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Guanosine-5′-triphosphate as the allosteric effector of fructose 1,6-diphosphatase in Rhodopseudomonaspalustris
BIOCHEMICAL
Vol. 39, No. 4,197O
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
GUANOSINE-5'- TRIPHOSPHATEAS THE ALLOSTERIC EFPECTOROF FRUCTOSE1,6- DIPHOSPHATASEIN RHODOPSEUDOMONAS PALUSTRIS C. S, Stachow and C. F. Springgate Department of Biology, Boston College, Chestnut Hill, Massachusetts, 02167~
Received April 6, 1970 SUMMARY;The inhibition of 300-fold purified fructose 1,6dlphosphatase from Rhodopseudomonas palustris by guanosine5'-triphosphate is described. Kinetic data illustrates that GTP inhibition is specific, allosterlc In nature and noncompetitive. Guanosine-5'-triphosphate was not utilized in the enzymatic reaction. Evidence presented suggests that GTP levels play an important role in regulation of the photosynthetic reductive carbon cycle In Rhodopseudomonas. Adenosine-5'-monophosphate to be an allosteric
(AMP) has been demonstrated
Inhibitor
(Taketa
and Pogell,
1963, 1965;
Underwood and Newsholme, 1965) of fructose
1,6-dlphosphatase
from a wide variety
Mukkada and Bell
(1969)
have reported
Acinetobacter
a fructose
Studies
oycle (Pedersen have provided
et. al., evidence
the light-dark is reported
diphosphatase
1966;
inhlbltion and partially
photoheterotroph
in regulating In this
of fructose
Rsp. palustris. 637
1968, 1969)
diphosphatase biosynthesis
communication 1,6-dlphosphatase
characterized
but AMP-
carbon reduction
Bassham et. al.,
that the fructose
transition.
(FDPase) of
by ATP and citrate
on the photosynthetic
plays a key role
allosterlc
However,
which is inhibited
Insensitive.
reaction
of organisms.
and
the by GTP
in the facultatlve
BIOCHEMICAL
Vol. 39, No. 4,197O
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALSANDMEIHODS: Approximately
300-fold
purified
from a.
palustris,
synthetic
medium (Cohen-Bazire
grown photoheterotrophically
and acetate
malate, disrupted operated
ammonium sulfate
buffer,
and streptomycin
column chromatography. will
be published
tion
was stable
free
of the following
Details
for
sulfate
Fructose
enzyme preparaat -150 and was
phosphofructokinase activity
by following
at 340 mu in the presence
buffer
6-phosphate
the rate
(pH 8.0) containing
1.0 ml. All reagents
1.0 mM FDP, 1,O mM
from Sigma Chemical Co, Uniformly purchased
2.pg
and 100 mM Trls-HCL
1.0 mM IXCT in a final
were analytical
from New England Nuclear
of NADP
of excess coupling
contained:
dehydrogenase
and
was deter-
NADP, 1.0 mM MnC12, 10 pg phosphoglucoisomerase, glucose
procedure
enzymes: NADPH oxldase,
1,6-diphosphatase
enzymes. The assay mixture
cell
precipitation,
of the purification
contaminating
mined spectrophotometrically
1.0
and DEAE-cellulose
two weeks when stored phosphatase,
were
by MnC12,
The resulting
elsewhere.
acid and alkaline
reduction
Cells
pH 7.4, containing
FDPase was purified
C-gamma adsorption-elution
aldolase.
1957). Glutamate,
(IYIT) by means of a Wench pressure
at 10,000 psi.
alumina
et, al.,
in
were used as carbon sources,
in 0.1 M Trls-HCL
mM dithlotheitol
FDPase was obtained
volume of
grade and purchased labelled
14C4TP was
Corp.
RESULTS AND DISCUSSION: Inhibition (figure
of fructose
1,6-diphosphatase
1.) was found to be specific
triphosphate
as the following
for guanosine-5'-
compounds tested 638
activtty at a concen-
BIOCHEMICAL
Vol. 39, No. 4,197O
Figure
1. Double reciprocal plots of velocity-versus FDP concentration at several GTP concentrations (fixed variable). Curve (A) minus GTPI (B) 1.0 mM GTP; (C) 1.25 mM GTP; (D) 1.5 mM GTP and (?I) 2.0 mM GTP. of 3.0 mM had no effect
tration
3',5'-AHP,
AMP,
cyclic
IMP,
GDP, GMP, cyclic
and NADP,
citrate,
of GTP used enzyme
in
our studies
activity;
CDP, CMP, UTP,
3*,5*-GMP,
plots
reduced
UDP,
ATP, ITP,
ADP,
IDP,
and oxidized
NAD
and pyrldoxal
phosphate.
had no effect
on the
coupling
versus
fructose
1,6-
1.)
several
inhibition
pattern.
does not
influence
8.3 x lo-5
resulted
From this
data
plant
from enzyme
It
Km of FDP which
results
fructose differ
(figure
variable)
the
M. These
of mammalian
1965) but
of velocity
concentration
of GTP (fixed
the
on FDPase
Levels
system,
diphosphate tions
CTP,
acetate
Reciprocal
for
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
are
similar
1,6-diphosphatase the (Scala,
competitive
at In
a non-competitive
can be seen that was calculated
GTP to be
to the
AMP inhibition
(Taketa
and Pogell,
inhibition
1969). GTP inhibition 639
concentra-
reported could
be
Vol. 39, No. 4,197O
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1 1 GTP mM
Figure
on fructose 2, Effect of guanoslne -j'-triphosphate Percent Inhibition of FDPase l,&diphosphatase activity. activity is plotted against varying GTP concentrations at several fixed variable concentrations of FDP. Curve (A) 1.0 mM FDPi (B) 0.4 mM FDP; (C) 0.1 mM FDP.
completely
reversed
concentrations Plots (figure
of percent
Inhibition
s&mold
or approximately series
simple mass action
at varying
the
theory.
The
in 505%inhibition
substrate
levels
of
ranged from
ten times Km. of straight
was plotted
against
coefficient,
indicating further
lines
was
n was calculated of the preoise
binding
obtained
when log
log GTP concentration
more than one GTP binding
The determination await
curves which demonstrate
M at 0.1 mM FDP to 12 x 10J, M at 1.0 mM FDP
7.4 x lOA
The Hill
versus GTP concentration
of GTP which resulted
enzymatic activity
V,-v/v
inhibition
does not follow
concentration
but not by substrate
as high as 20 x Km.
2.) yield
A
by dilution
studies. 640
(figure
3.).
to be 2.9 at 25O site
per enzyme molecule.
number of GTP sites
must
Vol. 39, No. 4,197O
BIOCHEMICAL
-l-
-2
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
/
:
-4
-3 LOG
Figure
-2 bTa
3. Hill plots of GTP Inhibition at various FDP concentrations. Plotted as log Vo-v/v versus log (GTP) where V, represents velocity in the absence of GTP and v represents velocity in the presence of GTP. Curve (A) 0.10 mM FDP; (B) 0.40 mM FDP; (C) 1.0 mM FDP.
To determine 14C labelled
GTP (5.0 mM containing
In the standard Subsequent
whether GTP was utilized reaction
identification
5'-triphosphate Laboratory demonstrated during
mixture
3
x lo6 DPM) was included
and Incubated
and percent
that
15
min.
of guanosine-
(System IV, Pabst
OR-101 and scintillation the Inhibitor,
for
recovery
by paper chromatography Circular
in the reaction,
counting
GTP was not hydrolyzed
the reaction. The regulatory
which is reflected figure
nature
of fructose
in the sigmoid
2, suggests that the levels
play an important
role
reductive
palustris.
to further
Studies
inhibition
mechanism are now in progress
data shown In
of GTP in the cells
in controlling
the photosynthetic
1,6-diphosphatase,
the flow
of carbon in
carbon cycle of Rhodopseudomonas characterize at this
641
this
laboratory.
control
Vol. 39, No. 4,197O
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RKFKRENCES Bassham, J.A., Kirk, M., and Jensen, R.G., Blochim. Biophys. Acta, a, 211 (1968). Bassham, J.A., and Krause, G.H., Biochim. Biophys. Acta, 189, 207 (1969). Cohen-Bazire, G., Slstrom, W.R., and Stander, R.Y., J. Cellular Camp, Physiol., &, 25 (1957). and Bell E.J., Biochem. Biophys. Res. Comm., Muklrada' '&'340 (1969j. Pedersen, T.A., Kirk, M., and Bassham, J.A., Bloohlmi Biophys. Acta, 112, 189 (1966). Scala, J., Ketner, G., and Jyung, W.H., Arch. Biochem, Blophys., Taketa K a, 111 (1969). and Pogell, B.M., Biochem. Biophys. Res. Comm., , '&, 229 (1963). Taketa, K,, and Pogell, B.M., J. Biol. Chem., 240, 651 (1965). Underwood, A.H., and Newsholme, E.A., Biochem. J,, s, 767 Underwood , (,'i"'9.9
and Newsholme, E.A., Biochem.J.,
642
s,
868 (1965).
Vol. 39, No. 4,197O
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
GUANOSINE-5'- TRIPHOSPHATEAS THE ALLOSTERIC EFPECTOROF FRUCTOSE1,6- DIPHOSPHATASEIN RHODOPSEUDOMONAS PALUSTRIS C. S, Stachow and C. F. Springgate Department of Biology, Boston College, Chestnut Hill, Massachusetts, 02167~
Received April 6, 1970 SUMMARY;The inhibition of 300-fold purified fructose 1,6dlphosphatase from Rhodopseudomonas palustris by guanosine5'-triphosphate is described. Kinetic data illustrates that GTP inhibition is specific, allosterlc In nature and noncompetitive. Guanosine-5'-triphosphate was not utilized in the enzymatic reaction. Evidence presented suggests that GTP levels play an important role in regulation of the photosynthetic reductive carbon cycle In Rhodopseudomonas. Adenosine-5'-monophosphate to be an allosteric
(AMP) has been demonstrated
Inhibitor
(Taketa
and Pogell,
1963, 1965;
Underwood and Newsholme, 1965) of fructose
1,6-dlphosphatase
from a wide variety
Mukkada and Bell
(1969)
have reported
Acinetobacter
a fructose
Studies
oycle (Pedersen have provided
et. al., evidence
the light-dark is reported
diphosphatase
1966;
inhlbltion and partially
photoheterotroph
in regulating In this
of fructose
Rsp. palustris. 637
1968, 1969)
diphosphatase biosynthesis
communication 1,6-dlphosphatase
characterized
but AMP-
carbon reduction
Bassham et. al.,
that the fructose
transition.
(FDPase) of
by ATP and citrate
on the photosynthetic
plays a key role
allosterlc
However,
which is inhibited
Insensitive.
reaction
of organisms.
and
the by GTP
in the facultatlve
BIOCHEMICAL
Vol. 39, No. 4,197O
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALSANDMEIHODS: Approximately
300-fold
purified
from a.
palustris,
synthetic
medium (Cohen-Bazire
grown photoheterotrophically
and acetate
malate, disrupted operated
ammonium sulfate
buffer,
and streptomycin
column chromatography. will
be published
tion
was stable
free
of the following
Details
for
sulfate
Fructose
enzyme preparaat -150 and was
phosphofructokinase activity
by following
at 340 mu in the presence
buffer
6-phosphate
the rate
(pH 8.0) containing
1.0 ml. All reagents
1.0 mM FDP, 1,O mM
from Sigma Chemical Co, Uniformly purchased
2.pg
and 100 mM Trls-HCL
1.0 mM IXCT in a final
were analytical
from New England Nuclear
of NADP
of excess coupling
contained:
dehydrogenase
and
was deter-
NADP, 1.0 mM MnC12, 10 pg phosphoglucoisomerase, glucose
procedure
enzymes: NADPH oxldase,
1,6-diphosphatase
enzymes. The assay mixture
cell
precipitation,
of the purification
contaminating
mined spectrophotometrically
1.0
and DEAE-cellulose
two weeks when stored phosphatase,
were
by MnC12,
The resulting
elsewhere.
acid and alkaline
reduction
Cells
pH 7.4, containing
FDPase was purified
C-gamma adsorption-elution
aldolase.
1957). Glutamate,
(IYIT) by means of a Wench pressure
at 10,000 psi.
alumina
et, al.,
in
were used as carbon sources,
in 0.1 M Trls-HCL
mM dithlotheitol
FDPase was obtained
volume of
grade and purchased labelled
14C4TP was
Corp.
RESULTS AND DISCUSSION: Inhibition (figure
of fructose
1,6-diphosphatase
1.) was found to be specific
triphosphate
as the following
for guanosine-5'-
compounds tested 638
activtty at a concen-
BIOCHEMICAL
Vol. 39, No. 4,197O
Figure
1. Double reciprocal plots of velocity-versus FDP concentration at several GTP concentrations (fixed variable). Curve (A) minus GTPI (B) 1.0 mM GTP; (C) 1.25 mM GTP; (D) 1.5 mM GTP and (?I) 2.0 mM GTP. of 3.0 mM had no effect
tration
3',5'-AHP,
AMP,
cyclic
IMP,
GDP, GMP, cyclic
and NADP,
citrate,
of GTP used enzyme
in
our studies
activity;
CDP, CMP, UTP,
3*,5*-GMP,
plots
reduced
UDP,
ATP, ITP,
ADP,
IDP,
and oxidized
NAD
and pyrldoxal
phosphate.
had no effect
on the
coupling
versus
fructose
1,6-
1.)
several
inhibition
pattern.
does not
influence
8.3 x lo-5
resulted
From this
data
plant
from enzyme
It
Km of FDP which
results
fructose differ
(figure
variable)
the
M. These
of mammalian
1965) but
of velocity
concentration
of GTP (fixed
the
on FDPase
Levels
system,
diphosphate tions
CTP,
acetate
Reciprocal
for
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
are
similar
1,6-diphosphatase the (Scala,
competitive
at In
a non-competitive
can be seen that was calculated
GTP to be
to the
AMP inhibition
(Taketa
and Pogell,
inhibition
1969). GTP inhibition 639
concentra-
reported could
be
Vol. 39, No. 4,197O
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1 1 GTP mM
Figure
on fructose 2, Effect of guanoslne -j'-triphosphate Percent Inhibition of FDPase l,&diphosphatase activity. activity is plotted against varying GTP concentrations at several fixed variable concentrations of FDP. Curve (A) 1.0 mM FDPi (B) 0.4 mM FDP; (C) 0.1 mM FDP.
completely
reversed
concentrations Plots (figure
of percent
Inhibition
s&mold
or approximately series
simple mass action
at varying
the
theory.
The
in 505%inhibition
substrate
levels
of
ranged from
ten times Km. of straight
was plotted
against
coefficient,
indicating further
lines
was
n was calculated of the preoise
binding
obtained
when log
log GTP concentration
more than one GTP binding
The determination await
curves which demonstrate
M at 0.1 mM FDP to 12 x 10J, M at 1.0 mM FDP
7.4 x lOA
The Hill
versus GTP concentration
of GTP which resulted
enzymatic activity
V,-v/v
inhibition
does not follow
concentration
but not by substrate
as high as 20 x Km.
2.) yield
A
by dilution
studies. 640
(figure
3.).
to be 2.9 at 25O site
per enzyme molecule.
number of GTP sites
must
Vol. 39, No. 4,197O
BIOCHEMICAL
-l-
-2
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
/
:
-4
-3 LOG
Figure
-2 bTa
3. Hill plots of GTP Inhibition at various FDP concentrations. Plotted as log Vo-v/v versus log (GTP) where V, represents velocity in the absence of GTP and v represents velocity in the presence of GTP. Curve (A) 0.10 mM FDP; (B) 0.40 mM FDP; (C) 1.0 mM FDP.
To determine 14C labelled
GTP (5.0 mM containing
In the standard Subsequent
whether GTP was utilized reaction
identification
5'-triphosphate Laboratory demonstrated during
mixture
3
x lo6 DPM) was included
and Incubated
and percent
that
15
min.
of guanosine-
(System IV, Pabst
OR-101 and scintillation the Inhibitor,
for
recovery
by paper chromatography Circular
in the reaction,
counting
GTP was not hydrolyzed
the reaction. The regulatory
which is reflected figure
nature
of fructose
in the sigmoid
2, suggests that the levels
play an important
role
reductive
palustris.
to further
Studies
inhibition
mechanism are now in progress
data shown In
of GTP in the cells
in controlling
the photosynthetic
1,6-diphosphatase,
the flow
of carbon in
carbon cycle of Rhodopseudomonas characterize at this
641
this
laboratory.
control
Vol. 39, No. 4,197O
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RKFKRENCES Bassham, J.A., Kirk, M., and Jensen, R.G., Blochim. Biophys. Acta, a, 211 (1968). Bassham, J.A., and Krause, G.H., Biochim. Biophys. Acta, 189, 207 (1969). Cohen-Bazire, G., Slstrom, W.R., and Stander, R.Y., J. Cellular Camp, Physiol., &, 25 (1957). and Bell E.J., Biochem. Biophys. Res. Comm., Muklrada' '&'340 (1969j. Pedersen, T.A., Kirk, M., and Bassham, J.A., Bloohlmi Biophys. Acta, 112, 189 (1966). Scala, J., Ketner, G., and Jyung, W.H., Arch. Biochem, Blophys., Taketa K a, 111 (1969). and Pogell, B.M., Biochem. Biophys. Res. Comm., , '&, 229 (1963). Taketa, K,, and Pogell, B.M., J. Biol. Chem., 240, 651 (1965). Underwood, A.H., and Newsholme, E.A., Biochem. J,, s, 767 Underwood , (,'i"'9.9
and Newsholme, E.A., Biochem.J.,
642
s,
868 (1965).