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GTP-binding protein(s) in green plant, Lemna paucicostata
Vol. 143, No. 3, 1987 March 30, 1987
RESEARCH COMMUNICATIONS
Pages 908-912
GTP-BINDING
PROTEIN(S)
Kohji
National
AND BIOPHYSICAL
BIOCHEMICAL
GREEN PLANT,
IN
Lemna paucicostata ---
Hasunuma and Kanako Funadera
Institute for Myodaijicho,
Basic Biology, 38 Nishigonaka, Okazaki, 444 Japan
Received February 3, 1987 in GTP-binding protein(s) assayed by [35S]GTP S was detected the extract of Lemna paucicostata containing meXIbrane components. About 15 % of =-- SIGTP S activated GTP-binding protein, separated from unbound [ 5 5SlGTP 1 by gel filtra was retained on Millipore HAWP membrane fi 3 ter. 80 % of'@" S]GTPyS activated protein, mixed with charcoal solution, remained in the supernatant after centrifugation of the mixture. Successive treatments of the assay mixture by charcoal solution established the assay system for the activation of GTP-binding protein. The Km value for the activation 0 1987 Academic Press, Inc. of GTP-binding protein was 8 nM. A growing
lines
in the
transduction
teins the
literature.
In
of
catalyzes
GTP
Transducin-GTP
vated
the
(2).
conversion
proteins
complexes
Ca2+ ions
1,4,5-trisphosphate,
GTP-binding
protein
bisphosphate
to
(4).
inositol
polyphosphoinositide of
a GTP-binding
binding oncogenic
capacity
of
of
and GTPase activity.
ras protein
having
0006-291X/87 $1.50 Copyright 0 I987 by Academic Press, Inc. All rights of reproduction in any form reserved.
light of
reticulum, to
phosphatidyl
and Ni,
Ns
receptor stimulated
be regulated inositol
was activated ras
protein
acti-
GTP to GDP
and diacyl
by a 4,5-
glycerol by the action
has both
Microinjection
a significantly
908
the
by hormone-hormone
1,4,5-trisphosphate
Normal
to transducin-
cyclase,
was suggested
in
photoactivated
hydrolysis
adenylate
endoplasmic
Cleavage
(5).
the
for
pro-
has appeared
transducin-GDP
with
phosphodiesterase protein
signal
an inhibitor
and regulated
by inositol
of GTP-binding
segment,
coupled
from
role
external
of
subunits
are GTP-binding (3).
of
removes
Regulatory
the
rod outer
cGMP phosphodiesterase
and Pi
for
chains
retinal
rhodopsin (1).
evidence
impaired
of
GTP-
mutated
GTPase acti-
by
Vol.
143,
vity
of
proteins green
PC12
these in
culture
on the similar
a stimulation
period
a GTP-binding
in
the
of
paper
we report
and
assay
method
in
in
on the Lemna
not
COMMUNICATIONS
is
reception existence paucicostata
(6).
been
paucicostata
controlled
of
made with
light
of and
also
3',5'-GMP by the
we postulated of
In
GTP-binding
oscillation
by 5 uM cyclic
cycle, the
of
have
Lemna
flowering
light-dark
in
roles
circadian
flowering
Since
protein
present its
a rhythmic
RESEARCH
differentiation
significant
concentrations
(7).
BIOPHYSICAL
observations
We detected
meduim
a dark
AND
a morphological
reports
3',5'-GMP
observed
cells
animal,
plant.
cyclic
BIOCHEMICAL
3, 1987
induced
spite
of
No.
in length
of
an involvement signal.
GTP-binding
In
the
protein(s)
441.
EXPERIMENTAL Strain and medium: Lemna paucicostata 441 has been maintained -__ by A. Takimoto of Kyoto University. The strain is a short day piant. A half strength Hutner's medium with 1 % sucrose was used to grow the plant. Glass distilled-deionized water was used to prepare culture medium. Growth of Lemna: For the maintenance of the strain, a three --frond colonv wastransplantedtothe above medium (50 ml) in a 100 ml Erlemneyer flask at‘every 7 days. twas incubated at 25 OC under white fluorescent light (3.9 W/m z ). For experimental use, the three frond colony wastransplantedto 200 mlofthe above medium in 1,000 ml Roux flasks. After incubation at 25 'C under continuous light for 10 days, about 50 fronds from the culture were transplanted to several petri dishes (6 cm) containing 10 ml each of theabove fresh medium. Afterincubationat 25 OC under white they were transferred to the dark room fluorescent light for 12 hr, 8 hr. at 25 OC for The following procedures were Preparation of crude extract: performed under dim green safelight. After removal of liquid liquid nitrogen was poured into a medium from the above culture, petri dish and the frozen plant was stored at -80 OC in darkness. Whole plants from 12 petri dishes were collected, thoroughly macerated in liquid nitrogen and mixed with 10 ml of extraction buffer containing 25 mM Pipes, pH 6.4, 0.25 mM EDTA, 1 mM MgC12, 0.5 mM diazoacetyl-DL-norleucine methyl ester, 1 mM phenyl methylsulfonyl fluoride and 0.01 mM pepstatin A. The mixture was thoroughly After macerated to frozen powder and then it was warmed to melt. thawing, the extract was centrifuged at15,OOO xg for 20 minat 2 OC. The supernatant (19 ml) was divided into 1 ml aliquots and stored at -80 OC. Assay activity: Assay for3;;phiflgdf3ngCyfm -for GTP-binding [35S]GTP S (Guanosine S'[y-thioltriphosphate, [ mol, NEGyO3OH) to GTP-binding proteins was performed according to Reaction mixture (200 ul) the modified method as described (8). contained 20 mM Pipes, pH 6.4, 0.1 mM EDTA, 0.1 M NaCl, 1.5 mM methylsulfonyl fluoride and crude extract of MC12 r 0.2 mM phenyl Incubation at 24 OC was started by adding the crude extract Lemna. --Reaction was stopped by adding to the preheated reaction mixture. 909
BIOCHEMICAL
Vol. 143, No. 3, 1987
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
400 ulofthe ice-coldquenching buffer composed of 20 mM Pipes, pH 6.4, 0.1 % Lubrol PX, 0.1 M NaCl, lO.mM MgCl 1 mM fi-mercaptoethano1 and 0.1 mM GTP. The mixture was filtere 2' with Millipore HAWP membrane filter and washed 8 times with the ice-cold washing buffer containing 20 mM Tris-HCl, pH 7.2, 0.1 M NaCl and 25 mM MgCl . Control experiment were performed by adding the quenching buf 8er The radioactivity on membrane filter before adding crude extract. in control experiments was subtracted from all sample counts. When charcoal was used to remove unbound [35S]GTP S, ice-cold 0.8 ml of charcoal solution containing 5 % of Norit SX'Plus, 1 % bovine serum albumin (Sigma; fraction V), 0.2 % dextran and 20 mM Pipes, pH 6.4 was added in sted of the quenching buffer. After 5 min of chilling in ice, it was centrifuged at 2,000 xg for 10 min at 4 OC. To the 0.7 ml of supernatant, 0.3 ml of charcoal solution was added and centrifuged as above. Resulting supernatant (0.8 ml) was mixed with 5 ml of Aquasol 2 scintillator and the radioactivity was counted. In control experiments, charcoal solution was added before the addition of crude extract, and the radioactivity was subtracted from all experimental counts. Protein was measured by the Bio-Rad protein assay kit with bovine serum albumin as standard.
RESULTS AND DISCUSSION Detection activity
of
of -
transducin
specifically method, from of
GTP-binding
the
trapping
the
activation
of
binding
Using
uCi
0.1
linear
of
for
activation
protein
was performed
in this
of
the
activation
that
in
the
presence
to GTP-binding
but
at
activation
of GTP-binding
protein
incubation
(data
higher
to maintain reduced
retention
of
volume
protein, of the
the
pressures [35 S]GTPyS
To improve binding
shown),
the the reaction
suction for
method
mixture
method
[35S]GTP,S
procedures
was relatively per assay,
the
up to
60 sec.
was about
five-fold
1.0 uCi the at
care
20 set
should
in
be since
reduction
in the
protein. activated
GTP-
were performed.
was increased 910
extract
to be constant,
resulted
this
The kinetics
IO-fold
GTP-binding
to assay
following
for
by
was examined.
and at
pressure
activated
the
work.
protein
this
suction
in
[35S]GTP,
was about
With
Using
activation
[35S]GTPYS,
GTP-binding
(1).
proteins
was linear
of GTP-binding 0.1 uCi
exercised
0.5 uCi
protein
of
not
the
the
membrane filter
filter
protein(s)
of GTP-binding
Rate
using
on the
per assay,
120 set,
for
GTP-binding
[35 S]GTPyS
[35 SIGTPyS
over
Assay
has been performed
Lemna by [35 SIGTPyS
the
protein:
to 2.5 mland
The 2.5 uCi
Vol. 143, No. 3, 1987
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
2
60
120 Incubation
100 tie
240
300
(set)
Sephadex G-100 gel filtration of reaction product of [ S)GTPyS and whole plant extract of Lemna. The procedure for the gel filtration of the reaction products through a Sephadex G-100 column (2x32 cm) was described in the text. () Radioactivity in 0.5 ml of each fraction. (---o---) Radioactivity in the supernatant of each fraction treated with charcoal solution. The radioactivity was calculated to the value which was expected when 0.5 mlof fraction was used and all the supernatantwas recovered for counting. ( ***.-...--..a- ) Protein concentration.
Fj$j.L
Fig. & Binding of [35 S]GTPyS as assayed after successive treatments with charcoal solution. ReqctOipn,~:x~~r~3~0S.:GTmd.)Sc~~:a~~~d 2.67 mg of protein and (7~ . . , (---a--) 0.5 nCi (2.5 nM) and (V ) 1.0 uCi (5YnM) Per assay, with the standard error bars shown.
[35S]GTPYS reaction trated
was added to mixture
for
quenching
the
5 min at
buffer
G-100
mM NaCl,
25 mM MgC12 and
ml
into
column
2
of each fraction
fraction
of the
GTP-binding fractions
gel
procedure.
To
0.1
15
of
the
1).
% of
the
for
fuged
radioactivity
in 0.7
the
60 min.
911
pH 7.2,
with
at
of
ml
of
in
the void
0.5
volume of
in the by the
charcoal
20
the same
counting
radioactivities
0.9
ml
on a
membrane localization
fraction,
chilledinice
concen-
was loaded
Radioactivity peak
the
IO-fold
HAWP membrane filter
was mixedand and the
of
PX and eluted
indicating
on Millipore ml
ml
of
20 mM Tris-HCl,
an apparant
filtration Only
with
(Fig.
incubation
The mixture
% Lubrol
0.1
revealed
protein. retained
24 OC, 0.5
equilibrated
fractions
ml
After
was added.
Sephadex
buffer
mixture.
peak
washing
solution
The mixture
was centri-
supernatant
was counted.
BIOCHEMICAL
Vol. 143, No. 3, 1987
About
65 % of radioactivities
in the
remained
in
the
supernatant,
remained
in the
supernatant.
mixtures
of
% of
the
80
the
The result
activated
reaction
free
fraction
with
protein
2 % of
time
of
provided
protein.
charcoal
[35S]GTPyS
ice-chilling
assay
remained method
Successive
solution
will
of
to 5 min,
protein
a rapid
fractions
free
was shortened
GTP-binding
GTP-binding
mixture
only
When the
activated
RESEARCH COMMUNICATIONS
GTP-binding
whereas
and the
[35 S]GTPyS
supernatant.
[35S]GTPyS the
charcoal
AND BIOPHYSICAL
the about in
for
treatments
completely
of
remove
[35S]GTPyS. Kinetics
method
of --
the activation
described
above,
protein
was followed
Results
in Fig.
different
at
of
of
different
of
the Km value
of
the
tion
of
t35~]G~~y~ in
GTP-binding
concentrations
activation
of
[35S]GTPyS from
(I)
the
M.
This
and the
its
of of
activation
for
at
double
GTP-binding
was 8~10~~
transducin
in
least
[35S]GTP,,S.
value
is very
Ni
of
three
5 min.
reciprocal with
the
GTP-binding
at
protein
subunit
Using
p rotein:
the activation
2 show an increase
rate
observed
kinetics
concentrations
Estimation
of -
plot the
of
the
concentra-
close
adenylate
to
those
cyclase
(8). ACKNOWLEDGEMENTS We are grateful to Dr. P.-S. Song for valuable discussion and critical reading of the manuscript and to Dr. A. Takimoto for providing strains of Lemna. We are also grateful to Mrs. Yazawa and Miss T. Imaizumi for excellent technical assistance.
M.
REFERENCES 1.
Bennett,
N. and DuPont,
Y. (1985)
J. Biol.
Chem. 260,
4156-
4168. 2. 3. 4. 5. 6. 7. 8.
Stryer, L., Hurley, J. B. and Fung, B. K-K. (1981) Curr. Top. 15, 93-108. Membr. Transp. Gilman, A. G. (1984) Cells, 577-579. Gill, D. L., Ueda, T., Chueh, S.-H. and Noel, M. W. (1986) Nature 320, 461-464. Cockcroft, S. and Gomperts, B. D. (1985) Nature 314, 534-536. Bar-Sagi, D. and Feramisco, J. R. (1985) Cell%, 841-848. Hasunuma, K., Shinohara, Y., Funadera, K. and Watanabe, M. (1986) Abstr. of XVI Yamada Conference: Phytochrome and Plant Photomorphogenesis, 155. Kurose, H., Katada, T., Haga, T., Haga, K., Ichiyama, A. and Ui, M. (1986) J. Biol. Chem. 261, 6423-6428. 912
RESEARCH COMMUNICATIONS
Pages 908-912
GTP-BINDING
PROTEIN(S)
Kohji
National
AND BIOPHYSICAL
BIOCHEMICAL
GREEN PLANT,
IN
Lemna paucicostata ---
Hasunuma and Kanako Funadera
Institute for Myodaijicho,
Basic Biology, 38 Nishigonaka, Okazaki, 444 Japan
Received February 3, 1987 in GTP-binding protein(s) assayed by [35S]GTP S was detected the extract of Lemna paucicostata containing meXIbrane components. About 15 % of =-- SIGTP S activated GTP-binding protein, separated from unbound [ 5 5SlGTP 1 by gel filtra was retained on Millipore HAWP membrane fi 3 ter. 80 % of'@" S]GTPyS activated protein, mixed with charcoal solution, remained in the supernatant after centrifugation of the mixture. Successive treatments of the assay mixture by charcoal solution established the assay system for the activation of GTP-binding protein. The Km value for the activation 0 1987 Academic Press, Inc. of GTP-binding protein was 8 nM. A growing
lines
in the
transduction
teins the
literature.
In
of
catalyzes
GTP
Transducin-GTP
vated
the
(2).
conversion
proteins
complexes
Ca2+ ions
1,4,5-trisphosphate,
GTP-binding
protein
bisphosphate
to
(4).
inositol
polyphosphoinositide of
a GTP-binding
binding oncogenic
capacity
of
of
and GTPase activity.
ras protein
having
0006-291X/87 $1.50 Copyright 0 I987 by Academic Press, Inc. All rights of reproduction in any form reserved.
light of
reticulum, to
phosphatidyl
and Ni,
Ns
receptor stimulated
be regulated inositol
was activated ras
protein
acti-
GTP to GDP
and diacyl
by a 4,5-
glycerol by the action
has both
Microinjection
a significantly
908
the
by hormone-hormone
1,4,5-trisphosphate
Normal
to transducin-
cyclase,
was suggested
in
photoactivated
hydrolysis
adenylate
endoplasmic
Cleavage
(5).
the
for
pro-
has appeared
transducin-GDP
with
phosphodiesterase protein
signal
an inhibitor
and regulated
by inositol
of GTP-binding
segment,
coupled
from
role
external
of
subunits
are GTP-binding (3).
of
removes
Regulatory
the
rod outer
cGMP phosphodiesterase
and Pi
for
chains
retinal
rhodopsin (1).
evidence
impaired
of
GTP-
mutated
GTPase acti-
by
Vol.
143,
vity
of
proteins green
PC12
these in
culture
on the similar
a stimulation
period
a GTP-binding
in
the
of
paper
we report
and
assay
method
in
in
on the Lemna
not
COMMUNICATIONS
is
reception existence paucicostata
(6).
been
paucicostata
controlled
of
made with
light
of and
also
3',5'-GMP by the
we postulated of
In
GTP-binding
oscillation
by 5 uM cyclic
cycle, the
of
have
Lemna
flowering
light-dark
in
roles
circadian
flowering
Since
protein
present its
a rhythmic
RESEARCH
differentiation
significant
concentrations
(7).
BIOPHYSICAL
observations
We detected
meduim
a dark
AND
a morphological
reports
3',5'-GMP
observed
cells
animal,
plant.
cyclic
BIOCHEMICAL
3, 1987
induced
spite
of
No.
in length
of
an involvement signal.
GTP-binding
In
the
protein(s)
441.
EXPERIMENTAL Strain and medium: Lemna paucicostata 441 has been maintained -__ by A. Takimoto of Kyoto University. The strain is a short day piant. A half strength Hutner's medium with 1 % sucrose was used to grow the plant. Glass distilled-deionized water was used to prepare culture medium. Growth of Lemna: For the maintenance of the strain, a three --frond colonv wastransplantedtothe above medium (50 ml) in a 100 ml Erlemneyer flask at‘every 7 days. twas incubated at 25 OC under white fluorescent light (3.9 W/m z ). For experimental use, the three frond colony wastransplantedto 200 mlofthe above medium in 1,000 ml Roux flasks. After incubation at 25 'C under continuous light for 10 days, about 50 fronds from the culture were transplanted to several petri dishes (6 cm) containing 10 ml each of theabove fresh medium. Afterincubationat 25 OC under white they were transferred to the dark room fluorescent light for 12 hr, 8 hr. at 25 OC for The following procedures were Preparation of crude extract: performed under dim green safelight. After removal of liquid liquid nitrogen was poured into a medium from the above culture, petri dish and the frozen plant was stored at -80 OC in darkness. Whole plants from 12 petri dishes were collected, thoroughly macerated in liquid nitrogen and mixed with 10 ml of extraction buffer containing 25 mM Pipes, pH 6.4, 0.25 mM EDTA, 1 mM MgC12, 0.5 mM diazoacetyl-DL-norleucine methyl ester, 1 mM phenyl methylsulfonyl fluoride and 0.01 mM pepstatin A. The mixture was thoroughly After macerated to frozen powder and then it was warmed to melt. thawing, the extract was centrifuged at15,OOO xg for 20 minat 2 OC. The supernatant (19 ml) was divided into 1 ml aliquots and stored at -80 OC. Assay activity: Assay for3;;phiflgdf3ngCyfm -for GTP-binding [35S]GTP S (Guanosine S'[y-thioltriphosphate, [ mol, NEGyO3OH) to GTP-binding proteins was performed according to Reaction mixture (200 ul) the modified method as described (8). contained 20 mM Pipes, pH 6.4, 0.1 mM EDTA, 0.1 M NaCl, 1.5 mM methylsulfonyl fluoride and crude extract of MC12 r 0.2 mM phenyl Incubation at 24 OC was started by adding the crude extract Lemna. --Reaction was stopped by adding to the preheated reaction mixture. 909
BIOCHEMICAL
Vol. 143, No. 3, 1987
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
400 ulofthe ice-coldquenching buffer composed of 20 mM Pipes, pH 6.4, 0.1 % Lubrol PX, 0.1 M NaCl, lO.mM MgCl 1 mM fi-mercaptoethano1 and 0.1 mM GTP. The mixture was filtere 2' with Millipore HAWP membrane filter and washed 8 times with the ice-cold washing buffer containing 20 mM Tris-HCl, pH 7.2, 0.1 M NaCl and 25 mM MgCl . Control experiment were performed by adding the quenching buf 8er The radioactivity on membrane filter before adding crude extract. in control experiments was subtracted from all sample counts. When charcoal was used to remove unbound [35S]GTP S, ice-cold 0.8 ml of charcoal solution containing 5 % of Norit SX'Plus, 1 % bovine serum albumin (Sigma; fraction V), 0.2 % dextran and 20 mM Pipes, pH 6.4 was added in sted of the quenching buffer. After 5 min of chilling in ice, it was centrifuged at 2,000 xg for 10 min at 4 OC. To the 0.7 ml of supernatant, 0.3 ml of charcoal solution was added and centrifuged as above. Resulting supernatant (0.8 ml) was mixed with 5 ml of Aquasol 2 scintillator and the radioactivity was counted. In control experiments, charcoal solution was added before the addition of crude extract, and the radioactivity was subtracted from all experimental counts. Protein was measured by the Bio-Rad protein assay kit with bovine serum albumin as standard.
RESULTS AND DISCUSSION Detection activity
of
of -
transducin
specifically method, from of
GTP-binding
the
trapping
the
activation
of
binding
Using
uCi
0.1
linear
of
for
activation
protein
was performed
in this
of
the
activation
that
in
the
presence
to GTP-binding
but
at
activation
of GTP-binding
protein
incubation
(data
higher
to maintain reduced
retention
of
volume
protein, of the
the
pressures [35 S]GTPyS
To improve binding
shown),
the the reaction
suction for
method
mixture
method
[35S]GTP,S
procedures
was relatively per assay,
the
up to
60 sec.
was about
five-fold
1.0 uCi the at
care
20 set
should
in
be since
reduction
in the
protein. activated
GTP-
were performed.
was increased 910
extract
to be constant,
resulted
this
The kinetics
IO-fold
GTP-binding
to assay
following
for
by
was examined.
and at
pressure
activated
the
work.
protein
this
suction
in
[35S]GTP,
was about
With
Using
activation
[35S]GTPYS,
GTP-binding
(1).
proteins
was linear
of GTP-binding 0.1 uCi
exercised
0.5 uCi
protein
of
not
the
the
membrane filter
filter
protein(s)
of GTP-binding
Rate
using
on the
per assay,
120 set,
for
GTP-binding
[35 S]GTPyS
[35 SIGTPyS
over
Assay
has been performed
Lemna by [35 SIGTPyS
the
protein:
to 2.5 mland
The 2.5 uCi
Vol. 143, No. 3, 1987
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
2
60
120 Incubation
100 tie
240
300
(set)
Sephadex G-100 gel filtration of reaction product of [ S)GTPyS and whole plant extract of Lemna. The procedure for the gel filtration of the reaction products through a Sephadex G-100 column (2x32 cm) was described in the text. () Radioactivity in 0.5 ml of each fraction. (---o---) Radioactivity in the supernatant of each fraction treated with charcoal solution. The radioactivity was calculated to the value which was expected when 0.5 mlof fraction was used and all the supernatantwas recovered for counting. ( ***.-...--..a- ) Protein concentration.
Fj$j.L
Fig. & Binding of [35 S]GTPyS as assayed after successive treatments with charcoal solution. ReqctOipn,~:x~~r~3~0S.:GTmd.)Sc~~:a~~~d 2.67 mg of protein and (7~ . . , (---a--) 0.5 nCi (2.5 nM) and (V ) 1.0 uCi (5YnM) Per assay, with the standard error bars shown.
[35S]GTPYS reaction trated
was added to mixture
for
quenching
the
5 min at
buffer
G-100
mM NaCl,
25 mM MgC12 and
ml
into
column
2
of each fraction
fraction
of the
GTP-binding fractions
gel
procedure.
To
0.1
15
of
the
1).
% of
the
for
fuged
radioactivity
in 0.7
the
60 min.
911
pH 7.2,
with
at
of
ml
of
in
the void
0.5
volume of
in the by the
charcoal
20
the same
counting
radioactivities
0.9
ml
on a
membrane localization
fraction,
chilledinice
concen-
was loaded
Radioactivity peak
the
IO-fold
HAWP membrane filter
was mixedand and the
of
PX and eluted
indicating
on Millipore ml
ml
of
20 mM Tris-HCl,
an apparant
filtration Only
with
(Fig.
incubation
The mixture
% Lubrol
0.1
revealed
protein. retained
24 OC, 0.5
equilibrated
fractions
ml
After
was added.
Sephadex
buffer
mixture.
peak
washing
solution
The mixture
was centri-
supernatant
was counted.
BIOCHEMICAL
Vol. 143, No. 3, 1987
About
65 % of radioactivities
in the
remained
in
the
supernatant,
remained
in the
supernatant.
mixtures
of
% of
the
80
the
The result
activated
reaction
free
fraction
with
protein
2 % of
time
of
provided
protein.
charcoal
[35S]GTPyS
ice-chilling
assay
remained method
Successive
solution
will
of
to 5 min,
protein
a rapid
fractions
free
was shortened
GTP-binding
GTP-binding
mixture
only
When the
activated
RESEARCH COMMUNICATIONS
GTP-binding
whereas
and the
[35 S]GTPyS
supernatant.
[35S]GTPyS the
charcoal
AND BIOPHYSICAL
the about in
for
treatments
completely
of
remove
[35S]GTPyS. Kinetics
method
of --
the activation
described
above,
protein
was followed
Results
in Fig.
different
at
of
of
different
of
the Km value
of
the
tion
of
t35~]G~~y~ in
GTP-binding
concentrations
activation
of
[35S]GTPyS from
(I)
the
M.
This
and the
its
of of
activation
for
at
double
GTP-binding
was 8~10~~
transducin
in
least
[35S]GTP,,S.
value
is very
Ni
of
three
5 min.
reciprocal with
the
GTP-binding
at
protein
subunit
Using
p rotein:
the activation
2 show an increase
rate
observed
kinetics
concentrations
Estimation
of -
plot the
of
the
concentra-
close
adenylate
to
those
cyclase
(8). ACKNOWLEDGEMENTS We are grateful to Dr. P.-S. Song for valuable discussion and critical reading of the manuscript and to Dr. A. Takimoto for providing strains of Lemna. We are also grateful to Mrs. Yazawa and Miss T. Imaizumi for excellent technical assistance.
M.
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Y. (1985)
J. Biol.
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4168. 2. 3. 4. 5. 6. 7. 8.
Stryer, L., Hurley, J. B. and Fung, B. K-K. (1981) Curr. Top. 15, 93-108. Membr. Transp. Gilman, A. G. (1984) Cells, 577-579. Gill, D. L., Ueda, T., Chueh, S.-H. and Noel, M. W. (1986) Nature 320, 461-464. Cockcroft, S. and Gomperts, B. D. (1985) Nature 314, 534-536. Bar-Sagi, D. and Feramisco, J. R. (1985) Cell%, 841-848. Hasunuma, K., Shinohara, Y., Funadera, K. and Watanabe, M. (1986) Abstr. of XVI Yamada Conference: Phytochrome and Plant Photomorphogenesis, 155. Kurose, H., Katada, T., Haga, T., Haga, K., Ichiyama, A. and Ui, M. (1986) J. Biol. Chem. 261, 6423-6428. 912