41840 to D.J.T., postdoctoral fellowship-National Research
Service Award F32 GM18089 from NIH to M.M.O.P., and Cellular Biotechnology Training Program NIH grant GM08353 to K.A.K. D.J.T. is a Burroughs Wellcome Toxicology Scholar.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biological Chemistry, The University of Michigan Medical School, 1301 Catherine Rd., Ann Arbor, MI 48109-0606. Phone: (313) 763-5717. Fax:
(313) 763-4581. E-mail: dthiele{at}umich.edu.
| |
REFERENCES |
| 1.
|
Ausubel, F. M.,
R. Brent,
R. E. Kingston,
D. D. Moore,
J. G. Seidman,
J. A. Smith, and K. Struhl (ed.).
1987.
In
Current protocols in molecular biology.
John Wiley & Sons, New York, N.Y.
|
| 2.
|
Bull, P. C., and D. W. Cox.
1994.
Wilson disease and Menkes disease: new handles on heavy metal transport.
Trends Genet. Sci.
10:248-252.
|
| 3.
|
Bull, P. C.,
G. R. Thomas,
J. M. Rommens,
J. R. Forbe, and D. W. Cox.
1993.
The Wilson disease gene is a putative copper transporting P-type ATPase similar to the Menkes gene.
Nat. Genet.
5:327-337[Medline].
|
| 4.
|
Butler, G., and D. J. Thiele.
1991.
ACE2, an activator of yeast metallothionein expression which is homologous to SWI5.
Mol. Cell. Biol.
11:476-485[Abstract/Free Full Text].
|
| 5.
|
Cousens, D. J.,
R. Greaves,
C. R. Goding, and P. O'Hare.
1989.
The C-terminal 79 amino acids of the herpes simplex virus regulatory protein, Vmw65, efficiently activate transcription in yeast and mammalian cells in chimeric DNA-binding proteins.
EMBO J.
8:2337-2342[Medline].
|
| 6.
|
Cress, W. D., and S. J. Triezenberg.
1991.
Critical structural elements of the VP16 transcriptional activation domain.
Science
251:87-90[Abstract/Free Full Text].
|
| 7.
|
Culotta, V. C.,
W. R. Howard, and X. F. Liu.
1994.
CRS5 encodes a metallothionein-like protein in Saccharomyces cerevisiae.
J. Biol. Chem.
269:25295-25302[Abstract/Free Full Text].
|
| 8.
|
Culotta, V. C.,
L. W. J. Klomp,
J. Strain,
R. L. B. Casareno,
B. Krems, and J. D. Gitlin.
1997.
The copper chaperone for superoxide dismutase.
J. Biol. Chem.
272:23469-23472[Abstract/Free Full Text].
|
| 9.
|
Dancis, A.,
D. Haile,
D. S. Yuan, and R. D. Klausner.
1994.
The Saccharomyces cerevisiae copper transport protein (Ctr1p).
J. Biol. Chem.
269:25660-25667[Abstract/Free Full Text].
|
| 10.
|
Dancis, A.,
D. S. Yuan,
D. Haile,
C. Askwith,
D. Eide,
C. Moehle,
J. Kaplan, and R. D. Klausner.
1994.
Molecular characterization of a copper transport protein in S. cerevisiae: an unexpected role for copper in iron transport.
Cell
76:393-402[Medline].
|
| 11.
|
Durnam, D. M., and R. D. Palmiter.
1981.
Transcriptional regulation of the mouse metallothionein-I gene by heavy metals.
J. Biol. Chem.
256:5712-5716[Abstract/Free Full Text].
|
| 12.
|
Evans, C. F.,
D. R. Engelke, and D. J. Thiele.
1990.
ACE1 transcription factor produced in Escherichia coli binds multiple regions within yeast metallothionein upstream activation sequences.
Mol. Cell. Biol.
10:426-429[Abstract/Free Full Text].
|
| 13.
|
Furst, P.,
S. Hu,
R. Hackett, and D. Hamer.
1988.
Copper activates metallothionein gene transcription by altering the conformation of a specific DNA binding protein.
Cell
55:705-717[Medline].
|
| 14.
|
Georgatsou, E.,
L. A. Mavrogiannis,
G. S. Fragiadakis, and D. Alexandraki.
1997.
The yeast Fre1p/Fre2p cupric reductases facilitate copper uptake and are regulated by the copper-modulated Mac1p activator.
J. Biol. Chem.
272:13786-13792[Abstract/Free Full Text].
|
| 15.
|
Glerum, D. M.,
A. Shtanko, and A. Tzagoloff.
1996.
Characterization of COX17, a yeast gene involved in copper metabolism and assembly of cytochrome oxidase.
J. Biol. Chem.
271:14504-14509[Abstract/Free Full Text].
|
| 16.
|
Graden, J. A., and D. R. Winge.
1997.
Copper-mediated repression of the activation domain in the yeast Mac1p transcription factor.
Proc. Natl. Acad. Sci. USA
94:5550-5555[Abstract/Free Full Text].
|
| 17.
|
Gralla, E. B.,
D. J. Thiele,
P. Silar, and J. S. Valentine.
1991.
ACE1, a copper-dependent transcription factor, activates expression of the yeast copper,zinc superoxide dismutase gene.
Proc. Natl. Acad. Sci. USA
88:8558-8562[Abstract/Free Full Text].
|
| 18.
|
Halliwell, B., and J. M. C. Gutteridge.
1984.
Oxygen toxicity, oxygen radicals, transition metals and diseases.
Biochem. J.
219:1-4[Medline].
|
| 19.
|
Hamer, D. H.
1986.
Metallothioneins.
Annu. Rev. Biochem.
55:913-951[Medline].
|
| 20.
|
Hamer, D. H.,
D. J. Thiele, and J. E. Lemontt.
1985.
Function and autoregulation of yeast copperthionein.
Science
228:685-690[Abstract/Free Full Text].
|
| 21.
|
Hassett, R., and D. J. Kosman.
1996.
Evidence for Cu(II) reduction as a component of Cu uptake by Saccharomyces cerevisiae.
J. Biol. Chem.
270:128-134[Abstract/Free Full Text].
|
| 22.
|
Hu, S.,
P. Furst, and D. Hamer.
1990.
The DNA and Cu binding functions of ACE1 are interdigitated within a single domain.
New Biol.
2:544-555[Medline].
|
| 23.
|
Huibregtse, J. M.,
D. R. Engelke, and D. J. Thiele.
1989.
Copper-induced binding of cellular factors to yeast metallothionein upstream activation sequences.
Proc. Natl. Acad. Sci. USA
86:65-69[Abstract/Free Full Text].
|
| 24.
|
Jungmann, J.,
H. A. Reins,
J. Lee,
A. Romeo,
R. Hassett,
D. Kosman, and S. Jentsch.
1993.
MAC1, a nuclear regulatory protein related to Cu-dependent transcription factors is involved in Cu/Fe utilization and stress resistance in yeast.
EMBO J.
12:5051-5056[Medline].
|
| 25.
|
Knight, S. A. B.,
S. Labbé,
L. F. Kwon,
D. J. Kosman, and D. J. Thiele.
1996.
A widespread transposable element masks expression of a yeast copper transport gene.
Genes Dev.
10:1917-1929[Abstract/Free Full Text].
|
| 26.
|
Koch, K. A.,
M. M. O. Peña, and D. J. Thiele.
1997.
Copper-binding motifs in catalysis, transport, detoxification and signaling.
Chem. Biol.
4:549-560.
[Medline] |
| 27.
|
Koch, K. A., and D. J. Thiele.
1996.
Autoactivation by a Candida glabrata copper metalloregulatory transcription factor requires critical minor groove interactions.
Mol. Cell. Biol.
16:724-734[Abstract].
|
| 28.
|
Kohrer, K., and H. Domdey.
1991.
Preparation of high molecular weight RNA.
Methods Enzymol.
194:398-405[Medline].
|
| 29.
|
Labbé, S.,
Z. Zhu, and D. J. Thiele.
1997.
Copper-specific transcriptional repression of yeast genes encoding critical components in the copper transport pathway.
J. Biol. Chem.
272:15951-15958[Abstract/Free Full Text].
|
| 30.
|
Lin, C., and D. J. Kosman.
1990.
Copper uptake in wild type and copper metallothionein-deficient Saccharomyces cerevisiae.
J. Biol. Chem.
265:9194-9200[Abstract/Free Full Text].
|
| 31.
|
Lin, S.-J.,
R. A. Pufahl,
A. Dancis,
T. V. O'Halloran, and V. C. Culotta.
1997.
A role for the Saccharomyces cerevisiae ATX1 gene in copper trafficking and iron transport.
J. Biol. Chem.
272:9215-9220[Abstract/Free Full Text].
|
| 32.
|
Linder, M. C.
1991.
In
Biochemistry of copper.
Plenum Press, New York, N.Y.
|
| 33.
|
Münger, K.,
U. A. Germann, and K. Lerch.
1987.
In
Isolation and regulation of expression of the Neurospora crassa copper metallothionein gene.
Birkhauser Verlag, Basel, Germany.
|
| 33a.
| Palmiter, R. Personal communication.
|
| 34.
|
Palmiter, R. D.,
T. B. Cole, and S. D. Findley.
1996.
ZnT-2, a mammalian protein that confers resistance to zinc by facilitating vesicular sequestration.
EMBO J.
15:1784-1791[Medline].
|
| 35.
|
Palmiter, R. D., and S. D. Findley.
1995.
Cloning and functional characterization of a mammalian zinc transporter that confers resistance to zinc.
EMBO J.
14:639-649[Medline].
|
| 35a.
| Parker, R. Personal communication.
|
| 35b.
| Peña, M. M. O., and D. J. Thiele. Unpublished data.
|
| 36.
|
Predki, P. F., and B. Sarkar.
1992.
Effect of replacement of "zinc finger" zinc on estrogen receptor DNA interactions.
J. Biol. Chem.
267:5842-5846[Abstract/Free Full Text].
|
| 37.
|
Rymond, B. C.,
R. S. Zitomer,
D. Schumperli, and M. Rosenberg.
1983.
The expression in yeast of the Escherichia coli galk gene on CYC1::galk fusion plasmids.
Gene
25:249-262[Medline].
|
| 38.
|
Sherman, F.,
G. R. Fink, and J. Hicks.
1986.
In
Methods in yeast genetics.
Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
|
| 39.
|
Szczypka, M. S., and D. J. Thiele.
1989.
A cysteine-rich nuclear protein activates yeast metallothionein gene transcription.
Mol. Cell. Biol.
9:421-429[Abstract/Free Full Text].
|
| 40.
|
Thiele, D. J.
1988.
ACE1 regulates expression of the Saccharomyces cerevisiae metallothionein gene.
Mol. Cell. Biol.
8:2745-2752[Abstract/Free Full Text].
|
| 41.
|
Thiele, D. J.
1992.
Metal-regulated transcription in eukaryotes.
Nucleic Acids Res.
20:1183-1191[Free Full Text].
|
| 42.
|
Thorvaldsen, J. L.,
A. K. Sewell,
A. M. Tanner,
J. M. Peltier,
I. J. Pickering,
G. N. George, and D. R. Winge.
1994.
Mixed Cu+ and Zn2+ coordination in the DNA-binding domain of the AMT1 transcription factor from Candida glabrata.
Biochemistry
33:9566-9577[Medline].
|
| 43.
|
Vulpe, C.,
B. Levinson,
S. Whitney,
S. Packman, and J. Gitschier.
1993.
Isolation of a candidate gene for Menkes disease and evidence that it encodes a copper transporting ATPase.
Nat. Genet.
3:7-13[Medline].
|
| 44.
|
Wach, A.,
A. Brachat,
R. Pohlmann, and P. Philippsen.
1994.
New heterologous modules for classical or PCR-based gene disruptions in Saccharomyces cerevisiae.
Yeast
10:1793-1808[Medline].
|
| 45.
|
Welch, J.,
S. Fogel,
C. Buchman, and M. Karin.
1989.
The CUP2 gene product regulates the expression of the CUP1 gene coding for yeast metallothionein.
EMBO J.
8:255-260[Medline].
|
| 46.
|
Wright, C. F.,
D. H. Hamer, and K. McKenney.
1988.
Autoregulation of the yeast copper metallothionein gene depends on metal binding.
J. Biol. Chem.
263:1570-1574[Abstract/Free Full Text].
|
| 47.
|
Yamaguchi, Y.,
M. E. Heiny, and J. D. Gitlin.
1993.
Isolation and characterization of a human liver cDNA as a candidate gene for Wilson disease.
Biochem. Biophys. Res. Commun.
197:271-277[Medline].
|
| 48.
|
Yamaguchi-Iwai, Y.,
M. Serpe,
D. Haile,
W. Yang,
D. J. Kosman,
R. D. Klausner, and A. Dancis.
1997.
Homeostatic regulation of copper uptake in yeast via direct binding of MAC1 protein to upstream regulatory sequences of FRE1 and CTR1.
J. Biol. Chem.
272:17711-17718[Abstract/Free Full Text].
|
| 49.
|
Yuan, D. S.,
R. Stearman,
A. Dancis,
T. Dunn,
T. Beeler, and R. D. Klausner.
1995.
The Menkes/Wilson disease gene homologue in yeast provides copper to a ceruloplasmin-like oxidase required for iron uptake.
Proc. Natl. Acad. Sci. USA
92:2632-2636[Abstract/Free Full Text].
|
| 50.
|
Zeng, J.,
R. Heuchel,
W. Schaffner, and J. H. R. Kagi.
1991.
Thionein (apometallothionein) can modulate DNA binding and transcription by zinc finger containing factor Sp1.
FEBS Lett.
279:310-312[Medline].
|
| 51.
|
Zeng, J.,
B. Vallee, and J. H. R. Kagi.
1991.
Zinc transfer from transcription factor IIIA fingers to thionein clusters.
Proc. Natl. Acad. Sci. USA
88:9984-9988[Abstract/Free Full Text].
|
| 52.
|
Zhao, H., and D. J. Eide.
1997.
Zap1p, a metalloregulatory protein involved in zinc-responsive transcriptional regulation in Saccharomyces cerevisiae.
Mol. Cell. Biol.
17:5044-5052[Abstract].
|
| 53.
|
Zhou, P., and D. J. Thiele.
1993.
Copper and gene regulation in yeast.
BioFactors
4:105-115[Medline].
|
| 54.
|
Zhou, P., and D. J. Thiele.
1993.
Rapid transcriptional autoregulation of a yeast metalloregulatory factor is essential for high-level copper detoxification.
Genes Dev.
7:1824-1835[Abstract/Free Full Text].
|
| 55.
|
Zhou, P., and D. J. Thiele.
1991.
Isolation of a metal-activated transcription factor gene from Candida glabrata by complementation in Saccharomyces cerevisiae.
Proc. Natl. Acad. Sci. USA
88:6112-6116[Abstract/Free Full Text].
|
| 56.
|
Zhu, Z.,
S. Labbé,
M. M. O. Peña, and D. J. Thiele.
1998.
Copper differentially regulates the activity and degradation of yeast Mac1 transcription factor.
J. Biol. Chem.
273:1277-1288[Abstract/Free Full Text].
|
| 57.
|
Zhu, Z., and D. J. Thiele.
1996.
A specialized nucleosome modulates transcription factor access to a C. glabrata metal responsive promoter.
Cell
87:459-470[Medline].
|
Mol Cell Biol, May 1998, p. 2514-2523, Vol. 18, No. 5
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Abstract
Introduction
