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Stimulation of the Ca2+-dependent polymerization of synexin by cis -unsaturated fatty acids
Vol.
132,
October
No. 2, 1985 30,
BIOCHEMICAL
BIOPHYSICAL
AND
RESEARCH
COMMUNICATIONS Pages
1985
STIMULATION OF THE Ca*+-DEPENDENT OF SYNEXIN BY =-UNSATURATED DAVID
C.
STERNER,
De,partment
of
Neuroscience,
Received
August
19,
WILLIAM
J.
Pharmacology and Cell University Charlottesville,
505-512
POLYMERIZATION FATTY ACIDS
ZAKS
AND CARL
and Programs and Molecular of Virginia VA 22908
in
E.
CREUTZ
Biophysics, Biology
1985
The influence of fatty acids on the polymerization of synexin was studied by monitoring light scattered from solutions of purified synexin. m-unsaturated fatty acids such as arachidonate or oleate stimulated synexin polymerization at sub-micromolar concentrations, while saturated fatty acids, a trans unsaturated fatty acid or a fatty acid methyl ester had little effect. The olymerization of synexin occurred at lower concentrations of Ca 4+ in the presence of the fatty acids than Therefore, Ca*+ and free fatty in the absence of fatty acids. acids may act as co-regulators of synexin action in stimulated 0 1985 Academic Press, Inc. secretory cells.
In
an
membrane
attempt
have in
have'been
identified
promote membrane
undertaken
the
both
that
close
These
the
case
of
mechanism
by which
follows:
1)
with
Kd -4
Ca2+
then
M (threshold
irreversible
When
uM, binds
to
- 10 membranes contact
to
one
synexin
a site
binds
to
membranes
polymerize form
between
one
to
proteins but
also
another, and
hypothesis
on
bind
two
membrane
to
causes
that
(1)
specific
of
several
least
to
promotes
class
regulate
membranes,
membranes
binds
PM) which
to
At
bind
are
protein
a second
to
(l-5).
proteins
this
synexin
proteins
of
synexin,
Ca2+
soluble
only
attachment
might
exocytosis,
Ca*+
not
that
during of
of
presence
fusion. In
proteins
occurring
been
membranes
different
identify
interactions
studies
(5).
to
and
calelectrin for
the
contacts
is
as
the
synexin
molecule
as
a monomer
(6);
site
Kd - 200
binding
the
synexin
(71,
thus
with
monomers promoting
the
membranes.
A2
Copyright 0 1985 rights of reproducfion
2)
on an Once
the
0006-291X/85 505
u
$1.50
by Academic Press, Inc. in any form reserved.
Vol.
132,
No. 2, 1985
membranes low
BIOCHEMICAL
have
concentrations
might
become
result
of
of
the
from
properties action The like
most
synexin
secretory
cells
necessary
to
may
mediate is
the
we have in
sensitivity
it
of
communication
the
synexin
sought
the we
cells
synexin describe
between
synexin
and
synexin
polymerization,
to
free
the
as a
Interestingly,
same
fusion
quite
mechanism
that
that
in
Ca2+
of
that
if
could
a protein
stimulated appears
polymerization
determine
to
other alter
important that at
appears low
be
reaction. cofactors the
may
Ca2+
reaction.
a potentially
particularly
cell
hypothesis
of
acids
as
polymerization
the
polymerization
fatty
to
(9).
membrane level
stimulated
and
contacts
high
exposed
immunochemically
possess
of
if acids,
(8).
binding
aspect
stimulate
Accordingly, present
Ca2+
membrane
might
fuse
secretory
and
has
COMMUNICATIONS
fatty
phospholipases
physically
troubling
will
a stimulated of
suggest
promoting
they
RESEARCH
a-unsaturated
in
synexin,
that in
free,
is
BIOPHYSICAL
contact,
activation which
distinct
this
available
calelectrin,
be
formed
AND
In
this
interaction to
concentrations
stimulate of
Ca2+.
MATERIALS
AND METHODS
Materials. Synexin was prepared from bovine liver by ammonium sulfate precipitation from a post microsomal supernatant and gel filtration on LKB Ultrogel ACA 34 (1). The synexin was isolated in 0.3 M sucrose, 40 mM MES pH 6.0; immediately before the light 40 mM HEPES was added and the pH scattering experiments, Fatty acids were obtained from Sigma adjusted to 7.3 with NaOH. and stock solutions of 5 mg/ml were prepared in ethanol. Calcium buffers were prepared as 50X stock solutions using CaC12 and EGTA according to the method described by Caldwell (10). In calculating the pCa, a binding constant of 1.897 x lo7 for Ca2+ and EGTA at pH 7.3 was used (10). Light scattering measurements. Intensity of 350 nm light scattered at 90’ was monitored continuously in a Spex 1llC spectroflurometer using a 0.5 cm square cuvette. The following additions were made to the cuvette: 263 ul synexin in 0.3 M surcose, 40 mM MES, 40 mM HEPES, pH 7.3; 66 nl 0.15 M kC1; 4.5 ~1 ethanol containing various concentrations of fatty acid (also included in controls without fatty acid). After recording baseline light scattering for 200 set, synexin polymerization was initiated by adding 6 ~1 506
Vol.
132,
No.
of Ca2+ various monitored
BIOCHEMICAL
2. 1985
AND
BIOPHYSICAL
RESEARCH
buffer to give a final EGTA concentration amounts of CaC12. Polymerization was for 400 sec.
COMMUNtCATtONS
of 2.5 subsequently
mM and
RESULTS The by
polymerization
measurement
of
of
light
spectroflourometer line
for
light
form,
of
Polymerization
scattering
If
reaction added no
2.2
mixture, is
greatly
increase
in
0.75E
the
(7)
and
PM arachidonic
acid
by
scattering
is
stable
in
upon
addition
level
in
2 to
data
(11)
these
included
no
the
the light
under
If seen
a base
the
response
1).
a standard
synexin
and
is
scattering (Fig.
in
centrifugution
occurs
increased light
a new
monitored
establishing
immediately to
90°
initiated
polymerization
light
at
from is
microscopy
conveniently
After
intensity
begins
that
conditions.
1).
increases
Electron confirmed
(Figure
be
scattering
polymerization
intensity
minutes. have
the
can
nm)
scattering
monomeric Ca2+.
(350
cell
the
synexin
in when
protein addition
the
Ca2+ is
is
present, of
Ca2+
05 300.00
Position Figure
1:
(secl
Intensity of light scattered from synexin solutions undergoing Ca*+ dependent polymerization. Raw data from fluorometer is plotted as intensity in photons per second versus time ("position") in seconds. At 200 seconds polymerization was initiated by adding 400 IJM Ca2+. Traces 3,4: 1 IJM synexin; traces 1,2: 1 VI4 synexin, 2.2 LIM arachidonic acid; traces 5,6: 2.2 PM arachidonic acid without synexin. 507
3
Vol.
132,
No. 2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
-
125
-5
Figure
2:
Stimulation of Ca2+ dependent synexin polymerization as a function of fatty acid concentration. Polymerization of 1 PM synexin initiated by the addition of 400 UM Ca2+ in the presence of various concentrations of oleic acid (solid line), arachidonic acid (dashed line) or myristic acid (dotted line). Percent stimulation = If-a -Io x 100, 10
where If a = increase in intensity of light scattered by a synexin solution containing added fatty acid, 400 set after the initiation of polymerization by the addition of Ca2+; and 10 = increase in intensity seen with synexin alone. The data points represent the mean + range for duplicate experiments.
(Fig.
indicating
11,
cation
and
the
scattering
fatty
stimulation
concentrations
of
molecules
(Fig.
interaction
not
between
responsible
synexin acid, of
Th is
for
with
small
Table
stimulating
The
one
methyl
Elaidic
necessary acid,
ineffective of
to
the
trans
(Table
1).
the
fatty
fatty
the
the
light
occurs
at
be
an
fatty
acids
ester
of
the
isomer It acid
is that
per
that
perhaps
The
greatest
stimulation
introduced acid
that
oleic
striking are 508
critical
acid
(Table
that
was the for
was
ineffective
a free
acid,
fa ttY
(Fig.
was
interaction
of
the
synexin,
oleic
at
seen
synexin
of
were
low
being
four
indication
suggesting promote
effects
acid
complex.
polymerization, is
initial
oligomers
a-unsaturated 1).
polymerization w ith
may
a nucleation
when
features
fatty
2).
interacts
group
is
ratios
stabilizing
and
acid
of
substoichiometic
seen
a direct
increase.
The
acid
that
1). also
structural promoting
head
2 at
Vol.
132,
No. 2, 1985
BIOCHEMICAL
Table
I.
AND
Stimulation
of by
Fatty
BIOPHYSICAL
RESEARCH
synexin acids
fatty
polymerization
acida
% stimulationb 0 +
IlOne
01 eic methyl
oleic
synexin the
Mean
The synexin (Fig. at
of
two
presence
+
1
of fatty PM synexin. =
range
If.a
acid,
- Io I0
lower
concentrations
Figure
3:
3
free
fatty at
the
all
of
100 in
without
fatty
acid
those
was
required
contact to of
stimulation 90%
at
to by
found
concentrations
Ca2+:
acid.
determinations.
into
percentage
16
rig/ml
increase
to
brought
5
0.65 x
duplicate
similar
membranes of
However,
for
are
polymerization 3).
+
16
polymerization
fusion
20
529
Where If a = intensity presence’of fatty acid. IO = intensity increase C.
2
palmitic
% stimulation
b.
+
321
Concentration pCa 3.4,
3c
96
myristic
elaidic a.
COMMUNICATIONS
nM
synexin
(8).
stimulate Ca2+
was 100
promote
Ca2+;
tested the
greatest 158%
at
Ca2+ dependence of synexin (1 PM) polymerization in the absence (solid line) or presence (dashed line) The intensity scale has of oleic acid (2.3 PM). been normalized so that 100 = increase in light scattered by 1 UM synexin alone 400 set after the The data represent the addition of 400 uM Ca2+. mean + standard deviation for the means from five independent experiments each conducted in duplicate. 509
10 1~
Vol.
132,
No.
2, 1985
M Ca2+;
and
curve
shows
as well is
BIOCHEMICAL
as
490%
at
4 UM Ca2+.
both
an
increase
a shift
reduced
AND
from
to 200
In in
the
the
maximum
so
35
RESEARCH
effect,
the
left
pM to
BIOPHYSICAL
that
COMMUNICATIONS
Ca2+
titration
polymer
the
formation,
apparent
Kd for
Ca2+
PM.
DISCUSSION The
apparent
shift
the
presence
with
the
behavior
of
Ca2’
and
lipids.
For
Ca2+
is
increased
when
this
protein
reported
of
free
is
the
fatty case
of
action sensitivity yet
of
to
be
interact interaction The stimulated
these
two
Ca2+
that
of
of
critical
interaction synexin-dependent presence
of
polymerization
interaction
between
provide chromaf
Ca2+:
When
f in
chromaffin
to
been of
Ca2+
interesting
diacyl
glycerol
of
or
the
Ca2’ general,
proteins
as that
allows
to
occur
in
secretion less
of
fatty
than
free
on
or acids
from 10
fatty off
liM. acid
(Fig. and
a curious
e membrane
fusion are
At may
3).
synexin
Furthermore, for
granules 510
bound
most
that
promote
explanation granul
are
sites.
importance. the
for
some
generally
synexin
albumin
be
expected
availability
serum
in
binding
that
both
a shift
cations
be
with
phospholipase
structure
of
might
physiological may
of
may
the
types
are
the
either
divalent
or
models, Ca2’,
this
and
cells,
cell
Therefore,
of
interact
C has
products
It
analogy
acids
Perhaps
where
in
concentrations
cause
(14).
the
turn
C,
feature
secretory
essentially
be
enzyme
of
low
(13).
phospholipids,
between
of
at
both
lipids
levels
affinity fatty
present
both
permeabilized
that
synexin
interesting
phospholipase
acids,
the
levels
proteins the
kinase
recognized, with
an
activity
fatty
of
provides
addition,
are
on membrane
sensitivity
&-unsaturated
protein
cis-unsaturated
other
example,
greater
acids
acid
some
In
have
Ca 2+
the
fatty
(12). to
if
free
in
may
this feature in
aggregated
of
the by
Vol.
132,
No. 2, 1985
synexin
and
BIOCHEMICAL
then
chemiosmotic fuse,
that
are
not
are
specifically
the
then
possible
synexin the
contact
membrane
structure.
where
study
that
it
lipids
affinity
will
bind
that
it
of fatty a
will
be
competing essential
to
membrane
fusion
is
to
the
dependence
presence
been
used
used
to
of to
answer
unpredictable the will
application be
Ca 2’ fatty
acids
study
membrane
this
question
manner
by
of
sucessful
more in
The
membrane
it fusion
answering
This
study Foundation
was
supported (PCM 8206453).
acid.
if
the
synexin
by
511
enough membrane In
Ca2+ and
fatty
in
assay
synexin
cannot
affected
in It
that
is
hoped approaches
questions.
grant
from
the
has be
an
Em_T a
acids
polymerization
biophysical these
areas
high
fatty
(8).
sophisticated
ACKNOWLEDG
Science
is
on
is
of
by
since
of
determine
turbidity
aggregation
acid,
to
presence
synexin
alone.
fatty
additional
determine by
location
effect
acid
for
fatty
regions
important
the
of
the
important
induced
the
disruptive
“sink”
of
the
in
the
be
these
fatty
even
dependence similar
be for
acid
may
only in
does
binds
two
will
synexin
resulting
in
to
it
break
this
a
leave
membranes
membrane-membrane
have
regions
a-unsaturated
of
synexin
at
if
why
if
do
and
arises,
that
could
break
another,
is
leads
provide it
the
concentrated
First,
the
addition,
be
therefore
investigation.
whether
and, may
system,
region
answer
acid
membrane
of
the
granules
contacts
however,
question
molecules
fatty
Our
The
the
simply
one
COMMUNICATIONS
activating
ATP,
(15);
with
weaken One
of
membrane
this
contact
(8).
by
membranes
forming
to
of
fusion
contact? of
added
RESEARCH
stress
presence
junctions
regions
membrane
the
in
BIOPHYSICAL
osmotic
granule
membrane
acids their
the
involved
firm
acid
in
instead
behind
at
to
swelling
not
fatty
exposed
AND
National
that
Vol. 132, No. 2, 1985
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Creutz, C.E., Pazoles, C.J. and Pollard, H.B. (1978) J. Biol. Chem. 253, 2858-2866. Creutz, C.E., Dowling, L.G., Sando, J.J., Villar-Palasi, C Whipple, J.H. and Zaks, W.J. (1983) J. Biol. Chem. 258, 11;64-14674. Geisow, M.J. and Burgoyne, R.D. (1982) J. Neurochem. 38, 1735-1741. Bader, M.F., Hikita, T. and Trifaro, J.M. (1985) J. Neurochem. 44, 526-539. Sudhof, T.C., Ebbecke, M., Walker, J.H., Fristsche, U. and Boustead, C. (1984) Biochemistry 23, 1103-1109. Creutz, C.E. and Sterner, D.C. (1983) Biochem. Biophys. Comm. 114, 355-364. Res. Creutz, C.E., Pazoles, C.J. and Pollard, H.B. (1979) J. Biol. Chem. 254, 553-558. (1981) J. Cell. Biol. 9l, 247-256. Creutz, C.E. Sudhof, T.C., Walker, J.H. and Obrocki, J. (1982) The EMBO Journal, 1, 1167-1170. Caldwell, P.C. (1970) in Calcium and Cellular Function (Cuthbert, A.W., ed.) pp. 10-16, McMillan, London. Morris, S.J., Hughes, J.M.X. and Whittaker, V.P. (1982) J. Neurochem. 39, 529-536. Aguanno, J.J. and Ladenson, J.H. (1982) J. Biol. Chem. 257, 8745-8748. Takenawa, T. and Yoshitaka N. (1981) J. Biol. Chem. 256, 6769-6775. McPhail, L.C., Clayton, C.C. and Snyderman, R. (1984) Science 224, 622-625. Creutz, C.E., Zaks, W.J., Hamman, H.C. and Martin, W.H. in Cell Fusion (A.E. Sowers, editor) Plenum Publishing Corp. 1986. -in press
512
132,
October
No. 2, 1985 30,
BIOCHEMICAL
BIOPHYSICAL
AND
RESEARCH
COMMUNICATIONS Pages
1985
STIMULATION OF THE Ca*+-DEPENDENT OF SYNEXIN BY =-UNSATURATED DAVID
C.
STERNER,
De,partment
of
Neuroscience,
Received
August
19,
WILLIAM
J.
Pharmacology and Cell University Charlottesville,
505-512
POLYMERIZATION FATTY ACIDS
ZAKS
AND CARL
and Programs and Molecular of Virginia VA 22908
in
E.
CREUTZ
Biophysics, Biology
1985
The influence of fatty acids on the polymerization of synexin was studied by monitoring light scattered from solutions of purified synexin. m-unsaturated fatty acids such as arachidonate or oleate stimulated synexin polymerization at sub-micromolar concentrations, while saturated fatty acids, a trans unsaturated fatty acid or a fatty acid methyl ester had little effect. The olymerization of synexin occurred at lower concentrations of Ca 4+ in the presence of the fatty acids than Therefore, Ca*+ and free fatty in the absence of fatty acids. acids may act as co-regulators of synexin action in stimulated 0 1985 Academic Press, Inc. secretory cells.
In
an
membrane
attempt
have in
have'been
identified
promote membrane
undertaken
the
both
that
close
These
the
case
of
mechanism
by which
follows:
1)
with
Kd -4
Ca2+
then
M (threshold
irreversible
When
uM, binds
to
- 10 membranes contact
to
one
synexin
a site
binds
to
membranes
polymerize form
between
one
to
proteins but
also
another, and
hypothesis
on
bind
two
membrane
to
causes
that
(1)
specific
of
several
least
to
promotes
class
regulate
membranes,
membranes
binds
PM) which
to
At
bind
are
protein
a second
to
(l-5).
proteins
this
synexin
proteins
of
synexin,
Ca2+
soluble
only
attachment
might
exocytosis,
Ca*+
not
that
during of
of
presence
fusion. In
proteins
occurring
been
membranes
different
identify
interactions
studies
(5).
to
and
calelectrin for
the
contacts
is
as
the
synexin
molecule
as
a monomer
(6);
site
Kd - 200
binding
the
synexin
(71,
thus
with
monomers promoting
the
membranes.
A2
Copyright 0 1985 rights of reproducfion
2)
on an Once
the
0006-291X/85 505
u
$1.50
by Academic Press, Inc. in any form reserved.
Vol.
132,
No. 2, 1985
membranes low
BIOCHEMICAL
have
concentrations
might
become
result
of
of
the
from
properties action The like
most
synexin
secretory
cells
necessary
to
may
mediate is
the
we have in
sensitivity
it
of
communication
the
synexin
sought
the we
cells
synexin describe
between
synexin
and
synexin
polymerization,
to
free
the
as a
Interestingly,
same
fusion
quite
mechanism
that
that
in
Ca2+
of
that
if
could
a protein
stimulated appears
polymerization
determine
to
other alter
important that at
appears low
be
reaction. cofactors the
may
Ca2+
reaction.
a potentially
particularly
cell
hypothesis
of
acids
as
polymerization
the
polymerization
fatty
to
(9).
membrane level
stimulated
and
contacts
high
exposed
immunochemically
possess
of
if acids,
(8).
binding
aspect
stimulate
Accordingly, present
Ca2+
membrane
might
fuse
secretory
and
has
COMMUNICATIONS
fatty
phospholipases
physically
troubling
will
a stimulated of
suggest
promoting
they
RESEARCH
a-unsaturated
in
synexin,
that in
free,
is
BIOPHYSICAL
contact,
activation which
distinct
this
available
calelectrin,
be
formed
AND
In
this
interaction to
concentrations
stimulate of
Ca2+.
MATERIALS
AND METHODS
Materials. Synexin was prepared from bovine liver by ammonium sulfate precipitation from a post microsomal supernatant and gel filtration on LKB Ultrogel ACA 34 (1). The synexin was isolated in 0.3 M sucrose, 40 mM MES pH 6.0; immediately before the light 40 mM HEPES was added and the pH scattering experiments, Fatty acids were obtained from Sigma adjusted to 7.3 with NaOH. and stock solutions of 5 mg/ml were prepared in ethanol. Calcium buffers were prepared as 50X stock solutions using CaC12 and EGTA according to the method described by Caldwell (10). In calculating the pCa, a binding constant of 1.897 x lo7 for Ca2+ and EGTA at pH 7.3 was used (10). Light scattering measurements. Intensity of 350 nm light scattered at 90’ was monitored continuously in a Spex 1llC spectroflurometer using a 0.5 cm square cuvette. The following additions were made to the cuvette: 263 ul synexin in 0.3 M surcose, 40 mM MES, 40 mM HEPES, pH 7.3; 66 nl 0.15 M kC1; 4.5 ~1 ethanol containing various concentrations of fatty acid (also included in controls without fatty acid). After recording baseline light scattering for 200 set, synexin polymerization was initiated by adding 6 ~1 506
Vol.
132,
No.
of Ca2+ various monitored
BIOCHEMICAL
2. 1985
AND
BIOPHYSICAL
RESEARCH
buffer to give a final EGTA concentration amounts of CaC12. Polymerization was for 400 sec.
COMMUNtCATtONS
of 2.5 subsequently
mM and
RESULTS The by
polymerization
measurement
of
of
light
spectroflourometer line
for
light
form,
of
Polymerization
scattering
If
reaction added no
2.2
mixture, is
greatly
increase
in
0.75E
the
(7)
and
PM arachidonic
acid
by
scattering
is
stable
in
upon
addition
level
in
2 to
data
(11)
these
included
no
the
the light
under
If seen
a base
the
response
1).
a standard
synexin
and
is
scattering (Fig.
in
centrifugution
occurs
increased light
a new
monitored
establishing
immediately to
90°
initiated
polymerization
light
at
from is
microscopy
conveniently
After
intensity
begins
that
conditions.
1).
increases
Electron confirmed
(Figure
be
scattering
polymerization
intensity
minutes. have
the
can
nm)
scattering
monomeric Ca2+.
(350
cell
the
synexin
in when
protein addition
the
Ca2+ is
is
present, of
Ca2+
05 300.00
Position Figure
1:
(secl
Intensity of light scattered from synexin solutions undergoing Ca*+ dependent polymerization. Raw data from fluorometer is plotted as intensity in photons per second versus time ("position") in seconds. At 200 seconds polymerization was initiated by adding 400 IJM Ca2+. Traces 3,4: 1 IJM synexin; traces 1,2: 1 VI4 synexin, 2.2 LIM arachidonic acid; traces 5,6: 2.2 PM arachidonic acid without synexin. 507
3
Vol.
132,
No. 2, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
-
125
-5
Figure
2:
Stimulation of Ca2+ dependent synexin polymerization as a function of fatty acid concentration. Polymerization of 1 PM synexin initiated by the addition of 400 UM Ca2+ in the presence of various concentrations of oleic acid (solid line), arachidonic acid (dashed line) or myristic acid (dotted line). Percent stimulation = If-a -Io x 100, 10
where If a = increase in intensity of light scattered by a synexin solution containing added fatty acid, 400 set after the initiation of polymerization by the addition of Ca2+; and 10 = increase in intensity seen with synexin alone. The data points represent the mean + range for duplicate experiments.
(Fig.
indicating
11,
cation
and
the
scattering
fatty
stimulation
concentrations
of
molecules
(Fig.
interaction
not
between
responsible
synexin acid, of
Th is
for
with
small
Table
stimulating
The
one
methyl
Elaidic
necessary acid,
ineffective of
to
the
trans
(Table
1).
the
fatty
fatty
the
the
light
occurs
at
be
an
fatty
acids
ester
of
the
isomer It acid
is that
per
that
perhaps
The
greatest
stimulation
introduced acid
that
oleic
striking are 508
critical
acid
(Table
that
was the for
was
ineffective
a free
acid,
fa ttY
(Fig.
was
interaction
of
the
synexin,
oleic
at
seen
synexin
of
were
low
being
four
indication
suggesting promote
effects
acid
complex.
polymerization, is
initial
oligomers
a-unsaturated 1).
polymerization w ith
may
a nucleation
when
features
fatty
2).
interacts
group
is
ratios
stabilizing
and
acid
of
substoichiometic
seen
a direct
increase.
The
acid
that
1). also
structural promoting
head
2 at
Vol.
132,
No. 2, 1985
BIOCHEMICAL
Table
I.
AND
Stimulation
of by
Fatty
BIOPHYSICAL
RESEARCH
synexin acids
fatty
polymerization
acida
% stimulationb 0 +
IlOne
01 eic methyl
oleic
synexin the
Mean
The synexin (Fig. at
of
two
presence
+
1
of fatty PM synexin. =
range
If.a
acid,
- Io I0
lower
concentrations
Figure
3:
3
free
fatty at
the
all
of
100 in
without
fatty
acid
those
was
required
contact to of
stimulation 90%
at
to by
found
concentrations
Ca2+:
acid.
determinations.
into
percentage
16
rig/ml
increase
to
brought
5
0.65 x
duplicate
similar
membranes of
However,
for
are
polymerization 3).
+
16
polymerization
fusion
20
529
Where If a = intensity presence’of fatty acid. IO = intensity increase C.
2
palmitic
% stimulation
b.
+
321
Concentration pCa 3.4,
3c
96
myristic
elaidic a.
COMMUNICATIONS
nM
synexin
(8).
stimulate Ca2+
was 100
promote
Ca2+;
tested the
greatest 158%
at
Ca2+ dependence of synexin (1 PM) polymerization in the absence (solid line) or presence (dashed line) The intensity scale has of oleic acid (2.3 PM). been normalized so that 100 = increase in light scattered by 1 UM synexin alone 400 set after the The data represent the addition of 400 uM Ca2+. mean + standard deviation for the means from five independent experiments each conducted in duplicate. 509
10 1~
Vol.
132,
No.
2, 1985
M Ca2+;
and
curve
shows
as well is
BIOCHEMICAL
as
490%
at
4 UM Ca2+.
both
an
increase
a shift
reduced
AND
from
to 200
In in
the
the
maximum
so
35
RESEARCH
effect,
the
left
pM to
BIOPHYSICAL
that
COMMUNICATIONS
Ca2+
titration
polymer
the
formation,
apparent
Kd for
Ca2+
PM.
DISCUSSION The
apparent
shift
the
presence
with
the
behavior
of
Ca2’
and
lipids.
For
Ca2+
is
increased
when
this
protein
reported
of
free
is
the
fatty case
of
action sensitivity yet
of
to
be
interact interaction The stimulated
these
two
Ca2+
that
of
of
critical
interaction synexin-dependent presence
of
polymerization
interaction
between
provide chromaf
Ca2+:
When
f in
chromaffin
to
been of
Ca2+
interesting
diacyl
glycerol
of
or
the
Ca2’ general,
proteins
as that
allows
to
occur
in
secretion less
of
fatty
than
free
on
or acids
from 10
fatty off
liM. acid
(Fig. and
a curious
e membrane
fusion are
At may
3).
synexin
Furthermore, for
granules 510
bound
most
that
promote
explanation granul
are
sites.
importance. the
for
some
generally
synexin
albumin
be
expected
availability
serum
in
binding
that
both
a shift
cations
be
with
phospholipase
structure
of
might
physiological may
of
may
the
types
are
the
either
divalent
or
models, Ca2’,
this
and
cells,
cell
Therefore,
of
interact
C has
products
It
analogy
acids
Perhaps
where
in
concentrations
cause
(14).
the
turn
C,
feature
secretory
essentially
be
enzyme
of
low
(13).
phospholipids,
between
of
at
both
lipids
levels
affinity fatty
present
both
permeabilized
that
synexin
interesting
phospholipase
acids,
the
levels
proteins the
kinase
recognized, with
an
activity
fatty
of
provides
addition,
are
on membrane
sensitivity
&-unsaturated
protein
cis-unsaturated
other
example,
greater
acids
acid
some
In
have
Ca 2+
the
fatty
(12). to
if
free
in
may
this feature in
aggregated
of
the by
Vol.
132,
No. 2, 1985
synexin
and
BIOCHEMICAL
then
chemiosmotic fuse,
that
are
not
are
specifically
the
then
possible
synexin the
contact
membrane
structure.
where
study
that
it
lipids
affinity
will
bind
that
it
of fatty a
will
be
competing essential
to
membrane
fusion
is
to
the
dependence
presence
been
used
used
to
of to
answer
unpredictable the will
application be
Ca 2’ fatty
acids
study
membrane
this
question
manner
by
of
sucessful
more in
The
membrane
it fusion
answering
This
study Foundation
was
supported (PCM 8206453).
acid.
if
the
synexin
by
511
enough membrane In
Ca2+ and
fatty
in
assay
synexin
cannot
affected
in It
that
is
hoped approaches
questions.
grant
from
the
has be
an
Em_T a
acids
polymerization
biophysical these
areas
high
fatty
(8).
sophisticated
ACKNOWLEDG
Science
is
on
is
of
by
since
of
determine
turbidity
aggregation
acid,
to
presence
synexin
alone.
fatty
additional
determine by
location
effect
acid
for
fatty
regions
important
the
of
the
important
induced
the
disruptive
“sink”
of
the
in
the
be
these
fatty
even
dependence similar
be for
acid
may
only in
does
binds
two
will
synexin
resulting
in
to
it
break
this
a
leave
membranes
membrane-membrane
have
regions
a-unsaturated
of
synexin
at
if
why
if
do
and
arises,
that
could
break
another,
is
leads
provide it
the
concentrated
First,
the
addition,
be
therefore
investigation.
whether
and, may
system,
region
answer
acid
membrane
of
the
granules
contacts
however,
question
molecules
fatty
Our
The
the
simply
one
COMMUNICATIONS
activating
ATP,
(15);
with
weaken One
of
membrane
this
contact
(8).
by
membranes
forming
to
of
fusion
contact? of
added
RESEARCH
stress
presence
junctions
regions
membrane
the
in
BIOPHYSICAL
osmotic
granule
membrane
acids their
the
involved
firm
acid
in
instead
behind
at
to
swelling
not
fatty
exposed
AND
National
that
Vol. 132, No. 2, 1985
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Creutz, C.E., Pazoles, C.J. and Pollard, H.B. (1978) J. Biol. Chem. 253, 2858-2866. Creutz, C.E., Dowling, L.G., Sando, J.J., Villar-Palasi, C Whipple, J.H. and Zaks, W.J. (1983) J. Biol. Chem. 258, 11;64-14674. Geisow, M.J. and Burgoyne, R.D. (1982) J. Neurochem. 38, 1735-1741. Bader, M.F., Hikita, T. and Trifaro, J.M. (1985) J. Neurochem. 44, 526-539. Sudhof, T.C., Ebbecke, M., Walker, J.H., Fristsche, U. and Boustead, C. (1984) Biochemistry 23, 1103-1109. Creutz, C.E. and Sterner, D.C. (1983) Biochem. Biophys. Comm. 114, 355-364. Res. Creutz, C.E., Pazoles, C.J. and Pollard, H.B. (1979) J. Biol. Chem. 254, 553-558. (1981) J. Cell. Biol. 9l, 247-256. Creutz, C.E. Sudhof, T.C., Walker, J.H. and Obrocki, J. (1982) The EMBO Journal, 1, 1167-1170. Caldwell, P.C. (1970) in Calcium and Cellular Function (Cuthbert, A.W., ed.) pp. 10-16, McMillan, London. Morris, S.J., Hughes, J.M.X. and Whittaker, V.P. (1982) J. Neurochem. 39, 529-536. Aguanno, J.J. and Ladenson, J.H. (1982) J. Biol. Chem. 257, 8745-8748. Takenawa, T. and Yoshitaka N. (1981) J. Biol. Chem. 256, 6769-6775. McPhail, L.C., Clayton, C.C. and Snyderman, R. (1984) Science 224, 622-625. Creutz, C.E., Zaks, W.J., Hamman, H.C. and Martin, W.H. in Cell Fusion (A.E. Sowers, editor) Plenum Publishing Corp. 1986. -in press
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