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Isolation and characterization of two 70 kDa modulator-complexes from rabbit skeletal muscle
BIOCHEMICAL
Vol. 135, No. 2, 1986
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 367-373
March 13, 1986
IBOLATIONANDCBARACTERIZATION OF TWO70 kDa MODULATOR-CORPLEXEB FROMRABBIT BXELETALMUSCLE Jackie R.Vandenheede*, Carline Vanden
Afdeling Received
Biochemie,
January
21,
Abeele and Wilfried
Faculteit Geneeskunde, Katholieke Leuven, B-30&7 Belgium
Merlevede
Universiteit
1986
The activation as well as the inactivation of the ATP,Mg-dependent protein phosphatase has been shown to be totally dependent upon the presence of the modulator subunit. This modulator (inhibitor-21 is a heat stable protein and its isolation in pure form (32 kDa) always includes a boilin& step. The boiled modulator fractions are known to be inhibitory to the phosphatase activity. Unboiled rabbit skeletal muscle preparations do not contain “free modulator”, but two higher molecular weight complexes (70 kDa) can be isolated One complex is which have the 32 kDa modulator toeether with a 38 kDa protein. the already characterized inactive ATP,Mg-dependent phosphatase [FCM] while the second one, HI, although seemingly of identical composition, does not exhibit phosphatase activity when measured under the usual conditions. The RX-complex does not inhibit the phosphatase activity unless subjected to a boiling step which dissociates the modulator subunit. The unboiled [MXI exhibits the activation as well as the inactivation characteristics of the free modulator. m1986 Academic
Press,
Inc.
The heat stable modulator [Ml represents a very unit of
the inactive
ATP,Mg-dependent phosphatase [F,$lI
[Ml
FA unless exogeneous modulator is added (1).
by kinase FA is a necessary step in the activation
and the
heat-stable
protein
The phosphorylation
of
of the phosphatase (4-6)
ATP,Mg-dependent form (l-4,7).
ATP,Mg-dependent phosphatase does not result
modulator from the catalytic
(l-3).
is also responsible for the conversion of the ac-
tive phosphatase to the inactive of the
sub-
An inactive FCn) cannot be activated
phosphatase which does not have modulator bound (“free by kinase
regulatory
important
The activation
in the dissociation
subunit (5) and we have recently
of the
reported that un-
boiled muscle preparations do not contain free modulator (2). This would suggest that at all times, the modulator is a constituent of higher mol. wt. complexes.
It copurifies
constitutes gen particle
with the inactive
a regulatory which only
modulator activity
subunit,
ATP,Mg-dependent phosphatase, where it
and it is also present in the isolated glyco-
contains active
phosphatase (7).
is associated with heat-labile
kDa complex in sucrose density gradients
(2,7).
In both cases the proteins and migrates as a 70 Isolation
of pure modulator
*To whomcorrespondence may be adressed. 0006-291X/86 367
$1.50
Copyright 0 1986 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL
always requires
a dissociating
potent inhibitor
of the phosphatase activity.
it as the heat-stable 70 kDa heat-labile
“inhibitor-2”
unit.
phosphatase to
This property originally
tunboiled)
its inactive
nase FA-mediated activation
is a
labeled
The present report characterizes
(10).
and is not
preparation reveals
The intact
step (8.9) and the boiled protein
modulator complex [Mxl which has little
dent phosphatase activity Boiling the
boiling
RESEARCH COMMUNICATIONS
inhibitory
the inhibitory
to
or no ATP,Mg-depen-
the active
capacity
a
phosphatase.
of its modulator sub-
RX-complex is however able to convert the active ATP,Mg-dependent form, and also stimulates the ki-
of a “free FC” enzyme.
MATERIALSANDMETHODS Materials and methods were as described in previous reports (1,5,6,12). The activity of the inactive ATP,Mg-dependent phosphatase was commonly measured after a 10 min preincubation at 30°C with 0.2 mI4ATP, 1 mM Mg2+ and the minimal amount of kinase FA required for full activation under the conditions used. The phosphatase activity unit is defined as the amount of enzyme which releases 1 nmol of [32Pl phosphate per min at 30°C from 32P-labeled phosphorylase a (2 me/ml). The assay time was 5 min unless mentioned otherwise. The preparation of “free PC” (1) had a specific activity of approximately 15,000 units/me when measured in the presence of optimal concentrations of modulator (1,5). In the absence of exogeneously added modulator, only 1,200 units of phosphorylase phosphatase were measured after activation by kinase FA and AP,Mg. The heat-stable modulator was purified to homogeneity from rabbit skeletal muscle as described in (6). The modulator activity was determined by measuring the increase in the kinase FA mediated activation of “free FC”(5.6): 5OmlJ“free FC“was usually preincubated at 30°C for 10 min with kinase FAATP,Mg and modulator and the phosphorylase phosphatase activity produced was measured in a 5 min assay. The active phosphatase catalytic subunit was isolated from rabbit skeletal muscle essentially as described in (11). It had a specific activity of about 50,000 U/w as phosphorylase phosphatase, and could be completely converted to the ATP,Mg-dependent form by preincubation with modulator. 10% Polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulfate (SDBPA6E) was performed according to (13) using the Idea 8cientific mini-slab. Marker proteins were myosin (210 kDa), phosphorylase b (95 kDa), bovine serum albumine (68 kDa), ovalbumin (43 kDa) and a-chymotrypsinogen (27 kDa). (17 hrs, 2V, 48,000 rpm) were Sucrose density gradient centrifugations performed using a Beckman BW50.1 rotor with 14C-labeled ovalbumin as marker protein (43 kDa). Approximate mol. wts were calculated according to (16).
RESULTSAND DISCUSSION 1) )I
- n of Extracts
t ions were prepared from 1.5 kg of rabbit
skeletal
muscle as described
in (12), all buffers containing the proteinase inhibitors and EGTAthroughout the isolation procedure. The whole extract (pH 7.0) was adsorbed batchwise onto 25 g of
DEAE-SephadexA-50, equilibrated 368
in buffer
A
120 mMTris,
1 mM di-
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS 0.4
8 %
a2 0.1
0
20
if Fig.
1.
60
FRACTION
M NaCl in buffer
proteins were then eluted
from the
0.2 M to 0.4 M NaCl in buffer the modulator
activity
A.
A before packing the column.
The
column with a 2x500 ml salt gradient from
(measured after
50% saturation).
(12)l and the resin was ex-
The ATP,Mg-dependent phosphatase activity boiling
coeluted and were pooled and concentrated (at
13
NUMBER
1 mMEGTA and proteinase inhibitors washed with 0.2
sulfate
0
60
Phenyl SephoroseU3 chromatography:gradient elution started at fraction one; ATP,lQ-dependentphosphataseactivity (01 and modulator activity to) measuredas stimulation of free FC-activation by kinase FA (5). protein concentrations were measuredby the absorption at 260 rxnand are indicated by the dotted line.
thiothreitol, tensively
LO
by
The precipitated
buffer A and the solution was made 1
M
the
individual
precipitation proteins
and
fractions)
with
awnonium
were redissolved in
in ammonium sulfate.
After
a clarifying
spin (10 min at 10,000 x g), the solution was adsorbed onto a column of phenylSepharose 48 (1.5~20 The proteins
were
cm) equilibrated
then
eluted with
containinS 1 M ammoniumsulfate elution
profile
tor activity
buffer A plus 1 M ammoniumsulfate.
a 2x200 ml linear gradient
to buffer
is shown in Fig. 1.
A
from buffer
containing 20% ethyleneglycol.
Two partially
A
The
overlapping peaks of modula-
were observed, only one of them corresponding to the ATP,Mg-depen-
dent phosphatase activity. separated from the activitybar (Fig.
in
1) the
conductivity
The vast majority of the other proteins were well fractions. After pooling as indicated by the solid
solution was dialyzed
of 0.1 M NaCl in buffer
until A.
the conductivity
The dialyzed
dropped below the
proteins were then passed
over a column of Blue Sepharose CL-68 (0.9~10 cm) onto a poly-L-lysine Sepharose column (0.9~10 cm). After applying the sample, the two columns were processed individually. The Blue Sepharose column was washed with 0.1 M NaCl in bound modulator
was then
ATP,Mg-dependent phosphatase
eluted with activity
0.2 M NaCl in
buffer
buffer
A.
was found in these fractions
A,
and the
Virtually
no
(Table I).
Roughly 40% of the total modulator activity present in the phenyl-Sepharose fraction was retained by the Blue Sepharose resin: this corresponds to the modulator
which
eluted ahead of the ATP,Mg-dependent phosphatase activity 369
in the
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table purification
of the heat-labile
I
modulator-complexes
Fraction
protein (me)
DEAE-Sephadex A-50 Phenyl-Sepharose 45 Blue Sepharose CL-68 (0.2 M NaCl eluate fraction) Poly-L-lysine Sepharose 48
390 8.5 0.2-0.4
(') Phosphorylase and ATP,m
activity
Modulator’ activity (Units x 10V3)
0.8
phosphatase
seemed to be complexed in
known not the
to bind
to the
poly-L-lysine
NaCl in
buffer
by dialysis
muscle
Phosphatase( ’ ) activity (Units x 10m3)
55 60 0.2-l .o
62
34
measured after
activation
by kinase
FA
1).
The rest of the modulator ac-
the inactive
phosphatase as [FCM], which is
Blue Sepharose resin (4,12).
resin with
skeletal
300 180 10-50
phenyl-Sepharose chromatography step (Fie. tivity
from rabbit
a linear gradient
(2x100 ml) from 0.2 M to 0.4 M
A (not shown). The two fractions
against 10% polyethyleneglycol
It was recovered from
were concentrated separately
in buffer
A, and stored at -2OV in
the presence of 50%glycerol. The ATP,Mg-dependent phosphatase isolated known aspect
from the
protein staining contained the catalytic
one isolated
activity,
38 kDa and 32 kDa proteins
two
discussed in (6).
so that at 1:l
molar ratio
The modulator
showedthe
same
suggest the
fraction
by kinase the
which
FA nor identity
modulator
fraction
represents
the
activity
by metal
ions
of
the two
which binds 38 kDa component
mainly
which represent
the
The enzyme seemedto
of the
ratio
phosphatase activity
could raise the phosphatase unit
is expected,
is indicated by the Coomassie activity
by kinase FA was about 40,000 U/me.
was retained
by the
Blue
bands on SDS-PAGE(Fig.
presence of the 38 kDa catalytic
phosphorylase phosphatase Until
2A),
of modulator to catalytic
activation
no
than ATP,Mg-dependent phosphatase
with trypsin
protein staining
two
The preparation
of the two proteins on SDS-PAGE. The specific
enzyme after
in
(12) except that the 62 kDa
(14,15).
inhibition
A similar
measurements.
blue staining
of the inactive
partial
Limited proteolysis
based on activity brilliant
the
(Fig.
respectively
more modulator activity
times
which reflects
activity
according to
way differed
band seen in SDS-PAGE(5) was absent.
and modulator subunits
have about
in this
subunit.
However,
Sepharose
resin
which may no significant
2A),
could be brought out of the preparation,
with
or without
38 kDa
an additional
proteins is proven,
trypsin
not
treatment.
we shall label the
to the Blue Sepharose resin as HI where [Xl of the modulator complex under investigation. 370
Vol. 135, No. 2, 1986
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
lane
1
2
3
FRACTION NUMBER Fig.
2.
SDS-PAS8 of 2 jog of modulator purified as in (5) (lane FCM-enzyme (lane 2) and 4 JIB of [MXI (lane 3) at the final purification (see text). A:
B and C: Sucrose density gradient centrifugatfon: (8) or boiled [MX] (C) were put on the gradient bumin as ml. wt. marker.
1);
4 fig
stages of
2 U of "native" MXI together with 14C-oval-
2) Ch ) Fig. 28 shows the migration of the MX-complex in sucrose density gradient centrifugation.
The modulator activity,
measured as stimulation
of the kinase
FA mediated “free FC” activity (5), was determined after boiling the individual fractions of the gradient and was localized several fractions ahead of the marker protein Boiling the
14C-ovalbumin, indicating
MX-complex
prior
of the usual “free modulator” (Fig. Gel filtration for the wt. of protein identical
native 65,000
known kinetic
This is
dependency of
the
gave an apparent
The modulator
protein
and [FCMI migrates
obtained
after
illustrated
added [MXI or boiled [Mxl.
wt.
in
of 140,000
as a 120-140 boiling
kDa
EMXI was (B,9) in all
The unboiled MX-complex however differed
modulator in that it was not inhibitory kinase
mol.
according to the published reports
aspects.
of 70,000.
in the appearance
Free modulator is known to have a mol.
columns
or molecular
from the heat-stable activity.
AcA-34
sieving
the one purified
mol. wt.
resulted
2C) with a mol. wt. of 17,000.
MX-complex (not shown).
(2,3,B). to
using Ultrogel
in molecular
an approximate
to the centrifugation
Figure 3.
to the phosphatase
Fig. 3A shows the concentration
FA mediated activation
of “free FC” on exogeneously
The boiled MX-preparation shows the biphasic tstim371
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
3.E @ 50 z 2 B=T” w 25 8 0I:0 8Y
5
10-2zlo
\ . 0
MX(ng)
2
Fig. 3. Determination
of the different
5
0'
10 50 loo MX(ng)
modulator
10
20
TIMEImin)
activities.
stimulation of the kinase FA-mediatedactivation of 50 mU of “free FC” 2.5 to 100 ng of native [MXI to) or boiled [Hxl (0) were addedin the activation mixture (20 ~1) of “free FC”, kinase FA and ATP,Mg as outlined in (5). Concentrations indicate the wount of protein present before the boiling step. A:
Inhibition of 50 mU of active phosphatasecatalytic subunit by different amountsof u&oiled to) and boiled (0) [XXI. The DlXI proteins were not preincubated with the phosphataseand a 2 min assay was performed. B:
C: Time-dependentinactivation of 50 mU of active phosphatasecatalytic subunit by 10 ng of unboiled to) or boiled (0) NXI. The [MXI and phosphatasewere preincubated at 3OW for different periods of time, before a 2 min assaywasperformed. ulation-inhibition)
curve,
typical
of
the free modulator
Cl),
whereas
the
na-
tive MX-complex does not produce the phosphatase inhibition at the higher concentrations used. Similarly, [Hxl did not inhibit the activity of the phosphatase catalytic
subunit, whereas identical
an instantaneous inhibition able to
convert the
(Fig. 3B).
concentrations
Surprisingly,
active phosphatase catalytic
of boiled [KU] caused
the native MX-complex was subunit to the ATP,Mg-depen-
dent enzyme form at the samerate as the boiled modulator (Fig. 3C). plest explanation
for these results
is to invoke two separate binding sites for
modulator on the phosphatase catalytic versible
activation/inactivation
subunit: one site which governs the re-
of the phosphatase, and a separate inhibitory
site which can only be occupied by “free modulator”, ical MX-complex.
In vivo this putative
served for the regulation lated) inhibitor-l. In this site similar identical to
The sim-
of the
hypothesis, the
inhibitor
not by the more physiologsite
may
be specifically
phosphatase by the heat-stable
X-protein
re-
(phosphory-
bind the modulator at a specific If [Xl would be to the “inhibitory site” on the phosphatase. the FC-protein, then we could envisage the MX-complex as an FCMmay
enzyme which has modulator bound at the inhibitory site, instead of at the usuThe portion of the modulator which binds to al activation/inactivation site. the activation/inactivation site on the phosphatase may be fully exposed in the native [MXI, so that the interconverting properties of the modulator can be measured without a dissociating
boiling
step. 372
Vol.
135,
No. 2, 1986
BIOCHEMICAL
[MX] differs be revealed is
Both
from the normal [FCM] in that
proteolysis
retained
by
characteristics
sites
between
in the presence
argue
This is however
cogen particles
which
ated with
them,
modulator
activity
ulator-complex described
but
the
its
potential
such as activation
of metal ions
that
highly
FC-protein [Xl
in the two
may
simply
unlikely
since
have a considerable no inactive
(15)
COMMUNICATIONS
activity
cannot
by kinase
FA (5)
and secondly
because
found to
form (7).
be identical
complexes.
represent
a denatured
preparations amount of active do contain
F,$-enzyme,
in a 70 kDa
were
RESEARCH
the Blue-Sepharose resin as is also the free modulator (8). be explained by the difference in the binding may again
the M- and
One could unit.
BIOPHYSICAL
by any of the known procedures
or limited it
AND
The properties
FC-catalytic
of rabbit
muscle gly-
phosphatase an
associ-
equal amount
of this
to the characteristics
of
70 kDa modof the [MX]
here (not shown).
ACKNOWLEDGEMENT8 JRV is a Senior Research Associate of the “Nationaal Fords voor Wetenschappel i jk Onderzoek”. This work was supported by the “Ponds voor Geneeskundig Vetenschappelijk Ondmmek” and by the “Onderzoeksfonds K.U.Leuven”. The authors are grateful to Mr L. Vanden Bosch for expert technical assistance.
REFERENCES Chem. 256,
2.
Yang, S.-D., Vandenheede, J.R. ad Merlevede, W. (1983) Biochem. Biophys. Res. Comun. 113, 439-445. Herlevede, W., Vandenheede, J.R., Goris, J. and Yang, S.-D. (1984) Curr. Top. Cell. Regul. 22, 177-215. Hemmings, B.A., Resink, T.J. and Cohen, P. (1982) FEBSLett. 150, 319-324. Jurgensen, S., Shatter, E., Huang, C.Y., Chock, P.B., Yang, S.-D., Vandenheede, J.R. and Merlevede, W. (1984) J. Biol. Chem. 259, 5864-5870. Vandenheede, J.R., Yang, S.-D., Merlevede, W., Jurgensen, 5. and Chock, P.B. (1985) J. Biol. Chem. 260, 10512-10516. Vandenheede, J.R.,Yang, S.-D. and Merlevede, W. (1983) Biochem. Biophys. Res. Common.115, 871-877. Yang, S.-D., Vandenheede, J.R. and Merlevede, W. (1981) FEBSLett. 132,
4.
5. 6. 7. 8.
W.
(1981) J. Biol.
Yank, 10231-l
3.
S.-D., 0234.
Vandenheede, J.R. and Merlevede,
1.
293-295. 9. 10. 11. 12.
Foulkes, J.G. and Cohen, P. (1980) Eur. J. Biochem. 105, 195-203. Huang, F.L. and Glinsmann, W.H. (1976) Eur. J. Biochem. 70, 419-426. Tung, H.Y.L., Resink, T., Hemmings,B.A., Shenolikar, S. and Cohen, P. (1984) Eur. J. Biochem. 138, 635-641. Vandenheede, J.R., Yang, S.-D. and Merlevede, W. (1981) J. Biol. Chem. 256, 5894-5900.
Laemnli, V.K. (1970) Nature 227, 680-685. 14. Tung,H.Y.L. and Cohen, P. (1984) Eur. J. Biochem. 145, 57-64. 15. Villa-Moruzzi, E., Ballou, L.H. and Fischer, E.H. (1984) J. Biol. 13.
259, 16.
5857-5863.
Martin,
R.G. and Ames, B.N. (1961) J. Biol.
373
Chem. 236. 1372-1379.
Chem.
Vol. 135, No. 2, 1986
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 367-373
March 13, 1986
IBOLATIONANDCBARACTERIZATION OF TWO70 kDa MODULATOR-CORPLEXEB FROMRABBIT BXELETALMUSCLE Jackie R.Vandenheede*, Carline Vanden
Afdeling Received
Biochemie,
January
21,
Abeele and Wilfried
Faculteit Geneeskunde, Katholieke Leuven, B-30&7 Belgium
Merlevede
Universiteit
1986
The activation as well as the inactivation of the ATP,Mg-dependent protein phosphatase has been shown to be totally dependent upon the presence of the modulator subunit. This modulator (inhibitor-21 is a heat stable protein and its isolation in pure form (32 kDa) always includes a boilin& step. The boiled modulator fractions are known to be inhibitory to the phosphatase activity. Unboiled rabbit skeletal muscle preparations do not contain “free modulator”, but two higher molecular weight complexes (70 kDa) can be isolated One complex is which have the 32 kDa modulator toeether with a 38 kDa protein. the already characterized inactive ATP,Mg-dependent phosphatase [FCM] while the second one, HI, although seemingly of identical composition, does not exhibit phosphatase activity when measured under the usual conditions. The RX-complex does not inhibit the phosphatase activity unless subjected to a boiling step which dissociates the modulator subunit. The unboiled [MXI exhibits the activation as well as the inactivation characteristics of the free modulator. m1986 Academic
Press,
Inc.
The heat stable modulator [Ml represents a very unit of
the inactive
ATP,Mg-dependent phosphatase [F,$lI
[Ml
FA unless exogeneous modulator is added (1).
by kinase FA is a necessary step in the activation
and the
heat-stable
protein
The phosphorylation
of
of the phosphatase (4-6)
ATP,Mg-dependent form (l-4,7).
ATP,Mg-dependent phosphatase does not result
modulator from the catalytic
(l-3).
is also responsible for the conversion of the ac-
tive phosphatase to the inactive of the
sub-
An inactive FCn) cannot be activated
phosphatase which does not have modulator bound (“free by kinase
regulatory
important
The activation
in the dissociation
subunit (5) and we have recently
of the
reported that un-
boiled muscle preparations do not contain free modulator (2). This would suggest that at all times, the modulator is a constituent of higher mol. wt. complexes.
It copurifies
constitutes gen particle
with the inactive
a regulatory which only
modulator activity
subunit,
ATP,Mg-dependent phosphatase, where it
and it is also present in the isolated glyco-
contains active
phosphatase (7).
is associated with heat-labile
kDa complex in sucrose density gradients
(2,7).
In both cases the proteins and migrates as a 70 Isolation
of pure modulator
*To whomcorrespondence may be adressed. 0006-291X/86 367
$1.50
Copyright 0 1986 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL
always requires
a dissociating
potent inhibitor
of the phosphatase activity.
it as the heat-stable 70 kDa heat-labile
“inhibitor-2”
unit.
phosphatase to
This property originally
tunboiled)
its inactive
nase FA-mediated activation
is a
labeled
The present report characterizes
(10).
and is not
preparation reveals
The intact
step (8.9) and the boiled protein
modulator complex [Mxl which has little
dent phosphatase activity Boiling the
boiling
RESEARCH COMMUNICATIONS
inhibitory
the inhibitory
to
or no ATP,Mg-depen-
the active
capacity
a
phosphatase.
of its modulator sub-
RX-complex is however able to convert the active ATP,Mg-dependent form, and also stimulates the ki-
of a “free FC” enzyme.
MATERIALSANDMETHODS Materials and methods were as described in previous reports (1,5,6,12). The activity of the inactive ATP,Mg-dependent phosphatase was commonly measured after a 10 min preincubation at 30°C with 0.2 mI4ATP, 1 mM Mg2+ and the minimal amount of kinase FA required for full activation under the conditions used. The phosphatase activity unit is defined as the amount of enzyme which releases 1 nmol of [32Pl phosphate per min at 30°C from 32P-labeled phosphorylase a (2 me/ml). The assay time was 5 min unless mentioned otherwise. The preparation of “free PC” (1) had a specific activity of approximately 15,000 units/me when measured in the presence of optimal concentrations of modulator (1,5). In the absence of exogeneously added modulator, only 1,200 units of phosphorylase phosphatase were measured after activation by kinase FA and AP,Mg. The heat-stable modulator was purified to homogeneity from rabbit skeletal muscle as described in (6). The modulator activity was determined by measuring the increase in the kinase FA mediated activation of “free FC”(5.6): 5OmlJ“free FC“was usually preincubated at 30°C for 10 min with kinase FAATP,Mg and modulator and the phosphorylase phosphatase activity produced was measured in a 5 min assay. The active phosphatase catalytic subunit was isolated from rabbit skeletal muscle essentially as described in (11). It had a specific activity of about 50,000 U/w as phosphorylase phosphatase, and could be completely converted to the ATP,Mg-dependent form by preincubation with modulator. 10% Polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulfate (SDBPA6E) was performed according to (13) using the Idea 8cientific mini-slab. Marker proteins were myosin (210 kDa), phosphorylase b (95 kDa), bovine serum albumine (68 kDa), ovalbumin (43 kDa) and a-chymotrypsinogen (27 kDa). (17 hrs, 2V, 48,000 rpm) were Sucrose density gradient centrifugations performed using a Beckman BW50.1 rotor with 14C-labeled ovalbumin as marker protein (43 kDa). Approximate mol. wts were calculated according to (16).
RESULTSAND DISCUSSION 1) )I
- n of Extracts
t ions were prepared from 1.5 kg of rabbit
skeletal
muscle as described
in (12), all buffers containing the proteinase inhibitors and EGTAthroughout the isolation procedure. The whole extract (pH 7.0) was adsorbed batchwise onto 25 g of
DEAE-SephadexA-50, equilibrated 368
in buffer
A
120 mMTris,
1 mM di-
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS 0.4
8 %
a2 0.1
0
20
if Fig.
1.
60
FRACTION
M NaCl in buffer
proteins were then eluted
from the
0.2 M to 0.4 M NaCl in buffer the modulator
activity
A.
A before packing the column.
The
column with a 2x500 ml salt gradient from
(measured after
50% saturation).
(12)l and the resin was ex-
The ATP,Mg-dependent phosphatase activity boiling
coeluted and were pooled and concentrated (at
13
NUMBER
1 mMEGTA and proteinase inhibitors washed with 0.2
sulfate
0
60
Phenyl SephoroseU3 chromatography:gradient elution started at fraction one; ATP,lQ-dependentphosphataseactivity (01 and modulator activity to) measuredas stimulation of free FC-activation by kinase FA (5). protein concentrations were measuredby the absorption at 260 rxnand are indicated by the dotted line.
thiothreitol, tensively
LO
by
The precipitated
buffer A and the solution was made 1
M
the
individual
precipitation proteins
and
fractions)
with
awnonium
were redissolved in
in ammonium sulfate.
After
a clarifying
spin (10 min at 10,000 x g), the solution was adsorbed onto a column of phenylSepharose 48 (1.5~20 The proteins
were
cm) equilibrated
then
eluted with
containinS 1 M ammoniumsulfate elution
profile
tor activity
buffer A plus 1 M ammoniumsulfate.
a 2x200 ml linear gradient
to buffer
is shown in Fig. 1.
A
from buffer
containing 20% ethyleneglycol.
Two partially
A
The
overlapping peaks of modula-
were observed, only one of them corresponding to the ATP,Mg-depen-
dent phosphatase activity. separated from the activitybar (Fig.
in
1) the
conductivity
The vast majority of the other proteins were well fractions. After pooling as indicated by the solid
solution was dialyzed
of 0.1 M NaCl in buffer
until A.
the conductivity
The dialyzed
dropped below the
proteins were then passed
over a column of Blue Sepharose CL-68 (0.9~10 cm) onto a poly-L-lysine Sepharose column (0.9~10 cm). After applying the sample, the two columns were processed individually. The Blue Sepharose column was washed with 0.1 M NaCl in bound modulator
was then
ATP,Mg-dependent phosphatase
eluted with activity
0.2 M NaCl in
buffer
buffer
A.
was found in these fractions
A,
and the
Virtually
no
(Table I).
Roughly 40% of the total modulator activity present in the phenyl-Sepharose fraction was retained by the Blue Sepharose resin: this corresponds to the modulator
which
eluted ahead of the ATP,Mg-dependent phosphatase activity 369
in the
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table purification
of the heat-labile
I
modulator-complexes
Fraction
protein (me)
DEAE-Sephadex A-50 Phenyl-Sepharose 45 Blue Sepharose CL-68 (0.2 M NaCl eluate fraction) Poly-L-lysine Sepharose 48
390 8.5 0.2-0.4
(') Phosphorylase and ATP,m
activity
Modulator’ activity (Units x 10V3)
0.8
phosphatase
seemed to be complexed in
known not the
to bind
to the
poly-L-lysine
NaCl in
buffer
by dialysis
muscle
Phosphatase( ’ ) activity (Units x 10m3)
55 60 0.2-l .o
62
34
measured after
activation
by kinase
FA
1).
The rest of the modulator ac-
the inactive
phosphatase as [FCM], which is
Blue Sepharose resin (4,12).
resin with
skeletal
300 180 10-50
phenyl-Sepharose chromatography step (Fie. tivity
from rabbit
a linear gradient
(2x100 ml) from 0.2 M to 0.4 M
A (not shown). The two fractions
against 10% polyethyleneglycol
It was recovered from
were concentrated separately
in buffer
A, and stored at -2OV in
the presence of 50%glycerol. The ATP,Mg-dependent phosphatase isolated known aspect
from the
protein staining contained the catalytic
one isolated
activity,
38 kDa and 32 kDa proteins
two
discussed in (6).
so that at 1:l
molar ratio
The modulator
showedthe
same
suggest the
fraction
by kinase the
which
FA nor identity
modulator
fraction
represents
the
activity
by metal
ions
of
the two
which binds 38 kDa component
mainly
which represent
the
The enzyme seemedto
of the
ratio
phosphatase activity
could raise the phosphatase unit
is expected,
is indicated by the Coomassie activity
by kinase FA was about 40,000 U/me.
was retained
by the
Blue
bands on SDS-PAGE(Fig.
presence of the 38 kDa catalytic
phosphorylase phosphatase Until
2A),
of modulator to catalytic
activation
no
than ATP,Mg-dependent phosphatase
with trypsin
protein staining
two
The preparation
of the two proteins on SDS-PAGE. The specific
enzyme after
in
(12) except that the 62 kDa
(14,15).
inhibition
A similar
measurements.
blue staining
of the inactive
partial
Limited proteolysis
based on activity brilliant
the
(Fig.
respectively
more modulator activity
times
which reflects
activity
according to
way differed
band seen in SDS-PAGE(5) was absent.
and modulator subunits
have about
in this
subunit.
However,
Sepharose
resin
which may no significant
2A),
could be brought out of the preparation,
with
or without
38 kDa
an additional
proteins is proven,
trypsin
not
treatment.
we shall label the
to the Blue Sepharose resin as HI where [Xl of the modulator complex under investigation. 370
Vol. 135, No. 2, 1986
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
lane
1
2
3
FRACTION NUMBER Fig.
2.
SDS-PAS8 of 2 jog of modulator purified as in (5) (lane FCM-enzyme (lane 2) and 4 JIB of [MXI (lane 3) at the final purification (see text). A:
B and C: Sucrose density gradient centrifugatfon: (8) or boiled [MX] (C) were put on the gradient bumin as ml. wt. marker.
1);
4 fig
stages of
2 U of "native" MXI together with 14C-oval-
2) Ch ) Fig. 28 shows the migration of the MX-complex in sucrose density gradient centrifugation.
The modulator activity,
measured as stimulation
of the kinase
FA mediated “free FC” activity (5), was determined after boiling the individual fractions of the gradient and was localized several fractions ahead of the marker protein Boiling the
14C-ovalbumin, indicating
MX-complex
prior
of the usual “free modulator” (Fig. Gel filtration for the wt. of protein identical
native 65,000
known kinetic
This is
dependency of
the
gave an apparent
The modulator
protein
and [FCMI migrates
obtained
after
illustrated
added [MXI or boiled [Mxl.
wt.
in
of 140,000
as a 120-140 boiling
kDa
EMXI was (B,9) in all
The unboiled MX-complex however differed
modulator in that it was not inhibitory kinase
mol.
according to the published reports
aspects.
of 70,000.
in the appearance
Free modulator is known to have a mol.
columns
or molecular
from the heat-stable activity.
AcA-34
sieving
the one purified
mol. wt.
resulted
2C) with a mol. wt. of 17,000.
MX-complex (not shown).
(2,3,B). to
using Ultrogel
in molecular
an approximate
to the centrifugation
Figure 3.
to the phosphatase
Fig. 3A shows the concentration
FA mediated activation
of “free FC” on exogeneously
The boiled MX-preparation shows the biphasic tstim371
Vol. 135, No. 2, 1986
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
3.E @ 50 z 2 B=T” w 25 8 0I:0 8Y
5
10-2zlo
\ . 0
MX(ng)
2
Fig. 3. Determination
of the different
5
0'
10 50 loo MX(ng)
modulator
10
20
TIMEImin)
activities.
stimulation of the kinase FA-mediatedactivation of 50 mU of “free FC” 2.5 to 100 ng of native [MXI to) or boiled [Hxl (0) were addedin the activation mixture (20 ~1) of “free FC”, kinase FA and ATP,Mg as outlined in (5). Concentrations indicate the wount of protein present before the boiling step. A:
Inhibition of 50 mU of active phosphatasecatalytic subunit by different amountsof u&oiled to) and boiled (0) [XXI. The DlXI proteins were not preincubated with the phosphataseand a 2 min assay was performed. B:
C: Time-dependentinactivation of 50 mU of active phosphatasecatalytic subunit by 10 ng of unboiled to) or boiled (0) NXI. The [MXI and phosphatasewere preincubated at 3OW for different periods of time, before a 2 min assaywasperformed. ulation-inhibition)
curve,
typical
of
the free modulator
Cl),
whereas
the
na-
tive MX-complex does not produce the phosphatase inhibition at the higher concentrations used. Similarly, [Hxl did not inhibit the activity of the phosphatase catalytic
subunit, whereas identical
an instantaneous inhibition able to
convert the
(Fig. 3B).
concentrations
Surprisingly,
active phosphatase catalytic
of boiled [KU] caused
the native MX-complex was subunit to the ATP,Mg-depen-
dent enzyme form at the samerate as the boiled modulator (Fig. 3C). plest explanation
for these results
is to invoke two separate binding sites for
modulator on the phosphatase catalytic versible
activation/inactivation
subunit: one site which governs the re-
of the phosphatase, and a separate inhibitory
site which can only be occupied by “free modulator”, ical MX-complex.
In vivo this putative
served for the regulation lated) inhibitor-l. In this site similar identical to
The sim-
of the
hypothesis, the
inhibitor
not by the more physiologsite
may
be specifically
phosphatase by the heat-stable
X-protein
re-
(phosphory-
bind the modulator at a specific If [Xl would be to the “inhibitory site” on the phosphatase. the FC-protein, then we could envisage the MX-complex as an FCMmay
enzyme which has modulator bound at the inhibitory site, instead of at the usuThe portion of the modulator which binds to al activation/inactivation site. the activation/inactivation site on the phosphatase may be fully exposed in the native [MXI, so that the interconverting properties of the modulator can be measured without a dissociating
boiling
step. 372
Vol.
135,
No. 2, 1986
BIOCHEMICAL
[MX] differs be revealed is
Both
from the normal [FCM] in that
proteolysis
retained
by
characteristics
sites
between
in the presence
argue
This is however
cogen particles
which
ated with
them,
modulator
activity
ulator-complex described
but
the
its
potential
such as activation
of metal ions
that
highly
FC-protein [Xl
in the two
may
simply
unlikely
since
have a considerable no inactive
(15)
COMMUNICATIONS
activity
cannot
by kinase
FA (5)
and secondly
because
found to
form (7).
be identical
complexes.
represent
a denatured
preparations amount of active do contain
F,$-enzyme,
in a 70 kDa
were
RESEARCH
the Blue-Sepharose resin as is also the free modulator (8). be explained by the difference in the binding may again
the M- and
One could unit.
BIOPHYSICAL
by any of the known procedures
or limited it
AND
The properties
FC-catalytic
of rabbit
muscle gly-
phosphatase an
associ-
equal amount
of this
to the characteristics
of
70 kDa modof the [MX]
here (not shown).
ACKNOWLEDGEMENT8 JRV is a Senior Research Associate of the “Nationaal Fords voor Wetenschappel i jk Onderzoek”. This work was supported by the “Ponds voor Geneeskundig Vetenschappelijk Ondmmek” and by the “Onderzoeksfonds K.U.Leuven”. The authors are grateful to Mr L. Vanden Bosch for expert technical assistance.
REFERENCES Chem. 256,
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