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Endogenous activity of cyclic nucleotide-dependent protein kinase in plasma membranes isolated from Strongylocentrotus purpuratus sea urchin sperm
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 180, No. 3, 1991
Pages 1436-1445
November 14, 1991
ENDOGENOUS IN P L A S M A
Jesus
A C T I V I T Y OF C Y C L I C N U C L E O T I D E - D E P E N D E N T PROTEIN KINASE MEMBRANES I S O L A T E D F R O M Strongylocentrotus purpuratus SEA URCHIN SPERM
G a r c i a - S o t o a*, Luz Alberto Darszonb, c
M. A r a i z a a, M i r i a m B a r r i o s a, and Juan P. Luna-Arias a
aInstituto de Investigacion en Biologia Experimental, Facultad de Quimica~ Universidad de Guanajuato, A.P. 187, Guanajuato, GTO, Mexico bDepartamento de Bioquimica, Centro de Investigacion y de Estudios Avanzados and CDepartamento de Bioquimica, Centro de Investigacion sobre Ingenieria Gen~tica y Biotecnologla, Cuernavaca, Mexico Received September 27, 1991 SUMMARY: Activity of cyclic nucleotide-dependent protein kinase was investigated in flagellar plasma membranes of sea urchin sperm (S. purpuratus). Membranes incubated with [T-32p]ATP showed in the presence of 1 ~M cAMP an increased phosphorylation in multiple polypeptides. Half maximal response was seen at 0.6 ~M of cAMP. In contrast, higher concentrations (100 pM) of cGMP were required to cause the same amount of protein phosphorylation. 80% of the protein kinase activity stimulatable by cAMP was resistant to extraction by 10 mM EGTA and sonication but it was entirely recovered in a d e t e r g e n t - s o l u b i l i z e d fraction. Membranes pretreated with 200 p M cAMP, ultracentrifuged and resuspended in buffer solution did not undergo cAMP-stimulated phosphorylation in their polypeptides. This study demonstrates that flagellar plasma membranes isolated from S. purpuratus sea urchin sperm have an endogenous cAMP-dependent protein kinase, which may be bound to the membrane via its regulatory subunit. ©1991AcademicP..... Inc.
In mediated
eukaryotic via
This
enzyme
(R)
subunits
the
form
results subunit
the
cells,
activation
is composed that
(I).
of
protein
*To whom correspondence
of
constitute cAMP
to
years, kinase
an
the
(C)
the
subcellular
has
been
1436
two
regulatory
activation, the
are
protein
and
inactive
should be addressed.
0006-291X/91 $1.50 Copyright © 1991 by Academic Press, Inc. All rights of reproduction in any form reserved.
cAMP
of a cAMP-sensitive
and concomitant
In recent
cAMP-dependent
effects
of two catalytic
together
R2C 2. Binding in release,
the
largely kinase.
regulatory
holoenzyme subunit
of
dimer
of the catalytic distribution subject
of
of
more
Vol. 180, No. 3, 1991
detailed cytosol
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
studies but
since
also
and microtubules Cell eventto
and
are essential these
The
the
i.e.,
in
has been already
membranes
reaction
exocytotic
that sperm must perform in
(5). In sperm from sea of
-an
processes
cyclic
are
urchins
order
and
many
accompanied
nucleotides
and
by
of
a
cytosolic
cAMP-dependent
shown in sea urchin sperm
soluble
protein
sperm,
protein
representing
(9,10).
On the
kinase as much
other
hand,
of plasma membranes
L. pictus and A. punctulata sea urchin
sperm
from
(speract and resact)
[y-32p]ATP
report,
the
invoked,
an
protein
early studies have shown that incubation peptides
the
(6,7,8).
presence
1.5% of the
structures,
acrosome
cellular
metabolism
phosphorylation
cellular
functions
the egg
species
increased
as
other
not only
(2-4).
motility
fertilize
other
in
it seems to be localized
results
into several membrane
involvement
of
with
GTP
plus
in the incorporation polypeptides
a cGMP-dependent
without testing the extractability
(11).
protein
from egg
of 32p In this
kinase
was
of the kinase actvity
from the sperm membranes. In this work, whether associate membranes
a
experiments
cyclic with
therefore
nucleotide-dependent
plasma
derived
were
membranes
from
of
flagella
protein
sea of
undertaken
urchin
the
sea
to study
kinase sperm. urchin
does Plasma sperm
Strongylocentrotus purpuratus were used in this study. METHODS M a t e r i a l s . Sea u r c h i n s (Strongylocentrotus purpuratus) w e r e obtained from Pacific Bio-Marine Labs (Venice, CA). Spawning was induced by intracoelomic injection of 0.5 M KCl. Chemicals were obtained from Sigma, except materials for electrophoresis (Bio-Rad Labs.) and [7-32p]ATP (Amersham). Isolation of sperm plasma membranes. Collected sperm (i ml) were washed twice by diluting them 15-fold in Ca 2+ and Mg2+-free artificial seawater and centrifuging at 3000 x g for 10 min. The flagella were then broken off from sperm by passing the cell suspension ten times through a 21 gauge hypodermic needle (12). This suspension was then centrifuged (5000 x g for 5 min) and the flagella remaining in the supernate used as the starting material to isolate plasma membranes as already described (13,14). Measurements of protein kinase activity. Sperm membranes were incubated in a reaction mixture (75 ~i) containing 20 mM Tris-HCl (pH 7.4), 5 mM magnesium acetate, 1 mM theophylline, 150 mM NaCI, 10 mM NaF, 25 M [7-32p]ATP (600,000-900,000 cpm/assay), 0.25 % Nonidet P-40 and the indicated concentration of cAMP or cGMP. The medium also contained 1 mM ouabain and 1 mM EGTA to preclude ATP h y d r o l y s i s by N a + , K +- and C a 2 + - d e p e n d e n t ATPase activities, respectively (15). The reaction was initiated with the addition 1437
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of membrane protein (20-30 ~ g) and allowed to incubate at 30 °C for 3 min; the reaction was terminated by adding 75 pl 20% trichloroacetic acid (TCA). Precipitates were collected into GF/B Whatmann filters, which were then washed with 5 ml TCA (10%) and 5 ml ice-cold ethanol, dried and counted for radioactivity. Basal i n c o r p o r a t i o n of 32p was d e t e r m i n e d by o m i t t i n g the c y c l i c n u c l e o t i d e s from the assay medium. V a l u e s of p r o t e i n k i n a s e activity represented the substraction of 32p incorporated in the p r e s e n c e and absence of cyclic nucleotides. For the cAMPdependent protein kinase activity, linearity with respect to incubation time and membrane protein concentration were observed up to 3 min and 0.6 mg/ml of membrane protein, respectively. The concentration of ATP to give maximal incorporation of radioactivity was between 25 and 50 ~M. For e l e c t r o p h o r e s i s and a u t o r a d i o g r a p h y , the r e a c t i o n m i x t u r e (50 ~i) was as above, except that 1 p C i / a s s a y of r a d i o l a b e l e d ATP was used. In this case, the r e a c t i o n was terminated with the addition of 50 ~i electrophoresis sample buffer (Tris-HCl, pH 6.8, 8% SDS, 32% glycerol, 4% 2mercaptoethanol and 0.008% bromophenol-blue). Samples were boiled for 3 min, and then s u b j e c t e d to S D S - p o l y a c r y l a m i d e gel electrophoresis according to Laemmli (16). Gels were stained with 0.025% Commassie Blue, destained, dried and exposed to Kodak XOMAT-AR5 films for visualization of phosphorylated proteins. Protein was determined by the method of Lowry et al. (17), with bovine serum albumin as standard. RESULTS Effect
of
cyclic
nucleotides
on
protein
phosphorylation.
Flagellar plasma membranes were incubated with radiolabeled ATP in the presence of various concentrations of cyclic nucleotides and then results
processed for electrophoresis and autoradiography. are
presented
nucleotides,
the
in
amount
Fig.
i.
In
the
absence
of r a d i o p h o s p h a t e
membrane polypeptides was very low
of
cyclic
incorporated
(lane A).
Addition
The into
of cAMP
stimulated in a dose-dependent manner phosphorylation of multiple polypeptides (lanes B-E). Polypeptides that become phosphorylated corresponded to
molecular weights of about 95.5,
60.2,
39.4 and 29 kDa. Although
50,
40.7,
not
88,
78.5,
resolved
66,
in the
gel of Fig. i, at least three other polypeptides of 110, 125 and 160 Kda also accumulated radiophosphate in the presence of cAMP. cGMP, on the other hand, also stimulated protein phosphorylation in membranes but higher concentrations (50-100 PM) were required for
maximal
effect
(lanes
F-I);
the
pattern
of
phosphorylated
polypeptides was essentially the same than that elicited by cAMP. Quantitation of protein phosphorylation was accomplished by incubating
the
concentrations were
processed
membranes
with
[ y -32p]ATP
of cyclic nucleotides. for determination
into acid-precipitable material
of
and
After incubation, radioactivity
various samples
incorporated
(see Methods). As illustrated in
1438
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
25
A
B
C
D
E
F
G
H
I
97 -
20
"o
66-
~
E
_
"~
cGMP
15
45-
~:~ z
10
29-
~ ~
5 O
Q
i
®
_,
i
i
_o
i
log [CYCLIC NUCLEOTIDEL M
Fig. 1. Effect of cyclic nucleotides on 32p incorporation into polypep£ides of sperm plasma membranes. Lanes are: A, without cyclic nucleotides; R, 0.5 ~M cAMP; C, i ~ M cAMP; D, 50 ~ M cAMP; E, i00 ~M cAMP; F, 0.5 ~ cGMP; G, i ~M cGMP; H, 50 ~ M cGMP and I, i00 ~M cGMP. Three other experiments made with different membrane preparations gave the same results. Fig. 2. Protein kinase activity in sperm plasma membranes as a function of the cyclic nucleotide concentration. Incorporation of radiolabeled phosphate into membrane protein was determined by measuring the radioactivity associated with an acid-precipitable membrane material, as outlined in Methods. Values are the mean of three determinations. The results shown are representative of four independent experiments.
Fig. ~M;
2,
cAMP
stimulated
half-maximal
100 ~ M
of
maximally
response
cGMP
were
was
protein
seen
necessary
to
phosphorylation
at about
0.6 ~ M .
observe
a
In
similar
at
1
contrast,
stimulatory
effect. The
results
presented
kinase
in
protein
preferentially
Extraction
cyclic
of
kinase
investigating protein
the
then
buffer
with
sperm
the
protein
mM and
sedimented
solution
mM dithiothreitol
membranes, We
EGTA the
protein
kinase
surface
of
could
thereby
tested of
of
that
a is
for last
(i00,000
200 m M
30
x g for 10 m M
1439
occur
during for
the
this
the
membrane-associated
at of
4
°C,
this
lh)
KCI,
sucrose).
sperm
cytosolic
accounting
plasma
min
minute
from
the
for
Accordingly,
(I0 m M NaCl, and
presence
membrane
kinase
extractability
activity. i0
plasma
membrane
activity.
first
the
to c A M P m o d u l a t i o n .
plasma
the
kinase
incubated
were
the
suggest
cAMP-dependent to
AMP-dependent
measured
during
the
Binding
preparation
the
sensitive
of
membranes.
above
and
10 m M This
possibility
by
membranes
were
sonicating
them
period.
Membranes
resuspended Tris,
treatment
pH
in
a
7.4,
0.i
allows
the
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE 1.
Extraction from membranes of the cAMP-dependent protein kinase
Pretreatment
Total enzyme activity
(9) None (control)
i00
i0 mM EGTA + sonication: Supernate Pellet
19.6 81.2
Supernate Pellet
105 9.4
Nonidet P-40:
500 pg of membrane protein were subjected to the indicated treatment, followed by ultracentrifugation (see the Text). Resuspended membranes and the respective supernate were assayed for cAMP-dependent protein kinase activity. Total activity (pmol/min) was calculated for each condition and expressed as the percentage with respect to that measured in nontreated membranes. Values represent the mean of two independent experiments, each made in triplicate.
removal
of
membranes. above
approximately
25%
of
proteins
associated
Treated membranes and the supernate
centrifugation
step
were
then
with
obtained
the
from the
incubated
under
p h o s p h o r y l a t i n g conditions, with and without 25 p M cAMP. As shown in Table I, 81.2% of the total protein kinase activity stimulated by
cAMP
remained
in
the
treated
membranes,
while
a
minor
percentage was recovered in the supernate.
with the
In an additional
experiment,
1% NP-40
°C)
activity
(i h, 4 of
membranes were
and then ultracentrifuged.
cAMP-dependent
protein
kinase
both the resuspended pellet and the supernate. i,
the
enzyme
activity
first
was
only
detected
was
incubated
Thereafter, measured
in
As shown in Table in
the
supernate
indicating the total solubilization of the protein kinase. Thus, resistant
to
the
detected
extraction
cAMP-dependent
by
treatments
protein
that
remove
kinase
is
proteins
loosely bound to the membrane surface.
The enzyme may be however
recovered
disrupting
in
a
soluble
form
after
the
membrane
structure with NP-40.
Removal
of
the
pretreated
with
manner
which
in
cAMP-dependent cAMP.
the
We
protein
addressed
inactive
in
kinase
a
holoenzyme ]440
from
membranes
preliminary
form
the
interacts
with
the
V o l . 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
A
Fig. 3. pretreated
Absence with an
B
C
of p r o t e i n phosphorylation in m e m b r a n e s excess of cAMP. Flagellar plasma membranes
were preincubated with cAMP and then ultracentrifuged and resuspended in buffer solution (see the Text). cAMP-pretreated membranes were incubated with [7 -32p] ATP alone (A), with 25 ~M cAMP (B) or 25 ~M cAMP plus 5 units/100 pl of bovine heart catalytic subunit.
membrane. the
This
presence
protein).
was
of
accomplished
cAMP
in
Sonication
by
excess
was
sonicating (200
carried
the
~moles
out
to
membranes
cAMP/ pg allow
in
membrane
the
cyclic
nucleotide to reach both sides of the membranes.
After i n c u b a t i o n
(30 min,
i00,000
4 °C),
membranes
r e s u s p e n d e d in buffer incubated
under
were
centrifuged
solution,
at
cAMP-treated membranes
phosphorylating
conditions
and,
p r o c e s s e d for electrophoresis and autoradiography. in Fig. the
3, protein phosphorylation
absence
or
presence
of
cAMP
was abolished in the
assay
This result may not be due to inactivation
x
g
were
and then
thereafter,
As i l l u s t r a t e d irrespective
(lanes
A
and
of the protein
of B).
kinase
since nontreated membranes were responsive to cAMP. Additionally, polypeptides
derived
from
cAMP-treated
susceptible to phosphorylation, of
a marked
catalytic
radiolabeling
membranes
remained
as demonstrated by the a p p e a r a n c e
upon
introduction
subunit from bovine heart
of
an
exogenous
(lane C).
DISCUSSION
The present
study shows that plasma membranes
flagella
of
the
sea
urchin
contain
an
endogenous
sperm
activity
1441
isolated
from
Strongylocentrotus purpuratus of
protein
kinase
that
is
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
preferentially
stimulated
by cAMP
rather
than
cGMP.
mentioned that in terms of purity these membranes free of material that
they
from intracellular
maintain
functionally
transport properties
(14,15,18,19).
Given
its
resistance
sonication,
but
that
detected
the
not
physiologically
that not
this
shown).
protein
was
is
of
10
their
ion
EGTA
and
mM
plausible
activity
the
might
membrane,
rather
kinase
be than
activity
is
form was also supported by the fact as
an
exogenous
a reliable
sea
in addition,
of
therefore
membrane-bound
ineffective
Protamine
kinase
and,
with is
kinase
with
from the cytosolic
protamine
it
be
are relatively
many
extraction
protein
That
active
detergent,
associated
artifactually. different
to
with
structures
It must
urchin
substrate
sperm
substrate for
(i0);
the
this
(data
soluble previous
observation was also shown in our assay system. It whole
has
been
sperm
respond
to
that
plasma
L.
urchins and
A
similar
membranes
pictus
GTP
phosphorylation
(ii).
independently These
sea
peptides
the
polypeptides nM.
the
egg
production,
protein
reported
of
by
level
effect
of
was
data
suggest
the
although
indication
participation
of
of
to
be
their caused
between a
cGMP
10-100
cGMP-dependent
intrinsic
association
of this kinase with the membranes was not documented.
We have not
found
the
same
phsphorylation discrepancies different amounts
sensitivity
in f l a g e l l a r may
be
sea urchin of
purpuratus
a
conditions,
to
plasma
explained species,
by
ii)
cGMP-dependent
sperm
and
including
cGMP-mediated membranes.
i) the
protein
iii) the
of an
via
several shown
from
punctulata
increasing,
by cAMP and cGMP at concentrations
kinase,
isolated
A.
and
the
kinase
variations
use
of
use
presence in
protein
These of of
apparent
cells
undetectable
activity the
distinct
from in
S.
experimental
plasma
membrane
preparations. The by
subcellular
cAMP
has
investigations example,
been
distribution recently
the
in several types
cAMP-sensitive
Golgi
apparatus,
poles
and
rough
microtubules
performed
in mammalian
cytosolic
enzyme,
of protein
protein
subject
of cells. kinase
endoplasmic (2-4). sperm
of
On
the
been
cells,
found
in
for the
spindle
hand,
studies
in addition kinase
appears
present in the outer plasma membrane and in the axoneme 1442
detailed
mitotic
other
that,
protein
stimulated
more
In somatic
has
reticulum,
indicate
a cAMP-dependent
kinases
to
the
to be
(20-22).
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
The exact the
sperm
that
manner
membrane
in those
been
found
remains
cells in
subcellular
in which
absence
subunit.
Nevertheless, the
kinase
detected
to
experiments
isolated
from
preparation). nucleotides
membranes,
i.e.,
preference
for cAMP
the We
(data
was
not
plausible of sperm.
The
physiological
dependent,
protein
speculative. assume
could
be
bilayer
the
relevant
The
(ref.
with
of the
of the catalytic to c o n f i r m
membrane
~M for
to
via
its
importance
of
with the cytosolic
those
of
might
protein
cyclase
and
over
cGMP.
along
membrane-bound,
is
at
present it
is
and the
cAMPmerely
reasonable
in
the
membrane
substrates
placed
in
the
membrane
serve
as
surface; a
protein
this form of
reservoir
kinase
for
occurs
and probably
also
that the enzyme may be involved reaction,
likely
polypeptides for
the
here used,
acting
this
in
the
in the
in sperm
in concert
this
regard,
susceptible
possibly
the
the
it is expected
that become protein
the nature of the phosphorylated
membrane
flagellar
kinase
also
acrosome
substrates In
of
to
kinase.
not all the membrane
established.
response
of
this
Given the in vitro conditions physiological
details
distributes
a
activity
of the sperm flagellum,
and in the
found
in plasma
for
effect)
of compartmentalization,
suggests
also
the
that
half-maximal
that this kinase
occurrence for
we
15
that
similar
fact that the detected
head membrane,
hand,
to The
pretreated
protein kinase
head
or in the proximity of the membrane
plasma membrane motility
II serves
amounts of protein kinase activity
kinase
In terms
that
compartmentalization enzyme.
other
possibility.
shown)
anticipate
very
(0.4
It is therefore
sperm
can
identical
plasma membrane
to
the
has
the experiment
are necessary
binds
activity of cyclic nucleotide-dependent membranes cyclic
noteworthy kinase
of the dissociation
and the displacement
to
subunit.
In preliminary
membrane
same
binds
some
type
in membranes
other experiments
here
is
or
context,
this
as an indication
of the holoenzyme
regulatory
subunit
In this
to explore
subunits
It
protein
membranes
the regulatory
phosphorylation
cAMP was interpreted
holoenzyme
elucidated.
with
(2,4,22).
3 was made
of protein
whether
be
inactive
a cAMP-dependent
association
structures,
in Fig.
to
where
anchor the holoenzyme shown
the
only
phosphorylated
kinase.
1443
On
polypeptides known
of phosphorylation adenylate
that
cyclase
sea
are
the
other
remains
to be
urchin
sperm
is the guanylate (23,24).
Other
Vol. 180, No. 3, 1991
potential
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
substrates
function,
essential
might
under
be
phosphorylation receptor channels.
(26)
could
for
control
sperm by
include
Thus,
influence
the
transporters
and
acrosome
phosphorylation;
of the Ca 2+ channel may
ion
motility
cation
cAMP-dependent
(25)
and the
conductance protein
for
instance,
acetylcholine through
kinase
characterized in detail and its role in chemotaxis,
whose
reaction,
these
should
be
activation of
motility and acrosome reaction further explored.
This research was supported by The World Health O r g a n i z a t i o n , The T h i r d W o r l d A c a d e m y of S c i e n c e s , C O N A C Y T (Mexico) and by an International Research Scholar award from the Howard Huges Medical Institute to A.D. We thank Enrique Ramirez, Lucia Garcia and Irma Vargas for technical assistance, and Carmen Silva for help in preparing the manuscript.
ACKNOWLEDGMENTS:
REFERENCES
i. 2. 3. 4. 5. 6. 7. 8. 9. i0. ii. 12. 13. 14. 15. 16. 17. 18. 19.
Taylor, S.S. (1989) J. Biol. Chem. 264, 8443-8446. Nigg, E.A., Shafer, G., Hilz, H. and Eppenberger, H.M. (1985) Cell 41, 1039-1051. Nigam, S.K. and Blobel, G. (1989) J. Biol. Chem. 264, 16927-16932. DeCamilli, P., Moretti, M., Dennis Donini, S., Walter, U. and Lohmann, S.M. (1986) J. Cell Biol. 103, 189-203. Garbers, D.L. (1989) Ann. Rev. Biochem. 58, 719-742. Garbers, D.L. and Kopf, G.S. (1980) Adv. Cyclic Nucleotide Res. 13, 251-306. Suzuki, N., Shimomura, H., Radany, E.W., Ramarao, C.S., Ward, G.E., Bentley, J.K. and Garbers, D.L. (1984) J. Biol. Chem. 259, 14874-14879. Porter, D.C., Moy, G.W. and Vacquier, V.D. (1988) J. Biol. Chem. 263, 2750-2755. Lee, M.Y.W. and Iverson, R.M. (1972) Exptl. Cell Res. 75, 300-304. Lee, M.Y.W. and Iverson, R.M. (1976) Biochim. Biophys. Acta 429, 123-136. Bentley, J.K., Khatra, A.S. and Garbers, D.L. (1987) J. Biol. Chem. 262, 15708-15713. Gray, J.P. and Drummond, G.I. (1976) Arch. Biochem. Biophys. 172, 31-38 Cross, N.L. (1983) J. Cell Sci. 59, 13-25. Darszon, A., Gould, M., de De la Torre, L. and Vargas, I. (1984) Eur. J. Biochem. 144, 515-522. Garcia-Soto, J., M0urelle , M., Vargas, I., de De La Torre, L., Ramirez, E., Lopez-Colome, A.M. and Darszon, A. (1988) Biochim. Biophys. Acta 944, 1-12. Laemmli, U.K. (1970) Nature (Lond.) 227, 680-685. Lowry, O.H., Rosebrough, N.J., Farr, A.L. and Randall, R.J. (1951) J. Biol. Chem. 193, 265-275. Lievano, A., Sanchez, J.A. and Darszon, A. (1985) Dev.Biol. 112, 253-257. Lievano, A., J., Vega-Sainz De Miera, E.C. and Darszon, A. (1990) J. Gen. Physiol. 95: 273-296. 1444
Vol. 180, No. 3, 1991
20. 21. 22. 23. 24. 25. 26.
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Tash, J.S., Kakar, S.S. and Means, A.R. (1984) Cell 38, 551559. Horowitz, J.A., Wasco, W., Leiser, M. and Orr, G.A. (1988) J. Biol. Chem. 263, 2098-2104. Horowitz, J.A., Toeg, H. and Orr, G.A. (1984) J. Biol. Chem. 259, 832-838. Ward, G.E., Garbers, D.L. and Vacquier, V.D. (1985) Science 227, 768-770. Bookbinder, L.H., Moy, G.W. and Vacquier, V.D. (1990) J. Cell Biol. Iii: 1859-1866. Rehm, H., Peizer, S., Cochet, C., Chambaz, E., Tempel, B. and Tratwein, W. (1989) Biochemistry 28, 6455-6460. Smith, M.M., Merlie, J.P. and Lawrence, J.C., Jr. (1989) J. Biol. Chem. 264, 12813-12819.
1445
Vol. 180, No. 3, 1991
Pages 1436-1445
November 14, 1991
ENDOGENOUS IN P L A S M A
Jesus
A C T I V I T Y OF C Y C L I C N U C L E O T I D E - D E P E N D E N T PROTEIN KINASE MEMBRANES I S O L A T E D F R O M Strongylocentrotus purpuratus SEA URCHIN SPERM
G a r c i a - S o t o a*, Luz Alberto Darszonb, c
M. A r a i z a a, M i r i a m B a r r i o s a, and Juan P. Luna-Arias a
aInstituto de Investigacion en Biologia Experimental, Facultad de Quimica~ Universidad de Guanajuato, A.P. 187, Guanajuato, GTO, Mexico bDepartamento de Bioquimica, Centro de Investigacion y de Estudios Avanzados and CDepartamento de Bioquimica, Centro de Investigacion sobre Ingenieria Gen~tica y Biotecnologla, Cuernavaca, Mexico Received September 27, 1991 SUMMARY: Activity of cyclic nucleotide-dependent protein kinase was investigated in flagellar plasma membranes of sea urchin sperm (S. purpuratus). Membranes incubated with [T-32p]ATP showed in the presence of 1 ~M cAMP an increased phosphorylation in multiple polypeptides. Half maximal response was seen at 0.6 ~M of cAMP. In contrast, higher concentrations (100 pM) of cGMP were required to cause the same amount of protein phosphorylation. 80% of the protein kinase activity stimulatable by cAMP was resistant to extraction by 10 mM EGTA and sonication but it was entirely recovered in a d e t e r g e n t - s o l u b i l i z e d fraction. Membranes pretreated with 200 p M cAMP, ultracentrifuged and resuspended in buffer solution did not undergo cAMP-stimulated phosphorylation in their polypeptides. This study demonstrates that flagellar plasma membranes isolated from S. purpuratus sea urchin sperm have an endogenous cAMP-dependent protein kinase, which may be bound to the membrane via its regulatory subunit. ©1991AcademicP..... Inc.
In mediated
eukaryotic via
This
enzyme
(R)
subunits
the
form
results subunit
the
cells,
activation
is composed that
(I).
of
protein
*To whom correspondence
of
constitute cAMP
to
years, kinase
an
the
(C)
the
subcellular
has
been
1436
two
regulatory
activation, the
are
protein
and
inactive
should be addressed.
0006-291X/91 $1.50 Copyright © 1991 by Academic Press, Inc. All rights of reproduction in any form reserved.
cAMP
of a cAMP-sensitive
and concomitant
In recent
cAMP-dependent
effects
of two catalytic
together
R2C 2. Binding in release,
the
largely kinase.
regulatory
holoenzyme subunit
of
dimer
of the catalytic distribution subject
of
of
more
Vol. 180, No. 3, 1991
detailed cytosol
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
studies but
since
also
and microtubules Cell eventto
and
are essential these
The
the
i.e.,
in
has been already
membranes
reaction
exocytotic
that sperm must perform in
(5). In sperm from sea of
-an
processes
cyclic
are
urchins
order
and
many
accompanied
nucleotides
and
by
of
a
cytosolic
cAMP-dependent
shown in sea urchin sperm
soluble
protein
sperm,
protein
representing
(9,10).
On the
kinase as much
other
hand,
of plasma membranes
L. pictus and A. punctulata sea urchin
sperm
from
(speract and resact)
[y-32p]ATP
report,
the
invoked,
an
protein
early studies have shown that incubation peptides
the
(6,7,8).
presence
1.5% of the
structures,
acrosome
cellular
metabolism
phosphorylation
cellular
functions
the egg
species
increased
as
other
not only
(2-4).
motility
fertilize
other
in
it seems to be localized
results
into several membrane
involvement
of
with
GTP
plus
in the incorporation polypeptides
a cGMP-dependent
without testing the extractability
(11).
protein
from egg
of 32p In this
kinase
was
of the kinase actvity
from the sperm membranes. In this work, whether associate membranes
a
experiments
cyclic with
therefore
nucleotide-dependent
plasma
derived
were
membranes
from
of
flagella
protein
sea of
undertaken
urchin
the
sea
to study
kinase sperm. urchin
does Plasma sperm
Strongylocentrotus purpuratus were used in this study. METHODS M a t e r i a l s . Sea u r c h i n s (Strongylocentrotus purpuratus) w e r e obtained from Pacific Bio-Marine Labs (Venice, CA). Spawning was induced by intracoelomic injection of 0.5 M KCl. Chemicals were obtained from Sigma, except materials for electrophoresis (Bio-Rad Labs.) and [7-32p]ATP (Amersham). Isolation of sperm plasma membranes. Collected sperm (i ml) were washed twice by diluting them 15-fold in Ca 2+ and Mg2+-free artificial seawater and centrifuging at 3000 x g for 10 min. The flagella were then broken off from sperm by passing the cell suspension ten times through a 21 gauge hypodermic needle (12). This suspension was then centrifuged (5000 x g for 5 min) and the flagella remaining in the supernate used as the starting material to isolate plasma membranes as already described (13,14). Measurements of protein kinase activity. Sperm membranes were incubated in a reaction mixture (75 ~i) containing 20 mM Tris-HCl (pH 7.4), 5 mM magnesium acetate, 1 mM theophylline, 150 mM NaCI, 10 mM NaF, 25 M [7-32p]ATP (600,000-900,000 cpm/assay), 0.25 % Nonidet P-40 and the indicated concentration of cAMP or cGMP. The medium also contained 1 mM ouabain and 1 mM EGTA to preclude ATP h y d r o l y s i s by N a + , K +- and C a 2 + - d e p e n d e n t ATPase activities, respectively (15). The reaction was initiated with the addition 1437
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of membrane protein (20-30 ~ g) and allowed to incubate at 30 °C for 3 min; the reaction was terminated by adding 75 pl 20% trichloroacetic acid (TCA). Precipitates were collected into GF/B Whatmann filters, which were then washed with 5 ml TCA (10%) and 5 ml ice-cold ethanol, dried and counted for radioactivity. Basal i n c o r p o r a t i o n of 32p was d e t e r m i n e d by o m i t t i n g the c y c l i c n u c l e o t i d e s from the assay medium. V a l u e s of p r o t e i n k i n a s e activity represented the substraction of 32p incorporated in the p r e s e n c e and absence of cyclic nucleotides. For the cAMPdependent protein kinase activity, linearity with respect to incubation time and membrane protein concentration were observed up to 3 min and 0.6 mg/ml of membrane protein, respectively. The concentration of ATP to give maximal incorporation of radioactivity was between 25 and 50 ~M. For e l e c t r o p h o r e s i s and a u t o r a d i o g r a p h y , the r e a c t i o n m i x t u r e (50 ~i) was as above, except that 1 p C i / a s s a y of r a d i o l a b e l e d ATP was used. In this case, the r e a c t i o n was terminated with the addition of 50 ~i electrophoresis sample buffer (Tris-HCl, pH 6.8, 8% SDS, 32% glycerol, 4% 2mercaptoethanol and 0.008% bromophenol-blue). Samples were boiled for 3 min, and then s u b j e c t e d to S D S - p o l y a c r y l a m i d e gel electrophoresis according to Laemmli (16). Gels were stained with 0.025% Commassie Blue, destained, dried and exposed to Kodak XOMAT-AR5 films for visualization of phosphorylated proteins. Protein was determined by the method of Lowry et al. (17), with bovine serum albumin as standard. RESULTS Effect
of
cyclic
nucleotides
on
protein
phosphorylation.
Flagellar plasma membranes were incubated with radiolabeled ATP in the presence of various concentrations of cyclic nucleotides and then results
processed for electrophoresis and autoradiography. are
presented
nucleotides,
the
in
amount
Fig.
i.
In
the
absence
of r a d i o p h o s p h a t e
membrane polypeptides was very low
of
cyclic
incorporated
(lane A).
Addition
The into
of cAMP
stimulated in a dose-dependent manner phosphorylation of multiple polypeptides (lanes B-E). Polypeptides that become phosphorylated corresponded to
molecular weights of about 95.5,
60.2,
39.4 and 29 kDa. Although
50,
40.7,
not
88,
78.5,
resolved
66,
in the
gel of Fig. i, at least three other polypeptides of 110, 125 and 160 Kda also accumulated radiophosphate in the presence of cAMP. cGMP, on the other hand, also stimulated protein phosphorylation in membranes but higher concentrations (50-100 PM) were required for
maximal
effect
(lanes
F-I);
the
pattern
of
phosphorylated
polypeptides was essentially the same than that elicited by cAMP. Quantitation of protein phosphorylation was accomplished by incubating
the
concentrations were
processed
membranes
with
[ y -32p]ATP
of cyclic nucleotides. for determination
into acid-precipitable material
of
and
After incubation, radioactivity
various samples
incorporated
(see Methods). As illustrated in
1438
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
25
A
B
C
D
E
F
G
H
I
97 -
20
"o
66-
~
E
_
"~
cGMP
15
45-
~:~ z
10
29-
~ ~
5 O
Q
i
®
_,
i
i
_o
i
log [CYCLIC NUCLEOTIDEL M
Fig. 1. Effect of cyclic nucleotides on 32p incorporation into polypep£ides of sperm plasma membranes. Lanes are: A, without cyclic nucleotides; R, 0.5 ~M cAMP; C, i ~ M cAMP; D, 50 ~ M cAMP; E, i00 ~M cAMP; F, 0.5 ~ cGMP; G, i ~M cGMP; H, 50 ~ M cGMP and I, i00 ~M cGMP. Three other experiments made with different membrane preparations gave the same results. Fig. 2. Protein kinase activity in sperm plasma membranes as a function of the cyclic nucleotide concentration. Incorporation of radiolabeled phosphate into membrane protein was determined by measuring the radioactivity associated with an acid-precipitable membrane material, as outlined in Methods. Values are the mean of three determinations. The results shown are representative of four independent experiments.
Fig. ~M;
2,
cAMP
stimulated
half-maximal
100 ~ M
of
maximally
response
cGMP
were
was
protein
seen
necessary
to
phosphorylation
at about
0.6 ~ M .
observe
a
In
similar
at
1
contrast,
stimulatory
effect. The
results
presented
kinase
in
protein
preferentially
Extraction
cyclic
of
kinase
investigating protein
the
then
buffer
with
sperm
the
protein
mM and
sedimented
solution
mM dithiothreitol
membranes, We
EGTA the
protein
kinase
surface
of
could
thereby
tested of
of
that
a is
for last
(i00,000
200 m M
30
x g for 10 m M
1439
occur
during for
the
this
the
membrane-associated
at of
4
°C,
this
lh)
KCI,
sucrose).
sperm
cytosolic
accounting
plasma
min
minute
from
the
for
Accordingly,
(I0 m M NaCl, and
presence
membrane
kinase
extractability
activity. i0
plasma
membrane
activity.
first
the
to c A M P m o d u l a t i o n .
plasma
the
kinase
incubated
were
the
suggest
cAMP-dependent to
AMP-dependent
measured
during
the
Binding
preparation
the
sensitive
of
membranes.
above
and
10 m M This
possibility
by
membranes
were
sonicating
them
period.
Membranes
resuspended Tris,
treatment
pH
in
a
7.4,
0.i
allows
the
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE 1.
Extraction from membranes of the cAMP-dependent protein kinase
Pretreatment
Total enzyme activity
(9) None (control)
i00
i0 mM EGTA + sonication: Supernate Pellet
19.6 81.2
Supernate Pellet
105 9.4
Nonidet P-40:
500 pg of membrane protein were subjected to the indicated treatment, followed by ultracentrifugation (see the Text). Resuspended membranes and the respective supernate were assayed for cAMP-dependent protein kinase activity. Total activity (pmol/min) was calculated for each condition and expressed as the percentage with respect to that measured in nontreated membranes. Values represent the mean of two independent experiments, each made in triplicate.
removal
of
membranes. above
approximately
25%
of
proteins
associated
Treated membranes and the supernate
centrifugation
step
were
then
with
obtained
the
from the
incubated
under
p h o s p h o r y l a t i n g conditions, with and without 25 p M cAMP. As shown in Table I, 81.2% of the total protein kinase activity stimulated by
cAMP
remained
in
the
treated
membranes,
while
a
minor
percentage was recovered in the supernate.
with the
In an additional
experiment,
1% NP-40
°C)
activity
(i h, 4 of
membranes were
and then ultracentrifuged.
cAMP-dependent
protein
kinase
both the resuspended pellet and the supernate. i,
the
enzyme
activity
first
was
only
detected
was
incubated
Thereafter, measured
in
As shown in Table in
the
supernate
indicating the total solubilization of the protein kinase. Thus, resistant
to
the
detected
extraction
cAMP-dependent
by
treatments
protein
that
remove
kinase
is
proteins
loosely bound to the membrane surface.
The enzyme may be however
recovered
disrupting
in
a
soluble
form
after
the
membrane
structure with NP-40.
Removal
of
the
pretreated
with
manner
which
in
cAMP-dependent cAMP.
the
We
protein
addressed
inactive
in
kinase
a
holoenzyme ]440
from
membranes
preliminary
form
the
interacts
with
the
V o l . 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
A
Fig. 3. pretreated
Absence with an
B
C
of p r o t e i n phosphorylation in m e m b r a n e s excess of cAMP. Flagellar plasma membranes
were preincubated with cAMP and then ultracentrifuged and resuspended in buffer solution (see the Text). cAMP-pretreated membranes were incubated with [7 -32p] ATP alone (A), with 25 ~M cAMP (B) or 25 ~M cAMP plus 5 units/100 pl of bovine heart catalytic subunit.
membrane. the
This
presence
protein).
was
of
accomplished
cAMP
in
Sonication
by
excess
was
sonicating (200
carried
the
~moles
out
to
membranes
cAMP/ pg allow
in
membrane
the
cyclic
nucleotide to reach both sides of the membranes.
After i n c u b a t i o n
(30 min,
i00,000
4 °C),
membranes
r e s u s p e n d e d in buffer incubated
under
were
centrifuged
solution,
at
cAMP-treated membranes
phosphorylating
conditions
and,
p r o c e s s e d for electrophoresis and autoradiography. in Fig. the
3, protein phosphorylation
absence
or
presence
of
cAMP
was abolished in the
assay
This result may not be due to inactivation
x
g
were
and then
thereafter,
As i l l u s t r a t e d irrespective
(lanes
A
and
of the protein
of B).
kinase
since nontreated membranes were responsive to cAMP. Additionally, polypeptides
derived
from
cAMP-treated
susceptible to phosphorylation, of
a marked
catalytic
radiolabeling
membranes
remained
as demonstrated by the a p p e a r a n c e
upon
introduction
subunit from bovine heart
of
an
exogenous
(lane C).
DISCUSSION
The present
study shows that plasma membranes
flagella
of
the
sea
urchin
contain
an
endogenous
sperm
activity
1441
isolated
from
Strongylocentrotus purpuratus of
protein
kinase
that
is
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
preferentially
stimulated
by cAMP
rather
than
cGMP.
mentioned that in terms of purity these membranes free of material that
they
from intracellular
maintain
functionally
transport properties
(14,15,18,19).
Given
its
resistance
sonication,
but
that
detected
the
not
physiologically
that not
this
shown).
protein
was
is
of
10
their
ion
EGTA
and
mM
plausible
activity
the
might
membrane,
rather
kinase
be than
activity
is
form was also supported by the fact as
an
exogenous
a reliable
sea
in addition,
of
therefore
membrane-bound
ineffective
Protamine
kinase
and,
with is
kinase
with
from the cytosolic
protamine
it
be
are relatively
many
extraction
protein
That
active
detergent,
associated
artifactually. different
to
with
structures
It must
urchin
substrate
sperm
substrate for
(i0);
the
this
(data
soluble previous
observation was also shown in our assay system. It whole
has
been
sperm
respond
to
that
plasma
L.
urchins and
A
similar
membranes
pictus
GTP
phosphorylation
(ii).
independently These
sea
peptides
the
polypeptides nM.
the
egg
production,
protein
reported
of
by
level
effect
of
was
data
suggest
the
although
indication
participation
of
of
to
be
their caused
between a
cGMP
10-100
cGMP-dependent
intrinsic
association
of this kinase with the membranes was not documented.
We have not
found
the
same
phsphorylation discrepancies different amounts
sensitivity
in f l a g e l l a r may
be
sea urchin of
purpuratus
a
conditions,
to
plasma
explained species,
by
ii)
cGMP-dependent
sperm
and
including
cGMP-mediated membranes.
i) the
protein
iii) the
of an
via
several shown
from
punctulata
increasing,
by cAMP and cGMP at concentrations
kinase,
isolated
A.
and
the
kinase
variations
use
of
use
presence in
protein
These of of
apparent
cells
undetectable
activity the
distinct
from in
S.
experimental
plasma
membrane
preparations. The by
subcellular
cAMP
has
investigations example,
been
distribution recently
the
in several types
cAMP-sensitive
Golgi
apparatus,
poles
and
rough
microtubules
performed
in mammalian
cytosolic
enzyme,
of protein
protein
subject
of cells. kinase
endoplasmic (2-4). sperm
of
On
the
been
cells,
found
in
for the
spindle
hand,
studies
in addition kinase
appears
present in the outer plasma membrane and in the axoneme 1442
detailed
mitotic
other
that,
protein
stimulated
more
In somatic
has
reticulum,
indicate
a cAMP-dependent
kinases
to
the
to be
(20-22).
Vol. 180, No. 3, 1991
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
The exact the
sperm
that
manner
membrane
in those
been
found
remains
cells in
subcellular
in which
absence
subunit.
Nevertheless, the
kinase
detected
to
experiments
isolated
from
preparation). nucleotides
membranes,
i.e.,
preference
for cAMP
the We
(data
was
not
plausible of sperm.
The
physiological
dependent,
protein
speculative. assume
could
be
bilayer
the
relevant
The
(ref.
with
of the
of the catalytic to c o n f i r m
membrane
~M for
to
via
its
importance
of
with the cytosolic
those
of
might
protein
cyclase
and
over
cGMP.
along
membrane-bound,
is
at
present it
is
and the
cAMPmerely
reasonable
in
the
membrane
substrates
placed
in
the
membrane
serve
as
surface; a
protein
this form of
reservoir
kinase
for
occurs
and probably
also
that the enzyme may be involved reaction,
likely
polypeptides for
the
here used,
acting
this
in
the
in the
in sperm
in concert
this
regard,
susceptible
possibly
the
the
it is expected
that become protein
the nature of the phosphorylated
membrane
flagellar
kinase
also
acrosome
substrates In
of
to
kinase.
not all the membrane
established.
response
of
this
Given the in vitro conditions physiological
details
distributes
a
activity
of the sperm flagellum,
and in the
found
in plasma
for
effect)
of compartmentalization,
suggests
also
the
that
half-maximal
that this kinase
occurrence for
we
15
that
similar
fact that the detected
head membrane,
hand,
to The
pretreated
protein kinase
head
or in the proximity of the membrane
plasma membrane motility
II serves
amounts of protein kinase activity
kinase
In terms
that
compartmentalization enzyme.
other
possibility.
shown)
anticipate
very
(0.4
It is therefore
sperm
can
identical
plasma membrane
to
the
has
the experiment
are necessary
binds
activity of cyclic nucleotide-dependent membranes cyclic
noteworthy kinase
of the dissociation
and the displacement
to
subunit.
In preliminary
membrane
same
binds
some
type
in membranes
other experiments
here
is
or
context,
this
as an indication
of the holoenzyme
regulatory
subunit
In this
to explore
subunits
It
protein
membranes
the regulatory
phosphorylation
cAMP was interpreted
holoenzyme
elucidated.
with
(2,4,22).
3 was made
of protein
whether
be
inactive
a cAMP-dependent
association
structures,
in Fig.
to
where
anchor the holoenzyme shown
the
only
phosphorylated
kinase.
1443
On
polypeptides known
of phosphorylation adenylate
that
cyclase
sea
are
the
other
remains
to be
urchin
sperm
is the guanylate (23,24).
Other
Vol. 180, No. 3, 1991
potential
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
substrates
function,
essential
might
under
be
phosphorylation receptor channels.
(26)
could
for
control
sperm by
include
Thus,
influence
the
transporters
and
acrosome
phosphorylation;
of the Ca 2+ channel may
ion
motility
cation
cAMP-dependent
(25)
and the
conductance protein
for
instance,
acetylcholine through
kinase
characterized in detail and its role in chemotaxis,
whose
reaction,
these
should
be
activation of
motility and acrosome reaction further explored.
This research was supported by The World Health O r g a n i z a t i o n , The T h i r d W o r l d A c a d e m y of S c i e n c e s , C O N A C Y T (Mexico) and by an International Research Scholar award from the Howard Huges Medical Institute to A.D. We thank Enrique Ramirez, Lucia Garcia and Irma Vargas for technical assistance, and Carmen Silva for help in preparing the manuscript.
ACKNOWLEDGMENTS:
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