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Single-phase butanol extraction: A new tool for proteolipid isolation
Vol. 74, No. 1, 1977
BIOCHEMICAL
SINGLE-PHASE
BUTANOL EXTRACTION:
A NEW TOOL FOR PROTEOLIPID
Hans Sigrist: Kristine Sigrist-Nelson*=& of Membrane Research, Weizmann Institute
Departmsnt
Received
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
November
ISOLATION
Carlos Gitler of Science, Rehovot,
Israel
2,1976
SUMMARY
An alternative method to the proteolipids is presented. plasmic reticulum membranes extraction and subsequently step procedure described is of the dicyclohexylcarbodi-imide particles.
chloroform/methanol extraction of The proteolipid fraction from sarcois isolated by a single-phase n-butanol precipitated by diethyl ether. The two successfully applied in the purification binding protein from submitochondrial
INTRODUCTION The isolation pered ion
by the absence methods
system is
of suitable
utilizing
organic
was always
extraction
of highly
using
present.
as a pronounced
lipid-protein
interactions
of aqueous
solutions,
of the solubilized lipid binding
from
describes for
isolated
membrane
for
phase
system,
technique
favors detailed
and facil
two step
extracta biphasic proteolipid n-Butanol
system.
components,
and the mitochondrial
in a rapid
classical
a new technique
of n-butanol
a two-phase
By means of the
has been ham-
(l-6),
membrane
The miscibility
While
often
employed
in a single
agent
forming
reticulum
have been
techniques.
solvent
(7-9). without
sarcoplasmic
protein
as organic
proteins
have been widely
report
solubilizing
fraction.
membrane
nonaqueous solvents
This
n-butanol
known
hydrophobic
with an here
disorganizing small
amounts separation
easy
the proteo-
membrane
IXCD-
procedure.
METHODS AND MATERIALS Sarcoplasmic reticulum membranes were prepared from rabbit skeletal muscle (10) in the presence of $uM phenylmethylsulfonyl fluoride. The final membrane fraction was suspended in 1OOmM KCI, 5mM imidazole pH 7.4 and stored at -7OOC. Before isolation of the proteolipid fraction, sarcoplasmic reticulum membranes (15-20 mg/ml) were sedimented by centrifugation at 24,000 g for 60 minutes. The membrane pellet was suspended in 5mM CaC12 or water, conserving the initial protein concentration. Isolation of rat liver mitochondria was carried out according to Johnson and Lardy (11). Submitochondrial particles were prepared with a Branson sonifier in a medium containing 21nM EDTA pH 8.5 and were subsequently twice washed (105,000 g, The iso30 minutes) with a buffer containing 25OmM sucrose, 1OmM Tris-HCl pH 7.5. lated membranes were stored at -7OOC. Submitochondrial particles were incubated ATP'ase activity is dewith DCCD (2jug per mg protein) for 18 hours at O°C (6,12). fined and assayed as in reference 6 in the absence of an ATP regenerating system. The labeled membranes were washed twice with sucrose-Tris buffer and collected by Abbreviations: DCCD - N,N'-Dicyclohexylcarbodi-imide SDS - Sodium dodecylsulfate *Swiss
National
Science
Foundation
Copyright 0 I977 by Academic Press, Inc. All rights of reproduction in any form reserved.
fellows 178
Vol. 74, No. 1, 1977
Fig.
BIOCHEMICAL
1. Schematic
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
representation
of the proteolipid
isolation
procedure.
centrifugation at 105,000 g for 30 minutes. The final pelleted membranes were suspended in water (6-8mg/ml). Protein was determined in the presence of 0.1% SDS according to Lowry et. al (13). Samples containing organic solvents were dried under nitrogen before assaying for protein. Total phosphate was measured by the method of Chen et. al (14). SDS gel electrophoresis was carried out in accordance with Weber and Osborn The electrophoresis was performed in 0.1% SDS, 50mM sodium phosphate buffer (15). pH 7.2 using 10% polyacrylamide gels. Gels were stained with coomassie brillant blue and destained with 7% acetic acid. For molecular weight determinations bovine pancreatic insulin (MW 5,700) and egg white lysozyme (MW 14,300) served as standards in the co-electrophoretic analysis. When "C-LECD-labeled samples were electrophoressamples were applied to separate gels. One gel was stained; the ed, identical duplicate gel was immediately cut into 2mm slices. The individual gel slices were extracted overnight with 1OmM Triton X-100. Scintillation fluid was added and the slices were courted for radioactive content. All chemicals and reagents were of the highest purity commercially available. "C-DCCD (45tii/n@l) was a generous gift of Dr. H.R. Kaback, Roche Institute of Molecular Biology, Nutley. RESULTS Isolation
procedure: The isolation
n-butanol
followed
The widely Step
I:
by addition
applicable
Using formed
at 12,000 Step cooled
II:
is
ether
described
concentration
of the membrane to the butanol
suspension
fraction
into
(fig.
1).
as follows:
the membrane
is separated
suspension
of the aqueous by repeated
is
injected
component
centri.fugation,
is
into 2%.
usually
n-butanol The immedithree
times
10 minutes.
The n-butanol supernatant is The finely dispersed
to -2OOC.
when centrifuged
injection
of diethyl
syringe
Final
precipitate
g for
entails
procedure
a tuberculin
at room temperature. ately
procedure
at 12,000
g for
combined with 5 volumes precipitate (proteolipid
10 minutes
179
(4OC).
of diethyl fraction)
The sedimentation
ether, presediments of the sarco-
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
P
B
0
I. 2. Protein patterns of fractions obtained during the sarcoplasmic reticulum proteolipic isolation. SDS gel electrophoresis, staining and destaining were performed as described in METHODS. The amount of protein applied is given in brackets. precipitate (4Oug); A. Sarcoplasmic reticulum membranes (60,ug); B. Butanol C. Ether precipitate (proteolipid) (5,ug); D. Insulin (12,ug).
plasmic
reticulum
diethyl drial
ether,
proteolipid whereas
proteolipid
Sarcoplasmic
is
fraction
(fig.
proteolipid
lipid,
2). could
The proteolipid
All
performed
the n-butanol/diethyl stored
ether
purification
major
proteins
be identified
in
was present
periments the amount
reduced it
was noted of proteolipid
mixture
after
containing
the addition
of
the mitochon-
at -2OOC overnight.
in
was routinely
extent that
followed
of the sarcoplasmic
the gel gels
pattern
in gels
made of the ether
of low into
precipitate. concentrations When Ca++
butanol.
180
precipitate
by SDS gel
electrophore-
excepting precipitate (fig.
the proteo(fig. ZC).
ZB). In the
of 9,000 daltons was determined. was present in all gels although
of the butanol
the presence solubilized
reticulum,
of the butanol
gel system employed, an apparent molecular weight A faint band attributable to the lipid components to a greatly
immediately
fraction:
The proteolipid sis
is
In preliminary
ex-
(5mM) of Ca++ increased was absent
during
the ad.
Vol. 74, No. 1, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I Isolation
of proteolipid
and carbodi-imide total
fractions
- treated
protein
from sarcoplasmic
submitochondrial
Sarcoplasmic
Ether
Protein
reticulum
precipitation: precipitation:
dition
precipitation:
of sarcoplasmic
were detected
in
The recoveries proteolipid
,umoles
%
membranes
78.02
100.0
58.01
100.0
Precipitate
75.01
96.2
2.93
5.0
Superna tant
1.03
1.3
53.47
92.1
Precipitate
0.12
0.15
0.44
0.7
Supernatant
2.40
3.0
54.38
93.5
6.03
100.0
4.65
100.0
5.77
95.6
0.50
10.7
fectively
precipitated
total ly tent
in
treated
in
successful
3.65
78.4
to n-butanol,
small
amounts
membranes protein
of ether
served
and total
the ether
lipids
II
of proteolipid
96% being
butanol
in
not be detected
with
fraction
fig.
ef-
the butan-
of sarcoplasmic
particles supernatant.
94% of were
the
identical-
The protein
con-
due to the simultaneous
the Lowry
was confirmed
(see also
in
leaving
overestimated
to interfere
in this
n-butanol
supernatant
the ether
probably
of the
submitochondrial present
fraction
When submitochondrial most
the isolation
electrophoresis,
the proteolipid remained
is
known
of protein
could
by gel
to the separated
phosphate
during
and the DCCD-labeled
approximately
supernatant. step
phosphate
reticulum
to precipitate
proteolipid
viously-characterized
5.4
protein,
the absence
purification
0.32
As demonstrated
of concentrated
The versatility
Supernatant
all
in
Mitochondrial
9.4
almost
total
bands
83.8
0.44
I.
78% of the
ditionally, where protein
3.90
1.9
sarcoplsamic
of the supernatant
presence
3.4
0.12
table
Addition
membranes
phosphate
0.20
Precipitate
both
from
listed
01 precipitate. reticulum
Supernatant
precipitate.
of
fraction are
Phosphate %
reticulum
the butanol
particles
of
w
DCCD-treated submitochondrial particles Butanol precipitation: Precipitate Ether
membranes
Recoveries
and phosphate.
Fraction
Butanol
reticulum
particles:
determination by gel
(16).
electrophoresis
3C).
fraction: of the proteolipid of
isolation
the DCCD-binding
as a proteolipid
procedure
protein
by Catell
181
was demonstrated
from mitochondrial et.
al.
(5).
Under
membranes the described
by the precon-
Ad-
Vol. 74, No. 1, 1977
BfOCHEMfCAL
AND BlOPHYSfCAL RESEARCH COMMUNfCATfONS
30
00
00
10
20
Slice
Fig.
1 I 30
40
number
protein from submitochondrial particles: 3. Isolation of the 14 C-DCCD-binding ibution of protein and radioactivity in polyacrylamide gels. ,"f"B C-CCCD-treated submitochondrial particles (40,ug); B. Butanol precipitate (proteo C. Ether supernatant (equivalent to 4pg); D. Ether precipitate (32p9l; lipid) (Spg) . 182
BIOCHEMICAL
Vol. 74, No. 1, 1977
ditions
nonradioactive
the ATP'ase out
inhibitor.
(6)
and Cattell
drial ly
reported
ive, ing
(5).
DCCD-labeled
protein
being
electrophoresis.
in
DCCD-binding
of 11,000
daltons;
ref.
daltons
(fig.
complete
As previous-
totally 3B).
(fig.
was found
quantitat-
Protein
(fig.
(molecular
of the
30)
all
weight
weights
subjected
at the posit-
precipitation
molecular
band-
3C) were
on the gels
precipitate
was determined
5, 13,000-14,000
super-
the submitochondrial
was not
supernatant
al.
of submitochon-
band in
An apparent
band.
et.
and ether
precipitate
confirming
protein
by Steckhoven
analysis
proteolipid
In the ether
with-
14C-DCCD labeling.
one protein
the butanol
inhibited
suspension
(proteolipid),
no radioactivity
by ether.
reported
SDS gel
of the ether
mobility,
the corresponding
protein
6, 10,000
in
samples
relative
radioactivity
was present
found
protein)
to a membrane
of corresponding
selectively
Moreover,
of the proteolipid's
protein-bound
3 presents precipitate
of the DCCD-binding
when concentrated
2/ug/mg membrane
the data
ether
highly
Extraction
with
Figure
as the patterns
DCCD labeled 3A).
was absent
(both
compared
are in agreement
precipitate,
as well
(fig.
to SDS gel ion
butanol (5,6)
particles
results
and co-workers
fractions,
as 14C-IXCD
97% and 98% respectively,
These
particles,
natant
DCCD as well
activity,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
radioactivity for
the
reported
in ref.
daltons).
DISCUSSION: In various functions
(17-19),
DCCD-binding
in
fraction.
of membrane simplicity
proteins
transmembrane
with
submitochondrial
rapidity
times.
n-Butanol,
of all
globular
(5,6)
a weakly
method
and purity
protic
solvent
The use of a single-phase
extraction
additionally
two-phase
denaturated
systems
in
that
and resulting
such as the proteolipids a nonaqueous
of the proteolipid greater
extent
described
environment.
to an aqueous than
by other
be used to form injected Indeed,
Since
preliminary
studies
interfacial here
phase,
treatments.
liposomes
(20)
by the present
and lipids protein
is
183
procedure
of endogenous utilizing
rapid
(2-4)
of the
or
preparation precipitation
the organic
phase.
classical
hydrophobic
this
extensive (step
with exposure
may be retained
supernatant lipid
complexes
upon associations avoids
conformation butanol
procedures
absent.
dependent
extraction
authors
into
of highly
may be critically
composed
Other
and longer
the problems
properties
Concentrated
class
of
membranes
was used to effect
the functional
of this
the advantages
techniques
avoids
functional the present
presents reticulum
the proteolipids
Conformation
here
more laborious
nonaqueous
of
was developed. fractions.
extracting
the significance aspects
sarcoplasmic
proteins,
of a
of the sarcoplasmic
(4) emphasize
of the isolated
from either involve
The identification
and structural
described
respiratory-linked
involvement
translocation
isolation
impared
permeability.
the functional
procedure
extraction
particles
to restore
proton
ion
study
isolation
proteolipid
reported
(5) and the possible
an alternative
combined for
by decreasing
To further
The proteolipid reported
DCCD is
as a proteolipid
proteolipid
protein
systems
presumably
protein
reticulum this
membrane
to a I)
can
and proteolipid. technique
indicate
that
Vol. 74, No. 1, 1977
the proteolipid vestigations data
from for
Finally, plast
sarcoplasmic
on the butanol
reported
been further
BIOCHEMICAL
extracted
the ionophoric the general
demonstrated
membranes
reticulum
applicability personal
does possess
proteolipid
activity
may
of the of
by the successful
( N. Nelson,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
help
ionophoric
activity.
to elucidate
sarcoplasmic
reticulum
the proteolipid
isolation
isolation
of a proteolipid
Further
in-
the conflicting proteolipid technique fraction
(2,4,21) has from
chlorog
communication).
REFERENCES: 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21.
Folch, J. and Lees, M. (1951) J. Biol. Chem. 191, 807-817. MacLennan, D., Yip, C., Iles, G. and Seeman, P. (1972) Cold Spring Harbor Symp. Quant. 37, 469-478. Biol. P. and Barrat, M. (1975) Arch. Biochem. Biophys. 170, 92-101. Lawn=-, Racker, E. and Eytan, E. (1975) J. Biol. Chem. 250, 7533-7534. Cattell, K. J., Lindop, C. R., Knight, I. G., and Beechey, R. B. (1971) Biochem. J. 125, 169-177. Steckhoven, F. S., Waitkus, R. F. and van Moerkerk, H. (1972) Biochemistry 11, 11441150. Maddy, A. H. (1972) Biochim. Biophys. Acta 288, 255-262. Lenaz, G., Parenti-Castelli, G., Sechi, A. M. and Masotti, L. (1972) Arch. Biochem. Biophys. 148, 391-399. Lockshin, A. and Burris, R. H. (1966) Proc. Natl. Acad. Sci. (USA) 56, 1564-1570. Martonosi, A. (1968) J. Biol. Chem. 243, 71-81. Johnson, D. and Lardy, H. (1967) Methods in Enzymology 10, 94-96. Robertson, A. M., Holloway, C. T., Knight, I. G. and Beechey, R. B. (1968) Biochem. J. 445-456. Lowry, 0. H., Rosenbrough, N. J., Farr, A. L., and Randall, R. J. (1951) J. Biol. Chem, 193, 265. Chen, P. S., Toribara, T. and Warner, H. (1956) Anal. Chem. 28, 1756-1758. Weber, K. and Osborn, M. (1969) J. Biol. Chem. 244, 4406-4412. Eichberg, J. and Mokrash, L. (1969) Anal. Biochem. 30, 386-390. Racker, E. and Horstman, L. L. (1967) J. Biol. Chem. 242, 2547-2551. McCarty, R. E. and Racker, E. (1967) J. Biol. Chem. 242, 3435-3439. Patel, L., Schuldiner. S. and Kaback, H. R. (1975) Proc. Natl. Acad. Sci. (USA) 72, 3387-3391. Batzri, S. and Korn, E. D. (1973) Biochim. Biophys. Acta 298, 1015-1019. Laggner, P. and Graham, D. E. (1976) Biochim. Biophys. Acta 433, 311-317.
184
BIOCHEMICAL
SINGLE-PHASE
BUTANOL EXTRACTION:
A NEW TOOL FOR PROTEOLIPID
Hans Sigrist: Kristine Sigrist-Nelson*=& of Membrane Research, Weizmann Institute
Departmsnt
Received
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
November
ISOLATION
Carlos Gitler of Science, Rehovot,
Israel
2,1976
SUMMARY
An alternative method to the proteolipids is presented. plasmic reticulum membranes extraction and subsequently step procedure described is of the dicyclohexylcarbodi-imide particles.
chloroform/methanol extraction of The proteolipid fraction from sarcois isolated by a single-phase n-butanol precipitated by diethyl ether. The two successfully applied in the purification binding protein from submitochondrial
INTRODUCTION The isolation pered ion
by the absence methods
system is
of suitable
utilizing
organic
was always
extraction
of highly
using
present.
as a pronounced
lipid-protein
interactions
of aqueous
solutions,
of the solubilized lipid binding
from
describes for
isolated
membrane
for
phase
system,
technique
favors detailed
and facil
two step
extracta biphasic proteolipid n-Butanol
system.
components,
and the mitochondrial
in a rapid
classical
a new technique
of n-butanol
a two-phase
By means of the
has been ham-
(l-6),
membrane
The miscibility
While
often
employed
in a single
agent
forming
reticulum
have been
techniques.
solvent
(7-9). without
sarcoplasmic
protein
as organic
proteins
have been widely
report
solubilizing
fraction.
membrane
nonaqueous solvents
This
n-butanol
known
hydrophobic
with an here
disorganizing small
amounts separation
easy
the proteo-
membrane
IXCD-
procedure.
METHODS AND MATERIALS Sarcoplasmic reticulum membranes were prepared from rabbit skeletal muscle (10) in the presence of $uM phenylmethylsulfonyl fluoride. The final membrane fraction was suspended in 1OOmM KCI, 5mM imidazole pH 7.4 and stored at -7OOC. Before isolation of the proteolipid fraction, sarcoplasmic reticulum membranes (15-20 mg/ml) were sedimented by centrifugation at 24,000 g for 60 minutes. The membrane pellet was suspended in 5mM CaC12 or water, conserving the initial protein concentration. Isolation of rat liver mitochondria was carried out according to Johnson and Lardy (11). Submitochondrial particles were prepared with a Branson sonifier in a medium containing 21nM EDTA pH 8.5 and were subsequently twice washed (105,000 g, The iso30 minutes) with a buffer containing 25OmM sucrose, 1OmM Tris-HCl pH 7.5. lated membranes were stored at -7OOC. Submitochondrial particles were incubated ATP'ase activity is dewith DCCD (2jug per mg protein) for 18 hours at O°C (6,12). fined and assayed as in reference 6 in the absence of an ATP regenerating system. The labeled membranes were washed twice with sucrose-Tris buffer and collected by Abbreviations: DCCD - N,N'-Dicyclohexylcarbodi-imide SDS - Sodium dodecylsulfate *Swiss
National
Science
Foundation
Copyright 0 I977 by Academic Press, Inc. All rights of reproduction in any form reserved.
fellows 178
Vol. 74, No. 1, 1977
Fig.
BIOCHEMICAL
1. Schematic
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
representation
of the proteolipid
isolation
procedure.
centrifugation at 105,000 g for 30 minutes. The final pelleted membranes were suspended in water (6-8mg/ml). Protein was determined in the presence of 0.1% SDS according to Lowry et. al (13). Samples containing organic solvents were dried under nitrogen before assaying for protein. Total phosphate was measured by the method of Chen et. al (14). SDS gel electrophoresis was carried out in accordance with Weber and Osborn The electrophoresis was performed in 0.1% SDS, 50mM sodium phosphate buffer (15). pH 7.2 using 10% polyacrylamide gels. Gels were stained with coomassie brillant blue and destained with 7% acetic acid. For molecular weight determinations bovine pancreatic insulin (MW 5,700) and egg white lysozyme (MW 14,300) served as standards in the co-electrophoretic analysis. When "C-LECD-labeled samples were electrophoressamples were applied to separate gels. One gel was stained; the ed, identical duplicate gel was immediately cut into 2mm slices. The individual gel slices were extracted overnight with 1OmM Triton X-100. Scintillation fluid was added and the slices were courted for radioactive content. All chemicals and reagents were of the highest purity commercially available. "C-DCCD (45tii/n@l) was a generous gift of Dr. H.R. Kaback, Roche Institute of Molecular Biology, Nutley. RESULTS Isolation
procedure: The isolation
n-butanol
followed
The widely Step
I:
by addition
applicable
Using formed
at 12,000 Step cooled
II:
is
ether
described
concentration
of the membrane to the butanol
suspension
fraction
into
(fig.
1).
as follows:
the membrane
is separated
suspension
of the aqueous by repeated
is
injected
component
centri.fugation,
is
into 2%.
usually
n-butanol The immedithree
times
10 minutes.
The n-butanol supernatant is The finely dispersed
to -2OOC.
when centrifuged
injection
of diethyl
syringe
Final
precipitate
g for
entails
procedure
a tuberculin
at room temperature. ately
procedure
at 12,000
g for
combined with 5 volumes precipitate (proteolipid
10 minutes
179
(4OC).
of diethyl fraction)
The sedimentation
ether, presediments of the sarco-
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
P
B
0
I. 2. Protein patterns of fractions obtained during the sarcoplasmic reticulum proteolipic isolation. SDS gel electrophoresis, staining and destaining were performed as described in METHODS. The amount of protein applied is given in brackets. precipitate (4Oug); A. Sarcoplasmic reticulum membranes (60,ug); B. Butanol C. Ether precipitate (proteolipid) (5,ug); D. Insulin (12,ug).
plasmic
reticulum
diethyl drial
ether,
proteolipid whereas
proteolipid
Sarcoplasmic
is
fraction
(fig.
proteolipid
lipid,
2). could
The proteolipid
All
performed
the n-butanol/diethyl stored
ether
purification
major
proteins
be identified
in
was present
periments the amount
reduced it
was noted of proteolipid
mixture
after
containing
the addition
of
the mitochon-
at -2OOC overnight.
in
was routinely
extent that
followed
of the sarcoplasmic
the gel gels
pattern
in gels
made of the ether
of low into
precipitate. concentrations When Ca++
butanol.
180
precipitate
by SDS gel
electrophore-
excepting precipitate (fig.
the proteo(fig. ZC).
ZB). In the
of 9,000 daltons was determined. was present in all gels although
of the butanol
the presence solubilized
reticulum,
of the butanol
gel system employed, an apparent molecular weight A faint band attributable to the lipid components to a greatly
immediately
fraction:
The proteolipid sis
is
In preliminary
ex-
(5mM) of Ca++ increased was absent
during
the ad.
Vol. 74, No. 1, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I Isolation
of proteolipid
and carbodi-imide total
fractions
- treated
protein
from sarcoplasmic
submitochondrial
Sarcoplasmic
Ether
Protein
reticulum
precipitation: precipitation:
dition
precipitation:
of sarcoplasmic
were detected
in
The recoveries proteolipid
,umoles
%
membranes
78.02
100.0
58.01
100.0
Precipitate
75.01
96.2
2.93
5.0
Superna tant
1.03
1.3
53.47
92.1
Precipitate
0.12
0.15
0.44
0.7
Supernatant
2.40
3.0
54.38
93.5
6.03
100.0
4.65
100.0
5.77
95.6
0.50
10.7
fectively
precipitated
total ly tent
in
treated
in
successful
3.65
78.4
to n-butanol,
small
amounts
membranes protein
of ether
served
and total
the ether
lipids
II
of proteolipid
96% being
butanol
in
not be detected
with
fraction
fig.
ef-
the butan-
of sarcoplasmic
particles supernatant.
94% of were
the
identical-
The protein
con-
due to the simultaneous
the Lowry
was confirmed
(see also
in
leaving
overestimated
to interfere
in this
n-butanol
supernatant
the ether
probably
of the
submitochondrial present
fraction
When submitochondrial most
the isolation
electrophoresis,
the proteolipid remained
is
known
of protein
could
by gel
to the separated
phosphate
during
and the DCCD-labeled
approximately
supernatant. step
phosphate
reticulum
to precipitate
proteolipid
viously-characterized
5.4
protein,
the absence
purification
0.32
As demonstrated
of concentrated
The versatility
Supernatant
all
in
Mitochondrial
9.4
almost
total
bands
83.8
0.44
I.
78% of the
ditionally, where protein
3.90
1.9
sarcoplsamic
of the supernatant
presence
3.4
0.12
table
Addition
membranes
phosphate
0.20
Precipitate
both
from
listed
01 precipitate. reticulum
Supernatant
precipitate.
of
fraction are
Phosphate %
reticulum
the butanol
particles
of
w
DCCD-treated submitochondrial particles Butanol precipitation: Precipitate Ether
membranes
Recoveries
and phosphate.
Fraction
Butanol
reticulum
particles:
determination by gel
(16).
electrophoresis
3C).
fraction: of the proteolipid of
isolation
the DCCD-binding
as a proteolipid
procedure
protein
by Catell
181
was demonstrated
from mitochondrial et.
al.
(5).
Under
membranes the described
by the precon-
Ad-
Vol. 74, No. 1, 1977
BfOCHEMfCAL
AND BlOPHYSfCAL RESEARCH COMMUNfCATfONS
30
00
00
10
20
Slice
Fig.
1 I 30
40
number
protein from submitochondrial particles: 3. Isolation of the 14 C-DCCD-binding ibution of protein and radioactivity in polyacrylamide gels. ,"f"B C-CCCD-treated submitochondrial particles (40,ug); B. Butanol precipitate (proteo C. Ether supernatant (equivalent to 4pg); D. Ether precipitate (32p9l; lipid) (Spg) . 182
BIOCHEMICAL
Vol. 74, No. 1, 1977
ditions
nonradioactive
the ATP'ase out
inhibitor.
(6)
and Cattell
drial ly
reported
ive, ing
(5).
DCCD-labeled
protein
being
electrophoresis.
in
DCCD-binding
of 11,000
daltons;
ref.
daltons
(fig.
complete
As previous-
totally 3B).
(fig.
was found
quantitat-
Protein
(fig.
(molecular
of the
30)
all
weight
weights
subjected
at the posit-
precipitation
molecular
band-
3C) were
on the gels
precipitate
was determined
5, 13,000-14,000
super-
the submitochondrial
was not
supernatant
al.
of submitochon-
band in
An apparent
band.
et.
and ether
precipitate
confirming
protein
by Steckhoven
analysis
proteolipid
In the ether
with-
14C-DCCD labeling.
one protein
the butanol
inhibited
suspension
(proteolipid),
no radioactivity
by ether.
reported
SDS gel
of the ether
mobility,
the corresponding
protein
6, 10,000
in
samples
relative
radioactivity
was present
found
protein)
to a membrane
of corresponding
selectively
Moreover,
of the proteolipid's
protein-bound
3 presents precipitate
of the DCCD-binding
when concentrated
2/ug/mg membrane
the data
ether
highly
Extraction
with
Figure
as the patterns
DCCD labeled 3A).
was absent
(both
compared
are in agreement
precipitate,
as well
(fig.
to SDS gel ion
butanol (5,6)
particles
results
and co-workers
fractions,
as 14C-IXCD
97% and 98% respectively,
These
particles,
natant
DCCD as well
activity,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
radioactivity for
the
reported
in ref.
daltons).
DISCUSSION: In various functions
(17-19),
DCCD-binding
in
fraction.
of membrane simplicity
proteins
transmembrane
with
submitochondrial
rapidity
times.
n-Butanol,
of all
globular
(5,6)
a weakly
method
and purity
protic
solvent
The use of a single-phase
extraction
additionally
two-phase
denaturated
systems
in
that
and resulting
such as the proteolipids a nonaqueous
of the proteolipid greater
extent
described
environment.
to an aqueous than
by other
be used to form injected Indeed,
Since
preliminary
studies
interfacial here
phase,
treatments.
liposomes
(20)
by the present
and lipids protein
is
183
procedure
of endogenous utilizing
rapid
(2-4)
of the
or
preparation precipitation
the organic
phase.
classical
hydrophobic
this
extensive (step
with exposure
may be retained
supernatant lipid
complexes
upon associations avoids
conformation butanol
procedures
absent.
dependent
extraction
authors
into
of highly
may be critically
composed
Other
and longer
the problems
properties
Concentrated
class
of
membranes
was used to effect
the functional
of this
the advantages
techniques
avoids
functional the present
presents reticulum
the proteolipids
Conformation
here
more laborious
nonaqueous
of
was developed. fractions.
extracting
the significance aspects
sarcoplasmic
proteins,
of a
of the sarcoplasmic
(4) emphasize
of the isolated
from either involve
The identification
and structural
described
respiratory-linked
involvement
translocation
isolation
impared
permeability.
the functional
procedure
extraction
particles
to restore
proton
ion
study
isolation
proteolipid
reported
(5) and the possible
an alternative
combined for
by decreasing
To further
The proteolipid reported
DCCD is
as a proteolipid
proteolipid
protein
systems
presumably
protein
reticulum this
membrane
to a I)
can
and proteolipid. technique
indicate
that
Vol. 74, No. 1, 1977
the proteolipid vestigations data
from for
Finally, plast
sarcoplasmic
on the butanol
reported
been further
BIOCHEMICAL
extracted
the ionophoric the general
demonstrated
membranes
reticulum
applicability personal
does possess
proteolipid
activity
may
of the of
by the successful
( N. Nelson,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
help
ionophoric
activity.
to elucidate
sarcoplasmic
reticulum
the proteolipid
isolation
isolation
of a proteolipid
Further
in-
the conflicting proteolipid technique fraction
(2,4,21) has from
chlorog
communication).
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184