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Activation of rat lung particulate guanylate cyclase due to filipin induced fluidity change
Vol.
96, No.
1, 1980
September
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Pages 203-210
16, 1980
ACTIVATION OF RAT LUNG PARTICULATE GUANYLATE CYCLASE DUE TO FILIPIN INDUCED FLUIDITY CHANGE Pushkaraj John M. Dalton
Received
July
J.
Lad*
Research Center, University of Missouri-Columbia, Columbia, Missouri 65211 U.S.A.
25,198O
SUMMARY: Involvement of cholesterol in the regulation of rat lung particulate guanylate cyclase was studied with filipin. The enzyme was not activated to a great extent by sodium nitroprusside alone; however, in presence of filipin nitroprusside activated the enzyme about 12-16 fold over the basal. Filipin did not affect the soluble enzyme significantly. The changes induced by filipin did not cause solubilization of proteins or enzyme. The Arrhenius plot of filipin-treated particulate enzyme did not have a "break" which was evident with untreated enzyme. The results suggest that the sequestering of cholesterol by filipin can modulate the activity of membrane-associated guanylate cyclase probably by changing the membrane fluidity. INTRODUCTION Guanylate found
in particulate
mammalian soluble
and soluble
tissues.
Lubrol
activity
of the particulate Phospholipid
alamethicin investigation, guanylate
perturbing
other
polyenes,
bilayers
to ions,
membrane
cholesterol
Present
address:
in its
increases
guanylate
the
of the
in the presence X-100
to study
gramicidin cyclase
of cholesterol
hydrophilic
of most
from
Because
is
the
latent of or
regula-
surroundings.
, melittin
the permeability
differs
such as Triton
difficult
native
by utilizing
and small
assayed
detergents
involvement
was examined
lung (1,2).
usually
make it
the particulate
water
is
EC 4.6.1.21
from homogenates
properties
polypeptides
the possible cyclase
it
detergents
enzyme
stimulate
prepared
of nonionic
However,
(cyclizing),
enzyme from rat
and kinetic
concentrations
PX (2,3).
lyase
fractions
The particulate
of the particulate
solubilizing
like
[GTP pyrophosphate
enzyme in physical
nature
tion
cyclase
an antibiotic,
S and
(4,s).
In the present
in the regulation filipin.
of Filipin,
of cholesterol-containing molecules
by interacting
with
(6-8). The Salk
Institute,
P. 0. Box 85800,
San Diego,
CA 92138.
0006-291X/80/170203-08$01.00/0 203
Copyright 0 1980 by Academic Press, Inc. AN rights of reproduction in any form reserved.
Vol.
96, No.
BIOCHEMICAL
1, 1980
AND
MATERIALS
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
AND METHODS
Filipin (Lot #3-1194) was purchased from Polysciences, Inc. GTP and nystatin were purchased from P. L. Biochemicals, and [a-32PlGTP and 13H]cGMP were obtained from New England Nuclear. Cyclic GMP, creatine phosphate, amphotericin B and other unspecified biochemicals were creatine phosphokinase, from Sigma. Bio-Gel A-5m was obtained from Bio-Rad. Male rats weighing in the range of loo-150 g were Enzyme Preparation. decapitated and lungs were perfused in situ with 10 ml of homogenizing buffer (50 mM Tris-HCl, 0.5 mM Na2 EDTA, 10 mM Z-mercaptoethanol, pH 7.6) by injecting it in the right ventricle. The lungs were removed and washed twice, blotted, placed in 3 volumes homogenizing buffer (w/v> and homogenized for 10 set at The 10,000 rev/min with a Willems Polytron equipped with a PT 20 ST generator. homogenate was filtered through a 40-mesh stainless steel wire screen and centrifuged for 10 min at 8000 xg, after which the supernatant solution was The supernatant was used as soluble centrifuged at 160,900 xg for 40 min. enzyme. The pellet (microsomes) was resuspended in 1 ml buffer and chromatoThe column was eluted with graphed on a Bio-Gel A-5m column (1.6 X 15 cm). 50 mM Tris-HCl, pH 7.6 buffer containing 10 mM 2-mercaptoethanol. The void volume fractions were pooled and used as the particulate enzyme.
Assays and Biochemical Determinations. Guanylate cyclase assays were performed by determining the conversion [cr-32P]GTP to [c~-~~P]cGMP. The assay mix contained 1.2 mM GTP, 6 mM MnC12, 5 mM cGMP, 50 mM Tris-HCl, 15 mM Enz e activity creatine phosphate and 10 units of creatine phosphokinase (9). was assayed for 5 or 6 min at 37°C with lo-30 pg protein. The [a-3 TP]cGMP formed was separated from substrate by sequential chromatography on Dowex 50 and neutral aluminum oxide according to White and Karr (10). Proteins were determined by the method of Lowry --et al. (11) after precipitation with silicotungstic acid (12). Bovine serum albumin was used as the standard. Cholesterol was quantitated by the method of Zlatkis and Zak (13). Specific activities are expressed as picomoles cGMP formedlminfmg protein. All assays were in triplicate, and the activities are given as the mean 2 standard error of the mean. Data presented here are representative of at least 2 or 3 experiments.
RESULTS Rat lung cyclase.
homogenate
A vasodilator,
cyclase
20-25
fold
(5).
2-4
fold,
fold
and the optimum
with
higher
concentrations
than
that
nitroprusside
achieved plus
was greater
filipin than
the particulate 1, fillipin
activity
appeared
was about
the activity
activated
observed
204
mg/ml
A decrease
activated
synergistically
soluble
with
guanylate
activated
only
the particulate
at 0.2-0.4
However,
PX, which
guanylate
enzyme is activated
one.
of filipin. Lubrol
and particulate activates
in Fig.
ratio
with
soluble
nitroprusside,
however,
As illustrated
to filipin
both
sodium
(14);
cholesterol
which
contain
enzyme
filipin
where
in activity
was less fold.
the enzyme about Lubrol
PX.
the
was seen
the maximum activity the enzyme 7-9
2-3
Sodium 24-fold,
Vol.
96, No.
1, 1980
BIOCHEMICAL
FILlPIN
BIOPHYSICAL
CONCENTRATION
filipin on particulate tubes containing various at 37"C, then guanylate
for 6 min at 37°C with
( 0 ) and without
in
Filipin soluble
soluble
medium
enzyme activators activate
soluble
like
organic
the particulate
enzyme Km (with
with
disrupted
or without
nitroprusside
205
about
with
Other
hypo-
soluble
and arachidonic
enzyme treated
PX but
or
and column
shown).
0.2 mM, which
(not
contaminating
vesicles (not
the basal
by nitroprusside
lipoxygenase
the particulate
or without
and
assayed
cGMP formed/min/mg
by solubilization
peroxides,
Lubrol
was
not activate
not express
sensitive
with
picomoles
did
membrane
GTP of about
Enzyme
of filipin
activity
activation
enzyme treated
had a Km for enzyme treated
cyclase
its
was evident
nitroprusside
cyclase.
concentrations 1127.1
did
Furthermore,
GTP was determined,
nitroprusside particulate
This
guanylate
- 0.5 mg/ml
treatment
COMMUNICATIONS
( 0 ) 1 mM sodium nitroprusside.
PX was
or potentiated
studies. remained
Lubrol
of 0.001
filipin
enzyme.
chromatography
Km for
0.9%
cyclase
In addition
trapped
of
in the range
guanylate
shown).
tonic
presence
RESEARCH
(mg/ml)
Fig. 1. The effect of aliquots were added to preincubated for 5 min Activity protein.
not
AND
filipin. with
treatment).
higher
did
When the
filipin
was identical 4 times
acid
plus to the than
the
Vol.
96, No.
BIOCHEMICAL
1, 1980
AND
I. Effects of filipin rat lung particulate
Table
BIOPHYSICAL
RESEARCH
and detergents on the guanylate cyclase Guanylate
Treatment
- SNP
105.0 385.0 836.8 737.0 302.3
None
Tween 20 Triton X-100 Lubrol PX Filipin
4.0 4.0 1.2 0.4
Particulate and
fraction
assayed
for
sodium nitroprusside
Treatment activators zation did
(Table
I>.
of filipin
filipin
were
activity was found observations cyclase
activity.
filipin
treatment suggest Effect
preparation
that
volume. where filipin
was activated filipin
of temperature treated
there that
with
caused
the
filipin
speed
by sodium
was no significant
non-sedimentable preparations
did
nearly
amount
not
solubilize
cyclase
all
with
of the and enzyme
eluted. guanylate
rechromatographed better
These
than
after Lubrol
PX
change.
cyclase
206
used
treated
of protein
is normally
nitroprusside
(microsomes
centrifugation was no significant
enzyme
an irreversible
of protein
and there
a trace
guanylate
detergents
majority
the particulate
soluble
treatment
on guanylate
done,
A-5m column,
Only
in solubili-
guanylate
When microsomes
on a Bio-Gel
The particulate
that
Also
II),
enzyme contamination.
fractions
support
8.6 7.7 a.6 a.9 22.5
known
to filipin,
upon high
(Table
its
results
were
the pellet
suggesting
in the void
in the
2 i + 2 +
or 1 ti
with
of the particulate
fraction
chromatographed
preparation
studies
into
particulate
soluble
eluted
detergents and without
with
In contrast
activation
in control,
from
various
activity
(15).
enzyme activity.
enzyme activity free
activity
sedimented
non-sedimentable
with
413.6 408.3 859.8 714.4 1684.2
and lysolecithin
When solubilization
treated
2 1.6 + 9.8 t 2.6 f 12.5 2 10.3
cyclase
detergents
nitroprusside
and enzyme activity
which
guanylate
cyclase
not potentiate
cyclase
+ SNP
(SNP).
of particulate
of guanylate
were
(30 ug) was treated guanylate
such as non-ionic
cyclase
Cyclase Activity
Concentration bg/ml)
filipin
COMMUNICATIONS
activity
chromatographed
in particulate on Bio-Gel
A-5m
Vol.
96, No.
BIOCHEMICAL
1, 1980
Table
II.
AND
Solubilization
of by
BIOPHYSICAL
particulate
A.
Activity
Water
Protein
guanylate
COMMUNICATIONS
cyclase
filipin Enzyme
Fractions
RESEARCH
1.0% SA
in
Lubrol
Presence
of
PX
TA
1 mM SNP
SA
TA
SA
(4
TA
Original
1.96
260
132?
6
2239
1137
+ 15
1046
Pellet
2.6
196
752
1
2234
898
t 26
627
Supernatant
0.1
22
204
_+ 60
312 + 20
45
428
+ 12
2222
996 + 13
2449
1098
2161
795 2 29
1405
517
2 13
920
+ 76
CONTROL
B. FILIPIN
33
531
2 13
2412
4 ? 56
TREATED
Original
2.23
465
208
Pellet
2.7
339
125 t
Supernatant
0.1
15
8
140 ? 64
16
152 + 80
98
?
2
About 1.8 ml of a particulate enzyme preparation was mixed with 0.2 ml buffer (control) of 5 mg/ml filipin (filipin treated). About 0.25 ml from each tube was removed (original) and assayed, remaining suspensions were centrifuged at 139,000 xg for 60 min. Pellets and supernatants were also assayed for guanylate cyclase activity in presence of various treatments. TA = total activity, picomoles cGMP formed/min in each fraction, SA = specific
activity,
column
picomoles
after
filipin
without
filipin
control
enzyme
for
studies activates
membrane been
showed
with
lung
Kimelberg
In membranes, average
area
phospholipid at 37"C,
the
and Paphadjopoulos the effects
above
the transition
per molecule
and reduced
bilayer
(19-20).
membrane
matrix
The Arrhenius but
guanylate
The activity upon
During is
chromatographed plot
such a break
of the
was not
evident
filipin.
The Arrhenius
to describe
"viscotropic,"
2.
22-25"C,
particulate
changes.
(microsomes
DISCUSSION that the cholesterol
demonstrate
by nitroprusside. fluidity
shown in Fig.
treated
shown to be dependent
(16-18).
ation
is
around
rat
protein.
and untreated
a break
enzyme
These
activation
treatment)
treatment)
particulate
filipin,
cGMP formedlminlmg
plots of several
fluidity
binding cyclase
and potentiates
suggest
that
membrane
have introduced
of membrane
fluidity
temperature, the motion guanylate
in a liquid
207
filipin bound
of the phospholipid
(18)
the
antibiotic,
the
enzymes
has
term
on enzyme activity.
of hydrocarbon
crystalline
causes
environment
cholesterol
cyclase
its
condenses chains
activity state
thus
the
of determinfilipin
Vol.
96, No.
1. 1980
BIOCHEMICAL
Fig. 2. The effect Microsomal preparation were chromatographed for 2 min at various lines were determined
probably
increases
supported
by spin
label
fluidity
studies
by sequestering
which
in the
hydrophobic
core
However,
another
polyene
amphotericin
did
not activate
interacts
with
in nature,
(not
of an aminosugar
altered
"break"
other attached
alter
COMMUNICATIONS
fluidity
in Arrhenius
B did
not affect
cyclase for
to the macrolide of membranes of rat
208
ring
polyenes
amphoteric
and nystatin its
activation
that
filipin
and is neutral
properties
because
(22-23).
of various lung
is
(21).
(21).
B, candicidin
thanother
used possess
membrane
or potentiated
is
increased
fluidity
the difference
more effectively
This
filipin
containing
amphotericin
A reason
plot
that
of a cholesterol
studied,
polyenes
cholesterol.
demonstrated
guanylate
shown).
cholesterol
whereas
Alcohols
polyenes
particulate
by nitroprusside
RESEARCH
temperature on the particulate guanylate cyclase. treated with 0.3 mg/ml filipin ( 0 ) and buffer ( 0 ) on Bio-Gel A-5m column. The enzymes were preincubated temperatures and activity was assayed for 4 min. The by the method of least squares.
membrane
other
BIOPHYSICAL
of
fluidity
Interestingly,
AND
particulate
origin
(24-25). guanylate
Ethanol cyclase,
Vol.
96, No.
1, 1980
however, (Lad,
it
did
P. J.,
mechanisms induces
BIOCHEMICAL
not potentiate
paper
disorganization site
cyclase
is
submitted enzyme
hydrophobic It
site(s)
[26]).
This
altered
membrane
fluidity
changes
bound with
adrenergic cytochrome
postulated
that
a conformational
freedom
that
fluidity. is
receptor
in adenylate
(28,29).
the rate-limiting
of guanylate
cyclase
A conformational
change step
in the enzyme
in lipid for
fluidity
A. A.,
paper particulate complex
by detergent cyclase
molecules
activity
change
activation
by
due to
by catecholaminehas been observed
(30).
an enzyme-catalyzed
It
has been reaction
can be
(31).
ACKNOWLEDGEMENT This work was supported in part by a USPHS Grant I-IL 15002, from the National Institutes of Health, and by the John M. Dalton Research Center. I am grateful to Dr. Arnold A. White, in whose laboratory this work was done, for his generous support, advice and criticism. REFERENCES 1.
Chrisman,
T. D.,
Garbers,
J. BioZ. Chem. 250, 2. 3.
5. 6.
Parks,
M. A.,
and Hardman,
J.
G. (1975)
274-381.
White, A. A. (1975) Advances in CycZic NucZeotide Research (Drummond, G. I., Greengard, P., and Robison, G. A., eds.) Vol. 5, pp. 353-373, Raven Press, New York. Ishikawa, E., Ishikawa, S., Davis, J. W., and Sutherland, E. W. (1969)
J. BioZ. Chem. 244, 4.
D. L.,
6371-6376.
Lad, P. J., and Shier, W. T. (1978) Biochem. Biophys. Res. Conunun.89, 315-321. Lad, P. J., and White, A. A. (1979) Biochim. Biophys. Acta 570, 198-209. Babock, D. F., First, N. L., and Lardy, H. A. (1975) J. BioZ. Chem. 250,
6488-6495.
209
(27).
results
induced
of motion)
change
of
guanylate
solubilized
(freedom
in turn
Possibility
solubilized
in
occupied
diffusion
cyclase,
of soluble
or a conformational
Increased
bb due to the
change
are
cholesterol
interacts.
because
modulation
implicated
guanylate
why detergent
proteins
of motion
around
M. A. and White,
explain
of membrane
by nitroprusside
by sequestering
activation
Liebel,
COMMUNICATIONS
may be due to independent
metabolite
by nitroprusside,
possible
an increased
P. J.,
activation
filipin
chains
or its
may also
activated
also
that
acyl
RESEARCH
difference
in nitroprusside (Lad,
regions is
probable
nitroprusside
suggested
is not
is
cyclase
This
of fatty
where
such hydrophobic
from
It
BIOPHYSICAL
guanylate
in preparation).
of action.
exposing
AND
Vol.
7.
8. 9. 10. 11.
96, No.
1, 1980
De Kruijff, Demel, R. 44-56. Norman, A. (1972) J. White, A.
BIOCHEMICAL
B., A.,
AND
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RESEARCH
COMMUNICATIONS
Gerritsen, W. J., Oerlemans. A., Van Dijck, P. W. M., and Van Deenen, L. L. M. (1974) Biochim. Biophys. Acta 339,
W., Demel, R. A., De Kruijff, B., and Van Deenen, L. L. M. BioZ. them. 247, 1918-1929, A., Crawford, K. M., Patt, C. S., and Lad, P. J. (1976) J. BioZ. Chem. 251, 7304-7312. White, A. A. and Karr, D. B. (1978) Anal. Biochem. 85, 451-460. N. H., Farr, A. L., and Randall, R. J. (1951) Lowry, 0. II., Rosebrough,
J. BioZ. Chem. 193, 265-275. 12. 13. 14. 15. 16.
White, A. A., Northup, S. J., and Zenser, T. V. (1972) in Methods in CycZic Nucleotide Research (Chasin, M., ed.) pp. 125-167, Marcel1 Dekker, New York. Zlatkis, A., and Zak, B. (1969) Anal. Bioch-em. 29, 143-148. Liebel, M. A., Lad, P. J., and White, A. A. (1978) Fed. Proc. 37, 1537. Lad, P. J., and White, A. A. (1979) Arch. Biochem. Biophys. 197, 244-252. Engelhard, V. Ii., Esko, J. D., Strom, D. R., and Glaser, M. (1976)
17. 18.
Proc. NatZ. Acad. Sci. USA 73, 4482-4486. Dipple, I., and Houslay, M. D. (1978) Biochem. J. 174, 179-190. Kimelberg, H. K., and Papahadjopoulos, D. (1972) Biochim. Biophys. Acta
19. 20. 21.
282, 277-292. Rothman, J. E., and Engelman, D. M. (1972) Nature New Biol. 237, 42-44. Oldfield, E., and Chapman, D. (1972) FEBSLetts. 23, 285-297. Oski, K., Kozawa, Y., and Ohnishi, S. (1979) Biochim. Biophys. Acta 554,
39-50. 22. 23. 24. 25. 26. 27. 28.
Norman, A. W., Demel, R. A., De Kruyff, B., Geurts Van Kessel, W. S. M., and Van Deenen, L. L. M. (1972) Biochim. Biophys. Acta 290, 1-14. De Kruijff, B., Gerritsen, W. J., Oerlemans, A., Demel, R. A., and Van Deenen, L. L. M. (1974) Biochim. Biophys. Acta 339, 30-43. Chin, J. H., and Golstein, D. B. (1977) Mol. Phurmacok 13, 435-441. Johnson, D. A., Lee, N. M., Cooke, G., and Loh, M. M. (1979) MOT. Phannacok 15, 739-746. Struck, G. J., and Glossman, H. (1978) Naunyn-S&niedeberg's Arch. Phurmaco2. 304, 51-61. Helenius, A., and Simons, K. (1975) Biochim. Biophys. Acta 415, 29-79. Rimon, G., Hanski, E., Braun, S., and Levitzki, A. (1978) Nature 276,
394-396. 29. 30. 31.
Hanski, E., Rimon, G., and Levitzki, A. (1979) Biochemistry 18, 846-853. Dufoureq, J., Faucon, J. F., Lussan, D., and Bernon, R. (1975) FEBSLetts. 57, 112-116. Jencks, W. P. (1969) CataZysis in Chemistry and EnzymoZogy, pp. 308-312, McGraw-Hill, New York.
210
96, No.
1, 1980
September
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Pages 203-210
16, 1980
ACTIVATION OF RAT LUNG PARTICULATE GUANYLATE CYCLASE DUE TO FILIPIN INDUCED FLUIDITY CHANGE Pushkaraj John M. Dalton
Received
July
J.
Lad*
Research Center, University of Missouri-Columbia, Columbia, Missouri 65211 U.S.A.
25,198O
SUMMARY: Involvement of cholesterol in the regulation of rat lung particulate guanylate cyclase was studied with filipin. The enzyme was not activated to a great extent by sodium nitroprusside alone; however, in presence of filipin nitroprusside activated the enzyme about 12-16 fold over the basal. Filipin did not affect the soluble enzyme significantly. The changes induced by filipin did not cause solubilization of proteins or enzyme. The Arrhenius plot of filipin-treated particulate enzyme did not have a "break" which was evident with untreated enzyme. The results suggest that the sequestering of cholesterol by filipin can modulate the activity of membrane-associated guanylate cyclase probably by changing the membrane fluidity. INTRODUCTION Guanylate found
in particulate
mammalian soluble
and soluble
tissues.
Lubrol
activity
of the particulate Phospholipid
alamethicin investigation, guanylate
perturbing
other
polyenes,
bilayers
to ions,
membrane
cholesterol
Present
address:
in its
increases
guanylate
the
of the
in the presence X-100
to study
gramicidin cyclase
of cholesterol
hydrophilic
of most
from
Because
is
the
latent of or
regula-
surroundings.
, melittin
the permeability
differs
such as Triton
difficult
native
by utilizing
and small
assayed
detergents
involvement
was examined
lung (1,2).
usually
make it
the particulate
water
is
EC 4.6.1.21
from homogenates
properties
polypeptides
the possible cyclase
it
detergents
enzyme
stimulate
prepared
of nonionic
However,
(cyclizing),
enzyme from rat
and kinetic
concentrations
PX (2,3).
lyase
fractions
The particulate
of the particulate
solubilizing
like
[GTP pyrophosphate
enzyme in physical
nature
tion
cyclase
an antibiotic,
S and
(4,s).
In the present
in the regulation filipin.
of Filipin,
of cholesterol-containing molecules
by interacting
with
(6-8). The Salk
Institute,
P. 0. Box 85800,
San Diego,
CA 92138.
0006-291X/80/170203-08$01.00/0 203
Copyright 0 1980 by Academic Press, Inc. AN rights of reproduction in any form reserved.
Vol.
96, No.
BIOCHEMICAL
1, 1980
AND
MATERIALS
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
AND METHODS
Filipin (Lot #3-1194) was purchased from Polysciences, Inc. GTP and nystatin were purchased from P. L. Biochemicals, and [a-32PlGTP and 13H]cGMP were obtained from New England Nuclear. Cyclic GMP, creatine phosphate, amphotericin B and other unspecified biochemicals were creatine phosphokinase, from Sigma. Bio-Gel A-5m was obtained from Bio-Rad. Male rats weighing in the range of loo-150 g were Enzyme Preparation. decapitated and lungs were perfused in situ with 10 ml of homogenizing buffer (50 mM Tris-HCl, 0.5 mM Na2 EDTA, 10 mM Z-mercaptoethanol, pH 7.6) by injecting it in the right ventricle. The lungs were removed and washed twice, blotted, placed in 3 volumes homogenizing buffer (w/v> and homogenized for 10 set at The 10,000 rev/min with a Willems Polytron equipped with a PT 20 ST generator. homogenate was filtered through a 40-mesh stainless steel wire screen and centrifuged for 10 min at 8000 xg, after which the supernatant solution was The supernatant was used as soluble centrifuged at 160,900 xg for 40 min. enzyme. The pellet (microsomes) was resuspended in 1 ml buffer and chromatoThe column was eluted with graphed on a Bio-Gel A-5m column (1.6 X 15 cm). 50 mM Tris-HCl, pH 7.6 buffer containing 10 mM 2-mercaptoethanol. The void volume fractions were pooled and used as the particulate enzyme.
Assays and Biochemical Determinations. Guanylate cyclase assays were performed by determining the conversion [cr-32P]GTP to [c~-~~P]cGMP. The assay mix contained 1.2 mM GTP, 6 mM MnC12, 5 mM cGMP, 50 mM Tris-HCl, 15 mM Enz e activity creatine phosphate and 10 units of creatine phosphokinase (9). was assayed for 5 or 6 min at 37°C with lo-30 pg protein. The [a-3 TP]cGMP formed was separated from substrate by sequential chromatography on Dowex 50 and neutral aluminum oxide according to White and Karr (10). Proteins were determined by the method of Lowry --et al. (11) after precipitation with silicotungstic acid (12). Bovine serum albumin was used as the standard. Cholesterol was quantitated by the method of Zlatkis and Zak (13). Specific activities are expressed as picomoles cGMP formedlminfmg protein. All assays were in triplicate, and the activities are given as the mean 2 standard error of the mean. Data presented here are representative of at least 2 or 3 experiments.
RESULTS Rat lung cyclase.
homogenate
A vasodilator,
cyclase
20-25
fold
(5).
2-4
fold,
fold
and the optimum
with
higher
concentrations
than
that
nitroprusside
achieved plus
was greater
filipin than
the particulate 1, fillipin
activity
appeared
was about
the activity
activated
observed
204
mg/ml
A decrease
activated
synergistically
soluble
with
guanylate
activated
only
the particulate
at 0.2-0.4
However,
PX, which
guanylate
enzyme is activated
one.
of filipin. Lubrol
and particulate activates
in Fig.
ratio
with
soluble
nitroprusside,
however,
As illustrated
to filipin
both
sodium
(14);
cholesterol
which
contain
enzyme
filipin
where
in activity
was less fold.
the enzyme about Lubrol
PX.
the
was seen
the maximum activity the enzyme 7-9
2-3
Sodium 24-fold,
Vol.
96, No.
1, 1980
BIOCHEMICAL
FILlPIN
BIOPHYSICAL
CONCENTRATION
filipin on particulate tubes containing various at 37"C, then guanylate
for 6 min at 37°C with
( 0 ) and without
in
Filipin soluble
soluble
medium
enzyme activators activate
soluble
like
organic
the particulate
enzyme Km (with
with
disrupted
or without
nitroprusside
205
about
with
Other
hypo-
soluble
and arachidonic
enzyme treated
PX but
or
and column
shown).
0.2 mM, which
(not
contaminating
vesicles (not
the basal
by nitroprusside
lipoxygenase
the particulate
or without
and
assayed
cGMP formed/min/mg
by solubilization
peroxides,
Lubrol
was
not activate
not express
sensitive
with
picomoles
did
membrane
GTP of about
Enzyme
of filipin
activity
activation
enzyme treated
had a Km for enzyme treated
cyclase
its
was evident
nitroprusside
cyclase.
concentrations 1127.1
did
Furthermore,
GTP was determined,
nitroprusside particulate
This
guanylate
- 0.5 mg/ml
treatment
COMMUNICATIONS
( 0 ) 1 mM sodium nitroprusside.
PX was
or potentiated
studies. remained
Lubrol
of 0.001
filipin
enzyme.
chromatography
Km for
0.9%
cyclase
In addition
trapped
of
in the range
guanylate
shown).
tonic
presence
RESEARCH
(mg/ml)
Fig. 1. The effect of aliquots were added to preincubated for 5 min Activity protein.
not
AND
filipin. with
treatment).
higher
did
When the
filipin
was identical 4 times
acid
plus to the than
the
Vol.
96, No.
BIOCHEMICAL
1, 1980
AND
I. Effects of filipin rat lung particulate
Table
BIOPHYSICAL
RESEARCH
and detergents on the guanylate cyclase Guanylate
Treatment
- SNP
105.0 385.0 836.8 737.0 302.3
None
Tween 20 Triton X-100 Lubrol PX Filipin
4.0 4.0 1.2 0.4
Particulate and
fraction
assayed
for
sodium nitroprusside
Treatment activators zation did
(Table
I>.
of filipin
filipin
were
activity was found observations cyclase
activity.
filipin
treatment suggest Effect
preparation
that
volume. where filipin
was activated filipin
of temperature treated
there that
with
caused
the
filipin
speed
by sodium
was no significant
non-sedimentable preparations
did
nearly
amount
not
solubilize
cyclase
all
with
of the and enzyme
eluted. guanylate
rechromatographed better
These
than
after Lubrol
PX
change.
cyclase
206
used
treated
of protein
is normally
nitroprusside
(microsomes
centrifugation was no significant
enzyme
an irreversible
of protein
and there
a trace
guanylate
detergents
majority
the particulate
soluble
treatment
on guanylate
done,
A-5m column,
Only
in solubili-
guanylate
When microsomes
on a Bio-Gel
The particulate
that
Also
II),
enzyme contamination.
fractions
support
8.6 7.7 a.6 a.9 22.5
known
to filipin,
upon high
(Table
its
results
were
the pellet
suggesting
in the void
in the
2 i + 2 +
or 1 ti
with
of the particulate
fraction
chromatographed
preparation
studies
into
particulate
soluble
eluted
detergents and without
with
In contrast
activation
in control,
from
various
activity
(15).
enzyme activity.
enzyme activity free
activity
sedimented
non-sedimentable
with
413.6 408.3 859.8 714.4 1684.2
and lysolecithin
When solubilization
treated
2 1.6 + 9.8 t 2.6 f 12.5 2 10.3
cyclase
detergents
nitroprusside
and enzyme activity
which
guanylate
cyclase
not potentiate
cyclase
+ SNP
(SNP).
of particulate
of guanylate
were
(30 ug) was treated guanylate
such as non-ionic
cyclase
Cyclase Activity
Concentration bg/ml)
filipin
COMMUNICATIONS
activity
chromatographed
in particulate on Bio-Gel
A-5m
Vol.
96, No.
BIOCHEMICAL
1, 1980
Table
II.
AND
Solubilization
of by
BIOPHYSICAL
particulate
A.
Activity
Water
Protein
guanylate
COMMUNICATIONS
cyclase
filipin Enzyme
Fractions
RESEARCH
1.0% SA
in
Lubrol
Presence
of
PX
TA
1 mM SNP
SA
TA
SA
(4
TA
Original
1.96
260
132?
6
2239
1137
+ 15
1046
Pellet
2.6
196
752
1
2234
898
t 26
627
Supernatant
0.1
22
204
_+ 60
312 + 20
45
428
+ 12
2222
996 + 13
2449
1098
2161
795 2 29
1405
517
2 13
920
+ 76
CONTROL
B. FILIPIN
33
531
2 13
2412
4 ? 56
TREATED
Original
2.23
465
208
Pellet
2.7
339
125 t
Supernatant
0.1
15
8
140 ? 64
16
152 + 80
98
?
2
About 1.8 ml of a particulate enzyme preparation was mixed with 0.2 ml buffer (control) of 5 mg/ml filipin (filipin treated). About 0.25 ml from each tube was removed (original) and assayed, remaining suspensions were centrifuged at 139,000 xg for 60 min. Pellets and supernatants were also assayed for guanylate cyclase activity in presence of various treatments. TA = total activity, picomoles cGMP formed/min in each fraction, SA = specific
activity,
column
picomoles
after
filipin
without
filipin
control
enzyme
for
studies activates
membrane been
showed
with
lung
Kimelberg
In membranes, average
area
phospholipid at 37"C,
the
and Paphadjopoulos the effects
above
the transition
per molecule
and reduced
bilayer
(19-20).
membrane
matrix
The Arrhenius but
guanylate
The activity upon
During is
chromatographed plot
such a break
of the
was not
evident
filipin.
The Arrhenius
to describe
"viscotropic,"
2.
22-25"C,
particulate
changes.
(microsomes
DISCUSSION that the cholesterol
demonstrate
by nitroprusside. fluidity
shown in Fig.
treated
shown to be dependent
(16-18).
ation
is
around
rat
protein.
and untreated
a break
enzyme
These
activation
treatment)
treatment)
particulate
filipin,
cGMP formedlminlmg
plots of several
fluidity
binding cyclase
and potentiates
suggest
that
membrane
have introduced
of membrane
fluidity
temperature, the motion guanylate
in a liquid
207
filipin bound
of the phospholipid
(18)
the
antibiotic,
the
enzymes
has
term
on enzyme activity.
of hydrocarbon
crystalline
causes
environment
cholesterol
cyclase
its
condenses chains
activity state
thus
the
of determinfilipin
Vol.
96, No.
1. 1980
BIOCHEMICAL
Fig. 2. The effect Microsomal preparation were chromatographed for 2 min at various lines were determined
probably
increases
supported
by spin
label
fluidity
studies
by sequestering
which
in the
hydrophobic
core
However,
another
polyene
amphotericin
did
not activate
interacts
with
in nature,
(not
of an aminosugar
altered
"break"
other attached
alter
COMMUNICATIONS
fluidity
in Arrhenius
B did
not affect
cyclase for
to the macrolide of membranes of rat
208
ring
polyenes
amphoteric
and nystatin its
activation
that
filipin
and is neutral
properties
because
(22-23).
of various lung
is
(21).
(21).
B, candicidin
thanother
used possess
membrane
or potentiated
is
increased
fluidity
the difference
more effectively
This
filipin
containing
amphotericin
A reason
plot
that
of a cholesterol
studied,
polyenes
cholesterol.
demonstrated
guanylate
shown).
cholesterol
whereas
Alcohols
polyenes
particulate
by nitroprusside
RESEARCH
temperature on the particulate guanylate cyclase. treated with 0.3 mg/ml filipin ( 0 ) and buffer ( 0 ) on Bio-Gel A-5m column. The enzymes were preincubated temperatures and activity was assayed for 4 min. The by the method of least squares.
membrane
other
BIOPHYSICAL
of
fluidity
Interestingly,
AND
particulate
origin
(24-25). guanylate
Ethanol cyclase,
Vol.
96, No.
1, 1980
however, (Lad,
it
did
P. J.,
mechanisms induces
BIOCHEMICAL
not potentiate
paper
disorganization site
cyclase
is
submitted enzyme
hydrophobic It
site(s)
[26]).
This
altered
membrane
fluidity
changes
bound with
adrenergic cytochrome
postulated
that
a conformational
freedom
that
fluidity. is
receptor
in adenylate
(28,29).
the rate-limiting
of guanylate
cyclase
A conformational
change step
in the enzyme
in lipid for
fluidity
A. A.,
paper particulate complex
by detergent cyclase
molecules
activity
change
activation
by
due to
by catecholaminehas been observed
(30).
an enzyme-catalyzed
It
has been reaction
can be
(31).
ACKNOWLEDGEMENT This work was supported in part by a USPHS Grant I-IL 15002, from the National Institutes of Health, and by the John M. Dalton Research Center. I am grateful to Dr. Arnold A. White, in whose laboratory this work was done, for his generous support, advice and criticism. REFERENCES 1.
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guanylate
solubilized
(freedom
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in
occupied
diffusion
cyclase,
of soluble
or a conformational
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bb due to the
change
are
cholesterol
interacts.
because
modulation
implicated
guanylate
why detergent
proteins
of motion
around
M. A. and White,
explain
of membrane
by nitroprusside
by sequestering
activation
Liebel,
COMMUNICATIONS
may be due to independent
metabolite
by nitroprusside,
possible
an increased
P. J.,
activation
filipin
chains
or its
may also
activated
also
that
acyl
RESEARCH
difference
in nitroprusside (Lad,
regions is
probable
nitroprusside
suggested
is not
is
cyclase
This
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such hydrophobic
from
It
BIOPHYSICAL
guanylate
in preparation).
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White, A. A., Northup, S. J., and Zenser, T. V. (1972) in Methods in CycZic Nucleotide Research (Chasin, M., ed.) pp. 125-167, Marcel1 Dekker, New York. Zlatkis, A., and Zak, B. (1969) Anal. Bioch-em. 29, 143-148. Liebel, M. A., Lad, P. J., and White, A. A. (1978) Fed. Proc. 37, 1537. Lad, P. J., and White, A. A. (1979) Arch. Biochem. Biophys. 197, 244-252. Engelhard, V. Ii., Esko, J. D., Strom, D. R., and Glaser, M. (1976)
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39-50. 22. 23. 24. 25. 26. 27. 28.
Norman, A. W., Demel, R. A., De Kruyff, B., Geurts Van Kessel, W. S. M., and Van Deenen, L. L. M. (1972) Biochim. Biophys. Acta 290, 1-14. De Kruijff, B., Gerritsen, W. J., Oerlemans, A., Demel, R. A., and Van Deenen, L. L. M. (1974) Biochim. Biophys. Acta 339, 30-43. Chin, J. H., and Golstein, D. B. (1977) Mol. Phurmacok 13, 435-441. Johnson, D. A., Lee, N. M., Cooke, G., and Loh, M. M. (1979) MOT. Phannacok 15, 739-746. Struck, G. J., and Glossman, H. (1978) Naunyn-S&niedeberg's Arch. Phurmaco2. 304, 51-61. Helenius, A., and Simons, K. (1975) Biochim. Biophys. Acta 415, 29-79. Rimon, G., Hanski, E., Braun, S., and Levitzki, A. (1978) Nature 276,
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Hanski, E., Rimon, G., and Levitzki, A. (1979) Biochemistry 18, 846-853. Dufoureq, J., Faucon, J. F., Lussan, D., and Bernon, R. (1975) FEBSLetts. 57, 112-116. Jencks, W. P. (1969) CataZysis in Chemistry and EnzymoZogy, pp. 308-312, McGraw-Hill, New York.
210