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J Bacteriol, February 1998, p. 660-666, Vol. 180, No. 3
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
SacY, a Transcriptional Antiterminator from
Bacillus subtilis, Is Regulated by Phosphorylation
In Vivo
Maria
Idelson and
Orna
Amster-Choder*
Department of Molecular Biology, The Hebrew
University
Hadassah Medical School, Jerusalem 91120, Israel
Received 6 August 1997/Accepted 24 November 1997
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ABSTRACT |
SacY antiterminates transcription of the sacB gene in
Bacillus subtilis in response to the presence of sucrose in
the growth medium. We have found that it can substitute for BglG, a
homologous protein, in antiterminating transcription of the
bgl operon in Escherichia coli. We therefore
sought to determine whether, similarly to BglG, SacY is regulated by
reversible phosphorylation in response to the availability of the
inducing sugar. We show here that two forms of SacY, phosphorylated and
nonphosphorylated, exist in B. subtilis cells and that the
ratio between them depends on the external level of sucrose. Addition
of sucrose to the growth medium after SacY phosphorylation in the cell
resulted in its rapid dephosphorylation. The extent of SacY
phosphorylation was found to be proportional to the cellular levels of
SacX, a putative sucrose permease which was previously shown to have a
negative effect on SacY activity. Thus, the mechanism by which the
sac sensory system modulates sacB expression in
response to sucrose involves reversible phosphorylation of the
regulator SacY, and this process appears to depend on the SacX sucrose
sensor. The sac system is therefore a member of the novel
family of sensory systems represented by bgl.
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INTRODUCTION |
Sucrose induces the expression of
two loci in Bacillus subtilis: the sacB gene,
encoding levansucrase, and the sacPA operon, encoding a
sucrose permease and a phosphosucrase (32, 48). Expression
of these loci is controlled by transcriptional antitermination. Thus,
in the absence of sucrose, transcription initiates constitutively and
terminates at 
-independent transcriptional terminators located between the respective promoters and the first structural genes; in the
presence of sucrose, transcription proceeds through the putative
terminators. The transcriptional antiterminators SacY and SacT are
required for the sucrose-dependent readthrough of sacB and
sacPA, respectively (7, 17, 18). Expression of sacB is negatively regulated by SacX, a sugar
phosphotransferase-like protein (17). The sacX
and sacY genes are contiguous and probably constitute an
operon (55).
The B. subtilis antiterminators SacY and SacT highly
resemble the BglG protein from Escherichia coli, both in
sequence and in the mechanism of action (18, 47, 55). BglG
prevents transcription termination at two terminators within the
bgl operon by binding to the RNA chain and preventing the
formation of the terminator structure (27). The RNA sequence
recognized by BglG is highly conserved, and similar motifs which are
found in the leader of both sacB and sacPA were
suggested to be recognized by SacY and SacT, respectively
(10). The activity of BglG is regulated by reversible
phosphorylation (2, 3, 44) which, in turn, modulates the
protein activity by controlling its dimeric state (4). Thus,
BglG exists in the cell in two forms: an inactive, monomeric
phosphorylated form and an active, dimeric nonphosphorylated form.
Phosphorylation of BglG was recently shown to occur on a histidine
residue (6) and was localized to His 208 (15). The state of BglG phosphorylation depends on the availability of
-glucosides; their addition to the growth medium leads to BglG
dephosphorylation (3). The protein which functions as BglG
kinase and phosphatase is BglF, an enzyme II of the
phosphoenolpyruvate-dependent phosphotransferase system (PTS), which is
in charge of the transport and phosphorylation of -glucosides
(2, 3, 44). The way -glucosides lead to bgl
operon induction is by stimulating BglF to dephosphorylate BglG, thus
allowing it to function as an antiterminator. In the absence of sugar,
BglF inactivates BglG by phosphorylating it. BglG and BglF represent a
novel family of systems which utilize a sensor and a regulator to
transduce a signal from the cell surface to the transcription machinery
(5).
Based on indirect evidence, regulation of sacB expression in
B. subtilis seems to resemble bgl regulation in
E. coli. Controlled readthrough of both systems is induced
by sugars, sucrose and -glucosides, respectively, and is positively
regulated by homologous transcriptional antiterminators SacY and BglG,
respectively. Moreover, while bgl expression is negatively
regulated by BglF, the -glucoside PTS permease, sacB, is
negatively regulated by SacX, a sucrose PTS permease homolog
(9). Based on genetic studies, Crutz et al. (17)
concluded that SacX suppresses sacB transcription in the
absence of sucrose by inhibiting the antitermination activity of SacY.
The general PTS proteins were also shown to negatively control
sacB induction, most likely by inhibiting the function of
SacY (17, 47). Based on these observations and on the
striking similarity to the bgl system, a model was proposed
which suggests that SacX is a sucrose sensor which is phosphorylated by
the PTS general proteins and regulates SacY activity by phosphorylation according to sucrose availability in the medium (17).
To test this idea, we tested whether different forms of SacY,
phosphorylated and nonphosphorylated, exist in B. subtilis
cells. Two protein isoforms which differ in their charges were indeed precipitated by anti-SacY antibodies from extracts of cells induced for
SacY expression. The isoforms were separated on two-dimensional (2-D)
gels (isoelectric focusing in the first dimension and sodium dodecyl
sulfate-polyacrylamide gel electrophoresis [SDS-PAGE] in the second).
Due to its sensitivity to phosphatase, the more acidic form was
identified as the phosphorylated form of the protein. Our results
indicate that SacY is regulated in vivo by reversible phosphorylation.
The phosphorylation state of SacY depends on the availability of
sucrose, the inducer of the sac system, and on the cellular
level of SacX. Based on experiments which tested the stability of the
bond between SacY and the phosphoryl group, we suggest that SacY, like
BglG, is phosphorylated on a histidine residue. The similarity between
the two systems, sac and bgl, was manifested in
the ability of SacY to antiterminate transcription of the
bgl operon when it was expressed in E. coli.
Thus, the sac system is a member of the bgl
family of sensory systems.
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MATERIALS AND METHODS |
Bacterial strains.
E. coli AG1688 (MC1061 F'128
lacIq lacZ::Tn5
[4]) and TG1 [supE thi hsdD5
(lac-proAB) (F' traD36 proAB
lacIqZ M15) (24)] were used
for plasmid construction. E. coli MA152, which is
bgl and carries a bgl'-lacZ fusion on its
chromosome (
bglR7 bglG' lacZ+
lacY+ [34]), was used to measure
antitermination. The B. subtilis strain used throughout this
study is IS58 (trpC2 lys [46]).
Plasmids.
Plasmids pT712 and pT713 (used for overexpression
of genes in E. coli), containing the phage T7 late promoter,
were obtained from Bethesda Research Laboratories. Plasmid pDG148 (used
for overexpression of genes in B. subtilis
[50]) contains the Pspac promoter (composed of the
SPO-1 phage promoter and the lac operator [54]) and also the lacI gene (specifying
for the lac repressor). Plasmid pSL85 carries the entire
sacX and sacY genes (17). Plasmid pSL85-X1 carries the entire sacY gene but contains a
deletion within the SacX coding sequence (17). Plasmid
pSL165ATG, containing a sacX allele in which the
first codon, TTG, was replaced by an ATG, was obtained from M. Steinmetz. Plasmid pMN25 carries the entire bglG gene cloned
in pBR322 (34).
The following plasmids were constructed. pOACY is a derivative of
pMN25. The PpuMI-EcoRI fragment of pMN25 which
carries the entire bglG gene was replaced by a 930-bp
fragment carrying the entire sacY gene, which was prepared
by PCR amplification with pSL85 as a template. pT7OAC-Y contains a
1,042-bp AvaI-NruI fragment from pSL85, carrying
the entire sacY gene, cloned into pT713, which was digested
with AvaI and HincII. pT7OAC-XY contains a 2,518-bp SalI-NruI fragment from pSL85,
carrying the entire sacX and sacY genes, cloned
into pT712, which was digested with SalI and
SmaI. pT7OAC-XATG contains a 1,741-bp
SalI-BamHI fragment from pSL165ATG,
carrying a mutant sacX allele that contains an ATG
translation initiation codon, cloned into pT712, which was digested
with SalI and BamHI. pMI1 is the same as
pT7OAC-Y, except that the EcoRI site was replaced by an
HindIII site. This was achieved by digesting pT7OAC-Y
with EcoRI, incubating it with calf intestinal phosphatase (CIP), and ligating it to an oligonucleotide which contains an HindIII site and complements the sticky ends generated
after EcoRI digestion. pMI3 contains a 1,071-bp
HindIII fragment from pMI1, carrying the entire
sacY gene, cloned into the HindIII site on pDG148. pMI4 is the same as pT7OAC-XY, except that the EcoRI
site was replaced by an HindIII site. It was constructed
in the same way as pMI1. pMI5 contains a 2,550-bp
HindIII fragment, from pMI4, carrying the entire
sacX and sacY genes, cloned into the
HindIII site on pDG148. pMI4XATG was
constructed by ligating a 2,158-bp NcoI-PvuII
fragment from pMI4, carrying the C-terminal part of the sacX
gene and the entire sacY gene, to the 3,154-bp
NcoI-PvuII fragment from pT7OAC-XATG,
carrying the N-terminal part of the sacX gene, which
contains an ATG translation initiation codon. pMI5XATG
contains a 2,550-bp HindIII fragment from
pMI4XATG, carrying the sacX allele with the ATG
translation initiation codon and the sacY gene, cloned into
the HindIII site of pDG148.
Media.
For [35S]methionine labeling of
proteins in B. subtilis, Spizizen minimal medium
(25) was used with the following modifications. Lysine (100 µg/ml) and sodium glutamate (10 mg/ml) were also included, and the
tryptophan concentration was 100 µg/ml. The medium used for growing
B. subtilis for DNA transformation was as described previously (25). For all other purposes, E. coli
and B. subtilis were grown in Luria broth. Ampicillin (30 to
200 µg/ml) and kanamycin (10 to 30 µg/ml) were included in the
media when strains which contain plasmids that confer resistance to
either one of these antibiotics were being grown.
Genetic and cloning techniques.
All manipulations with
recombinant DNA were carried out by standard procedures
(43). Competent B. subtilis cells were prepared and transformed with plasmid DNA following the Groningen method (described in reference 25). Plasmid DNA was
isolated from B. subtilis cells by a modification of the
alkaline lysis method (11) which was described previously
(25). Assays for -galactosidase activity were carried out
as described by Miller (37). The cells used for these assays
were grown in minimal medium which was supplied with 0.4% succinate as
a carbon source.
Induction of expression and [35S]methionine
labeling of proteins.
B. subtilis cells, containing plasmids
carrying the sacY gene with or without the different
sacX alleles under the control of the Pspac promoter, were
grown in Spizizen minimal medium. Expression of the cloned genes was
induced by adding isopropyl--D-thiogalactopyranoside (IPTG) to cells that reached the exponential growth phase (optical density at 600 nm, 0.2 to 0.3) at a final concentration of 1 mM. Cells
were grown for an additional 1 to 3 h for 2-D gel analysis or
6 h for SDS-PAGE, followed by Western blot analysis. Following this growth period, [35S]methionine (1,200 Ci/mmol; Du
Pont) was added for 15 to 25 min at a final concentration of 30 µCi/ml. Cells were either precipitated and washed immediately or
incubated with 500 µg of methionine per ml for 5 to 15 min (chase).
Preparation of B. subtilis cell extracts.
B.
subtilis cells, harvested and washed with 10 mM Tris-HCl (pH 8.0)
and PI (phosphatase inhibitor mixture: 100 mM sodium pyrophosphate, 100 mM NaF, 4 mM EDTA, 4 mM sodium vanadate, adjusted to pH 7.6 with HCl),
were lysed by one of two methods. By the first method, cells were
resuspended in lysis buffer I (10 mM Tris-HCl [pH 8.0], 1 mM EDTA,
0.6 mg of lysozyme per ml, 1 mM phenylmethylsulfonyl fluoride [PMSF],
and PI) and incubated for 30 min at 37°C. Following the incubation,
SDS was added at a final concentration of 1% and the mixture was
boiled for 2 min and centrifuged for 5 min in an Eppendorf centrifuge.
The supernatant was used for further analyses. By the second method,
cells were resuspended in lysis buffer II (30 mM Tris-HCl [pH 8.0], 1 mM EDTA, 1 mg of lysozyme per ml, 1 mM PMSF, and PI) and incubated for
30 min at 4°C and 30 min at 30°C. Following the incubation, five
cycles of freeze and thaw were performed, the mixture was spun as
described above, and the supernatant was collected.
Immunoprecipitation and dephosphorylation of proteins.
Protein A-Sepharose beads (Pharmacia) were preincubated for 2 h at
4°C with 5 µl of rabbit nonimmune serum and then washed three times
with Triton buffer (25 mM Tris-HCl [pH 7.5], 150 mM NaCl, 5 mM EDTA,
0.25% Triton X-100, and 0.5 mM PMSF). The beads were subsequently
incubated for 2 h at 4°C in a solution containing 30 to 40 µl
of extract of B. subtilis cells induced for SacY
overproduction and 4 to 5 mg of bovine serum albumin, which was brought
to a final volume of 400 µl with Triton buffer containing 0.5%
Triton X-100. After centrifugation, the supernatant was incubated with 5 µl of anti-SacY antiserum for 15 h at 4°C. Protein
A-Sepharose was added, and incubation in the cold was continued for an
additional 2 h. After the beads were washed, proteins were eluted
from them by boiling in a solution of 10 mM Tris-HCl (pH 8.0), 1 mM
EDTA, and 1% SDS. For dephosphorylation, extracts of cells induced for SacY overproduction were incubated for 10 min at 30°C with CIP (20 U/µl; Boehringer). The reaction was stopped by adding isoelectric focusing sample buffer.
Hydrolysis of proteins with hydroxylamine.
The effect of
hydroxylamine on phosphorylated SacY was tested essentially as
described by Hokin et al. (26). Hydroxylamine was prepared
in the cold just before use by adding 2 parts of 8 N NaOH to 5 parts of
4 M hydroxylamine hydrochloride. Extracts of cells, which were induced
for SacY overproduction, were incubated in 0.1 M acetate buffer (pH
5.2) and 0.8 M hydroxylamine for 10 min at 30°C. Controls contained
cell extracts incubated with 0.1 M sodium acetate (pH 5.2) alone.
Electrophoresis, immunoblotting, autoradiography, and
densitometry.
Two-dimensional gel electrophoresis was performed
essentially as described by O'Farrell (38) with the
modification described by Messika et al. (36), except that
the proteins were solubilized in Garrels' sample buffer
(23) and the ampholytes (pIs, 5 to 7, 6 to 8, and 3.5 to 10)
in the first dimension (isoelectric focusing) were mixed at a ratio of
2:2:1. For regular separation of proteins according to molecular mass,
SDS-PAGE was performed (30). After electrophoresis, gels
with 35S-labeled proteins were dried and exposed either to
Kodak XAR-5 X-ray film or Fujix imaging plate and detected by the
Bio-imaging analyzer BAS1000. The relative amounts of radioactivity in
the two forms of SacY were quantitated by densitomery performed with the Bio-imaging analyzer BAS1000 after the scanning. For
immunoblotting, unlabeled proteins were transferred from an
SDS-polyacrylamide gel to a nitrocellulose filter as previously
described (52). The filter was incubated for 1 h at
room temperature in blocking buffer (5% dried milk [1% fat] in
phosphate-buffered saline) and then for 12 to 16 h at 4°C with
anti-SacY antibodies diluted 1:500 in blocking buffer. After three
washes in phosphate-buffered saline containing 0.1% Tween 20, the
filter was incubated for 1 h with horseradish peroxidase goat
anti-rabbit antibody (Jackson Immunoresearch Laboratories) diluted
1:20,000 in blocking buffer. Binding of antibodies to the membrane was
probed with the enhanced chemiluminescence light-based detection kit
(Amersham). Antibody-bound proteins were detected by exposure to Kodak
XAR-5 X-ray film.
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RESULTS |
SacY from B. subtilis can replace BglG in
antiterminating transcription of the bgl operon in E. coli.
The high degree of homology between the two antiterminators,
BglG from E. coli and SacY from B. subtilis, and
their RNA target sites stimulated us to try to determine whether SacY
can replace BglG in antiterminating transcription of the bgl
operon. We therefore introduced SacY-expressing plasmids into the
E. coli strain MA152. This strain is deleted for the
bgl operon and carries a chromosomal bgl'-lacZ
fusion (34). The lacZ gene is not expressed in
MA152, because transcription terminates at the bgl
terminator, which is located upstream to the lacZ gene.
Expression of plasmid-encoded BglG, the bgl antiterminator,
renders the lacZ expression in this strain constitutive
(34) (Table 1). The ability of
plasmid-encoded SacY to antiterminate transcription at the
bgl terminator and enable lacZ expression in
MA152 was tested by observing the color of the colonies containing
these plasmids on MacConkey lactose plates and by measuring the
-galactosidase levels produced by the cells expressing them. As
shown in Table 1, SacY behaved like BglG in its ability to allow for
lacZ expression. This result indicates that not only are
SacY and BglG similar in their sequences and activities but they also
function in an identical manner.
SacY is phosphorylated in the B. subtilis cell.
Based on the similarity between the sac system from B. subtilis and the bgl system from E. coli and
on the ability of SacY to replace BglG in antiterminating transcription
in E. coli, we speculated that sac is regulated
similarly to bgl, i.e., that the signal transduction
mechanism involves protein phosphorylation. It was previously suggested
that SacY activity might be regulated by phosphorylation
(17). To examine this hypothesis, we sought to determine
whether SacY forms, which differ in their charges, are present in
growing B. subtilis cells. Such forms can be separated from
one another and from other proteins in the cell by the use of 2-D gels.
Phosphorylation of BglG in vivo was demonstrated in this way
(3). To allow detection of SacY, we expressed it from
plasmid pMI3, which harbors sacY under control of the
inducible Pspac promoter, and labeled the cellular proteins with
[35S]methionine. Efficient expression of sacY
in B. subtilis cells containing pMI3, depending exclusively
upon the addition of IPTG to the growth medium, was demonstrated by
SDS-PAGE followed by Western blot analysis with anti-SacY antibodies
(Fig. 1, compare lanes 1 and 2). We then
labeled B. subtilis cells metabolically with
[35S]methionine in the presence and absence of IPTG and
analyzed the labeled proteins on 2-D gels. Two labeled spots, with a
molecular size expected for SacY, were detected only in cells treated
with IPTG (Fig. 2, compare A and B).
These spots were immunoprecipitated by anti-SacY antibodies (Fig. 2A,
insert). We could thus conclude that two forms of SacY are present in
B. subtilis cells.
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FIG. 1.
Induction of sacY expression from the Pspac
promoter in B. subtilis. Proteins were extracted from
B. subtilis cells, containing the sacY gene
cloned under Pspac promoter control on plasmid pMI3, which were grown
either without (lane 1) or with (lane 2) IPTG. Samples were analyzed by
SDS-PAGE, followed by Western blot analysis with anti-SacY antibodies.
Molecular masses of protein standards are given in kilodaltons.
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FIG. 2.
SacY protein is present in two forms in vivo. (A)
B. subtilis cells containing the sacY gene cloned
under Pspac promoter control on plasmid pMI3 were induced for SacY
production by adding IPTG. The cellular proteins were extracted, after
being labeled with [35S]methionine, and analyzed by 2-D
gel electrophoresis (isoelectric focusing in one dimension and SDS-PAGE
in the second dimension), followed by autoradiography. The insert (top,
right) shows fractionation of the same proteins, which were
immunoprecipitated with anti-SacY antibodies prior to the 2-D gel
analysis. (B) The same cells as described for panel A except that IPTG
was not added to the cells. Arrows indicate the positions of the two
forms of SacY. Molecular masses of protein standards are given in
kilodaltons.
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To test whether the two forms of SacY represent phosphorylated and
nonphosphorylated forms of the protein, we treated the
35S-labeled cellular proteins with alkaline phosphatase
before gel
analysis. This treatment led to the loss of the more acidic
form
of SacY (compare Fig.
3A,
nontreated, to 3B, phosphatase treated),
indicating that this indeed is
the phosphorylated form (as expected
from the charge conferred by a
phosphoryl group). This result
shows that SacY is phosphorylated in
vivo. The fraction of the
phosphorylated form of SacY detected by us in
this strain varied
between 30 to 60% in different experiments,
depending on the conditions
of the induction and the length of the
pulse-labeling and whether
a short chase period was included in the
experiment. Therefore,
in each of the experiments described below, we
repeated all the
controls rather than comparing different experiments.
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FIG. 3.
SacY is phosphorylated in vivo. (A) B. subtilis cells containing the sacY gene cloned in
plasmid pMI3 were induced for SacY production and labeled with
[35S]methionine, and proteins were extracted and
fractionated as described in the legend for Fig. 2A. (B) The same as
described for panel A, except that the extracted proteins were treated
with CIP prior to the 2-D gel analysis. Closed arrows indicate
nonphosphorylated SacY; open arrows indicate phosphorylated SacY.
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Sucrose affects the state of SacY phosphorylation.
SacY
antiterminates transcription of the sacB gene in response to
the presence of sucrose in the growth medium. Its E. coli homolog, BglG, antiterminates transcription of the bgl
operon, depending on the presence of -glucosides in the medium.
Therefore, we expected sucrose to influence the state of SacY
phosphorylation analogously to the known effect of -glucosides on
the extent of BglG phosphorylation (2, 3). To test this
hypothesis, sucrose was added to the growth medium of B. subtilis cells during SacY production at a final concentration of
30 mM (the concentration which leads to SacY-dependent sacB
expression). Cells overproducing SacY in the absence of sucrose served
as a control. Whereas the fraction of the phosphorylated form of SacY
in the absence of sucrose was approximately 40% (Fig.
4A), this form could hardly be detected
when sucrose was included in the medium (Fig. 4B). Thus, in the
presence of sucrose, SacY is present mainly in its nonphosphorylated
form, and we can therefore conclude that the extent of SacY
phosphorylation in vivo is influenced by the presence of sucrose in the
growth medium.
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FIG. 4.
Influence of sucrose on the state of SacY
phosphorylation in vivo. (A) B. subtilis cells containing
the sacY gene cloned in plasmid pMI3 were induced for SacY
production and labeled with [35S]methionine, and proteins
were extracted and fractionated as described in the legend for Fig. 2A.
(B) The same as described for panel A, except that 30 mM sucrose was
added to the growth medium together with the IPTG. Closed arrows
indicate nonphosphorylated SacY; open arrows indicate phosphorylated
SacY.
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In order to determine whether sucrose prevents SacY phosphorylation or
can actually lead to dephosphorylation of this protein,
similarly to
the ability of
-glucosides to lead to BglG dephosphorylation
(
2,
3), we carried out pulse-chase experiments in which
sucrose was added only after SacY had been phosphorylated in the
cell.
Addition of unlabeled methionine to cells which were pulse-labeled
with
[
35S]methionine did not reduce the relative amount of
phosphorylated
SacY (compare Fig.
5A and
B). However, when sucrose was added
to
the cells together with the unlabeled methionine, all of the
phosphorylated SacY was converted to the nonphosphorylated form
of this protein (Fig.
5C). Thus, addition of sucrose to the growth
medium leads to active dephosphorylation of SacY in vivo, and
not
merely to the inhibition of SacY phosphorylation.
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FIG. 5.
Sucrose stimulates dephosphorylation of SacY in vivo.
(A) B. subtilis cells containing the sacY gene
cloned under Pspac promoter control on plasmid pMI3 were induced for
SacY production by adding IPTG and were then labeled by incubation with
[35S]methionine for 15 min. Cells were further incubated
with excess unlabeled methionine for 5 (A) or 15 (B) min or as in panel
B except that sucrose was added during the last 10 min at a final
concentration of 60 mM (C). Proteins were extracted and fractionated as
described in the legend for Fig. 2A. Closed arrows indicate
nonphosphorylated SacY; open arrows indicate phosphorylated SacY.
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The effect of SacX on the state of SacY phosphorylation.
Expression of sacB, which is positively regulated by SacY,
is repressed by SacX, a PTS enzyme II-like protein (9).
Analogously to the negative regulation of BglG due to its
phosphorylation by BglF, an enzyme II of PTS (2, 3), it was
suggested that SacX negatively regulates SacY activity by
phosphorylating it (17). To determine whether SacX is
involved in SacY phosphorylation, we asked whether the extent of SacY
phosphorylation correlates with the level of SacX produced in the cell.
We therefore analyzed the extent of SacY phosphorylation in cells
producing different levels of SacX. To this end, we constructed
plasmids pMI5 and pMI5XATG, both carrying sacX
and sacY cloned after Pspac, but whereas the first carries
the wild-type sacX gene, which starts with a TTG codon, the
second carries a sacX allele, which starts with ATG, a more
efficient initiation codon than TTG (53). SDS-PAGE analysis
of labeled proteins from B. subtilis strains which carry a
chromosomal copy of sacX and contain either pMI3 (carrying
sacY alone), pMI5, or pMI5XATG revealed a
protein with the molecular size expected for SacX only when SacX was
overproduced from the plasmids, as expected (data not shown). It is
worth mentioning that the level of overexpressed SacX, even from the
more efficiently translated allele, was lower than the level of
overexpressed SacY, similar to the case of BglF and BglG
(3). Analysis by 2-D gel electrophoresis of SacY produced in
the three cell backgrounds, in the absence of sucrose, indicated that
the fraction of phosphorylated SacY increased with increased SacX
production (Fig. 6). The approximate
fraction of SacY present in the phosphorylated form was 30% in the
first background (Fig. 6A), 50% in the second (Fig. 6B), and more than
70% in the third (Fig. 6C). This experiment was carried out under
conditions that result in a relatively low extent of SacY
phosphorylation in the absence of SacX overproduction (short
induction period, low level of inducer, relatively short pulse,
and no chase). However, a similar dependence of SacY phosphorylation on
the level of SacX production was also observed under other experimental
conditions. Based on these results, we suggest that the extent of SacY
phosphorylation is proportional to the level of SacX in the cell and
thus that SacX appears to be involved in SacY phosphorylation.
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FIG. 6.
Influence of SacX on the state of SacY phosphorylation
in vivo. B. subtilis cells were treated with IPTG and
labeled with [35S]methionine, and proteins were extracted
and fractionated as described in the legend for Fig. 2A. The cells
contained the following plasmids: pMI3, which expresses sacY
from Pspac (A); pMI5, which expresses both sacY and
sacX from Pspac (B); and pMI5ATG, which is the
same as pMI5 except that it carries a sacX allele which
starts with an ATG codon (C). Closed arrows indicate nonphosphorylated
SacY; open arrows indicate phosphorylated SacY.
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Characterization of the bond between SacY and the phosphoryl
group.
Phosphorylation on histidine and aspartate residues (which
form phosphoramidates and acyl phosphates, respectively) is widespread among prokaryotes, although it also occurs on other residues
(42). BglG is phosphorylated on a histidine (6,
15), while regulators of the two-component family are
phosphorylated on an aspartate (see Discussion). To study the nature of
the bond between SacY and the phosphoryl group, we tested the stability
of P~SacY under conditions which destabilize acyl phosphates and
phosphoramidates but not phosphate esters. Only the former two are
susceptible to rapid aminolysis at a pH of <5.5 in the presence of
hydroxylamine (12, 26). We therefore incubated an extract of
cells overproducing SacY with hydroxylamine in acetate buffer, pH 5.2. This led to the complete disappearance of P~SacY (Fig.
7A). Incubation in acetate buffer (pH
5.2) without hydroxylamine did not affect the ratio between
phosphorylated and nonphosphorylated SacY, and the result was as in the
control presented in Fig. 7C (data not shown). This result indicates
that SacY-phosphate is present either as an N-phosphate or
as an acyl phosphate. Because both compounds are known for their
relative sensitivity to elevated temperatures (1), we tested
the stability of P~SacY to heat by boiling the proteins extracted
from cells overproducing SacY. This treatment also resulted in a sharp
decrease in the intensity of the phosphorylated form of SacY (Fig. 7B).
A new spot migrating between the two forms of SacY, which are routinely
observed, appeared after the boiling. The fraction of the protein
transferred to this intermediate location did not decrease upon
prolonged heating. An explanation for the stability of this new form to
heat is suggested in the Discussion.
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|
FIG. 7.
Sensitivity of the bond between SacY and the phosphoryl
group to hydroxylamine and heat. B. subtilis cells
containing the sacY gene cloned in plasmid pMI3 were induced
for SacY production and labeled with [35S]methionine.
Proteins were extracted and were either subjected to treatment with
hydroxylamine as described in Materials and Methods (A) or boiled for
10 min (B). Treated samples and an untreated control (C) were analyzed
by 2-D gel electrophoresis, followed by autoradiography. Closed arrows
indicate nonphosphorylated SacY; open arrows indicate phosphorylated
SacY.
|
|
| |
DISCUSSION |
The bgl system in E. coli, composed of a
membrane-bound sensor, BglF, and a cytoplasmic regulator, BglG, is not
a member of the known family of two-component sensory systems (reviewed
in references 40, 41, and 49).
BglF and BglG have no homology with the sensors and regulators of the
two-component systems, respectively. Moreover, it was recently shown
that BglG is phosphorylated on a histidine residue, unlike response
regulators of the two-component family, which are phosphorylated on an
aspartate (6). Thus, bgl represents a novel
family of systems involved in processing sensory data (reviewed in
reference 5). Based on sequence homology and
mechanistic similarity, other systems, responding to the presence of
various sugars, were suggested to affiliate to this family (see below).
Recent findings, showing that the two-component family and histidine
phosphorylation are not confined to prokaryotes (14, 33,
39), raise the possibility that eukaryotic systems of the
bgl family will be found in the future. To elucidate the general features of the mechanism that governs signal transduction in
the bgl family, it is important to study other members of
this family. Does the communication between sensors and regulators of
the new family involve reversible phosphorylation, which depends on the
presence of the respective sugars, as a general theme?
BglG and BglF have considerable homology with pairs of regulatory
proteins, including the B. subtilis pairs SacY and SacX (48, 55), SacT and SacP (18, 21), LicT and BglP
(29, 31, 45), and LevR and Lev-PTS (a complex of three
proteins) (19, 35), and the Erwinia chrysanthemi
pair ArbG and ArbF (20). Detailed analysis of the two
sac systems in B. subtilis, which are induced by
different concentrations of sucrose (48), indicates that
SacY and SacT, which antiterminate transcription of the sacB
gene and sacPA operon, respectively, function in a manner
analogous to that of BglG (7, 8, 10, 17) by binding to
ribonucleic acid antiterminator sequences highly homologous to the
target site of BglG on the bgl transcript (7,
10). The homology between BglG and SacY is striking (above 35%
identity and 65% similarity [55]), especially in
light of the evolutionary distance between the two organisms. Moreover,
as we show here, SacY expressed in E. coli can replace BglG
in antiterminating transcription of the bgl operon. Thus,
the two proteins act identically and are therefore expected to be
regulated similarly. Indeed, as shown in this paper, like BglG, SacY
exists in vivo in two forms, phosphorylated and nonphosphorylated. The
ratio between the SacY forms depends on the presence of sucrose in the
growth medium, similarly to the dependence of the BglG phosphorylation state on -glucosides. Therefore, the same model which was deduced for the regulation of BglG by reversible phosphorylation, depending on
the availability of the inducing sugar, holds for SacY regulation. Moreover, our results suggest that the negative effect of SacX, a
putative PTS sucrose permease, on SacY activity (9, 17, 55)
is due to its involvement in SacY phosphorylation, similarly to the
negative effect of BglF, the PTS -glucoside permease, on the
activity of BglG (2, 3, 44). We reached this conclusion by
comparing the relative amounts of phosphorylated and nonphosphorylated SacY in strains that produce different levels of SacX. It was difficult
to accurately quantitate the amounts of SacX produced by these strains,
due to the unavailability of anti-SacX antibodies. However, one finding
that emerged from these experiments is that SacX was produced at lower
levels than SacY in all the strains (even when both proteins were
overproduced from the same plasmid). Thus, SacX, like BglF, acts in a
catalytic rather than a stoichiometric way. In light of the catalytic
mode of action of BglF (a ratio of less than 1:200 between BglF and
BglG was enough to phosphorylate 50 to 60% of the overproduced BglG
[3]), the observed phosphorylation of overproduced
SacY by SacX expressed from a chromosomal gene is expected. Our results
suggest that SacX is involved in SacY phosphorylation but do not rule
out the possibility that the effect of SacX on SacY phosphorylation is
indirect. It is hoped that future in vitro studies of SacY
phosphorylation will answer the question of whether SacX is the SacY
kinase.
Genetic studies have demonstrated that the general PTS proteins, enzyme
I and HPr, negatively regulate SacY activity, and it was suggested that
they exert this effect through SacX (17). Interestingly,
unlike BglG and SacY, the BglG-like proteins SacT and LevR are
positively regulated by the general PTS proteins and were shown to be
phosphorylated by them in vitro (7, 8, 51). Thus, the
general PTS proteins repress the activity of some antiterminators from
the bgl family and activate others. The ability of SacY to
antiterminate transcription of the bgl operon in E. coli at a level comparable to BglG (Table 1) rules out the
possibility that the E. coli general PTS proteins can negatively regulate SacY activity by phosphorylation. Nevertheless, the
possibility that the B. subtilis enzyme I and HPr exert a negative effect on SacY activity by directly phosphorylating it, in
addition to their indirect effect via SacX, cannot be ruled out.
Another question is whether the phosphorylation of BglG on a histidine
residue is a general theme in the bgl family of sensory systems, similarly to the phosphorylation of the response regulators of
the two-component systems on an aspartate. The sensitivity of SacY-P to
hydroxylamine and heat suggests that it is either a phosphoramidate or
an acyl phosphate. Based on the types of amino acids that are known to
form these types of bonds in proteins, phosphorylation is suggested to
occur either on a histidine or an aspartate. One approach to decide
between these possibilities is to determine the stability of SacY-P to
acid and base, as was done with BglG-P (6). While
phosphoramidates are stable in basic conditions but sensitive to acidic
conditions (22), acyl phosphates are labile at either pH
extreme (28). We tried to incubate extracts of cells
overproducing SacY in HCl and NaOH prior to their analysis, but the 2-D
gel technique turned out to be sensitive to such harsh treatments of
the analyzed proteins, and the samples precipitated and smeared in a
way that made the interpretation of the results difficult. However, the
appearance, after boiling, of an additional spot on the 2-D gel, which
migrates between the two forms of SacY, provides a hint about the type of amino acid which is phosphorylated in this protein. The most plausible explanation for this phenomenon is the occurrence of a
phosphotransfer, i.e., the phosphoryl is transferred to a nearby residue (not necessarily adjacent on the primary sequence) to form a
phosphoester which is heat stable. The magnitude of the mobility shift
caused by phosphorylation on an aspartate in isoelectric focusing is
smaller than that of any other shift which is caused by phosphorylation
of other amino acids (13, 16). Therefore, a phosphotransfer
from an aspartate to a serine, threonine, or tyrosine should not lead
to the appearance of a spot with intermediary migration behavior but,
rather, to a shift to the other direction, i.e., to a more acidic
position. Phosphotransfer from a histidine to the phosphoester-forming
residues will generate the observed shift, both in direction and in
magnitude. Thus, this result supports the notion that SacY is
phosphorylated on a histidine rather than an aspartate. Theoretically,
phosphorylation on a lysine or an arginine, though not discovered yet,
should yield the same result and cannot be ruled out. An alternative
explanation to this result is phosphorylation of SacY on two histidines
or aspartates, combined with a higher sensitivity of one of the two to
heat, due to a difference in their immediate surroundings. This
explanation is unfavorable because, contrary to what we have observed,
prolonged heating in this case should lead to a decrease in the
intensity of the intermediate spot.
| |
ACKNOWLEDGMENTS |
We gratefully acknowledge M. Baniash and O. Avni for their advice
and help with the 2-D gel technique. We especially acknowledge M. Banish for fruitful discussions. We warmly thank M. Steinmetz and S. Aymerich for their support, openness, and willingness to exchange
information. We acknowledge them also for the gift of plasmids pSL85
and pSL165ATG. We thank A. M. Crutz for the gift of
the anti-SacY antiserum. We thank G. Glaser, L. Sonenshein, R. Rudner,
and P. Stragier for advice on B. subtilis techniques and for
the gifts of plasmid pDG148 and strain IS58. We thank O. Pines for
critically reading the manuscript. Investigation of the ability of SacY
to act in E. coli was initiated when O.A.-C. was a
postdoctoral fellow in A. Wright's lab.
This research was supported by the Israel Science Foundation
administered by the Israel Academy of Sciences and Humanities.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Biology, The Hebrew University, Hadassah Medical School, POB 12272, Jerusalem 91120, Israel. Phone: 972 2 675 8460. Fax: 972 2 6784010. E-mail: amster{at}cc.huji.ac.il.
This work is dedicated to the memory of Michel Steinmetz.
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Abstract
Introduction
