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fructose-2,6-bisphosphatase cycle
Vol.
131,
No. 2, 1985
September
16,
8lOCHEMlCAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1985
899-904
Pages
QUASI-STATIONARY CONCENTRATIONS OF FRUCTOSE-2,6-BISPHOSPHATE IN THE PHOSPHOFRUCTOKINASE-2/FRUCTOSE-2,6-BISPHOSPHATASE CYCLE Matthias
Kretschmer, Institute
Received
August
Wolfgang
Schellenberger
and Eberhard
Hofmann
of Biochemistry, Karl-Marx-University, Leipzig, German Democratic Republic
5, 1985
of phosphofructokinase-2 and fructose-2,6SUMMARY: The cooperation bisphosphatase is investigated. Experimentally derived rate laws of the kinase and bisphosphatase activities introduced into the respective differential equations permitted to describe the time evolution of fructoseThe two enzyme activities were 2,6-bisphosphate to quasi-stationary levels. The quasi-stationary levels of found to exert strong temperature dependence. are independent on temperature. 0 1985 fructose-2,6-bisphosphate, however, Academic
Press,
Inc.
The tissue dynamic
levels
of fructose-2,6-bisphosphate
characteristics
bisphosphatase
of the
cycle
same enzyme protein
and can be active
description
cycle
of the
individual
requires
measurements
have been derived.
These
cooperation
of the cycle
CAMP dependent activities the cycle Owing
protein
the effect
(2,3).
knowledge
and of their laws
taken
enzymes. kinases
PFK-2 and FBPase-2
detailed
rate
were
(1,Z).
simultaneously
enzyme activities
From kinetic
depend
on the
phosphofructokinase-2/fructose-2,6-
(PFK-2/FBPase-2)
of this
(F-2,6-P2)
for
Because
exerts
it
(4)
the
known
reciprocal
of phosphorylation
kinetic
behavior
cooperation.
for is
on the
A quantitative
of the
the PFK-2
as a basis
reside
and for
FBPase-2
investigation that
control
of the
phosphorylation over
on the quasi-stationary
by
the two enzyme dynamics
of
was investigated. to a strong
dependence
appeared
interesting
to study
stationary
levels
of F-2,6-P2
of the two activities whether
in the PFK-2/FBPase-2 MATERIALS
PFK-2/FBPase-2 Wistar rats after
the temperature
on temperature, influences
it
the quasi-
cycle.
AND METHODS
was prepared from liver starvation for 72 hours
899
according to (9,lO) using and 48 hours of refeeding.
male The
0006-291X/85 $1.50 Copyright 0 I985 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol.
131,
No. 2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
purified enzyme was phosphorylated as described in (5). The pure C subunit of CAMP dependent protein kinase type II from beef heart was a gift from Prof. F. Hofmann, Homburg, FRG. All experiments were carried out in 100 mM imidazole/HCl, pH 6.6, 20 mM KH PO /K HP0 , 10 mM MgCl , 10 mM mercaptoethanol and 100 mM KC1 ?Buffe? A)!The PFK-2 an 4 FBPase-2 activities were assayed according to (10,ll) and (7), respectively. For the investigation of the heat stability 0.25 mU of native PFK-2 (corresponding to 0.11 mU FBPase-2 at 30 "C) were incubated for 45 minutes in 100 pl of Buffer A at various temperatures. Then temperature was adjusted to 30 'C and the remaining activities were determined with 3 mM ATP and 2 mM fructose-6phosphate (F-6-P) for PFK-2 and 20 pM F-2,6-P for FBPase-2. The same substrate concentrations were used for the de z ermination of PFK-2 and FBPase2 activities at different temperatures. Aliquots of the reaction mixtures were removed after 5, 10 and 15 minutes and treated as described in (11). The dynamics of the PFK-2/FBPase-2 cycle was investigated by following the time evolution of the F-2.6-P concentration to quasi-stationary values. For this the native and phosphory 1ated enzyme was incubated in 100 pl with the indicated concentrations of ATP and F-6-P or ATP and F-2,6-P2, respectively. In all experiments a protein concentration was applied referring to 5 mu/ml PFK-2 (30 "C). The F-2,6-P2 concentrations obtained from these experiments were compared with the solution of the respective balance equations by means of nonlinear regression analysis. The expression for the PFK-2 activity in the differential equations was taken from (4). The kinetics of FBPase-2 was reinvestigated under the present experimental conditions (data not shown). It can be described by the following equation : [F-2,6-P2] 1 V (1) 'FBPase-2 = FBPase-2. 1+[F-6-P],K . Ks+[F-2,6-P2] i with
K = 0.51 pM and Ki = 25 p. S
RESULTS AND DISCUSSION Fig.
1 presents
temperature
the results
of the experiments
dependence of PFK-2 and FBPase-2.
found stable
up to a temperature
minutes
1C and D). Above this
(Fig
of PFK-2 and FBPase-2 occurred. two activities
were observed.
temperature
No differences Fig.
The two activities
"C. The Arrhenius
plots
are linear
an incubation fast
nearly
between
of the
the temperature
influence
fivefold
of 45
inactivation
in the heat stability
A strong
were
period
irreversible
1A and B demonstrate
increase
and
The two enzyme activities
of 40 "C within
dependence of the two enzyme activities. was found.
about heat stability
of temperature
between 25 "C and 35
10 'C and 40 'C (insets
of Fig.
and B). The time course
of the metabolites
PFK-2/FBPase-2
is governed
W-2,6-P21/dt
= vpFK-2 - VFBPase-2
d[ATP]/dt
= - vPFKm2
in a closed
by two coupled
differential
reaction
chamber containing
equations
:
1A
Vol.
131,
No. 2, 1985
Fig.
BIOCHEMICAL
1 : Effect
AND
of temperature
BIOPHYSICAL
on the
RESEARCH
native
COMMUNICATIONS
enzyme
A: PFK-2 ( 3mM ATP, 2mM F-6-P, Buffer A ) B : FBPase-2 ( 20 pM F-2,6-P2 , Buffer A ) C and D : Relative activity remaining after 45 minutes of incubation in Buffer A at various temperatures
denote
where “PFK-2 and "FBPase-2 respectively.
Integration
concentrations reactants closed
effective into
quasi-stationarity
weakly
Km value
account
of the
that
competitively
to ATP (2,4).
Experiments
stationary system
with
are
concentrations was started
Quasi-stationarity the investigated
kinase
with
for
of F-2,6-P2 range.
continuous
can be attained
for
is
not
The PFK-2/FBPase-2 901
must
on the
initial
the
evolution
time
identical
altered could
of Fquasi-
independently and ATP,
the
be taken
PFK-2
F-2,6-P2
system
of F-2,6-P2
ADP inhibits
attained
of the
sufficiently it
2A and B. Nearly
significantly
of ATP in the because
exceeds
enzyme demonstrating
and ATP or with
of the other
level
ATP depends
because
were
dependent
decrease
ATP. For calculation
Km value
of F-2,6-P2
time
the concentrations
as the ATP level
shown in Fig.
F-6-P
yields
The quasi-stationary
nucleotides
the native
concentrations
of the
enzymes.
the effective
of the adenine
and (3)
of F-2,6-P2
on ATP as long
concentration
2,6-P2
Despite
of the two cycle only
(2)
of PFK-2 and FBPase-2,
and ATP from which
2
may be calculated.
cooperation depends
of equations
of F-2,6-P
system
the activities
whether
the
respectively.
by temperature
satisfactorily
in be
Vol.
131,
No.
2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
100 -I
@
50
Fig.
50
100
Time
Imln)
A :
= 2360 pM 27 “C
;;I;-;;~
= =
50 P’ 100 pM 50 PM
=
100
=
B : [F-2,6-P2100 [F-2,6-P210
32
37
“C
by equations (1)
were
applied.
used as parameters shown
in Table
dependence the
(2)
in
1 are
28 f 2 71 f 3 30+2 68+4
0 I
and (3)
are
temperature
Quasi-stationary 2/FBPase-2 native
are
(Fig.
enzyme
Table
(Fig.
1 : V,,,
3).
values
'PFK-2 bU/ml ) VFBPasem2 (mu/ml) VPFK-2'VFBPase-2
given
the
1).
The ratio
hence,
the
(4)
and in
of PFK-2 and FBPase-2
The computed
with
in
shape
were
maximum activities
of the
temperature
of PFK-2/FBPase-2
quasi-stationary
is
nearly
concentrations
independent.
F-2,6-P2 two orders
parameters
procedure.
in good agreement
same at 27, 32 and 37 "C and,
of F-2,6-P2
when the
pM pM
the experiments
maximum activities
the fitting
of PFK-2/FBPase-2
[F-2,6-P21stat
;
@
Only
to quasi-stationary ‘C
ATP did not drop below 2100 t&i during
equation
Cm1n)
2 : Time evolution of F-2,6-P2 concentrations values with the native enzyme
[ATPI0
described
100
Time
concentrations of magnitude
They also
obtained
obtained lower
do not
than
depend
with those
32 "C 4.30 f 0.59 1.63 + 0.38 2.6
902
approached
with
on the temperature.
from data shown in Fig.
27 "C 1.70 f 0.53 0.64 f 0.26 2.7
phosphorylated
2 (native
enzyme)
37 OC 7.07 f 1.04 2.86 * 0.49 2.5
PFKthe
Vol.
131,
No. 2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
L 50
100 Time
Fig.
150
imInI
3 : Time evolution of F-2,6-P concentrations values with the phosphory 1 ated enzyme
[ATPI
= 2360 pM
[F-2,6-P210 [F-2,6-P210
= =
27 "C
32 "C
37 'C
it
is
parameters
given
0.2 f 0.1 pM 0.5 f 0.2 pl
sufficient
description
the
ratio
mainly is
between
(4)
the
independent increments characteristic
values
by the FBPase-2
defined(Table with
although
the native
is
and (3)
with
possible
The maximum
the
enzyme a by switching
of the curves
and phosphorylated
concentrations
temperature.
Table
(2)
For the phosphorylated cycle
activity.
the individual
times
equations
The shape
only.
the experiments
in Fig.
3 is
of the PFK-2
activity
2).
quasi-stationary
with
(1).
of the F-6-P/F-2,6-P2
The experiments that
to apply
and in equation
the Vm,,
determined
not well
possible
still
in
[F-2,6-P21stat
50 pM 100 PM
ATP did not drop below 2200 pM during
Interestingly,
to quasi-stationary
of F-2,6-P2
are
enzyme activities
However,
in which
PFK-2/FBPase-2
temperature
quasi-stationary
temperature
exhibit influences
states
27 "C 0.34 f 0.12 1.88 + 0.31 0.18
32 'C 0.65 f 0.46 2.82 f 0.54 0.23
903
strong the
are approached.
2 : Vm,, values obtained from data shown in Fig. (phosphorylated enzyme)
'PFK-2 W/ml) VFDpases2 (mu/ml> VPFK-2'VFBPase-2
show
3
37 "C 1.20 + 0.64 4.62 f 0.64 0.26
The
Vol.
131,
rate
No. 2, 1985
laws
for
the
respectively, 2/FBPase-2
out
low
enzyme are
metabolite
reported
obtained
with
hepatic
levels
reported
native
for
in
(4)
RESEARCH
COMMUNICATIONS
and in equation
a quantitative
which
are
of these cycle
for
F-2,6-P2
(l),
description
for
glucagon
fed rats
of the PFK-
are
rather This
metabolites
on the
cycle
quasi-stationary
of further
high
by the
concentrations
hepatocytes
ando(-glycerophosphate of the
adjusted
the cellular
treated
(12,13).
to be effecters
subject
with
PFK-2/FBPase-2
known
is
concentrations
in good agreement
citrate
of phosphoenolpyruvate,
2/FBPase-2
given
sufficient
quasi-stationary
values
action
BIOPHYSICAL
cycle.
phosphorylated
system,
AND
PFK-2 and FBPase-2
turned
The very
of this
BIOCHEMICAL
(12.13). compared
The with
may be due to the absence in the enzymes states
in vitro (2,4,5,7).
of the PFK-
investigation.
REFERENCES 1. Van Schaftingen, E., and Hers, H.-G. (1984) in : Advances in Cyclic Nucleotide and Protein Phosphorylation Research, Vol. 17 (eds. Greengard, P. et al.,) pp 343-349, Raven Press, New York 2. Pilkis, S.J., Regen, D.M., Stewart, B.H., Chrisman, T., Pilkis, J., Kountz, P., Pate, T., MC Grane, M., El-Maghrabi, M.R., and Claus, T.H. (1984) in: Enzyme Regulation by reversible Phosphorylation, (ed. Cohen, P.) pp 95-122, Elsevier Science Publishers B.V. 3. Pilkis, S.J., Regen, D.M., Stewart, B.H., Pilkis, J., M.R. Pate, T.M., and El-Maghrabi, (1984) J. Biol. Chem. 259, 949-958 4. Kretschmer, M., and Hofmann, E. (1984) Biochem. Biophys. Res. Commun. 124, 793-796 5. Van Schaftingen, E., Davies, D.R., and Hers, H.-G. (1981) Biochem. Biophys. Res. Commun. 103, 362-368 6. El-Maghrabi, M.R., Claus, T.H., Pilkis, J., and Pilkis, S.J. (1982) Proc. Natl. Acad. Sci. USA 79, 315-319 7. Van Schaftingen, E., Davies, D.R., and Hers, H.-G. (1982) Eur. J. Biochem. 124, 143-149 8. El-Maghrabi, M.R., Claus, T.H., Pilkis, J., Fox, E., and Pilkis, S.J. (1982) J. Biol. Chem. 257, 7603-7607 9. Sakakibara, R., Kitajima, S., and Uyeda, K. (1984) J. Biol. Chem. 259, 41-46 10. Van Schaftingen, E., and Hers, H.-G. (1981) Biochem. Biophys. Res. Commun. 101, 1078-1084 11. Van Schaftingen, E., Lederer, B., Bartrons, R., and Hers, H.-G. (1982) Eur. J. Biochem. 129, 191-195 12. Hue, L., Blackmore, P.F., Shikama, H., Robinson-Steiner, A., and Exton, J.H. (1982) J. Biol. Chem. 257, 4308-4313 13. Bartrons, R., Hue, L., Van Schaftingen, E., and Hers, H.-G. (1983) Biochem. J. 214, 829-837
904
the
The
131,
No. 2, 1985
September
16,
8lOCHEMlCAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1985
899-904
Pages
QUASI-STATIONARY CONCENTRATIONS OF FRUCTOSE-2,6-BISPHOSPHATE IN THE PHOSPHOFRUCTOKINASE-2/FRUCTOSE-2,6-BISPHOSPHATASE CYCLE Matthias
Kretschmer, Institute
Received
August
Wolfgang
Schellenberger
and Eberhard
Hofmann
of Biochemistry, Karl-Marx-University, Leipzig, German Democratic Republic
5, 1985
of phosphofructokinase-2 and fructose-2,6SUMMARY: The cooperation bisphosphatase is investigated. Experimentally derived rate laws of the kinase and bisphosphatase activities introduced into the respective differential equations permitted to describe the time evolution of fructoseThe two enzyme activities were 2,6-bisphosphate to quasi-stationary levels. The quasi-stationary levels of found to exert strong temperature dependence. are independent on temperature. 0 1985 fructose-2,6-bisphosphate, however, Academic
Press,
Inc.
The tissue dynamic
levels
of fructose-2,6-bisphosphate
characteristics
bisphosphatase
of the
cycle
same enzyme protein
and can be active
description
cycle
of the
individual
requires
measurements
have been derived.
These
cooperation
of the cycle
CAMP dependent activities the cycle Owing
protein
the effect
(2,3).
knowledge
and of their laws
taken
enzymes. kinases
PFK-2 and FBPase-2
detailed
rate
were
(1,Z).
simultaneously
enzyme activities
From kinetic
depend
on the
phosphofructokinase-2/fructose-2,6-
(PFK-2/FBPase-2)
of this
(F-2,6-P2)
for
Because
exerts
it
(4)
the
known
reciprocal
of phosphorylation
kinetic
behavior
cooperation.
for is
on the
A quantitative
of the
the PFK-2
as a basis
reside
and for
FBPase-2
investigation that
control
of the
phosphorylation over
on the quasi-stationary
by
the two enzyme dynamics
of
was investigated. to a strong
dependence
appeared
interesting
to study
stationary
levels
of F-2,6-P2
of the two activities whether
in the PFK-2/FBPase-2 MATERIALS
PFK-2/FBPase-2 Wistar rats after
the temperature
on temperature, influences
it
the quasi-
cycle.
AND METHODS
was prepared from liver starvation for 72 hours
899
according to (9,lO) using and 48 hours of refeeding.
male The
0006-291X/85 $1.50 Copyright 0 I985 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol.
131,
No. 2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
purified enzyme was phosphorylated as described in (5). The pure C subunit of CAMP dependent protein kinase type II from beef heart was a gift from Prof. F. Hofmann, Homburg, FRG. All experiments were carried out in 100 mM imidazole/HCl, pH 6.6, 20 mM KH PO /K HP0 , 10 mM MgCl , 10 mM mercaptoethanol and 100 mM KC1 ?Buffe? A)!The PFK-2 an 4 FBPase-2 activities were assayed according to (10,ll) and (7), respectively. For the investigation of the heat stability 0.25 mU of native PFK-2 (corresponding to 0.11 mU FBPase-2 at 30 "C) were incubated for 45 minutes in 100 pl of Buffer A at various temperatures. Then temperature was adjusted to 30 'C and the remaining activities were determined with 3 mM ATP and 2 mM fructose-6phosphate (F-6-P) for PFK-2 and 20 pM F-2,6-P for FBPase-2. The same substrate concentrations were used for the de z ermination of PFK-2 and FBPase2 activities at different temperatures. Aliquots of the reaction mixtures were removed after 5, 10 and 15 minutes and treated as described in (11). The dynamics of the PFK-2/FBPase-2 cycle was investigated by following the time evolution of the F-2.6-P concentration to quasi-stationary values. For this the native and phosphory 1ated enzyme was incubated in 100 pl with the indicated concentrations of ATP and F-6-P or ATP and F-2,6-P2, respectively. In all experiments a protein concentration was applied referring to 5 mu/ml PFK-2 (30 "C). The F-2,6-P2 concentrations obtained from these experiments were compared with the solution of the respective balance equations by means of nonlinear regression analysis. The expression for the PFK-2 activity in the differential equations was taken from (4). The kinetics of FBPase-2 was reinvestigated under the present experimental conditions (data not shown). It can be described by the following equation : [F-2,6-P2] 1 V (1) 'FBPase-2 = FBPase-2. 1+[F-6-P],K . Ks+[F-2,6-P2] i with
K = 0.51 pM and Ki = 25 p. S
RESULTS AND DISCUSSION Fig.
1 presents
temperature
the results
of the experiments
dependence of PFK-2 and FBPase-2.
found stable
up to a temperature
minutes
1C and D). Above this
(Fig
of PFK-2 and FBPase-2 occurred. two activities
were observed.
temperature
No differences Fig.
The two activities
"C. The Arrhenius
plots
are linear
an incubation fast
nearly
between
of the
the temperature
influence
fivefold
of 45
inactivation
in the heat stability
A strong
were
period
irreversible
1A and B demonstrate
increase
and
The two enzyme activities
of 40 "C within
dependence of the two enzyme activities. was found.
about heat stability
of temperature
between 25 "C and 35
10 'C and 40 'C (insets
of Fig.
and B). The time course
of the metabolites
PFK-2/FBPase-2
is governed
W-2,6-P21/dt
= vpFK-2 - VFBPase-2
d[ATP]/dt
= - vPFKm2
in a closed
by two coupled
differential
reaction
chamber containing
equations
:
1A
Vol.
131,
No. 2, 1985
Fig.
BIOCHEMICAL
1 : Effect
AND
of temperature
BIOPHYSICAL
on the
RESEARCH
native
COMMUNICATIONS
enzyme
A: PFK-2 ( 3mM ATP, 2mM F-6-P, Buffer A ) B : FBPase-2 ( 20 pM F-2,6-P2 , Buffer A ) C and D : Relative activity remaining after 45 minutes of incubation in Buffer A at various temperatures
denote
where “PFK-2 and "FBPase-2 respectively.
Integration
concentrations reactants closed
effective into
quasi-stationarity
weakly
Km value
account
of the
that
competitively
to ATP (2,4).
Experiments
stationary system
with
are
concentrations was started
Quasi-stationarity the investigated
kinase
with
for
of F-2,6-P2 range.
continuous
can be attained
for
is
not
The PFK-2/FBPase-2 901
must
on the
initial
the
evolution
time
identical
altered could
of Fquasi-
independently and ATP,
the
be taken
PFK-2
F-2,6-P2
system
of F-2,6-P2
ADP inhibits
attained
of the
sufficiently it
2A and B. Nearly
significantly
of ATP in the because
exceeds
enzyme demonstrating
and ATP or with
of the other
level
ATP depends
because
were
dependent
decrease
ATP. For calculation
Km value
of F-2,6-P2
time
the concentrations
as the ATP level
shown in Fig.
F-6-P
yields
The quasi-stationary
nucleotides
the native
concentrations
of the
enzymes.
the effective
of the adenine
and (3)
of F-2,6-P2
on ATP as long
concentration
2,6-P2
Despite
of the two cycle only
(2)
of PFK-2 and FBPase-2,
and ATP from which
2
may be calculated.
cooperation depends
of equations
of F-2,6-P
system
the activities
whether
the
respectively.
by temperature
satisfactorily
in be
Vol.
131,
No.
2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
100 -I
@
50
Fig.
50
100
Time
Imln)
A :
= 2360 pM 27 “C
;;I;-;;~
= =
50 P’ 100 pM 50 PM
=
100
=
B : [F-2,6-P2100 [F-2,6-P210
32
37
“C
by equations (1)
were
applied.
used as parameters shown
in Table
dependence the
(2)
in
1 are
28 f 2 71 f 3 30+2 68+4
0 I
and (3)
are
temperature
Quasi-stationary 2/FBPase-2 native
are
(Fig.
enzyme
Table
(Fig.
1 : V,,,
3).
values
'PFK-2 bU/ml ) VFBPasem2 (mu/ml) VPFK-2'VFBPase-2
given
the
1).
The ratio
hence,
the
(4)
and in
of PFK-2 and FBPase-2
The computed
with
in
shape
were
maximum activities
of the
temperature
of PFK-2/FBPase-2
quasi-stationary
is
nearly
concentrations
independent.
F-2,6-P2 two orders
parameters
procedure.
in good agreement
same at 27, 32 and 37 "C and,
of F-2,6-P2
when the
pM pM
the experiments
maximum activities
the fitting
of PFK-2/FBPase-2
[F-2,6-P21stat
;
@
Only
to quasi-stationary ‘C
ATP did not drop below 2100 t&i during
equation
Cm1n)
2 : Time evolution of F-2,6-P2 concentrations values with the native enzyme
[ATPI0
described
100
Time
concentrations of magnitude
They also
obtained
obtained lower
do not
than
depend
with those
32 "C 4.30 f 0.59 1.63 + 0.38 2.6
902
approached
with
on the temperature.
from data shown in Fig.
27 "C 1.70 f 0.53 0.64 f 0.26 2.7
phosphorylated
2 (native
enzyme)
37 OC 7.07 f 1.04 2.86 * 0.49 2.5
PFKthe
Vol.
131,
No. 2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
L 50
100 Time
Fig.
150
imInI
3 : Time evolution of F-2,6-P concentrations values with the phosphory 1 ated enzyme
[ATPI
= 2360 pM
[F-2,6-P210 [F-2,6-P210
= =
27 "C
32 "C
37 'C
it
is
parameters
given
0.2 f 0.1 pM 0.5 f 0.2 pl
sufficient
description
the
ratio
mainly is
between
(4)
the
independent increments characteristic
values
by the FBPase-2
defined(Table with
although
the native
is
and (3)
with
possible
The maximum
the
enzyme a by switching
of the curves
and phosphorylated
concentrations
temperature.
Table
(2)
For the phosphorylated cycle
activity.
the individual
times
equations
The shape
only.
the experiments
in Fig.
3 is
of the PFK-2
activity
2).
quasi-stationary
with
(1).
of the F-6-P/F-2,6-P2
The experiments that
to apply
and in equation
the Vm,,
determined
not well
possible
still
in
[F-2,6-P21stat
50 pM 100 PM
ATP did not drop below 2200 pM during
Interestingly,
to quasi-stationary
of F-2,6-P2
are
enzyme activities
However,
in which
PFK-2/FBPase-2
temperature
quasi-stationary
temperature
exhibit influences
states
27 "C 0.34 f 0.12 1.88 + 0.31 0.18
32 'C 0.65 f 0.46 2.82 f 0.54 0.23
903
strong the
are approached.
2 : Vm,, values obtained from data shown in Fig. (phosphorylated enzyme)
'PFK-2 W/ml) VFDpases2 (mu/ml> VPFK-2'VFBPase-2
show
3
37 "C 1.20 + 0.64 4.62 f 0.64 0.26
The
Vol.
131,
rate
No. 2, 1985
laws
for
the
respectively, 2/FBPase-2
out
low
enzyme are
metabolite
reported
obtained
with
hepatic
levels
reported
native
for
in
(4)
RESEARCH
COMMUNICATIONS
and in equation
a quantitative
which
are
of these cycle
for
F-2,6-P2
(l),
description
for
glucagon
fed rats
of the PFK-
are
rather This
metabolites
on the
cycle
quasi-stationary
of further
high
by the
concentrations
hepatocytes
ando(-glycerophosphate of the
adjusted
the cellular
treated
(12,13).
to be effecters
subject
with
PFK-2/FBPase-2
known
is
concentrations
in good agreement
citrate
of phosphoenolpyruvate,
2/FBPase-2
given
sufficient
quasi-stationary
values
action
BIOPHYSICAL
cycle.
phosphorylated
system,
AND
PFK-2 and FBPase-2
turned
The very
of this
BIOCHEMICAL
(12.13). compared
The with
may be due to the absence in the enzymes states
in vitro (2,4,5,7).
of the PFK-
investigation.
REFERENCES 1. Van Schaftingen, E., and Hers, H.-G. (1984) in : Advances in Cyclic Nucleotide and Protein Phosphorylation Research, Vol. 17 (eds. Greengard, P. et al.,) pp 343-349, Raven Press, New York 2. Pilkis, S.J., Regen, D.M., Stewart, B.H., Chrisman, T., Pilkis, J., Kountz, P., Pate, T., MC Grane, M., El-Maghrabi, M.R., and Claus, T.H. (1984) in: Enzyme Regulation by reversible Phosphorylation, (ed. Cohen, P.) pp 95-122, Elsevier Science Publishers B.V. 3. Pilkis, S.J., Regen, D.M., Stewart, B.H., Pilkis, J., M.R. Pate, T.M., and El-Maghrabi, (1984) J. Biol. Chem. 259, 949-958 4. Kretschmer, M., and Hofmann, E. (1984) Biochem. Biophys. Res. Commun. 124, 793-796 5. Van Schaftingen, E., Davies, D.R., and Hers, H.-G. (1981) Biochem. Biophys. Res. Commun. 103, 362-368 6. El-Maghrabi, M.R., Claus, T.H., Pilkis, J., and Pilkis, S.J. (1982) Proc. Natl. Acad. Sci. USA 79, 315-319 7. Van Schaftingen, E., Davies, D.R., and Hers, H.-G. (1982) Eur. J. Biochem. 124, 143-149 8. El-Maghrabi, M.R., Claus, T.H., Pilkis, J., Fox, E., and Pilkis, S.J. (1982) J. Biol. Chem. 257, 7603-7607 9. Sakakibara, R., Kitajima, S., and Uyeda, K. (1984) J. Biol. Chem. 259, 41-46 10. Van Schaftingen, E., and Hers, H.-G. (1981) Biochem. Biophys. Res. Commun. 101, 1078-1084 11. Van Schaftingen, E., Lederer, B., Bartrons, R., and Hers, H.-G. (1982) Eur. J. Biochem. 129, 191-195 12. Hue, L., Blackmore, P.F., Shikama, H., Robinson-Steiner, A., and Exton, J.H. (1982) J. Biol. Chem. 257, 4308-4313 13. Bartrons, R., Hue, L., Van Schaftingen, E., and Hers, H.-G. (1983) Biochem. J. 214, 829-837
904
the
The