From the Institut de Génétique et
Microbiologie, CNRS Unité Mixte de Recherche 8621, Université Paris-Sud XI, Centre d'Orsay, Bâtiment 409, F-91405 Orsay Cedex, France, the ¶ Section Molecular Genetics of
Industrial Microorganisms, Wageningen University, Dreijenlaan 2, NL-6703 HA Wageningen, The Netherlands, and the
§§ Imperial College of Science, Technology and
Medicine, Department of Infectious Diseases and Microbiology,
DuCane Road 150, London UK-W12 0NN, United Kingdom
Received for publication, September 16, 2002, and in revised form, December 20, 2002
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ABSTRACT |
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The role of hexose phosphorylating enzymes in the
signaling of carbon catabolite repression was investigated in
the filamentous fungus Aspergillus nidulans. A
D-fructose non-utilizing, hexokinase-deficient (hxkA1, formerly designated frA1) strain was
utilized to obtain new mutants lacking either glucokinase
(glkA4) or both hexose kinases (hxkA1/glkA4).
D-Glucose and D-fructose phosphorylation is
completely abolished in the double mutant, which consequently cannot
grow on either sugar. The glucokinase single mutant exhibits no
nutritional deficiencies. Three repressible diagnostic systems, ethanol
utilization (alcA and alcR genes), xylan
degradation (xlnA), and acetate catabolism
(facA), were analyzed in these hexose kinase mutants at the
transcript level. Transcriptional repression by D-glucose
is fully retained in the two single kinase mutants, whereas the
hexokinase mutant is partially derepressed for D-fructose. Thus, hexokinase A and glucokinase A compensate each other for carbon
catabolite repression by D-glucose in the single mutants. In contrast, both D-glucose and D-fructose
repression are severely impaired for all three diagnostic systems in
the double mutant. Unlike the situation in Saccharomyces
cerevisiae, the hexose phosphorylating enzymes play parallel
roles in glucose repression in A. nidulans.
To survive among competing microorganisms in an environment with
limited resources, saprophytic filamentous fungi such as Aspergillus nidulans and Aspergillus niger adapt
rapidly to changing nutrient conditions. Two major control circuits,
specific induction and general carbon catabolite repression
(CCR),1 enable considerable
versatility in utilizing a wide range of carbon sources while
preferentially consuming readily available substrates of high
nutritional value before less accessible ones. In A. nidulans, CCR is ultimately mediated by the DNA-binding transcriptional repressor CreA, which prevents activation of the catabolism of less preferred carbon sources if a more favorable growth
substrate is available (1) (reviewed in Refs. 2-4). CreA function
somewhat resembles that of Mig1p, the main mediator of
D-glucose repression in Saccharomyces cerevisiae
(5) (reviewed in Ref. 6). The presence of a high concentration of a
repressing growth substrate, not restricted to D-glucose,
is necessary to trigger the CCR response.
Much is known about the targeting of transcriptional control of
nutrient utilization in A. nidulans, the molecular means by which induction and repression are imposed on the promoter regions of
genes subject to catabolic regulation. In the inducible ethanol utilization pathway, the functional cis-acting elements
conferring induction and repression, the target sequences of the
DNA-binding activator AlcR and the general CCR-repressor, have been
identified in the regulatory alcR gene encoding the
pathway-specific activator and the structural genes for alcohol
dehydrogenase I and aldehyde dehydrogenase, alcA and
aldA, respectively (reviewed in Ref. 4). In this model
system, various mechanisms by which induction and repression of
induction are mediated were evidenced, and a subtle interplay between
the two regulatory circuits was shown to fine-tune the expression of
each of these three genes in distinct ways (7-12). Functional
regulatory target sites for CreA have also been identified in two other
catabolic systems, the xylanase gene xlnA and the proline
permease gene prnB (13-16).
Far less is known about the means by which the CreA repressor becomes
functional in response to repressing carbon sources and how the
repressional regulatory circuit adapts to changing nutrient conditions,
e.g. upon exhaustion of a preferable carbon source. It has
been shown that transcription of the creA gene itself is
negatively autoregulated in response to repressing carbon sources,
leading to a reduced steady-state creA transcript level (17). However, the CCR-repressor function appears to be mainly controlled at the post-transcriptional or post-translational level (17-20). In A. nidulans, strains mutant in two additional
genes, creB and creC, exhibit some derepressed
characteristics similar to those observed in loss-of-function
creA mutants but also show a number of phenotypes not
related to CCR (21, 22). These two genes have been characterized
recently and, interestingly, S. cerevisiae does not appear
to harbor any close homologues (23, 24).
Still less is known about the sensing of repressing compounds and the
means by which such compounds trigger the CCR response in filamentous
fungi. In S. cerevisiae, an important role in the glucose-sensing process has been ascribed to hexokinase Hxk2p, an
enzyme catalyzing the first step in glycolysis and glucose fermentation, phosphorylation of D-glucose at C6 (reviewed
in Ref. 6). Baker's yeast actually specifies three enzymes capable of
this phosphorylation, hexokinases (Hxk: EC 2.7.1.1) Hxk1p and Hxk2p,
and glucokinase (Glk: EC 2.7.1.2) Glk1p (25). Any one suffices for
growth on glucose, but Hxk2p is the main activity for phosphorylating
glucose because it is predominantly expressed during fermentation (26,
27). Concomitantly, only this isozyme is essential for repression of
catabolism of alternative carbon sources such as sucrose and maltose;
loss-of-function hxk2 mutants are defective in glucose
repression mediated by Mig1p (28) (reviewed in Refs. 6 and 29). The
mechanism by which Hxk2p participates in glucose repression remains
obscure to date. In general, a strong correlation is found between the
capacity of mutant Hxk2p to phosphorylate glucose or fructose and CCR
by these two sugars (30, 31). However, catalytic activity of Hxk2p
might not be essential for glucose repression; rather, signal
transmission might be linked to Hxk2p conformational changes induced by
the sugar and ATP (32-34).
In the filamentous fungus A. nidulans, hexose
phosphorylation was previously studied in the D-fructose
non-utilizing frA1 ("fructokinase") mutant (35, 36).
This mutant lacks Hxk activity but, unlike the situation in S. cerevisiae, its glucose CCR of ethanol and L-arabinose
catabolism appeared fully functional. Here, we have utilized three
carbon utilization systems, ethanol (alcA and
alcR genes), xylan (xlnA), and acetate
(facA), to investigate the role of hexose kinases in CCR at
the transcript level. The previously mentioned Hxk mutant
(frA1, herein renamed hxkA1) as well as newly
obtained Glk (glkA4) and hexose kinase double
mutants(hxkA/glkA4) were studied. We show that
the two hexose kinases play parallel roles in glucose repression in the
model organism A. nidulans.
A. nidulans Strains, Media, and Growth Conditions--
A.
nidulans strains used in this study are listed in Table I. The
references refer to the mutations relevant to this work. Other markers
are in standard use (37). Media composition, supplements, and basic
growth conditions at 37 °C were as described by Cove (38), using
di-ammonium tartrate (5 mM) as the nitrogen source and the
various carbon sources at 1% (w/v or v/v), unless stated otherwise.
Conidiospores were obtained on solidified complete medium with
either glycerol or sodium D-gluconate as the carbon source.
Mycelia for enzyme assays were grown on glycerol minimal medium for
16 h and then transferred to fresh minimal medium containing 1%
(v/v) ethanol and 1% (w/v) D-glucose or
D-fructose and incubated for another 4 h prior to
harvesting. Mycelia for the analysis of alc and
facA transcription were grown for 10-12 h in minimal medium
with glycerol as the carbon source and urea (5 mM) as the nitrogen source. For the analysis of xlnA transcription,
sodium D-gluconate replaced glycerol and the incubation
time was extended to 40 h. Induction was achieved by the addition
of the inducer compounds specific for the three diagnostic systems
examined, 2-butanone to 50 mM (final concentration) for
alc, D-xylose to 50 mM for
xlnA, or sodium acetate (pH 6.8) to 10 mM for
facA, respectively. Cultures were harvested after 2.5 h
of further incubation (inducing conditions). For repressed conditions,
D-glucose or D-fructose was added
simultaneously with the inducer to a final concentration of 1% (w/v)
(i.e. 55 mM). Noninduced mycelia were grown in
the initial growth media during the induction period.
Mutagenesis and Genetic Techniques--
Conventional genetic
techniques were employed (39). Following UV mutagenesis of a suspension
of 106 conidiospores of G092 per ml, the survival
rate was ~25%. Selection for resistance to 50 mg/l
2-deoxy-D-glucose (2DOG) was done in the presence of 1%
(v/v) glycerol as carbon source and 0.08% (w/v) sodium desoxycholate
to reduce colony size. Resistant colonies were allowed to develop for 6 days at 37 °C, and mutants were purified using the same medium.
Wild-type strain C62 was used to cross out the hxkA1
(frA1) translocation in NW298 to yield single glucokinase
(glkA4) mutants NW299 and NW300. Genetic mapping of the
glkA4 mutation was only possible in a Hxk-deficient
background (see "Results"). 2DOG-resistant strain NW193
(glkA4 hxkA2) was crossed to CEA54 to exchange auxotrophic
markers to facilitate the formation of a diploid between the progeny
strain NW303 and the tester strain NW301, utilized in parasexual
analysis to localize the glkA4 and hxkA2
mutations (see Table I).
Enzyme Assays--
Cell-free extracts were prepared from frozen
mycelia in liquid nitrogen as described previously (36). All enzyme
assays were done at 25 °C. Glucose- and fructose-phosphorylating
activities in crude extracts were determined as described by Ruijter
et al. (36). To distinguish better between in
vitro Hxk and Glk activities, assays were performed in both the
absence and presence of the Hxk-specific inhibitor
trehalose-6-phosphate (40). At 1 mM, the inhibitor reduced
the measured Hxk activity to about 1/10 of its actual value (see Table
II, compare with activities in the Glk mutant glkA4).
Isolation of RNA and Northern Blot Analysis--
Total RNA was
isolated from about 250 mg of mycelial powder, obtained by grinding
mycelia in liquid nitrogen, with RNA Plus extraction solution
(Qbiogene) following the manufacturer's instructions. It was further
purified by precipitation in 3 M sodium acetate, pH 6.0, for 2 h at Only Mutants Impaired in Both GlkA and HxkA Activity Cannot
Phosphorylate Glucose
To investigate the involvement of hexose phosphorylation in
the signaling of D-glucose repression in filamentous fungi,
we obtained new mutants lacking either Glk or both Glk and Hxk by classic means. D-Fructose non-utilizing Hxk-deficient
hxkA1 (frA1) mutant strains are unable to
phosphorylate fructose but grow quite well on glucose by virtue of Glk
activity (36). The selection of Glk mutations in a hxkA1
strain was based on increased resistance to the toxic antimetabolite
2DOG in the presence of glycerol as sole carbon source (see
"Experimental Procedures" for details). This glucose analogue is
phosphorylated by either hexose kinase but cannot be catabolized any
further (46).
Among the 2DOG-resistant mutants, several were unable to grow on
glucose. The glucose non-utilizing mutant exhibiting the lowest
residual glucose phosphorylating activity was chosen for further
analysis. Fructose-utilizing (hxkA+) progeny
from an outcross grew normally on glucose and were tested for hexose
phosphorylating activities in crude extracts as compared with wild
type, the 2DOG-resistant glucose non-utilizing parent, and the single
hxkA1 mutant. Some of the glucose- and fructose-utilizing progeny clearly lacked Glk activity (see Table
II). The mutation resulting in the Glk
lesion was designated glkA4. Other glucose and fructose
non-utilizing mutants were selected for 2DOG resistance in an
outcrossed glkA4 single mutant. Parasexual analysis of one such strain allocated glkA4 to chromosome III and the newly
selected hxkA2 mutation, as expected, to chromosome IV
(results not shown).
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
Aspergillus nidulans strains used in this study
20 °C. The precipitate was collected by
centrifugation, and residual salt was removed by conventional alcohol
precipitation. Northern analysis was carried out with 15-µg samples
of glyoxal-treated total RNA (41) using Hybond N membranes (Amersham
Biosciences). Membranes were hybridized with
32P-labeled probes synthesized from DNA fragments from the
cloned A. nidulans genes alcA (10),
alcR (42), xlnA (43), facA (44), and
acnA (
-actin) (45). Autoradiographs were exposed for
various time periods to avoid film saturation. Intensities of the
hybridization signals were quantified using a PhosphorImager (Amersham
Biosciences). The
-actin gene was used to normalize the data from a
single membrane. For alc and facA, panels
A and C of Figs. 1 and 4-7 originate from a
single membrane, enabling direct comparison among all principal
strains. For xlnA, panels B of Figs. 1 and 4-6
originate from a single membrane, allowing direct comparison between
wild type and the three different hexose kinase mutants. All expression
experiments were repeated at least twice.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
Phosphorylation of glucose and fructose in extracts of various A. nidulans strains
We can conclude that only hexose kinase double mutants are unable to grow on glucose as sole carbon source. In contrast to the fructose non-utilizing Hxk mutants, the Glk mutant strains do not show any obvious nutritional deficiencies. Table II shows high levels of glucose and fructose phosphorylating activities in a glkA4 strain that are decreased drastically in the presence of the Hxk inhibitor trehalose-6-phosphate. This strongly suggests that Hxk can compensate the lack of Glk activity, allowing glkA4 mutants to grow normally on glucose. Similarly, Glk appears to compensate the absence of Hxk in hxkA1 for glucose phosphorylation and growth because reasonable levels of glucose phosphorylation were measured in the absence and presence of trehalose-6-phosphate (Table II). In agreement with nutritional phenotypes, only the double sugar kinase double mutant (hxkA1/glkA4) is unable to phosphorylate either hexose (Table II).
Defining the Conditions to Trigger CCR Using Three Different Catabolic Systems
Ethanol Utilization--
The ethanol utilization (alc)
pathway is convenient for studying the signaling of CCR because of its
highly inducible structural (alcA) and regulatory
(alcR) gene expression, the marginal levels of non-induced
(constitutive) expression, and the high repressibility by CreA in the
presence of repressing carbon sources like glucose, fructose, and
D-xylose (Fig.
1A). Competition between the
pathway-specific activator AlcR and the general repressor CreA occurs
in the alcA and alcR genes under all conditions
of growth; alcR expression is, in addition, subject to
direct repression by CreA (7, 8, 10, 11). A further advantage is the
availability of an efficient gratuitous inducer, 2-butanone (47).
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Xylan Degradation-- The gene encoding xylanase A (X22) in A. nidulans, xlnA (43), was chosen as the second system (Fig. 1B). xlnA is one of the few genes in which a functional target site for CreA has been identified (13). In addition, the xlnR regulatory gene, encoding the pathway-specific activator, is most likely subject to CreA-mediated repression (48). For expression of xlnA, induction is absolutely required. The simplest inducer, D-xylose (the monomer of xylan), is highly metabolizable and is strongly repressing at high concentrations (1).2 This pentose requires specific transport (see below). The xylanase system is extremely sensitive to repression. D-Gluconate as carbon source for growth allows reproducible glucose-repressible, xylose-inducible expression of xlnA in wild type but, as will be shown below, nevertheless exerts significant repression.
Acetyl-CoA Synthetase--
The third system chosen is the
facA gene, encoding acetyl-CoA synthetase catalyzing the
first step of acetate catabolism in A. nidulans (44, 49).
This gene features expression characteristics completely different from
those of xlnA (Fig. 1C). Glycerol was used as
growth substrate. As on many other carbon sources, facA is
constitutively expressed to considerable levels on glycerol, but
wild-type strains remain clearly inducible by acetate and glyoxylate
(to between 2- and 3-fold the basal level). We utilized 10 mM acetate (pH 6.8) as inducer, because higher
concentrations reduce general transcription efficiency as characterized
by lower -actin transcript levels (47). The true inducer of
facA expression is neither acetate nor glyoxylate but more
likely acetyl-CoA, a key intermediate of cellular metabolism
(50).3
In contrast to the basal level, the acetate-induced facA
expression appears completely repressible by glucose and fructose in
the wild type. Although repression of induced facA
expression appears to depend on CreA (see below), no functional
analysis of CreA target sites has been reported.
The Onset of Induction is Faster than That of Carbon Catabolite Repression
To establish appropriate conditions to study the effects of hexose kinase mutations on carbon catabolite repression, it was important to analyze the time course of induction versus repression for the CCR-regulated systems.
For xlnA, a short induction period appears desirable because
the inducibility drops sharply with time when using a high
concentration of xylose as inducer of medium-shifted mycelia (51). This
feature could result from "self" CCR by the inducer
compound, xylose, consistent with observations for xylanolytic genes in
A. niger, for which the inducibility drops with increasing
xylose concentration (52). In the absence of medium shift, the
inducibility does not decline drastically with time or with increasing
xylose concentrations, although the xlnA transcript levels
are lower than those reported by MacCabe et al. (51)
(results not shown). Fig. 2A
shows that an induction period of 1 h was not sufficient to
observe any repression by fructose, whereas some xlnA
repression could be observed after 2.5 h. Comparison of these two
induction periods in wild type for the alc genes clearly
shows that induction by 2-butanone had been established within 1 h, whereas repression by fructose and also that by glucose was far from
complete at that time (Fig. 2B).
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Induction thus occurs faster than repression. For the alc system, induction is a rather straightforward process, requiring the binding of AlcR to DNA targets in the presence of the physiological inducer, acetaldehyde (reviewed in Ref. 4). Our results suggest that onset of transcriptional repression requires several steps such as sugar uptake, formation of a physiological repressor, post-translational modification of CreA, and possibly indirectly involved proteins such as CreB and CreC. For transcript analysis, we have chosen the longer time period of 2.5 h to properly evaluate induction and repression of all three systems.
Inducer Exclusion Accounts for One Apparent Form of CCR of xlnA Expression
A very straightforward way to prevent the expression of an inducible catabolic system is by inducer exclusion, i.e. blocking entry of the inducer. Inducer exclusion can result from direct CreA-mediated repression of the gene encoding the specific permease of the repressible catabolic system. This is the principal mechanism of repression of the structural genes of proline catabolism in A. nidulans (16, 53).
The regulation of the xlnA gene illustrates inducer
exclusion. 5 mM xylose is sufficient to induce
xlnA in wild type, and, as expected, xlnA
expression is completely prevented in the presence of 1% glucose
(results not shown). This is, however, not related to any action of
CreA because in the strongly derepressed mutant creAd30, expression of
xlnA is also prevented under these conditions (Fig.
3). The presence of fructose has no such
effect. Furthermore, this phenomenon did not occur in the
creAd30 strain when equimolar (50 mM) amounts of both xylose and glucose were present,
although xlnA was fully repressed in wild type under these
conditions (not shown). We therefore avoided inducer exclusion by
employing the higher xylose concentration (50 mM).
Presumably, the inducer exclusion is caused by a direct inhibition of
xylose transport by the structurally related sugar glucose. Xylose
inhibition of 2DOG transport in A. nidulans has been
reported (54).
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The Effect of Single Hexose Kinase Lesions on CCR by Glucose and Fructose: Hexokinase Is Required for Full Fructose Repression
The lack of hexokinase in the hxkA1 mutant does not
prevent glucose repression in any of the three systems at the
transcript level (Fig. 4). However, the
Hxk-deficient strain is clearly derepressed in the presence of
fructose, the sugar that is neither phosphorylated nor catabolized by
this mutant. This indicates that Hxk at least plays some role in the
transmission of the repression signal for fructose. In S. cerevisiae, elimination of Hxk activity by the deletion of both
the Hxk-encoding genes, HXK1 and HXK2, likewise leads to derepression on fructose (55).
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Interestingly, from the analysis in alc, clearly this derepression is far from complete (Fig. 4A). Partial derepression is consistent with the ability of hxkA1 mutants to be suitable for selection of CCR-derepressed creA mutants such as creAd30 (56). This strongly suggests that, in the absence of hexokinase, another factor, devoid of apparent fructose phosphorylating activity, can partly fulfil the regulatory function of Hxk with respect to CCR by fructose and its precursors.
One possible candidate for this regulatory factor would be glucokinase,
a hexose phosphorylating enzyme with a narrower substrate range
apparently constitutively produced (Table II). However, the single Glk
mutant glkA4 exhibits wild-type repression by both fructose
and glucose for all three systems (Fig.
5). It would thus appear that Glk
integrity is not important for CCR in A. nidulans. In
S. cerevisiae, Glk does not fulfil any regulatory function
in either glucose or fructose repression, even when artificially overexpressed (31, 55, 57).
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Derepression in Hexose Kinase Double Mutants: Hexokinase HxkA and Glucokinase GlkA Compensate Each Other for CCR by Glucose
In the hxkA1/glkA4 double mutant all three
systems are derepressed for both glucose and fructose (Fig.
6). The translocation-free hxkA2/glkA4 double mutant gave identical results
for the alc system derepression (not shown). This excludes
the possibility that derepression involved a consequence of a
translocation breakpoint other than the translocation associated with
the hxkA1 mutation. The derepression of the alcR
and alcA genes on fructose is almost complete (80-100%), whereas on glucose it is about 50%. The xlnA and
facA genes are completely derepressed both on fructose and
glucose. However, an unexpected observation for xlnA is that
its induced expression is decreased considerably. Furthermore, for
facA, the basal level expression is increased, whereas the
steady-state induced level remains similar to that in the wild type.
The reason for this increased facA basal level is
unknown.
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Comparison of the derepression of the alc genes on fructose in the single hxkA1 mutant and in both hexose kinase double mutants shows that derepression in the absence of both hexose phosphorylating enzymes is virtually complete, whereas that in the single hexokinase-deficient strain is only partial (Figs. 4A and 6A and data not shown). For signaling by the ketosugar, glucokinase appears to partially compensate the Hxk deficiency. Our results suggest that Glk is either directly or indirectly involved in fructose repression in A. nidulans, despite the fact that fructose is not a relevant catalytic substrate for the enzyme (see Table II). A direct involvement of Glk in fructose repression in A. nidulans would unambiguously distinguish the regulatory function of hexose phosphorylating enzymes in CCR-related signal transmission from the catalytic activity with regard to this sugar.
Derepression in Hexose Kinase Double Mutants Put in Perspective: Comparison with the Strongly Derepressed creAd30 Mutant
We compared the levels of transcriptional derepression of the three diagnostic systems in the hexose kinase double mutants and in a creA-derepressed strain. Nearly complete derepression of the alc genes is achieved either in an extreme creA mutant such as creAd30 (7) or by disrupting functional CreA targets in responsive promoters (10, 11). The observed "superinduction" of alcA and alcR expression is a direct result of the absence of promoter binding competition between AlcR and CreA that normally occurs under all physiological conditions.
In Fig. 7, the superinduction in the
creAd30 strain is evident for all
three systems. In no case does the level
of expression observed in the double hexose kinase mutant on glucose
and fructose equal that in the
creAd30 strain. For facA,
the basal (non-induced) level is elevated in the creA
mutant, but the gene remains inducible. The
creAd30 mutation virtually abolished
CreA-AlcR binding competition, whereas the more modest effect of the
double hexose kinase deficiency suggests it does not. This indicates
that hexose kinases are not involved in CreA-AlcR binding competition
and thus that CreA can bind its target sites in the absence of sugar
signaling.
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For xlnA, superinduction in the creAd30 strain is striking, at least 100-fold greater than in the wild type (Figs. 7B and 8). Apparently, xlnA is extremely sensitive to CCR, not only by repressing compounds such as glucose and fructose but also by compounds generally considered non-repressing for other catabolic systems such as ethanol utilization, e.g. glycerol, D-gluconate and L-glutamate (1, 2) (results not shown). We were in fact unable to find a completely derepressing, non-inducing carbon source for the analysis using xlnA. Gluconate was eventually selected because it allowed reproducible glucose-repressible and xylose-inducible xlnA expression in the wild type (see Fig. 1B). Hence, derepression observed in the hexose kinase double mutant appears to concern only the additional repression from glucose or fructose over the "basal" repression from gluconate and the inducer, xylose.
Reduced Inducibility of xlnA in Hexokinase Mutants, an Indication of Positive Involvement of Hexokinase in Xylose Induction
An interesting observation is the considerable reduction (3-fold)
in xylose-induced expression of xlnA in the single
hexokinase and hexose kinase double mutants, but not in the glucokinase
mutant (Figs. 1B, 4B, 5B, and
6B). Two hypotheses could explain this observation. First,
xlnA repression by xylose might be elevated in mutants
lacking Hxk, thereby decreasing the level of expression. Alternatively,
xylose induction of xlnA might be lower because of the Hxk
lesion. To distinguish between these hypotheses, we analyzed
xylose-induced xlnA steady-state transcription in a
derepressed triple mutant
(creAd30/glkA4/hxkA1).
If the first hypothesis were correct, the inducibility should be
restored to the level observed in the
creAd30 single mutant, 100-fold
higher than that in the wild type. In the second case, reduced
inducibility should still be seen in the triple mutant. Revealingly,
the xylose-induced xlnA level in the triple mutant is
clearly lower than that in the single creAd30 mutant (Fig.
8), although the induced level of
xlnA transcript is still elevated because of the absence of
functional CreA (30-fold greater than in wild type) (Table
III). Hence, the reduced (3-fold) inducibility observed in Hxk mutants is maintained in a truly derepressed background. This suggests that Hxk has a CreA-independent, positive role in xylose induction of xlnA.
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DISCUSSION |
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Hexose Kinase Single Mutants Are Not Affected in Glucose-mediated CCR-- Carbon catabolite repression in the filamentous fungus A. nidulans appears related to the capacity to utilize a given carbon source. The three repressible systems monitored here, ethanol catabolism (alcA and alcR), xylanase A (xlnA), and acetyl-CoA synthetase (facA), respond in a quantitatively similar manner in the different hexose kinase mutant backgrounds.
hxkA mutants have derepressed steady-state transcript levels for the three systems vis-à-vis fructose while being unable to utilize it. On the other hand, hxkA mutants grow normally on glucose, whereas the three diagnostic systems remain repressed in its presence, in sharp contrast to the situation in S. cerevisiae where Hxk2p is essential for glucose repression (but not for growth on glucose) (reviewed in Refs. 6 and 29). The hexokinase mutant produces glucokinase activity in the presence of either fructose or glucose (Table II).
The single glucokinase (glkA4) mutant data support the argument that CCR correlates with carbon source utilization. Glk mutants do not exhibit nutritional deficiencies because they produce high levels of Hxk activity, enabling phosphorylation of both fructose and glucose. The Glk mutant shows an apparently wild-type transcriptional repression for all our diagnostic systems in the presence of either sugar. The two glucose-phosphorylating enzymes thus substitute each other functionally in the single mutants, both with respect to catalytic function and in establishing glucose-mediated carbon catabolite repression. In this respect, transcript analyses of the three systems correlate with the measured hexose kinase activities.
Sugar Phosphorylation Is a Critical Step in CCR by Hexose Sugars-- The observations in both hexose kinase single mutants are in agreement with previous work with the hxkA1 mutant (36) and would suggest that hexokinase and glucokinase are not involved in CCR by glucose. However, both our double hexose kinase (hxkA/glkA4) mutants refute this conclusion because they show considerable transcriptional derepression for all three systems in the presence of either glucose or fructose. Derepression in both double mutants is total for xlnA and facA, whereas for alc it is greater on fructose than on glucose. For these double mutants, glucose is not a carbon source, and (in vitro) phosphorylation of both fructose and glucose is virtually abolished. The substantial residual repression of the alc genes on glucose in the double mutants might indicate involvement of a third protein, possibly capable of phosphorylating glucose in vivo although remaining undetected in vitro.
Overall, our results would implicate either glucose phosphorylation,
the first step in glycolysis, or the catabolic flux initiated from it
as essential for signaling glucose repression in A. nidulans. Two independent findings favor sugar phosphorylation as
the critical step. First, A. nidulans pyruvate
dehydrogenase-deficient (pdhA) strains are unable to grow on
glycolytic substrates (58, 59). In such glucose non-utilizing mutants,
sugar phosphorylation still occurs. However, they provide a very
amenable genetic background for the positive selection of derepressed
creAd mutants (2, 60). Second, our
repression-defective hexose kinase double mutants were isolated by
positive selection for resistance to 2DOG, a glucose analogue that is
phosphorylated without initiating catabolic flux (54). Nevertheless,
2DOG represses induced expression of the alc genes at the
transcript level as strongly as glucose does, as shown in Fig.
9. In S. cerevisiae, Hxk2p is
involved in the regulation of glucose uptake and hxk2 mutants have a different expression spectrum for hexose transporters (61) (reviewed in Ref. 62). Interestingly, preliminary results show
that both hexose kinase double mutants appear to have glucose uptake
characteristics similar to those of wild
type.4 This indicates that
the unphosphorylated sugar is unlikely to play a direct role in
signaling carbon catabolite repression in A. nidulans.
|
The levels of derepression of the three systems in glucose-derepressed hexose kinase double mutants are less than those seen in the creAd30 strain, widely used as a reference for derepression. These results suggest that the CreA protein normally mediates repression from other metabolites in the hexose kinase double mutant, irrespective of the sugar kinase lesions. This is most evident for xlnA (Table III). Several mechanisms, possibly acting in concert, might account for the 300-fold difference in induction: a total lack of repression from the carbon source gluconate and the inducer xylose, derepression of the activator-encoding xlnR gene in addition to that of the structural xlnA gene, and altered xylose transport. To this latter end, we have shown that the reduced inducibility of xlnA in hexokinase mutants is not because of CreA-mediated repression (Fig. 8 and Table III). In the derepressed triple mutant (creAd30/glkA4/hxkA1), a superinduction of xlnA is observed as expected from the creAd30 mutation, but the wild-type xylose inducibility ratio is not restored. The positive involvement of Hxk in xlnA induction might occur at the level of xylose uptake by hexose transporters. The xylose-fermenting yeast Pichia stipitis takes up xylose and glucose with a common transport system (63). Here, we have provided evidence for inducer exclusion of xylose by glucose (Fig. 3), consistent with a common transporter for xylose and glucose in A. nidulans.5 Possible regulatory functions of the hexose kinases in the catabolism of glucose and xylose are currently under study.
CCR in A. nidulans Differs Fundamentally from Glucose Repression in
S. cerevisiae--
In A. nidulans, glucokinase and
hexokinase appear to play a mere catalytic role in CCR, specific for
their substrates (repressing hexose sugars). The complete absence of
(in vitro) glucose phosphorylating activity in our hexose
kinase double mutants correlates with derepression of the three
diagnostic systems for glucose and fructose. In contrast to Hxk2p in
S. cerevisiae, neither hexose kinase exhibits a unique, general regulatory function in CCR in A. nidulans. A
possible reason could be that glucose repression in yeast is
specifically related to fermentation of glucose into ethanol (64),
whereas most filamentous fungi metabolize glucose almost uniquely
via oxidative phosphorylation. Moreover, CCR in filamentous
fungi can result not only from glucose, sucrose, or fructose but also from other carbon sources such as xylose and acetate
(1).6 These fundamental
differences might be relevant to the lack of similarity between the
respective CCR-mediating repressor proteins, Mig1p and CreA, beyond the
DNA-binding domains (the two Cys2His2-zinc fingers). CRE1, the CreA homologue from the filamentous fungus Sclerotinia sclerotiorum, cannot complement a
mig1 deletion in S. cerevisiae (65). In A. nidulans, CCR could be signaled independently for individual
carbon sources and CreA might be the ultimate receptor of multiple
converging signaling routes. In this respect, the signal transmission
processes preceding transcriptional repression also seem to differ
fundamentally between the two types of fungi.
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ACKNOWLEDGEMENTS |
---|
We thank Dr. Christophe d'Enfert and Dr. John Clutterbuck for kindly providing several A. nidulans strains and Maarten Bax for technical assistance at the laboratory in Wageningen.
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Note Added in Proof |
---|
Katz et al. (68) have characterized the Aspergillus nidulans xprF gene whose conceptual translation product shares sequence similarity with hexose kinases but apparently has little or no hexose kinase activity. xprF mutations affect the regulation of extracellular proteases, probably in response to carbon starvation or carbon catabolite repression. Whether xprF mutations affect the regulation of other activities has not been reported, but because xprF is on chromosome VII, it is clearly distinct from glkA and hxkA.
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FOOTNOTES |
---|
* This work was supported by the Centre National de la Recherche Scientifique (UMR 8621), the Université Paris-Sud XI, and by European Community Grants BIO4-CT96-0535 and QLK3-CT99-00729.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§ Both authors contributed equally to this work.
Present address: Laboratory of Phytopathology, Wageningen
University, Binnenhaven 5, NL-6709 PD Wageningen, The Netherlands.
** Present address: Dept. of Clinical Genetics, Leiden University Medical Centre, P. O. Box 9600, NL-2300 RC Leiden, The Netherlands.
Present address: Fungal Genetics and Technology Consultancy,
P. O. Box 396, NL-6700 AJ Wageningen, The Netherlands.
¶¶ To whom correspondence should be addressed. Tel.: 33-1-6915-6328; Fax: 33-1-6915-7808; E-mail: felenbok@igmors.u-psud.fr.
Published, JBC Papers in Press, January 7, 2003, DOI 10.1074/jbc.M209443200
2 As confirmed by transcript analyses in alc (M. Flipphi and B. Felenbok, unpublished data).
4 A. P. MacCabe, M. Flipphi, B. Felenbook, and D. Ramón, unpublished data.
5 This is the case for the A. niger sugar transporter MstA (P. A. vanKuyk, personal communication).
3 M. Flipphi and B. Felenbok, unpublished data.
6 M. M. Tanzer, H. N. Arst, Jr., A. R. Skalchunes, M. Coffin, B. A. Darveaux, R. W. Heiniger, and J. R. Shuster, unpublished data.
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ABBREVIATIONS |
---|
The abbreviations used are: CCR, carbon catabolite repression; 2DOG, 2-deoxy-D-glucose; Glk, glucokinase; Hxk, hexokinase.
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