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The roles of glucose and AMP in regulating the conversion of phosphorylase a into phosphorylase b
Vol. 46, No. 1, 1972
BIOCHEMICAL
THE ROLES REGULATING PHOSPHORYLASE
J.
Martyn
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF GLUCOSE AND AMP IN THE CONVERSION OF a INTO PHOSPHORYLASE b
Bailey
and
W.J.
Whelan
Department of Biochemistry, The George Washington University Medical Center, Washington, D.C. 20005 and
Department of Biochemistry, University of Miami SchooZ of Medicine, Miami, Florida 33152
Received
November
12, 1971
S UMMARY: The ability of glucose to assist the action of phosphorylase a phosphatase on phosphorylase a, appears to be mediated through conformational changes in the phosphoryl ase. The system is an example of control of enzyme activity by regulation of the conformation of the substrate, and parallels the similar effect of AMP in inhibiting the dephosphorylation. INTRODUCTION Phosphorylase the
“inactive”
The
best
b form studied
inhibits
a phosphatase by
examples
this of
It
was
thereby
of
the
substrate
AMP
effect,
than
lase
a.
to AMP
to
muscle
(3)
and
liver
is
to
an
from favored
have
0 1972 by Academic
AMP
the that
(4)
the
interaction
of
glucose
latter effects
tetramer
on
the
formation
while
Press, Inc.
dephosphory-
the
promotes a.
with since
state
of
AMP
phosphorylase
alter
phosphatase,
possibility
(1).
a.
conformation
(2).
phosphorylases of
the
to
enzyme glucose
rate
from is
residue.
muscle
the
a into
a serine
rabbit
affect
activation
opposing
promotes
of
191 Copyright
not
from
from
isolated
inhibit
reported
due
does
phosphorylase
group
are
action
was
results
also
the
it
evidence
known
that
rather
this
stantial
enzymes
tetradecapeptide
concluded
of
whether
these
a phosphate
but
a phosphorylated
Recently both
of
of
dephosphorylation,
lation
sion
cleavage
“active”
converts
of glucose
the We have or
the
a + b converinvestigated
rather,
like
substrate. AMP
and
Ci rcumglucose
aggregation favors
the
of the
are phosphory-
dimer
(5).
Vol. 46, No. 1, 1972
Furthermore,
BIOCHEMICAL
the
temperature
(5),
at
phosphorylase
form
which
temperatures
of
glucose
cleavage
by
AMP
both
being
or
assisting
variety
glucose
appears
to
have
effects
of
glucose
positive piece
of
is
at
evidence
phosphorylase
chymotrypsin
study
learned
colleagues
have
MATERIALS
confirms
rabbit
AND
is
enhanced
the by
physiological no
effect were
implicating
the
observation
that
glucose
on
(7)
and
noted actions
opposed
by
that
in
an
come
to
a similar
mlJ)
of 1 ml
Pi
protein
(10).
of
and
remaining
by on
I mU of
convert
1 mU
the
enzyme
NaCl was
(approx
25
gradient eluted
53 mU per
phosphatase protamine
in
protease
prepared
treatment
glucose
in
phosphorylase. Hers
and
his
with
(25ug)
dried
on
filter
washing
in
50%
dried
2 X crystallized
phosphorylase
b kinase
activity
with
of
aqueous was
range The activity
(1X3
ethanol,
and
determined
defined
as
phosphorylase
that a
was on
amount into
purified
b per from
salt,
enzyme was
essentially
tested
casein.
192
and
against
the
~1)
were The
liber-
32P-label
liquid
led
scintillation enzyme
which
will
min. rat
1 iver
The
bulk
specific free
by
containing
cm).
of
DEAE-cellulose.
0.28-0.32~
when
by
assayed
8.16, (100
strips
and
phosphatase
pH
Samples paper
phosphatase
was
phosphorylase buffer,
strips is
ng) a
the
from
phosphatase
chromatography
mg protein. and
and
H.G.
1OmM mercaptoethanol.
phosphatase
Phosphorylase by
of
(9).
tris-glycerophosphate and
removed
counting.
effect with
Dr.
a was
Phosphorylase
0.02M
intervals
was
study,
phosphorylase
acetate
at
the
interaction
conclusion
a by
labelled
3mM magnesium removed
that
by
phosphorylase
ATP
in
indeed
independent
phosphorylase
y-32P-labelled incubation
inference
METHODS
muscle
ated
the is
32 P-Labelled
was
on
dephosphorylation
We have
ates
exclusive
(8). This
(24
The
A final
30”.
trypsin
the
(6).
below and
is
temperature
inactivation
at
AMP
dimeric
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
from
phosphorylated
homogenof
the
activity non-specific histone,
Vol. 46, No. 1, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RESULTS When was
inhibited
the 90%
phosphatase by
0.1
acted
mM AMP,
on
phosphorylase
16.7 mM glucose
while
15” the
a at doubled
react
the
ion
rate
of
200+ AMP
I 40
0
I 80
I 120
I 160
TIME (minutes)
Fig. 1. Influence of glucose and AMP on the action of phosphorylase j2P-Labelled phosphorylase a was incubated phosphatase on phosphorylase a. with 16.7 mM glucose or 0.1 mM AMP at 15” with phosphorylase phosphatase, added as indicated. Samples were removed at intervals for determination of the 32P-labelled protein remaining (see Materials and Methods).
reaction
(Fig.
I).
Other
During ratio
of
its
constant
the
glucose
effect
was
When charcoal at
treatment,
37”.
AMP
still
(Fig.
2).
Only
at
overcome
levels
the
AMP
Paralleling phorylation is
tetrameric
were at
Is”,
no
on
absence
was
effect.
of
DEAE-cellulose, glucose
unlikely
a was by the
the
freed
glucose
enzyme fact
at
that
10 uM AMP,
that
the
system. completely
was
maximal
37”
and
the
the
remained
therefore
phosphatase-activating
below
sugar however,
from at
15-20’
a glucose
by and
absent
effect
opposed was
AMP
the
at
AMP
glucose
37”
inhibition
able
complete
inhibition. the
the
It
phosphorylase
from
and
profile.
a separate
or
phosphatase
presence
inhibited
demonstrated
1 ittle of
stimulation
be
to
the
enzyme on
the
could
ly
in
the
had
fractionation
activity
across
sugars
effects
ultracentrifugal wholly
of
glucose
and
observations dimeric
at
35”,
193
AMP that
and
dimer
on
the
rate
of
phosphorylase appears
at
dephosa
15”
if
Vol. 46, No. 1, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
240
4
6
AMP (lo-’
M)
Fig. 2. Restoration of the glucose sensitivity of the dephosphorylation of phosphorylase a at 37” by addition of AMP. The activity of the phosphatase was measured in the presence and absence of 28 mM glucose, with increasing amounts of AMP. The j2P-labelled phosphorylase had been treated with charcoal to remove AMP. See Materials and Methods for conditions.
Table
1.
Influence behaviour
of of
added a
glucose
on
the
Component(s) (dimer)
S1
sedimentation
observed S2 (tetramer)
15"
none
none
15.3
15"
g 1 ucose
9.8
14.7
23
g 1 ucose
9.8
13.9
35"
none
9.0
none
35"
g 1 ucose
9.1
none
35"
glucose
9.5
none
The solvent plus 0.01 coefficients
glucose
the
and
Additions
Temperature
in
temperature phosphorylase
was the phosphatase assay M NaCl, with 55 mM glucose in are-corrected to 20’
is
added
concentrations
(Fig. at
phosphorylase
was
32P-Labelled labelled
+ AMP
phosphorylase
3,
Table
which wholly
peptides a with
At 35",
1).
AMP
inhi
dimeri
buffer (see and 1 mM AMP water.
bition c were
of
and
AMP is
present manifested,
1 1.
prepared
194
glucose
and Methods) Sedimentation
dephosphorylation
(Table
chymotrypsin
with
Materials as noted.
by or
trypsin.
brief
treatment Neither
of glucose
nor
Vol. 46, No. 1,1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Influence of temperature and added glucose on the sedimentation Fig. 3. A, sedimentation of phosphorylase of phosphorylase a in the ultracentriguge. Lower curve, plus 55 mM glucose. Speed a at 15”. Upper curve, control. Movement from left to right. D and T 60,000 rev./min. Time 18 min. indicate the positions of the dimeric and tetrameric forms of phosphorylasee a. B, Sedimentation of phosphorylase a at 35”. Upper curve, phosphorylase Lower curve, phosphorylase b as reference. Note that phosphorylase u a. behaves as a tetramer at 15” but is completely dissociated to dimer at 35”. Addition of glucose at 15” causes the appearance of dimer (see also Table 1).
AMP is
affected
their
already
rates
known
(2,
of
dephosphorylation.
This
lack
of
effect
of
AMP
11).
DISCUSSION The that
the
effect
like
that
of
not
AMP
the
This
dimer
opposition at
ultracentrifuge
the
tetramer
37”
se
of
the (Fig.
on
on
the
was
that
the
is
2), shows
glucose
well
not
a substrate.
when
no
only
the
to
produce
glucose effect dimeric
was
was
and
shown
AMP on
of
glucose form
195
phosphorylase,
to
produce
dimer,
2,
is Table
a
a substrate.
cannot the
was
fact
be
the
case
that
dephosphorylation alone
(Fig.
not it
from
is,
however,
tetramer,
a substrate,
This
inference
inference,
effect
be
original
of
Another
was
of
our
dephosphorylation
the
very
effects
confirmed
substrate.
AMP effect may
per
experiment
glucose (2),
while
While
seen
of
sustained.
substrate,
that
last-mentioned
an can
noted, 1).
and
be
when
We have
the to
Vol. 46, No. 1, 1972
conclude and
that
there
stabilized
else
effect
of
ble.
When,
AMP,
the
effects
any
physiological
range In
early
AMP of
it
from
as
one
expose
of
can the
in and
(Fig.
inhibiting
trypsinolysis
include
the
resistant
opposing for
the
the
regulation
a substrate. of
glucose
reaction
is
glucose phosphate
the
b,
negligi-
We
producing in
the
mM).
serine
explaining
The
a and
envisage
It
2).
any is
mechanism
concentration
action.
a parallel
enhancing
products
terms
that form
phosphorylase
(4-5
rapid
of
a significant
the
At susceptible
stabilization
dephosphorylation glucose
to
in
so
the
susceptible
its
phosphatase,
glucose. in
is
phosphorylases
the
blood
phosphatase
finds
to
of
the
the
37")
point
level,
all
forms
to
to
by
demonstrated
changes
for
a so
be
levels
molecular
phosphorylase
respectively
to
resistant
either
two
change at
metabolites
given
stimulation
also
effect
is
the
present
relative
half-maximal
shield
is
one
stabilized a
the
conformational
at
dimer,
susceptible,
promoting
two the
on that
model
one
the
between
AMP
these of
depending
in
a glucose
regulation
to
and
of
phosphorylase
however,
of
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
forms
equilibrium
glucose
permits
noted
two
temperature
or
form
are
by
physiological form,
BlOCHEMlCAL
is
significant
the
effects
effects
as
reacting
group,
and that
of of
AMP
so
this
as
crude
glucose
trypsin,
phosphorylated
with
and since
AMP the
(8).
peptides
ACKNOWLEDGEMENTS This AM
10082
of
absence
and
work
was
AM 12532, at
the
supported and
was
University
by
U.S.
carried
of
Public
out
while
Health J.M.
Service Bailey
Grants was
on
leave
Miami.
REFERENCES I.
Fischer,
E.H.,
Packer,
A.
and
Saari,
J.C.,
Essays
in
Biochemistry
6:32 (1970). 2.
Nolan,
3.
Holmes,
4.
Stalmans,
C., 3:542
Novoa,
W.B.,
Krebs,
E.G.
and
Fischer,
E.H.,
Biochemistry
(1964).
P.A.
and
Mansour,
P.E.,
Biochim.
Biophys.
Acta
256:266,
275
(1968). ‘W.,
Biochem.
De Wulf,
25:9
H.,
Lederer,
B.
(1970).
196
and
Hers,
H-G.,
E~rop.
J.
in
Vol. 46, No. 1, 1972
5.
Wang,
6. 7.
BIOCHEMICAL
Comtun.
Shonka, ~8:
Torres,
H.N.
and
Graves,
A.J., Met&oZism,
J.M.,
M.L.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
and
Graves,
D.J.,
Biochem.
Biaphys.
Res.
131 (1965). Chelala,
Huang, Ed.
C.A.,
C.Y. by
and W.J.
Biochim. Mann, Whelan,
Acta 198:495 (1970).
Biophys.
S.A., in Academic
Control Press,
GZycogen
of
London,
1968,
p. 35.
8.
Fischer,
E.H.,
Graves,
D.J.,
Crittenden,
E.R.S.
and
Krebs,
E.G.,
J. BioZ. Chem. 234: 1698 (1959).
9.
DeBarsy,
10.
Krebs,
II.
T.,
Stalmans,
W.,
Laloux,
M.,
De Wulf, H. the press.
and
Hers,
H.G.,
Biochem. Biophys. Res. Cornmun., in E.G. N-0.
Martensen,
in Methods in Kaplan, Academic T.M.,
Brotherton,
Enzymology, Press, J.E.
New and
11971).
197
Ed. by York, Graves,
S.P. 0:543 D.J.,
Colowick (1966). Fed.
and
Proc.
30: 1180
BIOCHEMICAL
THE ROLES REGULATING PHOSPHORYLASE
J.
Martyn
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF GLUCOSE AND AMP IN THE CONVERSION OF a INTO PHOSPHORYLASE b
Bailey
and
W.J.
Whelan
Department of Biochemistry, The George Washington University Medical Center, Washington, D.C. 20005 and
Department of Biochemistry, University of Miami SchooZ of Medicine, Miami, Florida 33152
Received
November
12, 1971
S UMMARY: The ability of glucose to assist the action of phosphorylase a phosphatase on phosphorylase a, appears to be mediated through conformational changes in the phosphoryl ase. The system is an example of control of enzyme activity by regulation of the conformation of the substrate, and parallels the similar effect of AMP in inhibiting the dephosphorylation. INTRODUCTION Phosphorylase the
“inactive”
The
best
b form studied
inhibits
a phosphatase by
examples
this of
It
was
thereby
of
the
substrate
AMP
effect,
than
lase
a.
to AMP
to
muscle
(3)
and
liver
is
to
an
from favored
have
0 1972 by Academic
AMP
the that
(4)
the
interaction
of
glucose
latter effects
tetramer
on
the
formation
while
Press, Inc.
dephosphory-
the
promotes a.
with since
state
of
AMP
phosphorylase
alter
phosphatase,
possibility
(1).
a.
conformation
(2).
phosphorylases of
the
to
enzyme glucose
rate
from is
residue.
muscle
the
a into
a serine
rabbit
affect
activation
opposing
promotes
of
191 Copyright
not
from
from
isolated
inhibit
reported
due
does
phosphorylase
group
are
action
was
results
also
the
it
evidence
known
that
rather
this
stantial
enzymes
tetradecapeptide
concluded
of
whether
these
a phosphate
but
a phosphorylated
Recently both
of
of
dephosphorylation,
lation
sion
cleavage
“active”
converts
of glucose
the We have or
the
a + b converinvestigated
rather,
like
substrate. AMP
and
Ci rcumglucose
aggregation favors
the
of the
are phosphory-
dimer
(5).
Vol. 46, No. 1, 1972
Furthermore,
BIOCHEMICAL
the
temperature
(5),
at
phosphorylase
form
which
temperatures
of
glucose
cleavage
by
AMP
both
being
or
assisting
variety
glucose
appears
to
have
effects
of
glucose
positive piece
of
is
at
evidence
phosphorylase
chymotrypsin
study
learned
colleagues
have
MATERIALS
confirms
rabbit
AND
is
enhanced
the by
physiological no
effect were
implicating
the
observation
that
glucose
on
(7)
and
noted actions
opposed
by
that
in
an
come
to
a similar
mlJ)
of 1 ml
Pi
protein
(10).
of
and
remaining
by on
I mU of
convert
1 mU
the
enzyme
NaCl was
(approx
25
gradient eluted
53 mU per
phosphatase protamine
in
protease
prepared
treatment
glucose
in
phosphorylase. Hers
and
his
with
(25ug)
dried
on
filter
washing
in
50%
dried
2 X crystallized
phosphorylase
b kinase
activity
with
of
aqueous was
range The activity
(1X3
ethanol,
and
determined
defined
as
phosphorylase
that a
was on
amount into
purified
b per from
salt,
enzyme was
essentially
tested
casein.
192
and
against
the
~1)
were The
liber-
32P-label
liquid
led
scintillation enzyme
which
will
min. rat
1 iver
The
bulk
specific free
by
containing
cm).
of
DEAE-cellulose.
0.28-0.32~
when
by
assayed
8.16, (100
strips
and
phosphatase
pH
Samples paper
phosphatase
was
phosphorylase buffer,
strips is
ng) a
the
from
phosphatase
chromatography
mg protein. and
and
H.G.
1OmM mercaptoethanol.
phosphatase
Phosphorylase by
of
(9).
tris-glycerophosphate and
removed
counting.
effect with
Dr.
a was
Phosphorylase
0.02M
intervals
was
study,
phosphorylase
acetate
at
the
interaction
conclusion
a by
labelled
3mM magnesium removed
that
by
phosphorylase
ATP
in
indeed
independent
phosphorylase
y-32P-labelled incubation
inference
METHODS
muscle
ated
the is
32 P-Labelled
was
on
dephosphorylation
We have
ates
exclusive
(8). This
(24
The
A final
30”.
trypsin
the
(6).
below and
is
temperature
inactivation
at
AMP
dimeric
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
from
phosphorylated
homogenof
the
activity non-specific histone,
Vol. 46, No. 1, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RESULTS When was
inhibited
the 90%
phosphatase by
0.1
acted
mM AMP,
on
phosphorylase
16.7 mM glucose
while
15” the
a at doubled
react
the
ion
rate
of
200+ AMP
I 40
0
I 80
I 120
I 160
TIME (minutes)
Fig. 1. Influence of glucose and AMP on the action of phosphorylase j2P-Labelled phosphorylase a was incubated phosphatase on phosphorylase a. with 16.7 mM glucose or 0.1 mM AMP at 15” with phosphorylase phosphatase, added as indicated. Samples were removed at intervals for determination of the 32P-labelled protein remaining (see Materials and Methods).
reaction
(Fig.
I).
Other
During ratio
of
its
constant
the
glucose
effect
was
When charcoal at
treatment,
37”.
AMP
still
(Fig.
2).
Only
at
overcome
levels
the
AMP
Paralleling phorylation is
tetrameric
were at
Is”,
no
on
absence
was
effect.
of
DEAE-cellulose, glucose
unlikely
a was by the
the
freed
glucose
enzyme fact
at
that
10 uM AMP,
that
the
system. completely
was
maximal
37”
and
the
the
remained
therefore
phosphatase-activating
below
sugar however,
from at
15-20’
a glucose
by and
absent
effect
opposed was
AMP
the
at
AMP
glucose
37”
inhibition
able
complete
inhibition. the
the
It
phosphorylase
from
and
profile.
a separate
or
phosphatase
presence
inhibited
demonstrated
1 ittle of
stimulation
be
to
the
enzyme on
the
could
ly
in
the
had
fractionation
activity
across
sugars
effects
ultracentrifugal wholly
of
glucose
and
observations dimeric
at
35”,
193
AMP that
and
dimer
on
the
rate
of
phosphorylase appears
at
dephosa
15”
if
Vol. 46, No. 1, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
240
4
6
AMP (lo-’
M)
Fig. 2. Restoration of the glucose sensitivity of the dephosphorylation of phosphorylase a at 37” by addition of AMP. The activity of the phosphatase was measured in the presence and absence of 28 mM glucose, with increasing amounts of AMP. The j2P-labelled phosphorylase had been treated with charcoal to remove AMP. See Materials and Methods for conditions.
Table
1.
Influence behaviour
of of
added a
glucose
on
the
Component(s) (dimer)
S1
sedimentation
observed S2 (tetramer)
15"
none
none
15.3
15"
g 1 ucose
9.8
14.7
23
g 1 ucose
9.8
13.9
35"
none
9.0
none
35"
g 1 ucose
9.1
none
35"
glucose
9.5
none
The solvent plus 0.01 coefficients
glucose
the
and
Additions
Temperature
in
temperature phosphorylase
was the phosphatase assay M NaCl, with 55 mM glucose in are-corrected to 20’
is
added
concentrations
(Fig. at
phosphorylase
was
32P-Labelled labelled
+ AMP
phosphorylase
3,
Table
which wholly
peptides a with
At 35",
1).
AMP
inhi
dimeri
buffer (see and 1 mM AMP water.
bition c were
of
and
AMP is
present manifested,
1 1.
prepared
194
glucose
and Methods) Sedimentation
dephosphorylation
(Table
chymotrypsin
with
Materials as noted.
by or
trypsin.
brief
treatment Neither
of glucose
nor
Vol. 46, No. 1,1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Influence of temperature and added glucose on the sedimentation Fig. 3. A, sedimentation of phosphorylase of phosphorylase a in the ultracentriguge. Lower curve, plus 55 mM glucose. Speed a at 15”. Upper curve, control. Movement from left to right. D and T 60,000 rev./min. Time 18 min. indicate the positions of the dimeric and tetrameric forms of phosphorylasee a. B, Sedimentation of phosphorylase a at 35”. Upper curve, phosphorylase Lower curve, phosphorylase b as reference. Note that phosphorylase u a. behaves as a tetramer at 15” but is completely dissociated to dimer at 35”. Addition of glucose at 15” causes the appearance of dimer (see also Table 1).
AMP is
affected
their
already
rates
known
(2,
of
dephosphorylation.
This
lack
of
effect
of
AMP
11).
DISCUSSION The that
the
effect
like
that
of
not
AMP
the
This
dimer
opposition at
ultracentrifuge
the
tetramer
37”
se
of
the (Fig.
on
on
the
was
that
the
is
2), shows
glucose
well
not
a substrate.
when
no
only
the
to
produce
glucose effect dimeric
was
was
and
shown
AMP on
of
glucose form
195
phosphorylase,
to
produce
dimer,
2,
is Table
a
a substrate.
cannot the
was
fact
be
the
case
that
dephosphorylation alone
(Fig.
not it
from
is,
however,
tetramer,
a substrate,
This
inference
inference,
effect
be
original
of
Another
was
of
our
dephosphorylation
the
very
effects
confirmed
substrate.
AMP effect may
per
experiment
glucose (2),
while
While
seen
of
sustained.
substrate,
that
last-mentioned
an can
noted, 1).
and
be
when
We have
the to
Vol. 46, No. 1, 1972
conclude and
that
there
stabilized
else
effect
of
ble.
When,
AMP,
the
effects
any
physiological
range In
early
AMP of
it
from
as
one
expose
of
can the
in and
(Fig.
inhibiting
trypsinolysis
include
the
resistant
opposing for
the
the
regulation
a substrate. of
glucose
reaction
is
glucose phosphate
the
b,
negligi-
We
producing in
the
mM).
serine
explaining
The
a and
envisage
It
2).
any is
mechanism
concentration
action.
a parallel
enhancing
products
terms
that form
phosphorylase
(4-5
rapid
of
a significant
the
At susceptible
stabilization
dephosphorylation glucose
to
in
so
the
susceptible
its
phosphatase,
glucose. in
is
phosphorylases
the
blood
phosphatase
finds
to
of
the
the
37")
point
level,
all
forms
to
to
by
demonstrated
changes
for
a so
be
levels
molecular
phosphorylase
respectively
to
resistant
either
two
change at
metabolites
given
stimulation
also
effect
is
the
present
relative
half-maximal
shield
is
one
stabilized a
the
conformational
at
dimer,
susceptible,
promoting
two the
on that
model
one
the
between
AMP
these of
depending
in
a glucose
regulation
to
and
of
phosphorylase
however,
of
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
forms
equilibrium
glucose
permits
noted
two
temperature
or
form
are
by
physiological form,
BlOCHEMlCAL
is
significant
the
effects
effects
as
reacting
group,
and that
of of
AMP
so
this
as
crude
glucose
trypsin,
phosphorylated
with
and since
AMP the
(8).
peptides
ACKNOWLEDGEMENTS This AM
10082
of
absence
and
work
was
AM 12532, at
the
supported and
was
University
by
U.S.
carried
of
Public
out
while
Health J.M.
Service Bailey
Grants was
on
leave
Miami.
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Fischer,
E.H.,
Packer,
A.
and
Saari,
J.C.,
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Biochemistry
6:32 (1970). 2.
Nolan,
3.
Holmes,
4.
Stalmans,
C., 3:542
Novoa,
W.B.,
Krebs,
E.G.
and
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E.H.,
Biochemistry
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P.A.
and
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P.E.,
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Biophys.
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256:266,
275
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H.,
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H-G.,
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Wang,
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Comtun.
Shonka, ~8:
Torres,
H.N.
and
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A.J., Met&oZism,
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Fischer,
E.H.,
Graves,
D.J.,
Crittenden,
E.R.S.
and
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E.G.,
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DeBarsy,
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Krebs,
II.
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Stalmans,
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and
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H.G.,
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New and
11971).
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