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Molecular and Cellular Biology, March 2001, p. 1688-1699, Vol. 21, No. 5
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.5.1688-1699.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Ambient pH Signaling Regulates Nuclear Localization
of the Aspergillus nidulans PacC Transcription
Factor
José M.
Mingot,
Eduardo A.
Espeso,
Eliecer
Díez, and
Miguel
Á.
Peñalva*
Centro de Investigaciones Biológicas
CSIC, Madrid 28006, Spain
Received 10 August 2000/Returned for modification 11 October
2000/Accepted 7 December 2000
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ABSTRACT |
The Aspergillus nidulans zinc finger transcription
factor PacC is activated by proteolytic processing in response to
ambient alkaline pH. The pH-regulated step is the transition of
full-length PacC from a closed to an open, protease-accessible
conformation. Here we show that in the absence of ambient pH signaling,
the C-terminal negative-acting domain prevents the nuclear localization of full-length closed PacC. In contrast, the processed PacC form is
almost exclusively nuclear at any ambient pH. In the presence of
ambient pH signaling, the fraction of PacC that is in the open conformation but has not yet been processed localizes to the nucleus. Therefore, ambient alkaline pH leads to an increase in nuclear PacC by
promoting the proteolytic elimination of the negative-acting domain to
yield the processed form and by increasing the proportion of
full-length protein that is in the open conformation. These findings
explain why mutations resulting in commitment of PacC to processing
irrespective of ambient pH lead to permanent PacC activation and
alkalinity mimicry. A nuclear import signal that targets
Escherichia coli 
-galactosidase to the nucleus has
been located to the PacC zinc finger region. A mutation abolishing DNA
binding does not prevent nuclear localization of the processed form,
showing that PacC processing does not lead to nuclear localization by
passive diffusion of the protein made possible by the reduction in
size, followed by retention in the nucleus after DNA binding.
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INTRODUCTION |
Proteolytic processing activation of
transcription factors in response to their cognate environmental
signals occurs across distant groups of eukaryotic organisms. pH
regulation of gene expression in the mold Aspergillus
nidulans is one such example. Here, the key regulatory zinc finger
protein PacC activates alkaline genes and represses acidic genes
according to the needs imposed by ambient pH, thereby providing the
organism with one prerequisite for growing in environments as acidic as
pH 2.5 or as alkaline as pH 10.5 (7, 59). Other
prototypical members of the group of transcription factors activated by
proteolytic processing are the immune and inflammatory response
regulator NF-
B (23, 58), the Drosophila
melanogaster cubitus interruptus (Ci) zinc finger factor (the
transducer of the hedgehog signal) (29, 53), and the
sterol regulatory element-binding protein (SREBP), which switches on
genes for cholesterol biosynthesis and fat metabolism (5, 6).
The zinc finger transcription factor PacC is synthesized as a
674-residue precursor. At alkaline ambient pH, a signal transmitted to
PacC by the orphan pal gene signal transduction pathway
(13, 14, 37, 43, 44) results in a conformational change
leading to an open conformation in which PacC is accessible to a
processing protease (18, 41, 47). This protease removes
~400 residues from the C terminus, which includes a negative-acting
domain. The resulting product (248 to 250 residues) (41)
is fully competent in transcriptional regulation through
5'-GCCARG-3' sites (20) in the promoters of
both alkaline (activated by PacC) (17) and acidic
(repressed by PacC) (16) genes.
Prototypical NF-B is a heterodimer of p50 and p65 (RelA) subunits.
p50 originates from proteolytic processing of a p105 precursor. As in
PacC, a C-terminal moiety in p105 is a cis- and
negative-acting domain in the p105/p65 heterodimer. This negative
function can be also provided in trans by members of the
IB family of inhibitory proteins, which are homologues of the p105
C-terminal moiety and form heterotrimeric complexes with p50 and p65.
Both the C-terminal moiety of p105 (4, 25, 51) and the
IB proteins (3, 28, 30, 65, 66) preclude the nuclear
localization of NF-B and its binding to DNA. In cubitus
interruptus (2) and SREBP (5, 6, 54),
the presence of negative-acting domains C terminal to the mature
polypeptide also precludes nuclear localization. The fact that in all
cases in which the role of the negative-acting domains removable by
proteolysis has been investigated such domains preclude nuclear
localization underlines the regulatory possibilities offered by the
separation into distinct nuclear and cytoplasmic compartments that
characterizes eukaryotic cells.
Because translation takes place in the cytoplasm, transcription factors
need to be imported into and may also be exported from the nucleus. All
passive and active transport into and out of the nucleus occurs through
the nuclear pore complexes (NPCs) in the nuclear envelope, which
provide a diffusion channel for macromolecules smaller than ~40 to 60 kDa (45). However, transport of macromolecules through the
NPCs is generally energy dependent and requires components of the Ran
GTPase system as well as transport (both import and export) receptors
and adapter molecules recognizing nuclear localization signals and
nuclear export signals in their cargoes (see references 24 and
42 for reviews). The fact that such signals as well as domains
involved in their intramolecular masking may be cleaved off after
appropriate signaling opens new regulatory possibilities in this
category of transcription factors.
We use the genetically amenable system of pH regulation in A. nidulans to understand the mechanisms underlying the regulation of
gene expression through transcription factor proteolytic processing. Briefly, two different conformations ("open" and "closed") of the precursor form and the processed protein participate in pH regulation (18, 41, 47). By preventing the closed-to-open conformation transition (18), mutational inactivation of
any of the six palA, -B, -C, -F, -H, and -I genes
of the ambient pH signaling pathway prevents proteolytic processing
activation (47) and leads to the absence of
pacC function (59) and acidity mimicry (1, 7). pacC mutations such as
pacC+/-20205, leading to an
inability to undergo the conformational change at any ambient pH,
result in permanently closed PacC and thereby prevent proteolytic
processing and, similarly to pal
mutations, lead to a loss-of-function
(pacC+/-) acidity mimicry phenotype
(18, 41). Finally, by disrupting interactions between a
C-terminal domain of PacC and upstream regions that maintain the closed
conformation (18), another class of mutations
(pacCc) results in commitment of PacC to
the open conformation, consequent processing at any ambient pH
(41, 47), and an alkalinity mimicry, gain-of-function
phenotype (59). This pacCc class
includes missense mutations affecting PacC residues critical for the
interactions described above and C-terminal truncation mutations.
Here we address the role of the C-terminal, negative-acting domain of
PacC and demonstrate that, by governing the proteolytic removal of this
domain, the ambient pH signal regulates the subcellular localization of
PacC, which is largely cytoplasmic under acidic conditions. In
contrast, an almost exclusive nuclear localization is seen under
alkaline conditions, and this correlates with proteolytic processing. A
fraction of the full-length form, probably in the open conformation, is
able to enter into the nucleus.
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MATERIALS AND METHODS |
Aspergillus techniques and media.
A.
nidulans strains carrying markers in standard use and standard
genetic procedures were used (10). Media and phenotype testing for pH regulatory mutations have been described previously (1, 7). Complex PPB broth (41) with 3%
(wt/vol) sucrose as a carbon source was used for A. nidulans
liquid cultures. This broth was adjusted to an acidic, neutral, or
alkaline pH according to reference 47. For strains
carrying alcAp-driven transgenes, mycelia
were pregrown for 14 to 18 h in acidic PPB medium containing 3%
glucose as a carbon source (repressing conditions) and transferred to
fresh medium adjusted to different pH values and containing 0.05%
glucose and 100 mM threonine (inducing conditions). Mycelia were
incubated for a further 8 h before being used for protein
extraction, subcellular fractionation, and/or microscopic observation.
Alternatively, conidiospores were germinated for 14 h at 37°C in
minimal or PPB medium containing 0.05% (wt/vol) glucose and 100 mM
threonine, adjusted to different pH values as in reference
47.
Subcellular fractionation procedure and protein extraction.
For subcellular fractionation and protein extraction, we used a
modification of a published procedure (63). Washed mycelia were resuspended in buffer LYS, which contained 50 mM Tris-HCl (pH
7.5), 5 mM magnesium acetate, 5 mM EGTA, 3 mM
CaCl2, 3 mM dithiothreitol (DTT), 1 mM
phenylmethylsulfonyl fluoride (PMSF), 2 µM pepstatin, 1 M sorbitol,
7% (wt/vol) Ficoll 400, and 20% glycerol, and lysed with glass beads
in a Braun MSK cell disrupter. The lysate was gently mixed in the cold
with 2 volumes of buffer CUS (25 mM Tris-HCl [pH 7.5], 5 mM magnesium
acetate, 5 mM EGTA, 1 mM DTT, 0.25 mM PMSF, 10% glycerol), laid on top
of a 1:1.7 mixture of buffers LYS and CUS, and centrifuged for 7 min at
4,000 rpm in a Sorvall HB4 rotor. The lower phase, containing cell
debris, was discarded. The upper phase was loaded on top of a buffer
NUC cushion (buffer NUC is 25 mM Tris-HCl [pH 7.5], 1 M sucrose, 5 mM
magnesium acetate, 5 mM EGTA, and 10% glycerol) and centrifuged for 15 min at 7,000 rpm in an HB4 rotor. This step resulted in a nuclear
pellet with a microsomal fraction sedimenting in the interphase and a
cytoplasmic fraction in the upper phase. The nuclear pellet was
resuspended in buffer A (25 mM HEPES [pH 7.9], 5 mM
MgCl2, 0.1 mM EDTA, 20% glycerol, 1 mM PMSF, 1 µM pepstatin, 0.6 µM leupeptin) with 50 mM KCl, and nuclear protein
was extracted with 0.4 M ammonium sulfate. After removal of DNA and
debris by centrifugation at 100,000 × g, the cleared
nuclear extract was dialyzed against buffer A containing 100 mM KCl.
The upper (cytoplasmic) phase was extracted with 0.4 M ammonium sulfate
as described above, concentrated by ammonium sulfate precipitation, and
desalted through a PD-10 column equilibrated with buffer A containing
100 mM KCl. Mycelial (total) protein extracts were prepared as
described previously (47). Protein fractions were stored
at 
80°C. The presence of nuclei exclusively in the nuclear fraction
and their absence from the cytosolic fraction were confirmed by DAPI
(4',6'-diamidino-2-phenylindole) staining.
Plasmids and recombinant strains.
Plasmid pAN 52-1 sGFP
(48) (obtained from C. Scazzocchio) contains the coding
region of sGFP-TYG (9), previously used to track the
subcellular localization of transcription factors in A. nidulans (21, 48). pALC-argB(BglII) was
used for the expression of green flourescent protein (GFP) and
lacZ fusion proteins under
alcAp control. This plasmid
(41) contains a frameshift
argB allele that we used to target all of
the transforming constructs to the argB2 mutant allele of
the recipient strains, which prevented possible position effects on the
expression of the transgenes. The recombinant plasmids derived from
pALC-argB(BglII) are detailed in Table
1. These were constructed by standard
recombinant techniques or by PCR and were transformed (60)
into 
pacC argB2 and pacC palA1 argB2 strains (41), as appropriate. The correct
in-frame joining of the fragments and the absence of introduced
mutations in PCR-amplified fragments were verified by automatic DNA
sequencing. The correct integration of the transforming plasmid in the
argB locus was verified by Southern analysis. All
recombinant strains carried single-copy integration events, with the
exception of p[alcAp::PacC(241-280)::GFP]-
and
p[alcAp::PacC(5-250)Q155K::GFP]-transformed
strains, for which double integration events were the lowest copy
number recovered. For experiments involving the latter transgene, a
control transformant carrying a double-integration event of the
wild-type
p[alcAp::PacC(5-250)::GFP]
construct was used. The subcellular localization of the encoded fusion
protein in this double-copy transformant was indistinguishable from
that of its corresponding single-copy transformant. Growth tests under
inducing and repressing conditions were used to confirm that the
phenotype exclusively resulted from expression of the transgene.
EMSA and Western blot analysis.
Total, cytoplasmic, and
nuclear extracts were analyzed by Western blotting and electrophoretic
mobility shift assay (EMSA) as described previously (41).
Rat anti-PacC DNA binding domain antiserum (used at 1/4,000) was
directed against PacC(5-265) (41). Rabbit anti-PacC
C-terminal region antiserum (used at 1/2,000) was directed against
residues 529 through 678. Rabbit anti-GFP antiserum (used at 1/3,000)
was obtained from Clontech. Rabbit anti-yeast hexokinase antiserum
(used at 1/20,000) was obtained from Chemicom and recognizes a protein
with the expected electrophoretic mobility of A. nidulans
hexokinase. In these cases, peroxidase-coupled goat anti-rabbit (Sigma)
antiserum was used as a secondary antibody.
Microscopy.
Mycelial samples taken at appropriate times
after induction of transgenes were washed three times in water, and the
subcellular distribution of green fluorescence was observed under a
Zeiss epifluorescence microscope with 495- and 530-nm excitation and emission filters, respectively. Images were collected with an IPLab
Spectrum system and transferred to Adobe Photoshop, version 4.0. Samples stained with DAPI (0.1 µg/ml) were fixed with formaldehyde and washed in phosphate-buffered saline before microscopy.
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RESULTS |
Interactions between the C-terminal region and upstream regions in
the full-length PacC form do not prevent binding to DNA.
In
agreement with previous work with A. nidulans (41,
47), extracts of yeast strains expressing either PacC(5-678) or PacC(5-265) proteins (the latter approximating the processed form) contained similar levels of these proteins, as monitored by Western analysis, and similar levels of PacC DNA binding activity, as determined by the amounts of their respective DNA-protein complexes in
EMSA (data not shown), which confirms that the negative action of the
C-terminal region in the full-length form does not result from
prevention of DNA binding. Proteins expressed in yeast were used in
this experiment so that the full-length form would not be processed
(41).
The processed PacC form is localized in the nucleus.
A
plausible explanation for the negative action of the C-terminal region
in PacC would be that its presence or absence affects the PacC
nucleocytoplasmic distribution. To address this possibility, we used a
subcellular fractionation procedure to prepare nuclear and cytoplasmic
fractions of A. nidulans in different mutants and in the
wild type and examined the distribution of full-length and processed
PacC by Western blot analysis (using antiserum against the nearly
N-terminal zinc finger region) and by a sensitive EMSA (Fig.
1). Western analysis of the glycolytic,
cytosolic enzyme hexokinase was used to confirm that the nuclear
fractions were largely free of cytoplasmic contamination (Fig. 1).
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FIG. 1.
Subcellular PacC localization in wild-type and mutant
strains in pH regulation. Protein extracts from the nuclear (N) or
cytoplasmic (C) fractions or the total cell (T) (see Materials and
Methods) of the indicated strains were analyzed by EMSA with a
PacC-specific DNA probe (A) or by Western blotting (B) with antisera
against the PacC DNA binding domain. Strains were grown on sucrose-MFA
for 24 h at 37°C under acidic pH conditions. (A) Five micrograms
of each extract was incubated with the DNA probe. FL indicates the
protein-DNA complex corresponding to the PacC primary translation
product, and P denotes the complex corresponding to the processed PacC
form. A longer exposure of the region of the gel including the complex
corresponding to the truncated (after residue 492)
pacCc14 primary
translation product (FL') is shown on the right. (B) Fifty micrograms
of each protein extract was analyzed by Western blotting, both with an
anti-PacC ( -PacC) antiserum and with an antihexokinase (-HXK)
antiserum, as indicated.
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In a wild-type strain grown under acidic conditions, proteolytic
activation of PacC is largely prevented, and the full-length
form
predominates over the processed form (
47) (Fig.
1A and
B,
lanes 3). This processed form is largely enriched in the nuclear
fraction and is virtually undetectable in the cytosol (Fig.
1A
and B,
lanes 1 and 2). Under acidic conditions, the alkalinity-mimicking
pacCc14 mutation results in
predominance of the processed PacC form
that cofractionates with the
nuclear fraction (Fig.
1A and B,
lanes 4 to 6). A similar result was
obtained for the
pacCc50
product (data not shown). The alkalinity-mimicking
pacCc50 mutation truncates PacC
only ~13 residues downstream of the
deduced processing limit. Taken
together, these data strongly
suggest that the processed PacC form is
predominantly nuclear,
which agrees with its function as a
transcription factor. Second,
they indicate that the pH signal (whose
requirement for processing
is bypassed by the alkalinity-mimicking
pacCc mutation) leads to nuclear PacC
localization at least in part
by promoting PacC proteolytic
processing.
To confirm the nuclear localization of the processed PacC form in vivo,
we constructed a transgene encoding a PacC(5-250)
protein
(approximating the processed form) tagged with GFP in
its N terminus
(Table
1 and Fig.
2) under the control
of the
threonine-inducible
alcA promoter. This
GFP::PacC(5-250) construct
and a control construct
driving expression of GFP (without PacC
sequences) were transformed
into a null
pacC background in either
the
presence or the absence (inactivated by the
palA1 mutation)
of a functional
pal gene pathway. To avoid position effects,
these
and all other further constructs were targeted in single or
double
copy to the
argB locus. The null, strongly
acidity-mimicking
pacC allele leads to poor
conidiation and lack of growth at alkaline
pH (
59).
Expression of GFP::PacC(5-250) restored both conidiation
and
the ability to grow at alkaline pH in both the
pacC and the
pacC
palA1 backgrounds (data not shown), indicating that the
N-terminal
GFP tag in this processed PacC does not impair its
function. In a
control strain expressing GFP without PacC sequences,
fluorescence was
found throughout the hyphae (Fig.
3A and
C).
In contrast, in strains expressing the GFP::PacC(5-250) fusion
protein cultured at different pH values, the fluorescence localized
in
the nuclei, regardless of whether the transfer pH was acidic
or
alkaline or the functional status of the
pal pathway (Fig.
3B). Western blotting and EMSA showed that GFP::PacC(5-250)
was
largely intact under all conditions tested (Fig.
4A and B, right
panels). These results
agree with those of the subcellular fractionation
experiments presented
above and demonstrate the preferential and
ambient pH
signal-independent nuclear localization of the processed
PacC form in
vivo.
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FIG. 2.
Schematic representation of PacC derivatives used in
this work as GFP fusion proteins. All fusion proteins were expressed by
using the alcohol dehydrogenase I promoter, which is inducible by
threonine. The full-length PacC protein (residues 5 to 678; codon 5 is
the major translation start codon) is illustrated as an open rectangle,
with the zinc finger region shown in black. The approximate position of
the processing site in full-length PacC fusion proteins is shown by a
dashed line and indicated by an arrow. The fusion proteins are denoted
here and throughout the text according to the N-terminal or C-terminal
position of GFP and the amino acid coordinates of the corresponding
PacC polypeptide.
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FIG. 3.
Changes in the subcellular localization in vivo of
GFP-tagged full-length and processed PacC forms in response to ambient
pH changes. Strains were pregrown under acidic, repressing conditions
for alcAp and transferred to inducing
conditions for 8 h, in media buffered at the indicated pH values.
Typical final values were 5.8 (acidic pH), 6.8 (neutral pH), and 7.6 (alkaline pH). (A) Control experiment showing the uniform distribution
of GFP across the hyphae (left) compared to the position of nuclei
(right, by DAPI staining). Only acidic conditions are shown. This
uniform distribution does not change upon transfer to neutral pH (see
panel C). Note that this (null pacC) strain does not
grow under alkaline conditions. (B) Subcellular localization of
GFP::PacC(5-250) in palA+ and
palA1 backgrounds. (C) Subcellular localization of
GFP::PacC(5-678) under acidic, neutral, and alkaline
conditions, in the palA+ and
palA1 backgrounds. The palA1 mutation
precludes growth of this strain under alkaline conditions. In panels B
and C, the original magnifications were ×400 and ×1,000, as
indicated.
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FIG. 4.
Analysis of GFP::PacC(5-250) and
GFP::PacC(5-678) fusion proteins in transgenic
(pacC) strains. Samples of cultures used in the
experiments shown in Fig. 2 were collected and used to prepare
whole-cell protein extracts. (A) Western analyses of whole-cell
extracts (50 µg of protein in each lane) with antisera against the
PacC DNA binding domain (-PacC) or against GFP (-GFP). pH growth
conditions are indicated on top of each lane, as is the
palA+ or palA1 genotype of
the corresponding strains. Wild-type control extracts from acidic and
alkaline growth conditions are indicated with
pacC+. Full-length (FP) and processed (P)
PacC are revealed only by the anti-PacC antiserum. The full-length and
processed forms of GFP::PacC(5-678), revealed with both the
anti-PacC and the anti-GFP antisera, are indicated by solid and open
arrows, respectively. An asterisk indicates the position of GFP in the
lanes of the corresponding control strain. (B) EMSA analyses of the
above extracts with 5 µg of protein and a specific PacC DNA probe.
Extracts are as in panel A. Protein-DNA complexes formed by wild-type
full-length and processed forms of PacC are indicated, as are the
positions of complexes formed by the full-length (thin arrow) and
processed (diamond) forms of GFP::PacC(5-678).
Note the shift in mobility caused by the GFP tag in these
complexes compared to those of untagged PacC.
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The full-length form is normally distributed between nuclei and
cytosol, but is largely cytosolic in the absence of the
pal signal.
In contrast to the preferential nuclear
localization of the processed form, the full-length form that
predominates in the wild type grown under acidic conditions was found
in both the nuclear and the cytosolic fractions (Fig. 1A and B, lanes 1 to 3). The acidity-mimicking palA1 mutation, which
interrupted the pH signaling pathway and prevented proteolytic
processing, resulted in the almost exclusively cytosolic localization
of the full-length form (Fig. 1A and B, lanes 7 to 9). That this effect
is not specific to palA alleles was confirmed
by a subcellular fractionation experiment with a palH17
strain, which gave essentially the same results (data not shown). These
data showed that in the presence of a functional pal
pathway, the full-length PacC form distributes between nuclei and
cytosol, but in its absence, this full-length form is predominantly
cytosolic. In addition, this indicates that the full-length protein is
able to enter the nucleus and that a certain degree of ambient pH
signaling (which under the moderately acidic growth conditions used
here takes place in the wild type, but not in the palA1
strain) is required for the nuclear localization of a proportion of the
full-length form.
To confirm that a proportion of the full-length form is able to enter
the nucleus, we used two fusion proteins in which a
GFP tag was
attached to the C-terminal residue of PacC. One protein,
denoted
PacC(5-678)::GFP, corresponds to the full-length PacC
protein (Fig.
2 and Table
1). A second, denoted
PacC(250-678)::GFP,
corresponds to the region of PacC that
is removed by proteolytic
processing (Fig.
2 and Table
1).
PacC(5-678)::GFP can be proteolytically
processed (data not
shown). Under acidic conditions, the (GFP-tagged)
full-length fusion
protein predominates, but some processing occurs
(data not shown). The
resulting processed PacC form is released
from the C-terminal moiety of
PacC tagged with GFP after residue
678 and therefore is not fluorescent
(see the scheme in Fig.
2).
Therefore, nuclear green fluorescence would
indicate the nuclear
localization either of a proportion of the
full-length PacC form
or of the hypothetical C-terminal polypeptide
that would be released
after processing. Figure
5A shows that in a strain expressing
PacC(5-678)::GFP grown under acidic conditions, fluorescent
nuclei
were clearly observed over the cytosolic background. This
contrasted
with strains either expressing GFP alone (Fig.
3A and C and
Fig.
5A) or expressing a PacC(250-678)::GFP fusion protein
containing
the C-terminal moiety (Fig.
5B and C), in which fluorescence
was
similar throughout the cells. In control strains expressing
PacC(5-273)::GFP
or PacC(5-250)::GFP (Fig.
2),
fluorescence colocalized with nuclei
(Fig.
5A and B). Taken together,
all of the results presented
above strongly indicate that at least part
of the full-length
form is able to get into the nucleus. No indication
of nuclear
exclusion of the PacC(250-678)::GFP polypeptide,
which might have
suggested the presence of a nuclear export signal in
PacC residues
250 through 678, was observed.
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FIG. 5.
Nuclear fluorescence in a strain expressing
PacC(5-678)::GFP. (A) pacC strains
expressing GFP, PacC(5-678)::GFP, or
PacC(5-273)::GFP proteins from single-copy
alcAp-driven transgenes were pregrown
for 18 to 20 h under repressing conditions for
alcAp and transferred to inducing
medium for an additional 7-h incubation at acidic ambient pH, before
their green fluorescence was observed under the microscope. (B) Strains
expressing PacC(5-250)::GFP (i.e., the GFP-tagged processed
PacC form) or PacC(250-678)::GFP (i.e., the GFP-tagged
C-terminal moiety removed by processing) were grown at acidic ambient
pH under inducing conditions, fixed with formaldehyde, and stained with
DAPI. The green fluorescence (GF) and the DAPI channels are shown. (C)
The PacC(250-678)::GFP protein is expressed at high levels
under the conditions used in panel B. Western analysis was of a protein
extract (50 µg) from the following strains (only the relevant portion
of the gel is shown). Lanes: 1, PacC(5-250)::GFP strain; 2, PacC(250-678)::GFP strain, 3, GFP strain; 4, a
pacC+ strain. The blot was developed with an
antiserum raised against the C-terminal region (amino acids 529 through
678) of PacC. The weak cross-reacting band in lanes 1 and 3 is an
unspecific band. The band in lane 4 corresponds to full-length PacC.
The prominent protein band in lane 2 corresponds to
PacC(250-678)::GFP.
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In the absence of the pal signal, the region of PacC
removed by proteolytic processing prevents the nuclear localization of
the full-length form in vivo.
To analyze in vivo the changes in
the subcellular localization of PacC under different ambient
conditions, we constructed palA+ and
palA1 strains showing expression under the control of
alcAp a GFP::PacC(5-678) fusion
protein (Table 1 and Fig. 2) in a null pacC
background. In this fusion protein, GFP is attached to the N terminus
of full-length PacC, because this relative arrangement guarantees that
the fluorescent tag is not removed by proteolytic processing, which
eliminates the PacC C terminus. The phenotype of these strains is
indistinguishable from those of the corresponding strains expressing
untagged PacC(5-678) with regard to alkaline pH growth and hypostasis
of the introduced transgene to the palA1 mutation,
indicating that the function of these proteins is under ambient pH
control and that the presence of the GFP tag in the N terminus of PacC
does not preclude its function.
Under acidic conditions, the subcellular distribution of
GFP::PacC(5-678) largely resembled that of GFP (Fig.
3A and
C). In
contrast to the GFP strain, however, weak fluorescence
highlighting
the nuclei was reproducibly observed (Fig.
3C). Transfer
to either
neutral or alkaline conditions dramatically changed this
distribution
and unequivocally resulted in preferential nuclear
localization
(Fig.
3C). This dramatic change correlated with
proteolytic processing
of the GFP::PacC(5-678)
primary translation product (Fig.
4A and
B, left panels). The
palA1 mutation largely prevented this proteolytic
processing
(Fig.
4A and B, left panels), eliminated the exclusively
nuclear
fluorescence seen under neutral conditions [Fig.
3C; note
that the
alcAp-GFP::PacC(5-678)
allele is hypostatic to
palA1 and the double
mutant strain
cannot be grown under alkaline conditions], and
made the residual
nuclear staining seen under acidic conditions
less evident (Fig.
3C).
These data show that the processing pattern
and the subcellular
distribution of PacC forms determined by in
vitro fractionation studies
or by in vivo GFP tagging are coincident.
A conclusion of the above
experiments is that in the absence of
the
pal signal, the
region of PacC removed by proteolytic processing
prevents nuclear
localization of full-length PacC and that the
processed PacC product
[here, GFP::PacC(5-250)] is almost exclusively
nuclear.
The processed PacC form contains a nuclear import signal.
The
deduced Mr for
GFP::PacC(5-250) is 53.8 kDa. The
Mr estimated for this protein by gel
filtration chromatography of extracts was 101 kDa (Fig.
6A), which might result from either
dimerization or a particularly elongated shape of the fusion protein.
In any case, this size is above the limit below which proteins can
freely move between cytosolic and nuclear compartments and would
suggest that an active transport mechanism is active on the processed PacC form. To address this point, we constructed two
alcAp-driven genes encoding fusion
proteins between PacC polypeptides and the Escherichia coli
lacZ gene product. One encodes a
PacC(5-234)::lacZ polypeptide with a predicted
Mr of 140 kDa. PacC residues 5 through 234 contain the zinc finger region and lack all major and minor processing sites (E. Díez and M. A. Peñalva,
unpublished data). This transgene complements several aspects of the
pacC phenotype, strongly indicating that the
fusion protein is able to enter the nucleus. Subcellular fractionation
experiments confirmed that PacC(5-234)::lacZ is
indeed nuclear (Fig. 6B). In contrast, a PacC(169-234)::lacZ fusion protein (deduced
Mr of 123 kDa) showed cytosolic
localization (Fig. 6B). In vivo localization experiments with
equivalent GFP fusion proteins (data not shown) confirmed the
subcellular fractionation results. We conclude that PacC residues 5 through 234 contain a nuclear import signal.
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FIG. 6.
The processed PacC form contains a nuclear import
signal. (A) Protein extracts isolated from a strain expressing
GFP::PacC(5-250) were fractionated through a
Sephacryl S-200 column, calibrated with protein standards of the
indicated Mr. The fusion protein was
detected by EMSA, and protein-DNA complexes were quantified by
phosphorimaging. wt, wild type; IP, input extract. (B) Subcellular
fractionation experiments of mycelia from strains expressing the
indicated PacC::lacZ fusion proteins.
Nuclear (N), cytosolic (C), and total (T) protein extracts were
analyzed by Western blotting with the indicated antibodies. PacC
residues 169 through 234 are recognized by the anti-PacC DNA binding
domain (DBD) antiserum, which was raised against a polypeptide
containing residues 5 through 265.
|
|
The zinc finger region of PacC contains a nuclear localization
signal whose action is independent of DNA binding.
The nuclear
import region of PacC(5-250) was delimited by deletion analysis of GFP
fusion proteins to residues 66 through 173 (Fig.
7). PacC residues 69 through 168 correspond to the zinc finger region and suffice for high-affinity DNA
binding (20). To separate DNA binding from nuclear
localization, we used a Gln 155
Lys substitution affecting a critical
residue in the recognition -helix of the third zinc finger that
abolishes DNA binding in vitro and leads to a loss-of-function
phenotype (20). In common with its parental
PacC(5-250)::GFP fusion protein, a mutant
PacC(5-250)Q155K::GFP fusion protein
localized to the nuclei (Fig. 8A) despite the lack of DNA binding activity shown in vitro by the mutant fusion
protein (Fig. 8B and C). This dissociation of DNA binding from nuclear
localization based on the phenotype of the Gln 155Lys substitution
agrees with the above conclusion that the processed PacC form
(approximately containing residues 5 through 250) contains a nuclear
import signal, because it rules out the possibility that its nuclear
localization could result from passive diffusion and nuclear retention
by DNA binding
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FIG. 7.
Delimiting a nuclear localization signal to the zinc
finger region. Strains expressing the indicated GFP fusion proteins
were grown under inducing, acidic ambient pH conditions and examined by
epifluorescence microscopy.
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|
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FIG. 8.
A single amino acid substitution abolishing DNA binding
does not prevent the nuclear localization of the processed PacC form.
Strains expressing the wild type (WT) or a mutant Q155K
PacC(5-250)::GFP fusion protein were grown under
inducing (also acidic) conditions for 14 h at 37°C and used for
epifluorescence microscopy and protein extraction. (A) Samples of the
indicated strains were fixed with formaldehyde, stained with DAPI, and
analyzed under the microscope in the green fluorescence (GF) and DAPI
channels. (B) Protein extracts were analyzed by Western blotting with
an antiserum against PacC residues 5 through 265 (-PacC DBD). (C)
Protein extracts (5 or 18 µg, as indicated below the corresponding
lanes) were analyzed by EMSA with a PacC-specific probe. The relevant
region of the autoradiogram containing the wild-type PacC fusion
protein-DNA complex is shown. No binding was detected with the mutant
protein carrying the Gln 155Lys substitution, in agreement with
previous work (20).
|
|
Nuclear full-length PacC is in the open conformation.
In the
presence of the pal signal, a fraction of full-length PacC
is localized in the nucleus. This full-length form alternates between
two conformations, and the ambient pH signal is required for the
closed-to-open conformation transition (18). By removing the interacting C-terminal region of PacC, the truncation mutation in
the pacCc14 primary translation
product PacC(5-492) results in commitment to the open
(protease-accessible) conformation at any ambient pH, leading to
proteolytic processing, which results in low levels of the mutant
primary translation product (Fig. 1) and bypasses the requirement for
the ambient pH signal (18). If the transition to the open
conformation were required for the nuclear localization of the
full-length form, the pacCc14
primary translation product should be localized in the nucleus. Overexposure of the autorad region corresponding to the
pacCc14 full-length product-DNA
complex showed that this is indeed the case (Fig. 1A, lanes 4 to 6). In
contrast to the pacCc14
product, the pacC+/-20205
product is a prototypic mutant PacC shifted towards the closed
conformation. Subcellular fractionation analysis showed that, under
neutral growth conditions (in which significant pH signaling
occurs) (Fig. 3C), the predominant mutant full-length product
is largely excluded from the nuclei (Fig.
9). These data correlate the transition
of the PacC primary translation product towards the open conformation
with the nuclear localization of a part of the primary translation
product.
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FIG. 9.
Subcellular localization of PacC forms in a
pacC+/-20205 mutant strain.
Cytoplasmic (C), nuclear (N), and whole-cell (T) protein fractions were
prepared from a pacC+/-20205
strain grown under neutral conditions and analyzed by EMSA or Western
blotting, as in Fig. 1. Solid and open arrows indicate the full-length
and the processed PacC forms, respectively. The slight increase in
mobility of the mutant full-length form complex compared to that of the
wild type results from substitution of residues 465 through 540 in PacC
by an octapeptide encoded in a different reading frame
(41). The pacC+ extract used as
a size control corresponds to acidic conditions, to maximize levels of
the full-length form.
|
|
In the open conformation of full-length PacC, two regions between
residues 169 and 410 are available for interactions with
polypeptides
containing the C-terminal residues 529 through 678
(
18).
This interaction can be monitored by the resulting supershift
of the
full-length PacC-DNA complex in EMSA (
18) (Fig.
10). In
the closed conformation, these
regions are not available for interaction.
This different behavior
provides a test for distinguishing between
the two conformational
forms. We used longer electrophoretic runs
to resolve, under alkaline
pH conditions, a faster complex corresponding
to closed PacC protein
unavailable for interactions from a slower
complex corresponding to
open PacC protein, which is fully supershifted
by a purified
GST::PacC(410-678) polypeptide (Fig.
10, lanes 1
and 2).
This assay unambiguously showed that the full-length protein
present in
the nuclear fraction is in the open conformation (Fig.
10, lanes 5 and
6).
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FIG. 10.
Full-length PacC in the open conformation localizes in
the nuclear fraction. Five micrograms of protein from a whole-cell
extract (T) and a cytosolic fraction (C) obtained from wild-type cells
grown under alkaline conditions and 1.8 µg of the corresponding
nuclear extract were analyzed by EMSA. Two micrograms of purified
GST::PacC(410-678) was included in the indicated binding
mixtures. The open and solid arrows indicate the position of the open
and closed full-length PacC-DNA complexes, respectively. The most
prominent band corresponds to the protein-DNA complex of the
predominant processed form.
|
|
| |
DISCUSSION |
We show here that environmental pH regulates the subcellular
localization of the zinc finger transcription factor PacC. In the
absence of an ambient alkaline pH signal (for example, in a strain
lacking a functional pal pathway), proteolytic processing is
prevented and PacC is localized in the cytoplasm. Reception of the
ambient pH signal disrupts interactions involving the C-terminal region
of PacC and upstream regions and leads to an open (protease accessible)
conformation and proteolytic processing (18). The processed PacC form is exclusively found in the nucleus (see the model
in Fig. 11).
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FIG. 11.
A model for PacC subcellular trafficking in response to
ambient pH. Newly synthesized PacC adopts a protease-inaccessible,
closed conformation, which is unable to enter into the nucleus. When
the growth environment is alkaline, a signal is transmitted by the
pal gene pathway. Reception of this signal by PacC
switches the protein to an open conformation, in which PacC is
accessible to proteolytic processing. We favor a model in which
processing takes place exclusively in the cytosolic compartment (see
text). The processed protein would be transported into the nucleus,
where it activates expression of alkaline genes and represses that of
acidic genes. A fraction of full-length PacC, most likely representing
protein in the open conformation which escapes processing, is able to
enter the nucleus. Because definitive evidence for the cytosolic
localization of PacC processing is lacking, the possibility of nuclear
processing is indicated by a question mark. However, we note that quick
transfer into the nucleus of unprocessed polypeptides in the open
conformation would protect them from processing if this were
exclusively cytosolic, which would explain why, even with the most
extreme C-terminally truncating pacCc
alleles under alkaline growth conditions, a fraction of the full-length
product appears unprocessed.
|
|
In the presence of pH signaling, a proportion of the full-length PacC
form is also localized in the nucleus. Our data strongly suggest that
the full-length PacC showing nuclear localization corresponds to
protein that is the open conformation, but has not yet been processed
(Fig. 11). The nuclear localization of a proportion of the full-length
form might have implications for our current view of pH regulation
because, contrary to our initial molecular model (47), a
proportion of the full-length PacC form might be physiologically
relevant, since the presence of the C terminus does not preclude DNA binding.
Several possible examples of regulated nuclear transport
(26) have been described in transcription factors
regulated by proteolytic processing. In all cases, removal of the
negative-acting domain in the transcription factor results in nuclear
localization of the product. In SREBP, processing releases the
transcription factor domain from an endoplasmic reticulum
membrane-anchoring domain (5, 6). In cytosolic NF-B
p105/p65 heterodimer (25) or p65/p50/IB heterotrimer
(3, 28, 30, 39, 66), the ankyrin repeat domain masks the
nuclear localization signal. However, it has recently been shown that
the main function of IB is that of a nuclear export chaperone
(through a nuclear export signal within the N-terminal domain), rather
than a cytoplasmic tether, and that the largely cytoplasmic
localization of the p65/p50/IB heterotrimer is due to the
predominance of nuclear export over nuclear import (27, 31,
57).
In the Hedgehog signaling pathway, in the absence of the morphogen, the
full-length form of Ci is found in a cytoplasmic multiprotein complex
(52, 55), from which the processing product is released (2). The processing product, which contains a nuclear
localization signal (64), translocates into the nucleus,
where it acts as a transcriptional repressor. In addition, processing
removes a nuclear export signal (8). Hedgehog signal
reception leads to nuclear localization of the full-length
transcription factor. A shuttling mechanism, in which the opposite
actions of nuclear import and nuclear export mechanisms act through the
signals described above, ensures appropriate levels of the nuclear
full-length form (8), which has transcriptional activation
functions (40, 46). Therefore, three forms of the
Ci protein (full-length nuclear, cytoplasmic, and processed nuclear)
participate in Hedgehog signaling. We show here that, in marked
similarity to Ci, a modified version of the full-length PacC form
(corresponding to the open conformation) can get into the nucleus.
The change from the closed to the open conformation of full-length PacC
results in commitment for proteolytic processing, which hinders the
unambiguous characterization of the subcellular localization of the
processing reaction. Two opposite models are a priori possible. In the
first, open PacC translocates into the nucleus, where the processing
reaction would take place. In the second, processing of open PacC would
be cytosolic, and the proportion of full-length PacC translocated into
the nucleus would be protected from processing. Although we do not have
convincing evidence for either of these models, we favor the cytosolic
processing model (Fig. 11) for the following reasons. The
pacCc14 allele leads to strong
alkalinity mimicry at any ambient pH. It encodes a PacC primary
translation product truncated after residue 492 that lacks an
interacting region crucial for maintaining the closed conformation.
Therefore, even under acidic pH conditions, this protein is in the open
conformation, which in turn leads to low levels of primary translation
product due to processing. These low levels are hardly detectable by
Western blotting, but can be detected by using our sensitive EMSA (Fig.
1A, lanes 4 to 6). This open PacC is mostly present in the nucleus and
absent from the cytosol, which might be consistent with protection of this open PacC from cytosolic processing by its compartmentalization into the nucleus.
This work raises interesting questions about the mechanistic bases of
the different subcellular localizations of the full-length and
processed PacC forms. Our data unambiguously show that the processed
PacC form contains a functional nuclear import signal that can target
heterologous proteins to the nucleus and strongly indicate that this
import signal is localized within the DNA binding domain. While the
zinc finger region was sufficient for nuclear targeting of heterologous
proteins, the subcellular distribution of all fusion proteins between
GFP and PacC polypeptides lacking an intact zinc finger region was
indistinguishable from that of GFP. A single-residue substitution
abolishing DNA binding does not affect the nuclear localization of a
processed form-GFP protein fusion, thus separating nuclear targeting
and DNA binding activities. This rules out a model in which the
reduction in PacC size resulting from proteolytic processing could lead
to preferential nuclear localization by a mechanism involving a
combination of passive diffusion and nuclear retention after DNA
binding. Using a PacC(250-678)::GFP construct driving high
levels of expression of this protein (Fig. 5B), we have been unable to
detect the presence of a second nuclear import signal in the region
removed by proteolytic processing. In agreement, a bipartite cluster of
basic residues between PacC residues 252 and 269 does not act as
a nuclear import signal for a PacC(241-280)::GFP
fusion protein (data not shown). Therefore, the nuclear import
signal mapping to the zinc finger region most likely mediates import of
both the processed and the open full-length PacC forms.
While a role of nuclear import in PacC regulation seems clear, we have
been unable to obtain evidence for a role of nuclear export. The fact
that the subcellular localizations of a GFP::PacC(250-678) fusion protein and of GFP are indistinguishable might suggest that
residues removed by processing do not contain a nuclear export signal,
which would have led to preferential cytosolic labeling. This
conclusion has been verified by confocal fluorescence microscopy (data
not shown). A similar GFP-based methodology served to reveal the role
of nuclear export in Ci regulation (2, 8). Therefore, the
mechanism by which the closed, but not open, full-length PacC is
tethered to the cytosol remains elusive. Because the nuclear import
signal reported here and the DNA binding domain overlap, the fact that
closed PacC is able to bind DNA in vitro suggests that this
conformation does not involve masking of the zinc finger region and, by
extension, of the nuclear import signal.
Environmental signals (glucose and ambient pH) have been shown to
control the nuclear localization of yeast MIG1 (15) and Aspergillus PacC (this work), two key ascomycete wide-domain
transcription factors mediating glucose repression of genes for the
catabolism of alternative carbon sources and regulating expression of
genes for extracellular enzymes, certain permeases, and the
biosynthesis of secondary metabolites, respectively. Finally, our work
with PacC is relevant for understanding the invasiveness and resistance to alkaline pH in Saccharomyces (22, 34), the
adaptation of Candida albicans to changing pH environments
(a key factor in its pathogenicity) (11, 12, 49, 50), the
synthesis of extracellular metabolites and proteins by fungi (19,
33, 35, 36, 38, 56, 61, 62), and the regulation of aflatoxin biosynthesis (32), all of which are processes regulated by
the PacC/RIM101p family of transcription factors.
| |
ACKNOWLEDGMENTS |
We thank H. N. Arst for critical reading of the manuscript,
C. Scazzocchio for the gift of pAN52-1::sGFP, and E. Reoyo
for technical assistance.
We also are grateful for the support of the EU through contracts
BIO4-CT96-0535 and QLK3-CT-1999-0729, the CICYT through grant BIO97-348, the Basque Government through a predoctoral fellowship to
E.D., and the DGICYT for a postdoctoral contract with E.A.E. and a
predoctoral fellowship to J.M.M.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Centro de
Investigaciones Biológicas CSIC, Velázquez 144, Madrid
28006, Spain. Phone: 34 91 5644562, ext. 4358. Fax: 34 91 5627518. E-mail: penalva{at}cib.csic.es.
Present address: Zentrum für Molekulare Biologie der
Universität Heidelberg, 69120 Heidelberg, Germany.
| |
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Molecular and Cellular Biology, March 2001, p. 1688-1699, Vol. 21, No. 5
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.5.1688-1699.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
