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Previous Article | Next Article 
Journal of Bacteriology, December 1998, p. 6242-6251, Vol. 180, No. 23
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
The facC Gene of Aspergillus
nidulans Encodes an Acetate-Inducible Carnitine
Acetyltransferase
Christopher J.
Stemple,
Meryl
A.
Davis, and
Michael J.
Hynes*
Department of Genetics, The University of
Melbourne, Parkville, Victoria 3052, Australia
Received 11 May 1998/Accepted 1 October 1998
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ABSTRACT |
Mutations in the facC gene of Aspergillus
nidulans result in an inability to use acetate as a sole carbon
source. This gene has been cloned by complementation. The proposed
translation product of the facC gene has significant
similarity to carnitine acetyltransferases (CAT) from other organisms.
Total CAT activity was found to be inducible by acetate and fatty acids
and repressed by glucose. Acetate-inducible activity was found to be
absent in facC mutants, while fatty acid-inducible activity
was absent in an acuJ mutant. Acetate induction of
facC expression was dependent on the facB regulatory gene, and an expressed FacB fusion protein was demonstrated to bind to 5' facC sequences. Carbon catabolite repression
of facC expression was affected by mutations in the
creA gene and a CreA fusion protein bound to 5'
facC sequences. Mutations in the acuJ gene led
to increased acetate induction of facC expression and also
of an amdS-lacZ reporter gene, and it is proposed that this
results from accumulation of acetate, as well as increased expression
of facB. A model is presented in which facC
encodes a cytosolic CAT enzyme, while a different CAT enzyme, which is acuJ dependent, is present in peroxisomes and mitochondria,
and these activities are required for the movement of acetyl groups between intracellular compartments.
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INTRODUCTION |
Acetate and other two-carbon
compounds, such as ethanol, are capable of acting as sole carbon
sources for many microorganisms. Gluconeogenesis is required, and this
leads to depletion of citric acid cycle intermediates. These are
replenished by the anaplerotic glyoxalate bypass in which the action of
the enzymes isocitrate lyase (ICL) and malate synthase (MS) results in
the net production of intermediates from acetyl coenzyme A (acetyl-CoA)
(5, 46). The glyoxalate bypass is present in bacteria,
plants, and fungi, as well as some animals (reviewed in reference
19). ICL and MS are located in microbodies termed
peroxisomes or glyoxysomes, depending on whether they contain the
enzyme catalase (42, 69).
Therefore, for acetate utilization, three different subcellular
locations are required
the cytosol, the mitochondrion, and the
peroxisome. The activation of acetate to acetyl-CoA by acetyl-CoA synthase (ACS) occurs in the cytosol, as shown in Saccharomyces cerevisiae (43). Acetyl-CoA is imported into the
mitochondrion, where it is metabolized via the citric acid cycle. A
shuttle mechanism involving carnitine acetyltransferase (CAT) forming
acetylcarnitine from carnitine and acetyl-CoA in a reversible reaction
is required, since the outer mitochondrial membrane is permeable to
acetylcarnitine but not to acetyl-CoA (45, 64). In addition,
it has been recently shown that the peroxisomal membrane of S. cerevisiae is also impermeable to acetyl-CoA and that the
acetylcarnitine shuttle is involved in the entry of acetyl-CoA into the
peroxisome (70).
Acetate utilization mutants of a number of fungi have been isolated,
e.g., Neurospora crassa (30, 31), S. cerevisiae (reviewed in reference 51), and
Coprinus cinereus (9, 50). In Aspergillus nidulans, direct screening for acetate mutants led to the
identification of twelve acu genes (3) and a
further gene was identified by propionate resistance (62).
In addition, acetate nonutilization mutants carrying mutations in the
facA, facB, and facC genes have been
isolated by resistance to fluoroacetate, which is toxic by virtue of
conversion to fluorocitrate, an inhibitor of aconitase (2).
The facA gene has been shown to encode ACS (13,
60). Cloning and characterization of the facB gene
showed that it encodes a regulatory protein with a Zn(II)Cys
binuclear cluster DNA binding domain (38, 65) which is
involved in acetate induction of ACS (facA), ICL
(acuD), and MS (acuE), as well as in induction of
acetamidase (amdS) and NADP-specific isocitrate
dehydrogenase (33, 66).
Some fungal mutants unable to grow on acetate are also unable to
utilize fatty acids as sole carbon sources (3, 27). Selection of A. nidulans mutants unable to grow on fatty
acids resulted in the isolation of new alleles of previously identified acu genes (20, 41). Fatty acids are first
converted to their CoA esters and then, via the cyclic 
-oxidation
pathway, to acetyl-CoA (32, 42, 69). This pathway takes
place exclusively in the peroxisomes, and fatty acids induce peroxisome biogenesis.
Since acetyl-CoA is produced by -oxidation, enzymes of the
glyoxalate bypass and of gluconeogenesis are required for growth on
fatty acids as sole carbon sources. In A. nidulans, the
acuJ gene has been shown to be required for growth on fatty
acids (such as Tween 80 and oleate), as well as on acetate, and to
affect CAT activity in response to fatty acid induction
(53). This suggests that the formation of acetylcarnitine in
the peroxisome is likely to be required for shuttling of acetyl groups
into the cytosol and into the mitochondrion. The only acetate-specific mutations identified in A. nidulans are in the
facA, facB, and facC genes
(3). The growth responses of relevant A. nidulans mutants are summarized in Table 1, and
the proposed pathways and enzyme locations are shown in Fig.
1.
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FIG. 1.
Proposed locations and functions of enzymes involved in
fatty acid and acetate utilization in A. nidulans. The model
for the role of CAT enzymes is presented in this paper. During growth
on acetate, facC-encoded CAT activity in the cytosol
produces acetylcarnitine, which enters peroxisomes and mitochondria,
where acuJ-dependent CAT activity results in the formation
of acetyl-CoA which is metabolized via the glyoxalate bypass and the
citric acid cycle. During growth on fatty acids, acetyl-CoA formed by
-oxidation in the peroxisome is converted to acetylcarnitine by
acuJ-dependent CAT activity and then can be shuttled to the
mitochondria for metabolism via the citric acid cycle. Therefore,
acuJ-dependent activity is required for growth on both fatty
acids and acetate, while facC-dependent activity is required
only for growth on acetate. A question mark adjacent to AcuJ indicates
that it has not been demonstrated that the acuJ directly
encodes a CAT activity.
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The function of the facC gene has not been determined. The
phenotypes of fluoroacetate resistance and acetate nonutilization in
facC mutants clearly indicate an essential role in the
conversion of acetate to citrate. However, facC mutants have
not been found to have a specific enzyme defect (3, 33). We
have now cloned and characterized the facC gene. The
predicted polypeptide shows extended similarity to CAT proteins of
eukaryotes and is most similar to one of two CAT enzymes (YAT1p)
present in S. cerevisiae (44, 61). Mutations in
the acuJ gene of A. nidulans lead to reduced CAT
activity (53). We present evidence that there are two CAT
activities present in A. nidulansone that is encoded by
facC, is inducible by acetate via FacB, and is predicted to be cytosolic and one that is dependent on acuJ, is inducible
by fatty acids, and is predicted to be located in the mitochondria and
the peroxisomes. Furthermore, we have demonstrated that both of these
enzymes are subject to glucose repression mediated by the
creA gene (21, 22) and demonstrated binding of
expressed FacB and CreA fusion proteins to fragments of the 5'
untranslated region of facC containing predicted binding sites.
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MATERIALS AND METHODS |
Strains, media, and growth conditions.
The A. nidulans strains used in this work are shown in Table
2. The A. nidulans media and
growth conditions used were described by Cove (16). Nitrogen
sources were added to a final concentration of 10 mM. Carbon sources
were generally added to 1% (wt/vol), except for acetate, which was
added to 50 mM, and Tween 80, which was added to 0.5% (vol/vol).
Growth of mycelium for DNA, RNA, and enzyme extracts was in 100 ml of
medium in 250-ml Erlenmeyer flasks shaken at 37°C.
General methods.
A. nidulans strains were transformed
by the method of Andrianopoulos and Hynes (1). Plasmids were
prepared for transformation by centrifugation on a cesium chloride
gradient or by Magic Preps (Promega), Wizard Preps (Promega), or HPP
columns (Boehringer Mannheim). Genetic manipulations were carried out
as described by Clutterbuck (11). Genomic DNA was isolated
from mycelium by the method of Lee and Taylor (48). Total
RNA was isolated by using the FastRNA RED method (Bio 101, Inc.) in
accordance with the manufacturer's instructions.
DNA for Southern blot analysis was separated by electrophoresis through
1.0% agarose gels and transferred to Hybond N+ membrane
(Amersham) by alkaline transfer (0.4 M NaOH) for 3 to 4 h as
recommended by the manufacturer. Prior to transfer, the DNA was
depurinated by treatment of the gels with 0.25 M HCl for 10 min.
RNA was separated through 1.2% agarose containing 0.6 M formaldehyde
in 1× morpholinepropanesulfonic acid (MOPS) buffer (20 mM MOPS, 5 mM
sodium acetate, 1 mM Na2EDTA, pH 7.0). RNA samples were
mixed in a solution of 0.5% formamide, 37% formaldehyde, 1× MOPS
buffer, 1× loading dye, and 10-mg/ml ethidium bromide and heated to
68°C prior to loading. RNA was transferred to Hybond N+
(Amersham) by alkaline transfer in 0.04 M NaOH for 2 to 3 h.
DNA fragments were radioactively labelled for hybridization by using
standard random hexanucleotide priming procedures using the Klenow
fragment of DNA polymerase I (Promega Corp.) and
[
-32P]dATP (3,000 Ci/mmol; Bresatec).
For both Southern and Northern blot analyses, filters were
prehybridized (at least 30 min) and hybridized with a labelled DNA
probe overnight at 42°C in a solution of 50% formamide, 4× SSPE
(1× SSPE is 0.18 M NaCl, 10 mM NaH2PO4, and 1 mM EDTA [pH 7.7]), 1% sodium dodecyl sulfate (SDS), 5% BLOTTO (10%
skim milk powder), and 100-µg/ml sonicated herring sperm DNA. Filters
were washed with 2× SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodium citrate)-0.1% SDS for 30 min at 42°C and then with 0.1× SSC-0.1% SDS for 30 min at 68°C, except where noted otherwise. Filters were
then subjected to autoradiography.
DNA sequencing.
DNA fragments were subcloned into the
pBluescriptSK+ or pBluescriptSK
phagemid (Stratagene) for sequencing.
Single-stranded DNA was prepared for sequencing as described by
Sambrook et al. (59). Double-stranded plasmid DNA was
prepared for sequencing by polyethylene glycol precipitation or by use
of an HPP column (Boehringer Mannheim). Automated sequencing was
performed by using Dye Primer 373A DNA Cycle Sequencing Kits and Dye
Terminator 373A DNA Cycle Sequencing Kits (Applied Biosystems, Inc.).
The specific primers used in sequencing were 5' CTC ATC CAC AAT CTC ACC
3', 5' CCA AGC GAG AGA GCTAGG 3', and 5' ATG GATCGTGTGCATGGC
3'.
A. nidulans libraries.
A chromosome
VIII-specific A. nidulans genomic library (8) was
kindly supplied by M. Katz (University of New England, Armidale, New
South Wales, Australia), and an A. nidulans cDNA library in a 
gt10 vector was provided by G. S. May (Baylor College of
Medicine, Houston, Tex.).
EMSAs.
Probes for use in electrophoretic mobility shift
assays (EMSAs) were labelled by end filling 5' overhangs with the
Klenow fragment of DNA polymerase I (Promega Corp.) and
[-32P]dATP (3,000 Ci/mmol; Bresatec). They were then
purified by electrophoresis on a 4% nondenaturing polyacrylamide gel
in 1× Tris-borate-EDTA (TBE). Labelled fragments were localized by
autoradiography, excised, eluted in dialysis tubing by electrophoresis
in 0.2× TBE, and precipitated by standard techniques (59).
Binding reaction mixtures comprised protein extract, labelled DNA
probes, 1 µg of poly(dI-dC), and 1× binding buffer (25 mM HEPES
· KOH [pH 7.6], 40 mM KCl, 1 mM EDTA, 50% glycerol) in 20-µl
volumes. Binding reaction mixtures were incubated for 20 min at 25°C.
DNA binding reaction mixtures were electrophoresed on 4% nondenaturing
polyacrylamide gels containing (per 100 ml) 13.3 ml of a 30%
acrylamide mixture (29:1 acrylamide-bisacrylamide ratio), 20 ml of 5×
TBE, 66.2 ml of deionized H2O, 0.52 µl of 10% ammonium
persulfate, and 80 µl of
N,N,N',N'-tetramethylethylendiamine in 1× TBE at 100 to 150 V and 4°C (58). Gels were dried under a vacuum prior to autoradiography.
CAT assays.
Protein extracts were prepared by grinding
0.2 g of mycelium with glass beads under 1 ml of 50 mM Tris
· HCl (pH 7.5) and centrifuging the resulting slurry at maximum speed
in a microcentrifuge. CAT assays were done as described by Kawamoto et
al. (40). The reaction was monitored spectrophotometrically
at 30°C by monitoring the release of CoA-SH from acetyl-CoA using
5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB). The reaction mixture
contained 40 mM KH2PO4 (pH 8.0), 0.05 mM
acetyl-CoA, 0.12 mM DTNB, and 0.1 ml of crude extract. The reaction was
initiated by the addition of 2.2 mM DL-carnitine (-hydroxy-
-trimethylammonium butyrate) chloride, and the final reaction volume was 1.5 ml. A blank was used to which no carnitine was
added, as a slight background rate of carnitine-independent release of
CoA-SH from acetyl-CoA was observed. Protein concentrations were
determined by using the Bio-Rad Protein Assay reagent, and CAT
activities are expressed as nanomoles of CoA-SH produced per minute per
microgram of protein, assuming an extinction coefficient of 13,600/M/cm
for the chromophore formed from DTNB (26).
Nucleotide sequence accession number.
The GenBank accession
number of the sequence presented here (see Fig. 3) is AF023156.
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RESULTS |
Cloning and sequencing of the facC gene.
The
veA and facC genes are 6 map units apart on
chromosome VIII (12). A cosmid containing the veA
gene on a 4-kb XhoI fragment was provided by L. Yager
(Temple University). This fragment was used to probe a chromosome
VIII-specific cosmid library (8), and cosmid SW17D08 was
identified among a number hybridizing to the probe. Subsequently, this
cosmid was shown to complement the facC102 mutation for
growth on acetate in cotransformation experiments with a riboB2
facC102 strain (MH7065) by using riboB+
plasmid pPL3 (55) and selecting initially for
RiboB+ transformants. The
veA+-containing cosmid was then also found to
complement the facC102 mutation.
Subcloning of cosmid SW17D08 yielded a 10-kb BamHI fragment
in pUC13cmr (Fig. 2A) capable
of complementing the facC102 and facC301 alleles for growth on acetate in cotransformation experiments with pPL3. Restriction mapping (Fig. 2A) and Southern blotting of genomic DNA
showed that the cloned DNA was unique and was not rearranged. Low-stringency Southern analysis (hybridization in 30% formamide and
washing in 0.5× SSC at 37°C) failed to yield hybridizing bands other
than those predicted. The 4-kb KpnI fragment (Fig. 2A)
subcloned into pBluescriptSK+ (pCS3875) was found to be
capable of complementing facC102 and was sequenced. This
KpnI fragment was used as a probe to isolate two cDNA clones
from a cDNA library in gt10 (obtained from G. S. May). These
were found to be identical, and sequencing revealed the 5' and 3'
endpoints shown in Fig. 2A.
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FIG. 2.
(A) Restriction map of the genomic facC
region. The ends of the cDNA clone are indicated by the arrowheads. (B)
facC deletion plasmid. A 4-kb
PstI-BamHI fragment containing the
argB+ gene (68) was inserted into the
indicated PstI-BglII sites, resulting in the
replacement of 1,165 bp of facC sequences with the
argB+ gene.
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The facC sequence is shown in Fig.
3. Comparison of the genomic and cDNA
sequences revealed a long 5' untranslated region (681 bp) in the
predicted mRNA with an intron present prior to the predicted start
codon.
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FIG. 3.
Nucleotide and deduced amino acid sequences of the
facC gene. Nucleotide coordinates are given with respect to
the start of translation, and introns are in lowercase. The ends of the
cDNA are indicated by double underlining of the terminal bases.
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The FacC product has similarity to CATs.
Sequence alignments
showed that FacC has a high level of similarity throughout the sequence
to CATs from fungi, Homo sapiens (Fig.
4), and other species (results not
shown). A lower level of similarity to medium- and long-chain CATs of
mammals was also observed (results not shown). The comparisons
indicated that fungal CAT proteins fall into two classes based on
sequence similarity. Cat2P (S. cerevisiae) and Cat1P
(Candida tropicalis) fall into one class (62.6% similarity,
44.7% identity), while FacC and Yat1P (S. cerevisiae) fall
into the other (65.3% similarity, 49% identity). There is
approximately 50% similarity and 30% identity between these two
classes. Therefore, there may be two functional classes of CAT enzymes
in fungi.
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FIG. 4.
Comparison of the amino acid sequence of A. nidulans (An) FacC with those of CAT-encoding genes. The proteins
in the alignment are Yat1p (61) and Cat2p (44)
from S. cerevisiae (Sc), Cat1p (39)
from C. tropicalis (Ct), and Cat1 (15) from
H. sapiens (Hs). The comparison used the Box shade program
(http://ulrec3.unil.ch/software/Box_form.html). The black bars indicate
similar sequences in FacC and Yat1p but not in the other proteins.
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Since acuJ mutants are deficient in CAT activity
(53), the ability of pCS3875 containing the facC
gene to complement acuJ211 was tested by cotransformation
with riboB+-containing plasmid pPL3. No
complementation was observed in transformants shown to contain pCS3875
sequences by Southern blot analysis. This indicated that extra copies
of the facC gene could not compensate for the lack of
acuJ-dependent CAT activity.
Construction of a facC deletion mutant.
The
central region of the facC gene was replaced with the
A. nidulans argB+ gene (Fig. 2B). A plasmid
containing this sequence was transformed into an argB1
strain selecting for ArgB+. Twenty-six of 176 transformants
were unable to grow on acetate. Southern blot analysis of eight of
these confirmed that replacement of the native
facC+ gene with the deletion construct by a
homologous double crossover had occurred in seven of these. One of
these was shown in crosses to cosegregate ArgB+ and
acetate-negative phenotypes and had phenotypes similar to those of
facC102 mutant strains with respect to growth on acetate and
fatty acids and resistance to fluoroacetate (Table 1). Northern blot
analysis showed that no facC-specific RNA was present under acetate-induced conditions in a facC deletion mutant (data
not shown).
Regulation of CAT activity.
CAT activity in A. nidulans has been shown to be induced by both acetate and fatty
acids (53). We have confirmed this by using Tween 80 as a
fatty acid source (Table 3), as well as
oleate (results not shown). Both acuJ211 and facC
mutations affected CAT levels (Table 3). The acuJ211
facC::argB double mutant had no significant CAT
activity, indicating that these genes affect all CAT activity. The
acuJ211 mutation produced very low levels of activity with
Tween 80 induction but retention of acetate-inducible activity, while
the facC102 and facC::argB mutations
produced reduced levels with acetate induction but retention of Tween
80-inducible activity. Acetate-induced activity was restored to the
facC102 mutant by transformation with pCS3875. These data
strongly suggested that acuJ-dependent CAT activity was
fatty acid induced while facC-dependent activity was acetate
induced.
Acetate-induced activity was observed in a facA303 mutant
(lacking ACS activity), indicating that acetate does not need to be
metabolized to acetyl-CoA for induction. The
facB::BleR loss-of-function mutation
resulted in loss of acetate induction, indicating dependence on this
regulatory gene for induction of facC-dependent activity.
Consistent with this, the acuJ211
facB::BleR double mutant completely lacked
CAT activity.
Significant CAT activity occurred in the absence of an added inducer,
and in the presence of glucose, this was acuJ dependent. Carbon starvation in the absence of an inducer resulted in increased CAT activity. The major component of this was acuJ
dependent, but a minor component was observed in an acuJ211
background (Table 3). It is therefore suggested that expression of both
activities is subject to carbon catabolite repression. The
creA gene has been shown to encode a DNA binding protein
involved in this process (4, 22, 35). Consistent with this,
the creA204 mutation, which results from an amino acid
substitution in the DNA-binding domain of CreA (63),
affected CAT activity in the presence of glucose (Table
4).
In the presence of glucose and in the absence of an added inducer, CAT
activity was elevated about twofold in the creA204 strain.
Acetate-induced activity in the presence of glucose was elevated about
threefold in the creA204 strain, while Tween 80 induction
was elevated about twofold. These data suggest that both
facC- and acuJ-dependent activities are subject
to CreA-mediated repression. The data also indicate that acetate
induction of facC-dependent activity is subject to
CreA-mediated repression.
Regulation of facC expression.
Northern blot
analysis was used to analyze facC RNA (Fig.
5). Expression was induced by acetate,
and this induction was reduced by the presence of glucose. The
creA204 mutant was inducible by acetate and, in the presence
of glucose, showed slightly higher levels of RNA than the wild type,
but the sensitivity of the blot was not sufficient to clearly show the
two- to threefold effects observed (Table 4). The expression of
facC was clearly FacB dependent, since the
facB101 loss-of-function mutation (66) produced
low levels of expression under both noninduced and induced conditions. The facC102 mutant had low, weakly inducible levels of
expression, while the acuJ211 mutant had significantly
increased levels of induction by acetate.
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FIG. 5.
Analysis of facC expression. RNAs were
extracted from the wild type (MH0001) and the creA204
(MH0664), acuJ211 (MH8091), facB101 (MH0764), and
facC102 (MH7065) mutant strains. Mycelium was grown for
16 h in 1% glucose-10 mM ammonium tartrate medium before
transfer to medium containing glucose (1%) or no added carbon source
(C-free) with or without acetate (added as 50 mM sodium acetate).
facC RNA was detected by using the 4-kb KpnI
fragment of pCS3875 (Fig. 1) as a probe. H3 represents RNA detected by
probing with an EcoRI fragment of the histone H3 clone
(23). rRNA refers to the large rRNA species observed by
ethidium bromide staining of the gel.
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EMSAs of the 5' region of facC.
A fusion protein
(FacB-MBP) containing amino acids 4 to 417 of FacB [which includes the
ZnII(2)Cys6 DNA binding domain] fused to the maltose-binding protein
(MBP) expressed in Escherichia coli has been found to bind
in vitro to sequences in the 5' regions of FacB-regulated genes
(66). EMSA analysis showed that partially purified extracts
containing FacB-MBP bound to two fragments (552 to 19 and 220 to
19) from the 5' region of facC (Fig.
6). Inspection of these sequences
revealed two potential binding sites that conform to the two dissimilar
consensus sequences for FacB-MBP binding (67).
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FIG. 6.
EMSA of the facC 5' region using the FacB-MBP
fusion protein. (A) Two different fragments were labelled and used for
EMSAthe EcoRI-HindIII and
AccI-HindIII fragments, as indicated in panel
B. For each experiment, lane 1 contained no added extract, lane 2 contained a control of expressed MBP, and lanes 3 to 5 contained
increasing amounts of FacB-MBP fusion protein extract. The arrowheads
labelled F and B indicate the positions of free and bound probe,
respectively. (B) facC 5' regions used as probes. The black
rectangles indicate the positions of sequences (shown below) which
conform to previously determined FacB binding site consensus
sequencesTCC/GN8-10C/GGA and GCC/AN8-10G/TGC (67).
Coordinates are relative to the 5' end of the cloned cDNA.
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A fusion between the DNA binding domain of CreA and glutathione
S-transferase (CreA-GST) has been widely used for studies of
CreA binding sites (17, 28, 47). EMSA analysis of the 5'
facC sequence detected specific binding to the 220 to 19 fragment (Fig. 7). This fragment contains
two sequences (on the noncoding strand) consistent with the proposed
consensus (5'-SYGGRG-3') for CreA binding (17).
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FIG. 7.
EMSA of the facC 5' region using the CreA-GST
fusion protein. (A) The AccI-HindIII fragment
shown in panel B was used as a probe. Lane 1 contained no added
extract, lane 2 contained a control extract of expressed GST, and lanes
3 and 4 contained increasing amounts of the CreA-GST extract. The
arrowheads labelled F and B indicate free and bound probe,
respectively. (B) facC 5' region indicating the position of
the probe used and the locations of potential consensus CreA binding
sites (black rectangles) with the sequences indicated. Coordinates are
relative to the 5' end of the cloned cDNA.
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These data are therefore consistent with the idea that facC
is directly regulated by FacB and CreA.
Acetate induction of amdS expression in
acuJ211 backgrounds.
The observation that the
acuJ211 mutation resulted in increased acetate induction of
facC expression (Fig. 5) led us to investigate the effects
of this mutation on amdS expression. This was studied by
using an amdS-lacZ fusion present in single copy at the
amdS locus (18) and determining acetate induction
of -galactosidase levels (Table 5).
The acuJ211 mutation resulted in slightly elevated uninduced
activity and an increased response to acetate induction. This effect
was abolished by the facB::BleR and
facC102 loss-of-function mutations. Under uninduced
conditions, it is likely that there is some endogenous induction, and
the results are consistent with the idea that the acuJ211
mutation results in the accumulation of an acetate-derived inducer
which acts via FacB.
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DISCUSSION |
We have established that the facC gene encodes a CAT
enzyme required for acetate utilization but not for fatty acid
utilization. Although no substrates other than acetyl-CoA have been
tested, the similarity of FacC to other CAT protein sequences, together with the phenotype of facC mutants, clearly indicates that
the major substrate is acetyl-CoA. This gene is directly regulated by
acetate induction mediated by the facB gene, and binding of a FacB fusion protein to 5' sequences of facC has been
demonstrated. Binding of a CreA fusion protein to 5' facC
sequences has also been demonstrated, and the creA204
mutation results in elevated expression in the presence of glucose and
acetate. The data are consistent with the proposal that CreA has a weak
direct effect on facC expression and a strong indirect
effect via effects on facB expression, which is subject to
CreA-mediated glucose repression (38). Therefore,
facC is regulated similarly to the facA
(ACS-encoding) gene.
In addition to the facC-encoded activity, there is an
additional CAT activity dependent on the acuJ gene, as
suggested by Midgley (53). Our data suggest that this
activity is present constitutively and is inducible by fatty acids and
subject to catabolite repression. This pattern of regulation is
consistent with the observation that this activity is required for
growth on both acetate and fatty acids as sole carbon sources.
Since intracellular membranes are impermeable to acyl-bound CoA
molecules, such as acetyl-CoA, acetyltransferase enzymes are required
for shuttling of acyl groups across these membranes by formation of
acylcarnitine derivatives which pass the membranes and then reform
acyl-CoA derivatives in the organelle (7, 45, 64, 70). In
vertebrates, multiple enzymes with overlapping activities have been
isolated. CAT, specific for short-chain (C2 to C4) acyl derivatives, is
localized in both mitochondria and peroxisomes (29, 54);
carnitine palmitoyltransferase, specific for medium- and long-chain
(C10 to C18) molecules, is mitochondrial (10); while
carnitine octanoyltransferase (C6 to C8) is peroxisomal (29). This is consistent with the idea that -oxidation of
fatty acids occurs in both peroxisomes and mitochondria. In
peroxisomes, oxidation terminates at the medium chain length (C6 to
C8), and these shuttle to the mitochondria, where they are fully
oxidized. In addition, acetyl-CoA formed in peroxisomes must enter
mitochondria for entry into the citric acid cycle (reviewed in
reference 7). In humans, a single gene encoding CAT
proteins targeted to both mitochondria and peroxisomes has been found
(15).
In fungi, -oxidation can progress to completion in peroxisomes and
does not occur in mitochondria (69; reviewed in
reference 57). Consistent with this, only CAT
activity has been detected in fungi and not carnitine transferases
specific for longer-chain acyl derivatives. Cloning of CAT-encoding
genesYCAT1 from S. cerevisiae (25,
44) and CT-CAT from C. tropicalis
(39)has demonstrated that there is a single gene encoding
the mitochondrial and peroxisomal CAT activities. Two different
transcriptional start points result in two different proteins, one with
an N-terminal mitochondrial localization sequence and one without. A
C-terminal peroxisomal localization sequence results in peroxisomal
localization of proteins lacking the mitochondrial localization
sequence. A second gene, YAT1, encoding CAT activity was
identified in S. cerevisiae, and this activity was found on
the outer surface of intact mitochondria and lacked localization
sequences (61).
It would be expected that CAT activity is required for shuttling of
acetyl-CoA across mitochondrial and peroxisomal membranes and is
therefore necessary for growth on acetate and fatty acids. However, in
S. cerevisiae, deletion of either YCAT1 or
YAT1 did not significantly alter growth rates on acetate or
fatty acids (44, 61, 70). Either the presence of the second
CAT gene could compensate for the loss of the first, or there is an
additional shuttle system that could compensate for the
carnitine-dependent shuttle. The properties of a double mutant have not
been reported, but the finding that deletion of the CIT2
gene encoding peroxisomal citrate synthase prevented a YCAT
null mutant from growing on acetate or fatty acids (70)
indicates the second possibility. A second shuttle involving citrate
can compensate for the loss of peroxisomal CAT activity.
It is clear that the situation is different in A. nidulans.
Loss of facC-encoded CAT activity prevents growth on acetate
but not on fatty acids, and this is consistent with acetate induction of facC expression. Therefore, this activity is proposed to
be present in the cytosol, and this is supported by the lack of signal sequences. In addition, FacC shows greater similarity to YAT1p, which
is proposed to be located on the outer surface of mitochondria (61), than it does to YCATp, which is located in peroxisomes and mitochondria.
Mutations in the acuJ gene result in loss of growth on both
acetate and fatty acids as carbon sources. The
acuJ-dependent activity is present at significant levels in
noninduced cells and is inducible by fatty acids. We propose that the
activity is localized in peroxisomes and mitochondria and is absolutely required for the formation of acetyl-CoA in peroxisomes and
mitochondria from acetylcarnitine during growth on acetate and for the
shuttling of acetyl groups from peroxisomes to mitochondria during
growth on fatty acids. This implies that the citrate shuttle present in
S. cerevisiae is absent in A. nidulans, and this
is supported by the lack of peroxisomal citrate synthase activity
(6, 56). It is predicted that the acuJ-dependent
CAT enzyme protein will contain mitochondrial and peroxisomal
localization signals and be more similar to YCATp and CT-CATp than to
FacC. A model for the proposed pathways is presented in Fig. 1.
We have shown that acetate induction of facC and of an
amdS-lacZ reporter is increased in an acuJ211
background (Fig. 5 and Table 5). Previous results have indicated that
facB-dependent acetate induction is observed in a
facA mutant background lacking ACS (33, 34). This
indicates that acetate does not have to be metabolized to acetyl-CoA
for induction to occur. Loss of peroxisomal and mitochondrial CAT
activity in an acuJ211 background is proposed to result in
elevated acetate levels and, hence, increased induction. In an
acuJ mutant, acetate would be converted to acetyl-CoA (by ACS), and this would be converted to acetylcarnitine by
facC-encoded CAT activity. The acetylcarnitine, however,
would accumulate in mitochondria and peroxisomes due to the absence of
acuJ-dependent CAT activity. Since the CAT shuttle is
reversible, this would lead to reversal of the pathway leading to
facC-dependent accumulation of acetyl-CoA in the cytosol.
Acetyl-CoA hydrolase, which has been detected in N. crassa
(14), might then convert this to acetate, which would
accumulate. A gene encoding a protein with extensive similarity to the
N. crassa acetyl-CoA hydrolase has recently been isolated
from A. nidulans (34). This hypothesis is
consistent with increased acetate induction of the amdS-lacZ gene in an acuJ211 background that is dependent on
facB (Table 5).
In addition, facB expression itself is inducible by acetate
and subject to carbon catabolite repression (38). However,
acetate induction is not observed in either a facA or a
facC mutant background, indicating that acetate must be
metabolized to induce facB expression (34).
Furthermore, preliminary data indicate that the acuJ211 mutation leads to increased levels of facB expression
(34). Therefore, it is proposed that increased levels of
FacB occur in an acuJ mutant, and this results from
accumulation of acetylcarnitine (or a derivative), which is the true
inducer of facB expression. The increased amount of FacB
results in increased expression of facC and amdS.
Consistent with this, the facC102 mutation, which prevents
acetylcarnitine formation from acetate, is epistatic to the
acuJ211 mutation with respect to acetate induction (Table 5). This model predicts that there is an additional regulatory gene
regulating facB expression in response to the level of acetylcarnitine.
Overall, this interpretation is consistent with the previous suggestion
that facB-mediated induction has two componentsinduction of FacB levels and increased activity of FacB caused by acetate itself
(65). It should also be noted that catabolite repression of
structural genes (e.g., facC and amdS) subject to
facB control may be directly regulated by CreA as well as
indirectly via CreA regulation of facB expression.
The acuJ-dependent CAT activity is inducible by fatty acids
(53, this study). Fatty acid induction of gene
expression in A. nidulans is not well characterizedin
contrast to the situation in S. cerevisiae, where two
transcription factors, OAF1p and OAF2p, are proposed to bind to oleate
response elements in the promoters of oleate-inducible genes (24,
37, 49). It is clear that there are at least three classes of
genes involved in acetate and fatty acid utilization. Acetate-specific
genes such as facA and facC are regulated by
facB-mediated acetate induction. Genes involved in the
glyoxalate bypass (acuD and acuE) are acetate inducible via facB but are also required for growth on fatty
acids. Since facB mutations do not affect growth on fatty
acids (Table 1), it is likely that these genes are subject to
facB-independent control. It is of interest that genes
additional to facB have been found to influence
acuD-dependent isocitrate lyase activity (see reference
52). The third class of genes is those encoding enzymes of -oxidation and the acuJ-dependent CAT
activity, and they are fatty acid inducible. Characterization of the
acuJ gene is clearly of particular interest, and we have
recently cloned the gene and found that this gene encodes a CAT.
| |
ACKNOWLEDGMENTS |
This work was supported by the Australian Research Council.
Assistance with the figures and the provision of protein extracts by
Alex Andrianopoulos are appreciated. The gifts of the
creA-GST fusion construct given by Joan Kelly and the
veA-containing cosmid given by L. Yager are acknowledged.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Genetics, University of Melbourne, Parkville, Victoria 3052, Australia. Phone: (61 3) 9344 6246. Fax: (61 3) 9344 5139. E-mail:
hynes.lab{at}genetics.unimelb.edu.au.
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Hynes, M. J., Szewczyk, E., Murray, S. L., Suzuki, Y., Davis, M. A., Sealy-Lewis, H. M.
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Hynes, M. J., Murray, S. L., Duncan, A., Khew, G. S., Davis, M. A.
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Hynes, M. J., Draht, O. W., Davis, M. A.
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Szewczyk, E., Andrianopoulos, A., Davis, M. A., Hynes, M. J.
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Abstract
Introduction
