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Binding of nucleotides AMP and ATP to yeast phosphofructokinase: Evidence for distinct catalytic and regulatory subunits
Vol. 80, No. 3, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
Pages
February 14, 1978
646-652
BINDING OF NUCLEOTIDES AMP AND ATP TO YEAST PHOSPHOFRUCTOKINASE:EVIDENCE DISTINCT
Michel
LAURENT, Alain
CATALYTIC
FOR
AND REGULATORY SUBUNITS
F. CHAFFOTTE, Jean-Pierre TENU, Colette FranGois J. SEYDOUX.
ROUCOUS and
Laboratoire d'Enzymologie Physico-Chimique et Moleculaire Universitk de Paris-Sud, 91405, Orsay-France.
Received
October
27,
1977
SUMMARY The binding of ATP to yeast phosphofructokinase, as monitored by flow dialysis, is heterogeneous and is adequately described by assuming two independent classes of three binding sites each per enzyme molecule. Under similar conditions, theming of 5'AMP is homogeneous and a binding stoichiometry of three S'AMP molecules per enzyme molecule is evaluated. Displacement experiments show that only the ATP molecules bound to the first class of three tight binding sites are displaced by an excess of 5'AMP. Thus, these tight ATP binding sites can be identified as "regulatory sites" in agreement with kinetic data. Furthermore, molecular weight determinations and electrophoresis results are consistent with an heterologous a 6, structure of the enzyme oligomer. Therefore the present binding data sugges ? that yeast phosphofructokinase is constituted by three "catalytic" and three "regulatory" subunits. .
INTRODUCTION Phosphofructokinase pathway, tic
shows a great
organisms.
number
In the
of subunits
now well
of two types
weight
(4).
are
easily
degradation features
These
variability case of yeast that
the
two types
in the presence of the yeast
a matter
native
form
are
relative
of specific
enzyme are
not unique
646
in their
immunologically (5).
the exact
(1,2,3),
enzyme contains slightly
it
is
an equal molecular
distinct
susceptibility substrates
0006-291X/78/0803-0646$01,00/0 Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
of this
and eukaryo-
although
of controversy
c1 and 6 differing
of subunits by their
among prokaryotic
phosphofructokinase,
still
of subunits
differentiated
a key enzyme of the glycolytic
of structures
(6 or 8) is
established
number
(EC 2.7.1.11),
(4)
and
to proteolytic These
among eukaryotic
structural phosphofructokinases
BIOCHEMICAL
Vol. 80, No. 3, 1978
since
the enzyme
contain
two types
weight
quaternary
significance
from human erythrocytes of subunits structures.
has been given
phosphofructokinase. that
yeast
(i.e
"catalytic"
binds sites)
(i.e
equilibrium
binding data
be correlated
are
however,
contains
data
for
with
no particular (8)
class
of sites
The allosteric
the occurence leading
our previous
binds
of two equally
distributed that
catalytic
in yeast showing sites;
reaction
ATP as an allosteric 5'AMP modifies work,
we report
phosphofructokinase.
kinetic
to the conclusion
of distinct
molecular
of ATP binding
enzymatic
In the present
ATP and 5'AMP to yeast with
data
activator
sites.
high functional
kinetic
in the
to also
of subunits
classes
donnor
(7)
complex,
of two types
two distinct
other
sites).
found
into
presented
ATP as phosphate
in agreement
to be composed
MATERIAL
now,
to the regulatory
in the enzyme oligomer, likely
Until
and the
of ATP only
is
distributed
to the occurence
"regulatory"
the binding binding
are
We have previously
of sites
inhibitor
has been recently
which
phosphofructokinase
one class
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
These
measurements types yeast
and regulatory
and can of subunits
phosphofructokinase subunits.
AND METHODS
Phosphofructokinase was prepared from baker's yeast according to the slightly modified procedure of Diezel et al. (1). Unlabelled 5'AMP and ATP were purchased from Sigma. Radioactive [Ul"C] ATP (562 mCi/mmol) and (U14C] 5'AMP (538 mCi/mmol) were obtained from the Radiochemical Center Amersham (England). All other chemicals were of the best available purity. The evaluation of ATP and 5'AMP binding by gel-filtration experiments was performed as previously described (9). Flow dialysis (10) measurements were conducted according to Tenu et al. (11) using Instagel (Packard, France) as scintillation liquid. All binding experiments were carried out at 25OC, pH 6.8, in 50 mM Tris-sulfonate buffer containing 25 mM K2HP04, 1 mM dithiothreitol, 5 mM MgC12 and 1 mM EDTA. Phosphofructokinase concentrations were determined from refraction index measurements, assuming an increment value dn/dc of 1.85 (mg/ml)-l ; this value leads to an absorption coefficient of 0.97 A/mg at 280 nm. Cross-linked hemoglobin and bovin serumalbumin prepared according to the procedure of Payne (12) were a generous gift of Dr. A. d'Albis. The electrophoresis technique was adapted from that of Taucher et al. (6) using a 4% polyacrylamide gel. Light scattering measurements were performed as described by Dessen and Pantaloni (13). RESULTS QUATERNARY STRUCTURE OF YEAST PHOSPHOFRUCTOKINASE. The molecular evaluated
by light
scattering
730 000 + 30 000 daltons by Diezel Hess (2) sodium
et al.
weight
(1)
dodecylsulfate
phosphofructokinase
and gel filtration 1). This value
(fig.
and agrees
in the case of the
of native
very
well
brewer
yeast
polyacrylamide
gel
647
has been consistently
on Utrogel AcA 22 (LKB) to is slightly smaller than that reported
with enzyme.
that
reported
by Tamaki
and
in fig.
2,
As illustrated
electrophoresis
performed
on freshly
BIOCHEMICAL
Vol. 80, No. 3, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I Q7 9’ -f
5
01
CONCENTRATION
02
IfTMJ/fllll
Fig.
1 :
scattering data for yeast phosphofructokinase. Plot of the relative scattered intensity at 436 nm, 20°C, versus protein concentration as obtained for two distinct enzyme preparations ( 0 and 0). Scattered intensities are extrapolated to 0" angle and are normalized with respect to the scattered intensity of the reference glass of the FICA 50 photogoniometer.The least square fitted straight line has a slope of 10.84 + 0.39 intensity units/mg of protein. From this value, a molecilar weight of 730 000 ;t 30 000 daltons can be calculated for yeast phosphofructo kinase, using a calibration factor of 67 000 + 400 daltons per unit of scattered intensity/me of protein (13f.Note that no significant departure from linearity is observed, as an indication of a negligible contribution of the second virial coefficient.
Fig.
2 :
Polyacrylamide gel electrophoresis of yeast phosphofructokinase in 0.1% sodium dodecyl sulfate. Experimental conditions : 4% acrylamide gels , 5 hrs. of migration at 8 mA/gel tube, 20 ng of protein were applied. Staining of the bands was achieved with Coomassie brilliant blue (6). According to the densitometric analysis shown on the right,the a, B, a' and B' bands are in the ratio 1 : 0.87 : 0.22 : 0.18 respectively. The amount of proteolysed material (IX' and B' chains) was particularly high in this one week old enzyme preparation. For most enzyme preparations used in the present work, when electrophoresis was carried out immediately after the last purification step, the partially proteolysed material amounted to 5-10" o of the total protein material.
prepared
Light
enzyme shows the
et al. (1). A strong followed by a rather a' and B' chains
typical
migration
doublet corresponding faint doublet which
(about
5-10% of the
weight of these subunits with a series gives the values of 124 000, 113 000, a' and B' chains,
respectively.
pattern is
total
previously
reported
to the native a and B chains is formed by the partially proteolysed protein).
Evaluation
of cross-linked proteins 95 000 and 88 000 daltons
These values
648
by Diezel
were
confirmed
of the
molecular
as markers for the cx, 6,
by electrophoresis
Vol. 80, No. 3, 1978
with
BIOCHEMICAL
uncrosslinked
filtration
molecular
experiments
results,
native
by the
association
F. Seydoux
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
weight
markers
on Sepharose
yeast
appears
a and three
and J. Yon, manuscript
dodecylsulfate
and by gel
CL 6B in 6 M guanidine.Thus,
phosphofructokinase
of three
in sodium
from
as an hexameric
8 chains
(i.e
these
enzyme formed
a3B3 structure,
A. Chaffotte,
in preparation).
BINDING OF !5'AMP AND ATP TO YEAST PHOSPHOFRUCTOKINASE. The binding monophasic,
isotherm
and a stoichiometry
determined
viith
binding
constant of
data
per
is clearly
oligomer
the binding
biphasic,
can be fitted
3a,
can be
16 nM.
S'AMP,
is distinctly
the binding
sites
of about
to the binding
phosphofructokinase
Accordingly,
as shown in fig.
of three
a dissociation
In contrast to yeast
of 5'AMP,
isotherm
of ATP
as shown in fig.
to the
following
3b.
equation
:
n(ATPjfree ATP bound which
accounts
sites.
for
of sites
constants
loose
binding
Thus,
yeast
three
binding
enzyme (mol/mol)
the binding
The number
dissociation
per
are
in the
sites
by flow
experiments
using
stoichiome;:ries,
it
sites
regulatory only
by an excess that
5'AMP rapidly
behavior hexamer. binding catalytic the
Thus, sites
the this
of sites
similar
and
of
bound
allows with (36.5
kinetically
of our
us to identify
this
second
class
interpretation,
uM) compares for
conditions. 649
well
the catalytic
be
dialysis
ATP was displaced experiment
shows
an appreciable
5'AMP concentrations.
by assuming
that
only
kinetic
should
4, this
that
binding
previous
in a flow
in fig. ATP but
filtration contains
sites
of bound
to the three
and the
stoichiometries by gel
From these
tested
amount
bound
sites
agreement
ATP (31 FM) as determined
In view
has been
described
experiment
binding confirmed
to the regulatory
As depicted
ATP molecules
In
classes
phosphofructokinase
enzyme even at high
class
two distinct
peculiar
yeast
This
tightly
the
as regulatory
sites. second
that
bound
5'AMP.
can be quantitatively
more efficiently
nM respectively).
to contain
of
and the
2.3 and 36.5
substoichiometric
displaces
boundto
to three
of 15 (i.e
enzyme preparations.
by S'AMP.
small
of unlabelled
of ATP remains
for
a
close
number
to the tight
per enzyme oligomer.
ATP molecules
where
of equal
respectively
1, these
different
displaced
experiment
was found
5'AMP and ATP were
can be deduced
the
significantly
with
several
classes
K2 + (Wfree
ATP.
in Table
dialysis
(n)
+
correspond
appears
each for
three results,
ratio
phosphofructokinase As illustrated
obtained
in each class
n(ATP)free
Kl + (A'Wfree
of ATP to two distinct
and K2 which
K1
sites,
= ; =
fraction This
5'AMP displaces
tight
sites
the first of sites the with
of the class
enzyme
of ATP
as the
dissociation the
reaction
constant
Km value (8)
for
under
Vol. 80, No. 3, 1978
l-i g.3
:
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Binding isotherm of 5'AMP and ATP to yeast phosphofructokinase as determined in flow dialysis experiments. Scatchard plot of the data ; corresponds to the apparent number of bound ligand molecules per enzyme oligomer. (a) Binding isotherm of 5'AMP. c]: 5.2 UM enzyme. a : 12.6 PM enzyme The solid line is calculated for a single class of 2.75 sites per enzyme oligomer with a dissociation constant of 16.2 FIM. (b) Binding isotherm of ATP : 3.9 uM enzyme. Solid line is calculated fromequation 1 with Kl q 2.35 uM, K2 q 36.6 PM and n = 3.07.
1.5
50 [5’AMP] Fig.
4 :
pM
Displacement of ATP by 5'AMP from yeast phosphofructokinase as measured by flow dialysis. Experimental conditions : 4 PM enzyme, 1.93V M (U-14C)ATP. The solid curve is calculated by assuming a competitive displacement of ATP by 5'AMP from the regulatory tight binding sites as discussed in the text. The corresponding equation used in that case is obtained by multiplying the dissociation constant K in equation 1 by (1 + AMP/K), K (=9 PM) being the dissociation coAstant for 5'AMP ; other parameters values as given in fig. 3b.
650
BIOCHEMICAL
Vol. 80, No. 3, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE 1 Comparison of the data obtained by gel filtration and flow dialysis the binding of ATP and 5'AMP to yeast phosphofructokinase. Apparent numbers of bound ligand molecules per enzyme oligomer (;) measured in gel filtration experiments were obtained with 3 distinct enzyme preparations. ( ( ( ( ( ( i
Ligand
.:
Concentration'=) ( PM)
for
;
i : gel
filtration
: flow
dialysis (b)
(
ATP
:
ATP
i
9.30 47.5
: 3.02
t
0.37
:
3.05
: 4.95
+
0.40
:
4.62
) ) ) ) ; 1 ) i
i ( (
5'AMP
(a) free
:
ligand
(b) These
69.3
: 2.45
t
0.20
:
2.23
; 1
concentration.
values
were
interpolated
from the
data
of fig.
3.
DISCUSSION Although structure,
the
the present
essential
yeast
phosphofructokinase
sites
which
oligomer.
is
equal
contains
to only
in view
to assume that
the
lytic for
half
"303
ATP as phosphate
donnor.
In this
of asymmetrical
by our previous fructokinase
kinetic with
of three
interacting
pretation
should
and functional
of regulatory
and catalytic structure
ATP or 5'AMP and each catalytic
as a trimer
an hexameric work
sites,
of yeast
dimeric results
respect
but
per
that
6-phosphate
be substantiated by additional yeast phosphofructokinase
levels,
651
interpretation
the cooperativity
enzyme oligomer
that
that the enzyme one type
the most plausible
phosphofructokinase
contains only enzyme oligomer This
c1 fi units.
showing
to fructose
protomers
subunit sense, the
"3B3 is
ATP and 5'AMP binding
the number of subunits constituting we cannot exclude the possibility
regulatory
of the
with
of the present
enzymeoligomer is composed of three regulatory each regulatory subunit should contain Therefore,
subunits. for
a number
data,
both
interpretation
site
are consistent conclusion
contains
From the present
of subunits
data
qualitative
is
and three cataone regulatory one binding site should be considered is supported of yeast
phospho-
was best explained on the basis this tentative inter (8). Although evidence at both structural may constitute a new example
BIOCHEMICAL
Vol. 80, No. 3, 1978
of a highly distinct mylase
specialized subunits,
from
E. coli
allosteric
as already
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
enzyme with described
for
the
structurally
and functionally
enzyme aspartate
transcarba-
(14).
ACKNOWLEDGMENTS We are indebted to Professor J. Yon for her interest to this work. We are very grateful to Dr. A. d'Albis for her generous gift of cross-linked proteins and to Dr. Pantaloni for his assistance and advices concerning light scattering measurements. We acknowledge Dr. Thusius and M.J. Lavorel for careful reading of this manuscript. This work was supported by grants from the Centre National de la Recherche Scientifique (G.R. no 13).
REFERENCES
(1)
(2) (3) (4) (5)
(6) (7) (8) (9) (10) (11)
(12) (13) (14)
Diezel, W., Bdhme, H.J., Nissler, K., Freyer, R., Heilman, W., Kopperschlzger, G. and Hofmann, E. (1973) Eur. J. Biochem. 38, 479-488. Tamaki, N. and Hess, B. (1975) Hoppe Seyler's Z. Physiol. Chem. 356, 4, 399-415. Kopperschlgger, G., Usbeck, E. and Hofmann, E. (1976) Biochem. Biophys. Res. Commun. 71, 371-378. Herrmann, K., Diezel, W., Kopperschlgger, G. and Hofmann, E. (1973) FEBS Lett. 36, 190-192. Huse, K., Kopperschlgger, G. and Hofmann, E. (1976) Biochem. J. 155, 721-723. Taucher, M., Kopperschlager, G. and Hofmann, E. (1975) Eur. J. Biochem. 59, 319-325. Karadsheh, N.S., Uyeda, K. and Oliver, R.M. (1977) J. Biol. Chem. 252, 3515-3524. Laurent, M. and Seydoux, F. (1977) Biochem. Biophys. Res. Commun., 78, 1289-1295. Seydoux, F., Kelemen, N., Kellershohn, N. and Raucous, C. (1976). Eur. J. Biochem. 64, 481-489. Colowick, S.P. and Womack, F.C. (1969) J. Biol. Chem. 244, 774-717. Tenu, J.P., Ghelis, C., Yon, J. and Chevallier, J. (1976) Biochimie 58, 513-519. Payne, J.W. (1973) Biochem. J. 135, 867-873. Dessen, P. and Pantaloni, D. (1973) Eur. J. Biochem. 39, 157-169. Gerhart, J.C. and Schachman, H.K. (1965) Biochemistry 4, 1054-1062.
652
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
Pages
February 14, 1978
646-652
BINDING OF NUCLEOTIDES AMP AND ATP TO YEAST PHOSPHOFRUCTOKINASE:EVIDENCE DISTINCT
Michel
LAURENT, Alain
CATALYTIC
FOR
AND REGULATORY SUBUNITS
F. CHAFFOTTE, Jean-Pierre TENU, Colette FranGois J. SEYDOUX.
ROUCOUS and
Laboratoire d'Enzymologie Physico-Chimique et Moleculaire Universitk de Paris-Sud, 91405, Orsay-France.
Received
October
27,
1977
SUMMARY The binding of ATP to yeast phosphofructokinase, as monitored by flow dialysis, is heterogeneous and is adequately described by assuming two independent classes of three binding sites each per enzyme molecule. Under similar conditions, theming of 5'AMP is homogeneous and a binding stoichiometry of three S'AMP molecules per enzyme molecule is evaluated. Displacement experiments show that only the ATP molecules bound to the first class of three tight binding sites are displaced by an excess of 5'AMP. Thus, these tight ATP binding sites can be identified as "regulatory sites" in agreement with kinetic data. Furthermore, molecular weight determinations and electrophoresis results are consistent with an heterologous a 6, structure of the enzyme oligomer. Therefore the present binding data sugges ? that yeast phosphofructokinase is constituted by three "catalytic" and three "regulatory" subunits. .
INTRODUCTION Phosphofructokinase pathway, tic
shows a great
organisms.
number
In the
of subunits
now well
of two types
weight
(4).
are
easily
degradation features
These
variability case of yeast that
the
two types
in the presence of the yeast
a matter
native
form
are
relative
of specific
enzyme are
not unique
646
in their
immunologically (5).
the exact
(1,2,3),
enzyme contains slightly
it
is
an equal molecular
distinct
susceptibility substrates
0006-291X/78/0803-0646$01,00/0 Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
of this
and eukaryo-
although
of controversy
c1 and 6 differing
of subunits by their
among prokaryotic
phosphofructokinase,
still
of subunits
differentiated
a key enzyme of the glycolytic
of structures
(6 or 8) is
established
number
(EC 2.7.1.11),
(4)
and
to proteolytic These
among eukaryotic
structural phosphofructokinases
BIOCHEMICAL
Vol. 80, No. 3, 1978
since
the enzyme
contain
two types
weight
quaternary
significance
from human erythrocytes of subunits structures.
has been given
phosphofructokinase. that
yeast
(i.e
"catalytic"
binds sites)
(i.e
equilibrium
binding data
be correlated
are
however,
contains
data
for
with
no particular (8)
class
of sites
The allosteric
the occurence leading
our previous
binds
of two equally
distributed that
catalytic
in yeast showing sites;
reaction
ATP as an allosteric 5'AMP modifies work,
we report
phosphofructokinase.
kinetic
to the conclusion
of distinct
molecular
of ATP binding
enzymatic
In the present
ATP and 5'AMP to yeast with
data
activator
sites.
high functional
kinetic
in the
to also
of subunits
classes
donnor
(7)
complex,
of two types
two distinct
other
sites).
found
into
presented
ATP as phosphate
in agreement
to be composed
MATERIAL
now,
to the regulatory
in the enzyme oligomer, likely
Until
and the
of ATP only
is
distributed
to the occurence
"regulatory"
the binding binding
are
We have previously
of sites
inhibitor
has been recently
which
phosphofructokinase
one class
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
These
measurements types yeast
and regulatory
and can of subunits
phosphofructokinase subunits.
AND METHODS
Phosphofructokinase was prepared from baker's yeast according to the slightly modified procedure of Diezel et al. (1). Unlabelled 5'AMP and ATP were purchased from Sigma. Radioactive [Ul"C] ATP (562 mCi/mmol) and (U14C] 5'AMP (538 mCi/mmol) were obtained from the Radiochemical Center Amersham (England). All other chemicals were of the best available purity. The evaluation of ATP and 5'AMP binding by gel-filtration experiments was performed as previously described (9). Flow dialysis (10) measurements were conducted according to Tenu et al. (11) using Instagel (Packard, France) as scintillation liquid. All binding experiments were carried out at 25OC, pH 6.8, in 50 mM Tris-sulfonate buffer containing 25 mM K2HP04, 1 mM dithiothreitol, 5 mM MgC12 and 1 mM EDTA. Phosphofructokinase concentrations were determined from refraction index measurements, assuming an increment value dn/dc of 1.85 (mg/ml)-l ; this value leads to an absorption coefficient of 0.97 A/mg at 280 nm. Cross-linked hemoglobin and bovin serumalbumin prepared according to the procedure of Payne (12) were a generous gift of Dr. A. d'Albis. The electrophoresis technique was adapted from that of Taucher et al. (6) using a 4% polyacrylamide gel. Light scattering measurements were performed as described by Dessen and Pantaloni (13). RESULTS QUATERNARY STRUCTURE OF YEAST PHOSPHOFRUCTOKINASE. The molecular evaluated
by light
scattering
730 000 + 30 000 daltons by Diezel Hess (2) sodium
et al.
weight
(1)
dodecylsulfate
phosphofructokinase
and gel filtration 1). This value
(fig.
and agrees
in the case of the
of native
very
well
brewer
yeast
polyacrylamide
gel
647
has been consistently
on Utrogel AcA 22 (LKB) to is slightly smaller than that reported
with enzyme.
that
reported
by Tamaki
and
in fig.
2,
As illustrated
electrophoresis
performed
on freshly
BIOCHEMICAL
Vol. 80, No. 3, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I Q7 9’ -f
5
01
CONCENTRATION
02
IfTMJ/fllll
Fig.
1 :
scattering data for yeast phosphofructokinase. Plot of the relative scattered intensity at 436 nm, 20°C, versus protein concentration as obtained for two distinct enzyme preparations ( 0 and 0). Scattered intensities are extrapolated to 0" angle and are normalized with respect to the scattered intensity of the reference glass of the FICA 50 photogoniometer.The least square fitted straight line has a slope of 10.84 + 0.39 intensity units/mg of protein. From this value, a molecilar weight of 730 000 ;t 30 000 daltons can be calculated for yeast phosphofructo kinase, using a calibration factor of 67 000 + 400 daltons per unit of scattered intensity/me of protein (13f.Note that no significant departure from linearity is observed, as an indication of a negligible contribution of the second virial coefficient.
Fig.
2 :
Polyacrylamide gel electrophoresis of yeast phosphofructokinase in 0.1% sodium dodecyl sulfate. Experimental conditions : 4% acrylamide gels , 5 hrs. of migration at 8 mA/gel tube, 20 ng of protein were applied. Staining of the bands was achieved with Coomassie brilliant blue (6). According to the densitometric analysis shown on the right,the a, B, a' and B' bands are in the ratio 1 : 0.87 : 0.22 : 0.18 respectively. The amount of proteolysed material (IX' and B' chains) was particularly high in this one week old enzyme preparation. For most enzyme preparations used in the present work, when electrophoresis was carried out immediately after the last purification step, the partially proteolysed material amounted to 5-10" o of the total protein material.
prepared
Light
enzyme shows the
et al. (1). A strong followed by a rather a' and B' chains
typical
migration
doublet corresponding faint doublet which
(about
5-10% of the
weight of these subunits with a series gives the values of 124 000, 113 000, a' and B' chains,
respectively.
pattern is
total
previously
reported
to the native a and B chains is formed by the partially proteolysed protein).
Evaluation
of cross-linked proteins 95 000 and 88 000 daltons
These values
648
by Diezel
were
confirmed
of the
molecular
as markers for the cx, 6,
by electrophoresis
Vol. 80, No. 3, 1978
with
BIOCHEMICAL
uncrosslinked
filtration
molecular
experiments
results,
native
by the
association
F. Seydoux
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
weight
markers
on Sepharose
yeast
appears
a and three
and J. Yon, manuscript
dodecylsulfate
and by gel
CL 6B in 6 M guanidine.Thus,
phosphofructokinase
of three
in sodium
from
as an hexameric
8 chains
(i.e
these
enzyme formed
a3B3 structure,
A. Chaffotte,
in preparation).
BINDING OF !5'AMP AND ATP TO YEAST PHOSPHOFRUCTOKINASE. The binding monophasic,
isotherm
and a stoichiometry
determined
viith
binding
constant of
data
per
is clearly
oligomer
the binding
biphasic,
can be fitted
3a,
can be
16 nM.
S'AMP,
is distinctly
the binding
sites
of about
to the binding
phosphofructokinase
Accordingly,
as shown in fig.
of three
a dissociation
In contrast to yeast
of 5'AMP,
isotherm
of ATP
as shown in fig.
to the
following
3b.
equation
:
n(ATPjfree ATP bound which
accounts
sites.
for
of sites
constants
loose
binding
Thus,
yeast
three
binding
enzyme (mol/mol)
the binding
The number
dissociation
per
are
in the
sites
by flow
experiments
using
stoichiome;:ries,
it
sites
regulatory only
by an excess that
5'AMP rapidly
behavior hexamer. binding catalytic the
Thus, sites
the this
of sites
similar
and
of
bound
allows with (36.5
kinetically
of our
us to identify
this
second
class
interpretation,
uM) compares for
conditions. 649
well
the catalytic
be
dialysis
ATP was displaced experiment
shows
an appreciable
5'AMP concentrations.
by assuming
that
only
kinetic
should
4, this
that
binding
previous
in a flow
in fig. ATP but
filtration contains
sites
of bound
to the three
and the
stoichiometries by gel
From these
tested
amount
bound
sites
agreement
ATP (31 FM) as determined
In view
has been
described
experiment
binding confirmed
to the regulatory
As depicted
ATP molecules
In
classes
phosphofructokinase
enzyme even at high
class
two distinct
peculiar
yeast
This
tightly
the
as regulatory
sites. second
that
bound
5'AMP.
can be quantitatively
more efficiently
nM respectively).
to contain
of
and the
2.3 and 36.5
substoichiometric
displaces
boundto
to three
of 15 (i.e
enzyme preparations.
by S'AMP.
small
of unlabelled
of ATP remains
for
a
close
number
to the tight
per enzyme oligomer.
ATP molecules
where
of equal
respectively
1, these
different
displaced
experiment
was found
5'AMP and ATP were
can be deduced
the
significantly
with
several
classes
K2 + (Wfree
ATP.
in Table
dialysis
(n)
+
correspond
appears
each for
three results,
ratio
phosphofructokinase As illustrated
obtained
in each class
n(ATP)free
Kl + (A'Wfree
of ATP to two distinct
and K2 which
K1
sites,
= ; =
fraction This
5'AMP displaces
tight
sites
the first of sites the with
of the class
enzyme
of ATP
as the
dissociation the
reaction
constant
Km value (8)
for
under
Vol. 80, No. 3, 1978
l-i g.3
:
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Binding isotherm of 5'AMP and ATP to yeast phosphofructokinase as determined in flow dialysis experiments. Scatchard plot of the data ; corresponds to the apparent number of bound ligand molecules per enzyme oligomer. (a) Binding isotherm of 5'AMP. c]: 5.2 UM enzyme. a : 12.6 PM enzyme The solid line is calculated for a single class of 2.75 sites per enzyme oligomer with a dissociation constant of 16.2 FIM. (b) Binding isotherm of ATP : 3.9 uM enzyme. Solid line is calculated fromequation 1 with Kl q 2.35 uM, K2 q 36.6 PM and n = 3.07.
1.5
50 [5’AMP] Fig.
4 :
pM
Displacement of ATP by 5'AMP from yeast phosphofructokinase as measured by flow dialysis. Experimental conditions : 4 PM enzyme, 1.93V M (U-14C)ATP. The solid curve is calculated by assuming a competitive displacement of ATP by 5'AMP from the regulatory tight binding sites as discussed in the text. The corresponding equation used in that case is obtained by multiplying the dissociation constant K in equation 1 by (1 + AMP/K), K (=9 PM) being the dissociation coAstant for 5'AMP ; other parameters values as given in fig. 3b.
650
BIOCHEMICAL
Vol. 80, No. 3, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE 1 Comparison of the data obtained by gel filtration and flow dialysis the binding of ATP and 5'AMP to yeast phosphofructokinase. Apparent numbers of bound ligand molecules per enzyme oligomer (;) measured in gel filtration experiments were obtained with 3 distinct enzyme preparations. ( ( ( ( ( ( i
Ligand
.:
Concentration'=) ( PM)
for
;
i : gel
filtration
: flow
dialysis (b)
(
ATP
:
ATP
i
9.30 47.5
: 3.02
t
0.37
:
3.05
: 4.95
+
0.40
:
4.62
) ) ) ) ; 1 ) i
i ( (
5'AMP
(a) free
:
ligand
(b) These
69.3
: 2.45
t
0.20
:
2.23
; 1
concentration.
values
were
interpolated
from the
data
of fig.
3.
DISCUSSION Although structure,
the
the present
essential
yeast
phosphofructokinase
sites
which
oligomer.
is
equal
contains
to only
in view
to assume that
the
lytic for
half
"303
ATP as phosphate
donnor.
In this
of asymmetrical
by our previous fructokinase
kinetic with
of three
interacting
pretation
should
and functional
of regulatory
and catalytic structure
ATP or 5'AMP and each catalytic
as a trimer
an hexameric work
sites,
of yeast
dimeric results
respect
but
per
that
6-phosphate
be substantiated by additional yeast phosphofructokinase
levels,
651
interpretation
the cooperativity
enzyme oligomer
that
that the enzyme one type
the most plausible
phosphofructokinase
contains only enzyme oligomer This
c1 fi units.
showing
to fructose
protomers
subunit sense, the
"3B3 is
ATP and 5'AMP binding
the number of subunits constituting we cannot exclude the possibility
regulatory
of the
with
of the present
enzymeoligomer is composed of three regulatory each regulatory subunit should contain Therefore,
subunits. for
a number
data,
both
interpretation
site
are consistent conclusion
contains
From the present
of subunits
data
qualitative
is
and three cataone regulatory one binding site should be considered is supported of yeast
phospho-
was best explained on the basis this tentative inter (8). Although evidence at both structural may constitute a new example
BIOCHEMICAL
Vol. 80, No. 3, 1978
of a highly distinct mylase
specialized subunits,
from
E. coli
allosteric
as already
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
enzyme with described
for
the
structurally
and functionally
enzyme aspartate
transcarba-
(14).
ACKNOWLEDGMENTS We are indebted to Professor J. Yon for her interest to this work. We are very grateful to Dr. A. d'Albis for her generous gift of cross-linked proteins and to Dr. Pantaloni for his assistance and advices concerning light scattering measurements. We acknowledge Dr. Thusius and M.J. Lavorel for careful reading of this manuscript. This work was supported by grants from the Centre National de la Recherche Scientifique (G.R. no 13).
REFERENCES
(1)
(2) (3) (4) (5)
(6) (7) (8) (9) (10) (11)
(12) (13) (14)
Diezel, W., Bdhme, H.J., Nissler, K., Freyer, R., Heilman, W., Kopperschlzger, G. and Hofmann, E. (1973) Eur. J. Biochem. 38, 479-488. Tamaki, N. and Hess, B. (1975) Hoppe Seyler's Z. Physiol. Chem. 356, 4, 399-415. Kopperschlgger, G., Usbeck, E. and Hofmann, E. (1976) Biochem. Biophys. Res. Commun. 71, 371-378. Herrmann, K., Diezel, W., Kopperschlgger, G. and Hofmann, E. (1973) FEBS Lett. 36, 190-192. Huse, K., Kopperschlgger, G. and Hofmann, E. (1976) Biochem. J. 155, 721-723. Taucher, M., Kopperschlager, G. and Hofmann, E. (1975) Eur. J. Biochem. 59, 319-325. Karadsheh, N.S., Uyeda, K. and Oliver, R.M. (1977) J. Biol. Chem. 252, 3515-3524. Laurent, M. and Seydoux, F. (1977) Biochem. Biophys. Res. Commun., 78, 1289-1295. Seydoux, F., Kelemen, N., Kellershohn, N. and Raucous, C. (1976). Eur. J. Biochem. 64, 481-489. Colowick, S.P. and Womack, F.C. (1969) J. Biol. Chem. 244, 774-717. Tenu, J.P., Ghelis, C., Yon, J. and Chevallier, J. (1976) Biochimie 58, 513-519. Payne, J.W. (1973) Biochem. J. 135, 867-873. Dessen, P. and Pantaloni, D. (1973) Eur. J. Biochem. 39, 157-169. Gerhart, J.C. and Schachman, H.K. (1965) Biochemistry 4, 1054-1062.
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