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Elution of the regulatory subunit of cAMP-dependent protein kinase Type I isozyme derived from epididymal fat within the Type II isozyme chromatographic peak
Vol. 112, No. 1, 1983 April
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
15, 1983
Pages
214-220
ELUTION OF THE REGULATORY SUBUNIT OF CAMP-DEPENDENT PROTEIN KINASE TYPE I ISOZYME DERIVED FROM EPIDIDYMAL WITHIN THE TYPE II Alvin
School
ISOZYME CHROMATOGRAPHIC PEAK
M. Malkinson,
Jeanne
M. Wehner
of Pharmacy,
University
*Dight
Institute
Genetics
for
and Cell
Deborah
February
S. Beer,
and J. R. Sheppard* of Colorado,
Human Genetics Biology,
Boulder,
CO 80309
and Department
University
Minneapolis, Received
FAT
of
of Minnesota
MN 55455
28, 1983
No CAMP-dependent protein kinase activity is found upon DEAE-cellulose chromatography of mouse fat extracts at the low salt concentration characterThe RI detected in fat extracts by photoincoristic of the Type I isozyme. poration of the analog, 8-N3[ 32P]cAMP, elutes within the high salt Type II The multiple charge variants of this photolabeled RI which isozyme peak. can be resolved by two-dimensional gel electrophoresis are similar to those of the histoptypically-related cultured cells, SV3T3 and 3T6, which do contain Type I kinase isozyme activity peaks. This high salt-eluting RI may be part of a Type I holoenzyme whose elution properties are altered by interactions with other substances present in the extract.
CAMP-dependent es,
called
Types
lulose
columns
units
and vary
on what
these
These
roles
(4,5),
kinase
salt
(Type
0006-291X/83
II)
.
enzymes on the
their
have
during
usually peaks
traverse
based
(6),
method
$1.50
Copyright 0 I983 by Academic Press, Inc. AN rights of reproduction in any form reserved.
214
(2).
from DEAE-cel-
the
relative
re-
speculation
Such changes
at low
the
in the proporinclude
tranformation
the sizes
DEAE columns
(C) sub-
Although
on alterations (3).
class-
catalytic
and neoplastic
measures
isozymic
been delineated,
by comparing
from
major
elution
subunits
changes
estimated
An alternative
of their
have not
largely
two
or identical
(R)
isozymes
eluting
into
similar
physiological
cycle
fall
order
regulatory
may be is
cell are
activity
based
of these
isozymes
proportions
tein
in
functions
of the
kinase
The isozymes
only
--in vivo
development
I and II,
(1).
spective
tions
protein
of the (Type
I)
amounts
(7). two proand high of
the
Vol. 112, No. 1, 1983
photoaffinity
analog Although
unit.
can RI
TyJje
II
st:lte
elute
zyrle act-ivity
peaks
a variety
(11-13). peak
would
solely
on
the
concentrations.
contain
an that
RI--subunits
--Materials
RI
no
which
apparent contained
and
DRAB
from
the
salt
of
certainly
cloud
proportion
of Herein
elutes
an
that
within
I
isozyme
the
mouse Type exist
peaks
from
by
I
isozyme
Type
I
and
dissociation
within
peaks
the
differences
Type the
to
of
activity
show
the
addition
isozyme
R-sub-
detectable
between
interpretation
these
each
uncharacterized in
I
is
of
elutes
of
the
solely
Type
outside
C-subunit
Type
we
structural in
columns
into
which
RI,
concentrations
presence
RESEARCH COMMUNICATIONS
incorporated
(9),
RI-subunits
of The
(8),
agree
from
while
(lo),
at
often
elute free
AND BIOPHYSICAL
8-N3[32P]cAMP
assays
also
isozyme
and
CAMP,
dissociated
peak
re1.y
of both
photolaheling peak.
BIOCHEMICAL
the
those to
Type
Type
I iso-
II
kinase
studies
which
estimate
relative
epididymal
fat
II
kinase
peak,
Rl
those
between related
isozyme this
extracts
and
sources.
Methods:
Epididymal fat was removed from adult BALB/cByJ mice and Chromatography. 7 honogenlzed in 10 mM potassium phosphate, pH 7.0, containing 1 mM EDTA (2 vol/ pm wet wt.). The crude homogenate was passed through silk to remove excess lipid, and centrifuged at 27,000g for 35 min to obtain supernatant fractions. Chromatography on DE-52 cellulose (Whatman) equilibrated with this same buffer was done according to the method of Corbin et al. (l), as previously modified (14). Prior to chromatography, the extract was preincubated with ATP and MgC12 to final concentrations of 0.15 mM and 3.5 mM, respectively, to facilitate association of the Type I holoenz,yme. After 30 min at 30°C the extract was chromatographed on a Sephadex G-25 column (30 X 0.9 cm) and fluted at 4°C at a flow rate of 30 ml/hr. Proteins eluting in with homogenization buffer the void volume, as determined by absorption at 280 nm, were pooled and 20-30 mg of protein was applied to the DEAR-cellulose column. Assays. Protein concentrations were determined according to Lowry et -_ (15), with crystalline bovine serum albumin used as a standard. Protein --al. kinase activity was assayed with a 250 ~1 reaction mixture containing 6.7 mM 2.0 mM 2-(N-Morpholino) ethane-sulphonate (MES) buffer (pH 6.5), 233 I.cg MN2, Type II A mixed histone, 0.23 mM (Y-~'P]ATP (40 Ci/mmole), and a 25 pl aliquot with or without 3.3 PM CAMP. After 30 min at from a DEAE-cellulose fraction, 100 ~1 aliquots were transferred onto filter paper and washed with tri3O"C, The photoincorporation procedure used chloroacetic acid as described (16). previously (17) was slightly modified. Twenty ~1 of a column fraction and 1 U1 of Ml'S buffer were added to a 5 ~1 aliquot of 8-N3['2P]cAMP to obtain a final analog concentration of 125 nM. These components were mixed with an The samples were incubated at 35'C for 30 min in airstream on a spot plate. the ligand and any endogenous CAMP altJe dark to promote exchange hetween ready hound to regulatory suhunits and were further incubated for 30 min at Photolysis with IV (254 nM) was done at 4°C with a DVS-54 4'C in the dark. Mineralight handlamp held at 12 cm for 15 min. The reaction was terminated with 26 ~1 of an SDS-containing stop solution (18), and the photolabeled Protcins separated on P-12"/ linear gradient denaturing gels.
215
Vol. 112, No. 1, 1983
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Gel Electrophoresis. Two-d$?ensional electrophoretic separation of crude was done as follows. Epididymal fat extracts photolaheled with S-N3 [ P]cAMP was homogenized in 0.32 Y sucrose and post-mitochondrial fractions prepared as ahove. Roller bottles of PALR 3T3, SV3T3, and 3T6 cells were grown in Dulbecco’s modified Eagle’s medium, supplemented with serum. The cells were rinsed twice with cold 0.32 M sucrose, scraped and centrifuged at 900g. The pelleted cells were then sonicated for 10 set at 1.5 watts on a Bronson sonicator, and frozen for later assay. Twenty ~1 of extract containing 20 ug of protein was photolabeled using an S-N3 [ 32PjcAMP concentration of 750 nM and the reaction terminated with 26 u1 of lysis buffer (19). The O’Farrell (19) electrophoretic procedure was modified as described previously (17). First-dimension gels were run for 6400 volt-hrs. Samples were overlayed with 5% Nonidet P-40, 8 M urea, and 1% ampholines, composed of 0.8% of the pH 5 to 7 ampholine and 0.2% of the pH 3.5 to 10 ampholine, both from LKB Instruments, Inc. Second-dimension gels were 8 to 12% linear gradients. Dried gels were placed on DuPont Xray film with DuPont Quanta-111 intensifying screens for l-2 days at -75’C for autoradiographic detection. Results
and Fig.
tein
Discussion: 1A illustrates
that
activity
measurements
kinase
activity
elutes
enzyme
at When
(1).
photolaheled, in
on
its
suggest he
size
associated
hound
CAMP
elutes
from
Type
II
the
void
Type
II
and
activity volume peak
This at
the
RALB
is
the 3T3
pI
range
(5.4
the
RI
and
RII
subunits
more
salt
peaks
(10);
3.
(14),
was
observed;
4.
(M.S.
Butley
has
cells
not
salt-eluting
characteristic
peak
yet
been
RI
was I
a Type
C-subunit In
and
A.M. in
other
isozyme
I
with
position.
are
photolabeled RI
is
Type
II
allows
charge
variants.
isozyme
kinase
bas-
peak
may
extract
was
preincuhated
release
of
endogenously
Free to
RI
typically
the
Type
which
the
RI
Malkinson,
I
and
elutes
eluting
at
in
the
unpublished
re-
systems. RI-subunits
which
elute
Two-dimensional
proteins
216
holo-
considerations
this
2.
lung
II
extract
as
activity,
mouse
compared
R-subunit lack
of
fat the
intermediate
tested
photolabeled
photolabeled (7,21,22)
No
the
(14,20);
concentrations
Type of
facilitate
reassociation
at
a holoenzyme
The
prothis
Type
following in
1.
the
protein
The
5.6).
by
extracts;
of
this
present
to
subunit
separation various
-
holoenzymes:
chromatography
columns
this
high
trophoretic of
and
encourage
DFAF
although
suits),
K)
for from
of
detected
fat
one-third
Identification
RI.
he
of
typical
than
is
to
can
derived
greater
as
peak
range fractions
lB),
C-suhunits
prior
DEAF: chromatography
peak
with
E!pATP
single
upon
column
(Fig.
(49 hoth
a
concentration
individual
this
that
with
salt
however
material ed
the
only
qualitative Both activity
eleccomparisons
fat peak,
tissue but
and con-
Vol. 112, No. 1, 1983
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
FRACTION NUMBER (A) Protein kinase activity in the 1 presence (U) or absence --Figure (C-@) of CAMP, and (B) 8-N3[32P]cAMP incorporation into RI (@----O) and RI1 ( l -. ) in DEAE-cellulose fractions collected after chromatographic elution of extracts from epididymal fat. The NaCl concentrations were estimated by conductivity measurements of each fraction and extrapolation from a standard curve.
ta:n
RI-subunits
This
is
detectable
interesting
prajducts
that The
ha*;
anchorage
tain
an
SV3T3
autoradiogram
trophoretic ovarian
viral dependence
from of
patterns
are (24),
I
and
kinase
one
3T6,
similar
3T6, to
lung
the
(17),
other, and
217
potential
BALB
can
3T3
gel
of
and
epididymal
mammalian
and
22).
rise
each
proteins fat.
those
described
brain
(25).
con-
2 is
Fig.
(22).
to which
SV3T3,
photolabeled
to
give
transformant
peak
and
1B;
differentiated
cells
activity
SV3T3,
each
(Fig.
a spontaneous
between isozyme
3T3,
of
precursor
a two-dimensional
BALB
mouse
photolabeling
mesenchymal
intermediate
Type
extracts
follicles
are
transformant
prepared
from
8-N3[32P]cAMP
adipocytes
multipotent
demonstrable
a
tained
since these
(23).
by
ob-
These
elecfor
When
an
rat large
Vol. 112, No. 1, 1983
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
54K 4 49K4 45K 4
MW 54K+ 4QK+ 45K 4
Figure 2 Autoradiogram of proteins from (A) BALR 3T3, (B) 3T6, (C) SV3T3 and (D) epididymal fat extracts which were labeled with 750 &I 8-N3[32P]cAMP and fractionated by two-dimensional gel electrophoresis.
amounts
of
iants
g-N3[ 32P]cAMP
ranging
central
in
spots
of these
migrates
RI1
presence
of
of
present
the in
does
42-44K
charge
lines
is
ment
derived
brain
(25)
at
not
of
since the are
prominent in
the
RI,
observed
label. are
the
but
most
These
of
in
labeling
labeled
in
the
SV3T3
8-iV3[32 PIcAMP-labeled
also
a single
labeling
of
less
var-
the RI,
two only
fat
218
are the of
these
but The main in
frag-
endogenously of protease
proteins.
from
extracts,
extract.
probably
the
Labeled
proteolytic
presence
extracts
R-subunits
37K spot.
suggesting charge.
represent
fragments
in
from
with
p1 dimension,
likely
found
labeled
charge
samples,
non-identical
homogenization amount
discrete
in all
With
along
42-44K
four
detected.
similar
(26,27).
variants most
most
elongated
37K and at
reduce
into
are
species
Proteins
samples
detected
is
the
R-subunits
and are
fragment
to 5.6
charge
RII
these
hibitors
5.4
as a spot
two
variants
ments
incorporated
incorporating
two or three
charge
pI from
are
the only
Multiple cultured a single
proteolytic
mouse
in-
lung
cell 37K frag-
(17)
and
BIOCHEMICAL
Vol. 112, No. 1, 1983
The
affinities
similar
for
of
the
affinities
fat
nor
and
the
cell
density
was
fron
0.4-2.5
mg/ml
the
charge,
and
thereby
ty
of
the
as
resolved
charge by
peak
may
by
MgPTP inp
in
(29))
and
capacity
of
birding This
of
is
cA?fP-dependent su’>unit
structure
stlldies,
along
R-,:uhuni
peaks Type
I
of
8-N3
11s ,
functional
and
even
as
subcellular
status
R-subunits
be
valid
On
the
into in
the
concentration
the
suggested
by
high
salt
lack
characterizing
titration accurately
since
similari-
the
the
relative
sizes
of
type
hand, R-subunit
II
the
activ-
the
relative
can
be
modi-
concentrations can
affect
of
stoichiometry
has
been
and and
quantitative
with
antisera the
net
concentrations
the
such
describe
the
of on
which
R-subunits
the
explanation
endogenous
A
sub-
This
other
of
analog.
within
possibly
columns.
each
all
chromatography
to
when
and
solely
distribution
immunochemical
of
not
(30))
for
kinases
required
the
conformation
and
based
and
purified
useful
be
protein
Estimates
[32P]cAMP
to
most
may
is
low
isozyme.
perhaps
with
RI
the
may
the
DEAE
affected
its
DEAE
of
(28)
for
(30).
from
adenosine
R-subunits
also
Neither
substances,
influence
isozymes
strength
[32 P]cAMP
8-N3
analog
MgCTP
were
cellular
at
kinase
ionic
are
shown).
the
electrophoresis.
the
[32P]cAMP
not
varying
may
eluting
incorporation changes
other
position
activity
contain
8-N3
protein
by
properties
protein
kinase
quantitative fied
elution
variants
the
(data
RESEARCH COMMUNICATIONS
assay.
enzyme,
two-dimensional
of
samples
or
and
kinase its
binding
photolabeling RI
protein
CAMP-dependent ity
the
for
bound/mg
growth
ion-exchange
RI
prcportions
ligand
during
in
atypical
cell
of
hetween
for
the
cultured
varied
strates
subunits
RI
amounts
Interactions
for
the
AND BIOPHYSICAL
of the
bindin
the
described properties
(31). of
modifications
the
of
R-
photolabeling prepared
against
concentrations
and
cell.
--Acknowledgements: This sota
We thank work was Leukemia
Martin S. Butley for his supported by USPHS grant Task Force (to J.R.S.).
valuable ES02370
(to
comments A.M.M.)
on
this manuscript. and by the Minne-
References: --1.
Corbin, 225.
J-D.,
Keely,
S.C.
and
Park,
219
C.R.
(1975)
J.
Biol.
Chem.
250:218-
Vol. 112, No. 1, 1983
2. 2: 5. 6. 7. 8. 9.
10. 11. 12.
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Hofmann, F., Reavo, J.A., Bechtel, P.J. and Krebs, E.G. (1975) J. Biol. Chem. 250~7795-7301. D.H. (1977) Life Sci. 20:1787-1798. Jungmann, R.A. and Russell, Lee, P.C., Radloff, D., Schweppe, J.C. and Jungmann, R.A. (1976) J. 251:914-921. Riol. Chem. Malkinson, A.M., Hogy, L., Gharrett, A.J. and Gunderson, T.J. (1978) J. Exp. Zool. 205~423-432. Costa, M., Gerner, E.W. and Russell, D.H. (1976) J. Biol. Chem. 251:33133319. Gharrett, A.J., Malkinson, A.M. and Sheppard, J.R. (1976) Nature 264:673675. Haley,
B.E. (1977) Meth. Enzymol. 46:339-346. Walter, IJ. and Greengard, P. (1978) in Handbook of Experimental PharmaVol. 58, Eds. Nathanson, J.A. and Kebabian, J.W. COl%Y, Springer-Verlag, New York, pp 479-505. Walter, U., Costa, M.R.C, Breakfield, X.0. and Greengard, P. (1979) Proc. Natl. Acad. Sci. USA 75:3251-3255. Walter, U., Uno, I., Liu, A.Y.-C. and Greengard, P. (1977) J. Biol. Chem. 252:6494-6500. D.L. and Strittholt, J.T. (1981) Biochim. Biophys. Acta. 675: Friedman, 334-343.
13. 14.
Singh, T.J., Roth, C., Gottesman, M.M. and Pastan, Chem. 256:926-932. Malkinson, A.M., Gharrett, A.J. and Hogy, L. (1978)
I.H.
(1981)
Biochem.
J. J.
Biol.
175:367-
375.
15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.
Lowry, O.H., Rosebrough, N.J., Farr, A.L. and Randall, R.J. (1951) J. 293:265-275. Riol. Chem. 38:287-299. Corhin, J.D. and Reimann, E.M. (1974) Meth. Enzymol. Malkinson, A.M. and Butley, M.S. (1981) Cancer Res. 41:1334-1341. Laemmli, U.K. (1970) Nature 227:680-685. O'Farrell, P.H. (1975) J. Riol. Chem. 250:4007-4021. Beavo, J.A., Bechtel, P.J. and Krebs, E.G. (1975) Adv. Cyclic Nucleotide Res. 5:241-251. Wigglesworth, N.M., Mastro, A., Bourne, H.R. and Rozengurt, E. (1977) Arch. Biochem. Biophys. 180:358-263. Wehner, J.M., Malkinson, A.M., Wiser, M.F. and Sheppard, J.R. (1981) J. Cell. Physiol. 108:175-184. Boone, C.W. and Scott, R.E. (1980) J. Supramolec. Strut. 14:233-240. Richards, J.S. and Rolfes, A.I. (1980) J. Biol. Chem. 255:5481-5489. Panter, S.S., Butley, M.S. and Malkinson, A.M. (1981) J. Neurochem. 36: 2080-2085.
26. 27. 28. 29. 30. 31.
Sugden, P.H. and Corbin, J.D. (1976) Biochem. J. 159:423-433. Imashuku, I., Fossett, M.C. III and Green, A.A. (1979) Cancer Res. 39: 3006-3013. Hoyer, P., Owens, J.R. and Haley, B.E. (1980) Ann. N.Y. Acad. Sci. 346: 280-301. Owens, J.R. and Haley, B.E. (1978) J. Supramolec. Strut. 9:57-68. Khatoon, S., Atherton, R., Al-Jumaily, W. and Haley, B.E. (1983) Biol. Repro., In Press Kerlavage, A.R. and Taylor S.S. (1980) J. Biol. Chem. 255:8483-8488.
220
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
15, 1983
Pages
214-220
ELUTION OF THE REGULATORY SUBUNIT OF CAMP-DEPENDENT PROTEIN KINASE TYPE I ISOZYME DERIVED FROM EPIDIDYMAL WITHIN THE TYPE II Alvin
School
ISOZYME CHROMATOGRAPHIC PEAK
M. Malkinson,
Jeanne
M. Wehner
of Pharmacy,
University
*Dight
Institute
Genetics
for
and Cell
Deborah
February
S. Beer,
and J. R. Sheppard* of Colorado,
Human Genetics Biology,
Boulder,
CO 80309
and Department
University
Minneapolis, Received
FAT
of
of Minnesota
MN 55455
28, 1983
No CAMP-dependent protein kinase activity is found upon DEAE-cellulose chromatography of mouse fat extracts at the low salt concentration characterThe RI detected in fat extracts by photoincoristic of the Type I isozyme. poration of the analog, 8-N3[ 32P]cAMP, elutes within the high salt Type II The multiple charge variants of this photolabeled RI which isozyme peak. can be resolved by two-dimensional gel electrophoresis are similar to those of the histoptypically-related cultured cells, SV3T3 and 3T6, which do contain Type I kinase isozyme activity peaks. This high salt-eluting RI may be part of a Type I holoenzyme whose elution properties are altered by interactions with other substances present in the extract.
CAMP-dependent es,
called
Types
lulose
columns
units
and vary
on what
these
These
roles
(4,5),
kinase
salt
(Type
0006-291X/83
II)
.
enzymes on the
their
have
during
usually peaks
traverse
based
(6),
method
$1.50
Copyright 0 I983 by Academic Press, Inc. AN rights of reproduction in any form reserved.
214
(2).
from DEAE-cel-
the
relative
re-
speculation
Such changes
at low
the
in the proporinclude
tranformation
the sizes
DEAE columns
(C) sub-
Although
on alterations (3).
class-
catalytic
and neoplastic
measures
isozymic
been delineated,
by comparing
from
major
elution
subunits
changes
estimated
An alternative
of their
have not
largely
two
or identical
(R)
isozymes
eluting
into
similar
physiological
cycle
fall
order
regulatory
may be is
cell are
activity
based
of these
isozymes
proportions
tein
in
functions
of the
kinase
The isozymes
only
--in vivo
development
I and II,
(1).
spective
tions
protein
of the (Type
I)
amounts
(7). two proand high of
the
Vol. 112, No. 1, 1983
photoaffinity
analog Although
unit.
can RI
TyJje
II
st:lte
elute
zyrle act-ivity
peaks
a variety
(11-13). peak
would
solely
on
the
concentrations.
contain
an that
RI--subunits
--Materials
RI
no
which
apparent contained
and
DRAB
from
the
salt
of
certainly
cloud
proportion
of Herein
elutes
an
that
within
I
isozyme
the
mouse Type exist
peaks
from
by
I
isozyme
Type
I
and
dissociation
within
peaks
the
differences
Type the
to
of
activity
show
the
addition
isozyme
R-sub-
detectable
between
interpretation
these
each
uncharacterized in
I
is
of
elutes
of
the
solely
Type
outside
C-subunit
Type
we
structural in
columns
into
which
RI,
concentrations
presence
RESEARCH COMMUNICATIONS
incorporated
(9),
RI-subunits
of The
(8),
agree
from
while
(lo),
at
often
elute free
AND BIOPHYSICAL
8-N3[32P]cAMP
assays
also
isozyme
and
CAMP,
dissociated
peak
re1.y
of both
photolaheling peak.
BIOCHEMICAL
the
those to
Type
Type
I iso-
II
kinase
studies
which
estimate
relative
epididymal
fat
II
kinase
peak,
Rl
those
between related
isozyme this
extracts
and
sources.
Methods:
Epididymal fat was removed from adult BALB/cByJ mice and Chromatography. 7 honogenlzed in 10 mM potassium phosphate, pH 7.0, containing 1 mM EDTA (2 vol/ pm wet wt.). The crude homogenate was passed through silk to remove excess lipid, and centrifuged at 27,000g for 35 min to obtain supernatant fractions. Chromatography on DE-52 cellulose (Whatman) equilibrated with this same buffer was done according to the method of Corbin et al. (l), as previously modified (14). Prior to chromatography, the extract was preincubated with ATP and MgC12 to final concentrations of 0.15 mM and 3.5 mM, respectively, to facilitate association of the Type I holoenz,yme. After 30 min at 30°C the extract was chromatographed on a Sephadex G-25 column (30 X 0.9 cm) and fluted at 4°C at a flow rate of 30 ml/hr. Proteins eluting in with homogenization buffer the void volume, as determined by absorption at 280 nm, were pooled and 20-30 mg of protein was applied to the DEAR-cellulose column. Assays. Protein concentrations were determined according to Lowry et -_ (15), with crystalline bovine serum albumin used as a standard. Protein --al. kinase activity was assayed with a 250 ~1 reaction mixture containing 6.7 mM 2.0 mM 2-(N-Morpholino) ethane-sulphonate (MES) buffer (pH 6.5), 233 I.cg MN2, Type II A mixed histone, 0.23 mM (Y-~'P]ATP (40 Ci/mmole), and a 25 pl aliquot with or without 3.3 PM CAMP. After 30 min at from a DEAE-cellulose fraction, 100 ~1 aliquots were transferred onto filter paper and washed with tri3O"C, The photoincorporation procedure used chloroacetic acid as described (16). previously (17) was slightly modified. Twenty ~1 of a column fraction and 1 U1 of Ml'S buffer were added to a 5 ~1 aliquot of 8-N3['2P]cAMP to obtain a final analog concentration of 125 nM. These components were mixed with an The samples were incubated at 35'C for 30 min in airstream on a spot plate. the ligand and any endogenous CAMP altJe dark to promote exchange hetween ready hound to regulatory suhunits and were further incubated for 30 min at Photolysis with IV (254 nM) was done at 4°C with a DVS-54 4'C in the dark. Mineralight handlamp held at 12 cm for 15 min. The reaction was terminated with 26 ~1 of an SDS-containing stop solution (18), and the photolabeled Protcins separated on P-12"/ linear gradient denaturing gels.
215
Vol. 112, No. 1, 1983
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Gel Electrophoresis. Two-d$?ensional electrophoretic separation of crude was done as follows. Epididymal fat extracts photolaheled with S-N3 [ P]cAMP was homogenized in 0.32 Y sucrose and post-mitochondrial fractions prepared as ahove. Roller bottles of PALR 3T3, SV3T3, and 3T6 cells were grown in Dulbecco’s modified Eagle’s medium, supplemented with serum. The cells were rinsed twice with cold 0.32 M sucrose, scraped and centrifuged at 900g. The pelleted cells were then sonicated for 10 set at 1.5 watts on a Bronson sonicator, and frozen for later assay. Twenty ~1 of extract containing 20 ug of protein was photolabeled using an S-N3 [ 32PjcAMP concentration of 750 nM and the reaction terminated with 26 u1 of lysis buffer (19). The O’Farrell (19) electrophoretic procedure was modified as described previously (17). First-dimension gels were run for 6400 volt-hrs. Samples were overlayed with 5% Nonidet P-40, 8 M urea, and 1% ampholines, composed of 0.8% of the pH 5 to 7 ampholine and 0.2% of the pH 3.5 to 10 ampholine, both from LKB Instruments, Inc. Second-dimension gels were 8 to 12% linear gradients. Dried gels were placed on DuPont Xray film with DuPont Quanta-111 intensifying screens for l-2 days at -75’C for autoradiographic detection. Results
and Fig.
tein
Discussion: 1A illustrates
that
activity
measurements
kinase
activity
elutes
enzyme
at When
(1).
photolaheled, in
on
its
suggest he
size
associated
hound
CAMP
elutes
from
Type
II
the
void
Type
II
and
activity volume peak
This at
the
RALB
is
the 3T3
pI
range
(5.4
the
RI
and
RII
subunits
more
salt
peaks
(10);
3.
(14),
was
observed;
4.
(M.S.
Butley
has
cells
not
salt-eluting
characteristic
peak
yet
been
RI
was I
a Type
C-subunit In
and
A.M. in
other
isozyme
I
with
position.
are
photolabeled RI
is
Type
II
allows
charge
variants.
isozyme
kinase
bas-
peak
may
extract
was
preincuhated
release
of
endogenously
Free to
RI
typically
the
Type
which
the
RI
Malkinson,
I
and
elutes
eluting
at
in
the
unpublished
re-
systems. RI-subunits
which
elute
Two-dimensional
proteins
216
holo-
considerations
this
2.
lung
II
extract
as
activity,
mouse
compared
R-subunit lack
of
fat the
intermediate
tested
photolabeled
photolabeled (7,21,22)
No
the
(14,20);
concentrations
Type of
facilitate
reassociation
at
a holoenzyme
The
prothis
Type
following in
1.
the
protein
The
5.6).
by
extracts;
of
this
present
to
subunit
separation various
-
holoenzymes:
chromatography
columns
this
high
trophoretic of
and
encourage
DFAF
although
suits),
K)
for from
of
detected
fat
one-third
Identification
RI.
he
of
typical
than
is
to
can
derived
greater
as
peak
range fractions
lB),
C-suhunits
prior
DEAF: chromatography
peak
with
E!pATP
single
upon
column
(Fig.
(49 hoth
a
concentration
individual
this
that
with
salt
however
material ed
the
only
qualitative Both activity
eleccomparisons
fat peak,
tissue but
and con-
Vol. 112, No. 1, 1983
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
FRACTION NUMBER (A) Protein kinase activity in the 1 presence (U) or absence --Figure (C-@) of CAMP, and (B) 8-N3[32P]cAMP incorporation into RI (@----O) and RI1 ( l -. ) in DEAE-cellulose fractions collected after chromatographic elution of extracts from epididymal fat. The NaCl concentrations were estimated by conductivity measurements of each fraction and extrapolation from a standard curve.
ta:n
RI-subunits
This
is
detectable
interesting
prajducts
that The
ha*;
anchorage
tain
an
SV3T3
autoradiogram
trophoretic ovarian
viral dependence
from of
patterns
are (24),
I
and
kinase
one
3T6,
similar
3T6, to
lung
the
(17),
other, and
217
potential
BALB
can
3T3
gel
of
and
epididymal
mammalian
and
22).
rise
each
proteins fat.
those
described
brain
(25).
con-
2 is
Fig.
(22).
to which
SV3T3,
photolabeled
to
give
transformant
peak
and
1B;
differentiated
cells
activity
SV3T3,
each
(Fig.
a spontaneous
between isozyme
3T3,
of
precursor
a two-dimensional
BALB
mouse
photolabeling
mesenchymal
intermediate
Type
extracts
follicles
are
transformant
prepared
from
8-N3[32P]cAMP
adipocytes
multipotent
demonstrable
a
tained
since these
(23).
by
ob-
These
elecfor
When
an
rat large
Vol. 112, No. 1, 1983
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
54K 4 49K4 45K 4
MW 54K+ 4QK+ 45K 4
Figure 2 Autoradiogram of proteins from (A) BALR 3T3, (B) 3T6, (C) SV3T3 and (D) epididymal fat extracts which were labeled with 750 &I 8-N3[32P]cAMP and fractionated by two-dimensional gel electrophoresis.
amounts
of
iants
g-N3[ 32P]cAMP
ranging
central
in
spots
of these
migrates
RI1
presence
of
of
present
the in
does
42-44K
charge
lines
is
ment
derived
brain
(25)
at
not
of
since the are
prominent in
the
RI,
observed
label. are
the
but
most
These
of
in
labeling
labeled
in
the
SV3T3
8-iV3[32 PIcAMP-labeled
also
a single
labeling
of
less
var-
the RI,
two only
fat
218
are the of
these
but The main in
frag-
endogenously of protease
proteins.
from
extracts,
extract.
probably
the
Labeled
proteolytic
presence
extracts
R-subunits
37K spot.
suggesting charge.
represent
fragments
in
from
with
p1 dimension,
likely
found
labeled
charge
samples,
non-identical
homogenization amount
discrete
in all
With
along
42-44K
four
detected.
similar
(26,27).
variants most
most
elongated
37K and at
reduce
into
are
species
Proteins
samples
detected
is
the
R-subunits
and are
fragment
to 5.6
charge
RII
these
hibitors
5.4
as a spot
two
variants
ments
incorporated
incorporating
two or three
charge
pI from
are
the only
Multiple cultured a single
proteolytic
mouse
in-
lung
cell 37K frag-
(17)
and
BIOCHEMICAL
Vol. 112, No. 1, 1983
The
affinities
similar
for
of
the
affinities
fat
nor
and
the
cell
density
was
fron
0.4-2.5
mg/ml
the
charge,
and
thereby
ty
of
the
as
resolved
charge by
peak
may
by
MgPTP inp
in
(29))
and
capacity
of
birding This
of
is
cA?fP-dependent su’>unit
structure
stlldies,
along
R-,:uhuni
peaks Type
I
of
8-N3
11s ,
functional
and
even
as
subcellular
status
R-subunits
be
valid
On
the
into in
the
concentration
the
suggested
by
high
salt
lack
characterizing
titration accurately
since
similari-
the
the
relative
sizes
of
type
hand, R-subunit
II
the
activ-
the
relative
can
be
modi-
concentrations can
affect
of
stoichiometry
has
been
and and
quantitative
with
antisera the
net
concentrations
the
such
describe
the
of on
which
R-subunits
the
explanation
endogenous
A
sub-
This
other
of
analog.
within
possibly
columns.
each
all
chromatography
to
when
and
solely
distribution
immunochemical
of
not
(30))
for
kinases
required
the
conformation
and
based
and
purified
useful
be
protein
Estimates
[32P]cAMP
to
most
may
is
low
isozyme.
perhaps
with
RI
the
may
the
DEAE
affected
its
DEAE
of
(28)
for
(30).
from
adenosine
R-subunits
also
Neither
substances,
influence
isozymes
strength
[32 P]cAMP
8-N3
analog
MgCTP
were
cellular
at
kinase
ionic
are
shown).
the
electrophoresis.
the
[32P]cAMP
not
varying
may
eluting
incorporation changes
other
position
activity
contain
8-N3
protein
by
properties
protein
kinase
quantitative fied
elution
variants
the
(data
RESEARCH COMMUNICATIONS
assay.
enzyme,
two-dimensional
of
samples
or
and
kinase its
binding
photolabeling RI
protein
CAMP-dependent ity
the
for
bound/mg
growth
ion-exchange
RI
prcportions
ligand
during
in
atypical
cell
of
hetween
for
the
cultured
varied
strates
subunits
RI
amounts
Interactions
for
the
AND BIOPHYSICAL
of the
bindin
the
described properties
(31). of
modifications
the
of
R-
photolabeling prepared
against
concentrations
and
cell.
--Acknowledgements: This sota
We thank work was Leukemia
Martin S. Butley for his supported by USPHS grant Task Force (to J.R.S.).
valuable ES02370
(to
comments A.M.M.)
on
this manuscript. and by the Minne-
References: --1.
Corbin, 225.
J-D.,
Keely,
S.C.
and
Park,
219
C.R.
(1975)
J.
Biol.
Chem.
250:218-
Vol. 112, No. 1, 1983
2. 2: 5. 6. 7. 8. 9.
10. 11. 12.
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Hofmann, F., Reavo, J.A., Bechtel, P.J. and Krebs, E.G. (1975) J. Biol. Chem. 250~7795-7301. D.H. (1977) Life Sci. 20:1787-1798. Jungmann, R.A. and Russell, Lee, P.C., Radloff, D., Schweppe, J.C. and Jungmann, R.A. (1976) J. 251:914-921. Riol. Chem. Malkinson, A.M., Hogy, L., Gharrett, A.J. and Gunderson, T.J. (1978) J. Exp. Zool. 205~423-432. Costa, M., Gerner, E.W. and Russell, D.H. (1976) J. Biol. Chem. 251:33133319. Gharrett, A.J., Malkinson, A.M. and Sheppard, J.R. (1976) Nature 264:673675. Haley,
B.E. (1977) Meth. Enzymol. 46:339-346. Walter, IJ. and Greengard, P. (1978) in Handbook of Experimental PharmaVol. 58, Eds. Nathanson, J.A. and Kebabian, J.W. COl%Y, Springer-Verlag, New York, pp 479-505. Walter, U., Costa, M.R.C, Breakfield, X.0. and Greengard, P. (1979) Proc. Natl. Acad. Sci. USA 75:3251-3255. Walter, U., Uno, I., Liu, A.Y.-C. and Greengard, P. (1977) J. Biol. Chem. 252:6494-6500. D.L. and Strittholt, J.T. (1981) Biochim. Biophys. Acta. 675: Friedman, 334-343.
13. 14.
Singh, T.J., Roth, C., Gottesman, M.M. and Pastan, Chem. 256:926-932. Malkinson, A.M., Gharrett, A.J. and Hogy, L. (1978)
I.H.
(1981)
Biochem.
J. J.
Biol.
175:367-
375.
15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.
Lowry, O.H., Rosebrough, N.J., Farr, A.L. and Randall, R.J. (1951) J. 293:265-275. Riol. Chem. 38:287-299. Corhin, J.D. and Reimann, E.M. (1974) Meth. Enzymol. Malkinson, A.M. and Butley, M.S. (1981) Cancer Res. 41:1334-1341. Laemmli, U.K. (1970) Nature 227:680-685. O'Farrell, P.H. (1975) J. Riol. Chem. 250:4007-4021. Beavo, J.A., Bechtel, P.J. and Krebs, E.G. (1975) Adv. Cyclic Nucleotide Res. 5:241-251. Wigglesworth, N.M., Mastro, A., Bourne, H.R. and Rozengurt, E. (1977) Arch. Biochem. Biophys. 180:358-263. Wehner, J.M., Malkinson, A.M., Wiser, M.F. and Sheppard, J.R. (1981) J. Cell. Physiol. 108:175-184. Boone, C.W. and Scott, R.E. (1980) J. Supramolec. Strut. 14:233-240. Richards, J.S. and Rolfes, A.I. (1980) J. Biol. Chem. 255:5481-5489. Panter, S.S., Butley, M.S. and Malkinson, A.M. (1981) J. Neurochem. 36: 2080-2085.
26. 27. 28. 29. 30. 31.
Sugden, P.H. and Corbin, J.D. (1976) Biochem. J. 159:423-433. Imashuku, I., Fossett, M.C. III and Green, A.A. (1979) Cancer Res. 39: 3006-3013. Hoyer, P., Owens, J.R. and Haley, B.E. (1980) Ann. N.Y. Acad. Sci. 346: 280-301. Owens, J.R. and Haley, B.E. (1978) J. Supramolec. Strut. 9:57-68. Khatoon, S., Atherton, R., Al-Jumaily, W. and Haley, B.E. (1983) Biol. Repro., In Press Kerlavage, A.R. and Taylor S.S. (1980) J. Biol. Chem. 255:8483-8488.
220