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Reconstitution of band 3, the erythrocyte anion exchange protein
BIOCHEMICAL
Vol. 74, No. 4, 1977
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RECONSTITUTION
OF BAND 3,
THE ERYTHROCYTE ANION Alonzo
H. Ross and Harden
Stauffer Laboratory Stanford University, Received
December
EXCHANGE PROTEIN M. McConnell
for Physical Chemistry Stanford, California 94305
7,1976
SUMMARY: Band 3, the erythrocyte membrane protein thought to be responsible for anion transport, was purified to near homogeneity using a Concanavalin A affinity column. Band 3 was then combined with egg lecithin, erythrocyte lipid, cholesterol, and glycophorin, the major erythrocyte sialoglycoprotein, to form vesicles capable of The transport activity was sensitive to rapid sulfate transport. prior treatment of the erythrocytes with pyridoxal phosphate-NaBH4, a potent inhibitor of anion transport in these cells.
Studies
INTRODUCTION: suggested
that
protein,
is
hypothesis a crude cyte for
band
with
3, a 100,000
responsible
for
rich
structure
band
a lectin
affinity
combined
it
vesicles
capable
transport
Abbreviations:
column
with
to treatment
in band
3 have
other
by pyridoxal in
intact
weight anion
see ref.
protein
human
red
sulfate
band blood
4 for
(5,6,7,8). 3 to near cell
transport.
phosphate-NaBH4,
integral
(1,2).
This
a review
with of erythro-
Several
methods
We have
employed
homogeneity,
and
(RBC) components The activity a potent
have
membrane
of transport
nomenclature).
been reported
of transport
transport
reconstitution
3 (3;
to purify
of rapid
molecular
by the
and membrane
isolating
inhibitors
erythrocyte
was strengthened extract
specific
to form is
inhibitor
sensitive of anion
RBC (9).
amount of protein dissolved A-U., absorbance unit, 1 ml buffer which would give an absorbance of 1.0 278 nm; DTAB, dodecyl trimethyl ammonium bromide; RBC, red blood cell.
Copyright 0 1977 by Academic AN rights of reproduction in any
Press, Inc. form reserved.
1318
ISSN
in at
0006-291X
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALS AND METHODS: Egg lecithin was prepared by the method of Singleton et al. (10). RBC lipid was isolated from ghosts by successive extraction with 2:l chloroform methanol, 1:2 chloroform methanol, and 7:l chloroform methanol saturated with 28% ammonium hydroxide. Non-lipid material was removed with the Folch washing procedure (11). Glycophorin prepared by the method of Marchesi and Andrews (12) was the gift of E. J. Luna and J. T. Lewis. Dodecyl trimethyl ammonium bromide (DTAB) was synthesized according to Hong and Hubbell (13). Phosphate was assayed by the method of Ames (14), cholesterol by the method of Zlatkis and Zak (15), and protein by the Lowry method (16) (adding 0.1 ml 4% SDS to each tube). Bound pyridoxamine phosphate was assayed by its fluorescence (9). a-Methylmannoside from Pfanstiehl Laboratories was used because of its low absorbance at 278 nm. Sodium dodecyl sulfate polyacrylamide electrophoresis gels were run and stained according to Steck and Yu (17). Erythrocyte ghosts were prepared from outdated RBCs (type 0' from the Stanford Blood Bank) (18). Prior to lysis some of the cells were treated with pyridoxal phosphate and NaBH4 using 20 mM pyridoxal phosphate and 100 mM NaBH4 (9). Polyacrylamide gel electrophoresis was used to check for proteolysis by the NaBH4. Following lysis, the ghosts were washed twice with 3 vols of 15 mM histidine pH 6.6 and then lyophilized. The freeze-dried ghosts were resuspended at lo-15 mg/ml in 100 mM DTAB, 1 mM dithiothreitol, 15 mM histidine pH 6.6, and vigorously stirred for l-l.5 hrs. Insoluble material was removed by centrifugation at 67,500 xg for 30 min. The white pellet was discarded, the yellow supernatant was mixed with a concentrated divalent cation solution. The resulting mixture contained 1 mM CaC12, 1 mM MgC12, 1 mM MnC12. Band 3 was purified by affinity chromatography using a Pharmacia Concanavalin A Sepharose 4B column similar to that used by Findlay (8). Approximately 2 ml of column material was equilibrated with 100 mM DTAB, 1 mM CaC12, 1 mM MgC12, 1 mM MnC12, 15 mM histidine pH 6.6 in a 5 ml pipette. The extract from 20-40 mg ghosts was added to the column followed by a 25 ml rinse with the same buffer. The protein was We collected eluted with 100 mM a-methylmannoside in the same buffer. 2.7 ml column fractions and measured protein content by absorbance at 278 nm. The column was shielded from light during separation of pyridoxal phosphate-treated band 3. Band 3 was reconstituted by a method closely analogous to that of Hong and Hubbell (13) for rhodopsin, and Grant and McConnell (19) for glycophorin. Egg lecithin and RBC lipid at a molar ratio 86:14 were dried from ethanol with a stream of Ar and then placed under vacuum The lipid and lyophilized glycophorin were disfor several hours. Cholesterol dispersed in 100 mM DTAB and solved in column buffer. eluted band 3 were added to give a final composition of 0.79 mM egg 0.13 mM RBC lipid, 0.45 mM cholesterol, 71 pg/ml glycophorin, lecithin, The molar ratios for band 3, glycoand 0.005 A.U. band 3 (Q4 Vg)/ml. phorin, and total lipid were 1:27:29,000. The solution was incubated dialysed against on ice under Ar for 4-5 hrs, and then exhaustively 10 mM sodium phosphate, 2 mM NaCl, 2 mM Na2S04, 1 mM EDTA, 0.1 mM To avoid lipid oxidation, the dialysis buffer dithiothreitol pH 6.6. During dialysis, solutions was continuously aerated with nitrogen. containing pyridoxamine phosphate-band 3 were shielded from light. Lipid protein aggregates were eliminated by 2 or 3 10 min centrifuThe vesicles were harvested from gations (1325 xg) following dialysis. the low speed centrifugation supernatant by centrifugation at 60,000 xg for 45 min. were suspended To study uptake of radioactive compounds, vesicles
1319
BIOCHEMICAL
Vol. 74, No. 4, 1977
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FRACTION
Figure
1.
NUMBER
Elution profile of band 3 from Concanavalin A affinity The three arrows indicate the addition of the column. solubilized ghosts, the rinse buffer, and the cr-methylmannoside solution.
in dialysis buffer (~2 mM phospholipid) with the radioactive compound, at 23 "C, and at suitable intervals 10 ~1 aliquots were diluted with 5 ml 14.4 mM sodium phosphate, 2 mM NaCl pH 6.6, passed over a 0.22 or 0.45 u Millipore filter, and then washed on the filter with an additional 5 ml solution. The filters were dried and then counted in 10 ml Aquasol (New England Nuclear). Filters were washed with H20 and soaked in the wash buffer prior to use. Incorporation of the protein into the vesicles was checked on a 6 cm 5-15% linear sucrose gradient. The samples were layered on the top of the gradient and centrifuged at 297,000 xg for 7-12 hrs. The protein and lipid content of fractions collected from the bottom of the tube were assayed using the Lowry Assay and 14C-phospholipid. RESULTS: affinity
chromatography
contaminating protein
retained (Fig.
protein has been
by the 1).
This
assigned
figure
gel (Fig.
to the
3 assuming
band
by lectin
3 with
very
solubilized
was eluted
of the
detergent 88,000
little
ghost with
ct-methyl-
by dialysis
daltons
as the
represents
an upper
limit
to the
since
3 itself
might
be phosphor-
band
electrophoresis 2).
band
of total
A column
removal
phospholipids
>90% pure
fraction
band
followed
homogeneous
Concanavalin
per
Polyacrylamide is
nearly
Following
weight.
of contaminating
of RBC ghosts
The small
2-7 phosphates
molecular
ylated.
gave
lipid.
mannoside we found
DTAB solubilization
showed that
The minor 3 dimer
1320
(7).
high
molecular
The identity
the
number
eluted
weight
band
of the
con-
Vol. 74, No. 4, 1977
Figure
2.
taminants
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Gel electrophoresis of column eluate. The eluate was dialysed against distilled water and then 0.1% SDS prior to electrophoresis in order to eliminate the DTAB. The gel shown in the upper tracing was stained with Coomassie Blue and the lower gel with periodic acid-Schiff reagent. The right edge of the trace represents the leading edge Roughly of the tracking dye, and the bar is 0.1 A.U. 20 pg protein was applied to each gel.
varied
with
the preparation.
Glycophorin
and band 4.2 were
by dialysis
of
the most common. Lipid
protein
vesicles
During
the dialysis
peared
and had to be eliminated
vesicles
in the
large
were formed
supernatant
aggregates
of
lipid
the DTAB.
and protein
by low speed centrifugation.
contained
1321
16-36% of
the
total
also
apThe
phospholipid
BIOCHEMICAL
Vol. 74, No. 4, 1977
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
20. zN iI,. !--&Oa-
<00 tL+ Oo FRACTION 8
4
Figure
3.
Sucrose gradient Percent of total Assay and percent
12
16
20
NUMBER
profiles of reconstituted vesicles. b the Lowry protein was measured of total lipid with 1 i C-phospholipid.
30 TIME
Figure
4.
cholesterol
protein
into
content
tein
Lipid
were nearly
vesicles all
could
but
in
little
be loaded
with
all
formed the
tried
with
mole
was verified
Nearly
We originally alone,
35
40
45
N)
was 23-28
the vesicles
ultracentrifugation. 3).
(MI
Uptake of SO4' (01, sucrose (A.), and Na+ (0) by the reconstituted vesicles. Each point for SO4' uptake represents an average of two runs.
and the
(Fig.
0
top
by sucrose
of in
the the
S04=,
protein same
density banded
manner
but
of
gradient with
the
lacking
lipid pro-
fraction.
to reconstitute success.
The incorporation
%.
band
Even though
egg lecithin
1322
band
3 with
egg lecithin
egg lecithin 3 vesicles
vesicles gave
low pro-
BIOCHEMICAL
Vol. 74, No. 4, 1977
tected
volumes
method or the
(O-O.7
pl/mg
ion exchange
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
phospholipid)
with
column method of Michaelson
The problem
was not
caused by the vesicles
since
filters
retained
0.22~
cholesterol,
phospholipid.
effective
than
shows that data
The halftime
by the
vesicles
observing sulfate
to the very
sucrose
degree.
for
Ghosts 4.4 million
prepared
prepared
doxal intact
volume
the
These
was
retained
of uptake
shows that since
nonspecifically
find
4
vesicles
of radioactivity
the completion
internal
Fig.
or Na+.
glycophorin
it
was
we are
is unlikely
to the membrane
endpoint
4 we calculated
for
Na' due to its
the Na+ uptakes
with
control
using
pyridoxal
using
the
about
per ghost.
phosphates
60% greater
band 3 (average
The purified
per band 3 molecule.
of
than
3 pairs
that
band 3 took for
a band 3 associated
a potent
The transport inhibitor
erythrocytes. 1323
is
vesicles
of reconstitutions). sulfate
homogeneous band 3, glycophorin,
and egg lecithin.
phosphate-NaBH4,
molecules
RBC contained
phosphate-NaBH4-treated
We have observed nearly
phosphate-treated
pyridoxamine
a halftime
DISCUSSION:
cholesterol,
the
was more
we have carried
The experiment
phosphate
1.5-2.5
with with
transport
following
from pyridoxal
pyridoxamine
prepared
up sulfate
by lipid
would bind
In Fig.
to 1.5-
sulfate.
band 3 contained Vesicles
reconstitutions
filter vesicles
components
sucrose
(20).
of RBC lipid,
volumes
three
than
the fraction
We did not
slow uptake.
endpoint
into
and sucrose
same
five
and sulfate.
uptake
with
any one or two components.
that
times
the
the addition
of all
up much faster
found
through
the protected
SO4' uptake
at long
actual
of
of the
for
We also
the same for
that
the addition
S04= was taken
25-30 min.
raised
that
The addition
are representative
out.
We found
and glycophorin
6.0 pl/mg
passinq
filter
and Raftery
80-95% of the radioactivity
14C phospholipid.
containing
the Millipore
RBC lipid,
sensitive
of anion
anion
transport
to pyriin
Vol. 74, No. 4, 1977
At present vesicles the
it
with
for
sulfate
transport
transport data
the
per
molecule 0.27
are
sulfate
for
sulfates/set/band
volume
specific
interaction
may stabilize specific
through
membrane
interaction
complex --et al.
suggested (23)
activity
strengthens
in
found in the
and provides
(21) (2)
of
solution.
phos-
have used
we
Ho
to make a rough Using
0.07
of
Since
RBC per ml packed a flux
by the
study
reported.
our vesicles.
lOlo
of uptake
No complete
similar
their
com-
values
RBC and lo6
band
phosphates/set/band
Our experimental
the
other
RBC components
a nonspecific
with
the
quite
rate
3
3
result
is
3 molecule.
know whether
protected
RBC.
transport
flux
a 2 mM phosphate
the
has been
on phosphate
RBC, we calculate
We do not
tein
in an intact
Vmax and Km and assuming
molecules
port
to compare
of
and Guidotti's with
difficult
activity
and sulfate
parison
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the
saturation
phate
is
BIOCHEMICAL
band
3.
that
and reduce
da Silva
a whole
a good
the
protein
of band system
(band
was required
for
the
or through negative
charges A
3) (glycophorin) (22).
Also,
to reconstitute extract.
Gasko trans-
Our study
3 as an anion
studying
a
permeability.
and Nicolson
RBC ghost
identification
large
nonspecific
with
RBC lipid
effect
Glycophorin's
is consistent by Pinto
physical
increase
transport
interactions
pro-
between
RBC components. ACKNOWLEDGEMENTS: We are grateful to Drs. R. D. Simoni and W. H. Huestis for many helpful discussions and for the use of their equipment. Alonzo Ross is the recipient of a National Science Foundation Graduate Fellowship. This research has been supported by the National Science Foundation Grant nos. BMS 75-02381 and BMS 75-02381 AOl. It has benefited from facilities made available to Stanford University by the Advanced Research Projects Agency through the Center for Materials Research. REFERENCES 1.
Cabantchik, 2. I. PPS- 207 and 227.
2.
Ho,
and Rothstein,
M. K. and Guidotti,
G.
A.
(1975)
1324
J.
(1974)
J.
Membrane
Biol.
Chem.
250,
Biol. 675.
15,
BIOCHEMICAL
Vol. 74, No. 4, 1977
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3.
Rothstein, A., Cabantchik, 2. I., Balshin, M., (1975) Biochem. Biophys. Res. Comm. 64, 144.
4.
Steck,
5.
Kahlenberg,
6.
Furthmayr, Biol. 26,
7.
Yu, J.
8.
Findlay,
9.
Cabantchik, 2. I., Balshin, (1975) J. Biol. Chem. 250,
T. L.
(1974) A.
H., 173.
Cell
(1976)
Anal.
Kahane,
I.,
and Steck, J.
J.
T. L.
B. C.
Biol.
Biochem.
J.
J.
74,
337. V. T.
Biol.
Biol.
Chem. 249,
M., Breuer, 5130.
W.,
11.
Folch, J., Chem. 226,
12.
Marchesi,
13.
Hong, K. and Hubbell, 69, 2617.
14.
Ames, B. N. (1966) in Methods Ginsburg, V. (eds.), Academic p. 115.
15.
Zlatkis,
16.
Lowry, (1951)
0. H., Rosebrough, J. Biol Chem. 193,
17.
Steck,
T. L.
18.
Steck, T. L., Weinstein, D. F. H. (1970) Science
19.
Grant, C. W. M. and McConnell, Sci. USA 71, 4653.
H. M. ( 1974)
20.
Michaelson, D. M. and Raftery, Sci. USA 71, 4768.
M. A.
21.
Passow, H.
22.
Pinto da Silva, Acta 363, 311.
23.
Gasko, 0. D., Knowles, A. F., Shertzer, H. G., and Racker, E. (1976) Anal. Biochem. 72, 57.
V. T. and Andrews,
A. and Zak,
and Yu,
(1968)
W. L.
B.
J.
Prog.
E. P. (1972)
Proc.
9170.
and White,
G. H.
(1971)
Membrane
and Rothstein,
Brown, M. L., 42, 53.
and Sloane-Stanley,
J.
4398.
Singleton, W. S., Gray, M. S., (1965) J. Amer. Oil Chem. Sot. M.,
(1976)
Chem. 250,
10.
Lees, 497.
R.
1.
and Marchesi, (1975)
(1974)
62,
and Juliano,
(1957)
Science Natl.
J. J.
174,
Acad.
A. L.
Biol.
1247.
Sci.
USA
in Enzymology, Neufeld, E. F. and Press, New York, New York, Vol. 8,
(1967)
Anal.
N. J., 265. (1973)
Biochem.
Farr, J.
A. L.,
Supra.
R. S., Strauss, 168, 255.
Biophys.
P. and Nicolson,
1325
Mol. G. L.
2,
and Randall,
Struct. J.
143. R. J.
A, 220.
H.,
and Wallach,
Proc.
Natl.
Acad.
1974) Proc.
Natl.
Acad.
Biol.
19,
(1974)
423.
Biochim. Suolinna,
Biophys. E. M.,
Vol. 74, No. 4, 1977
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RECONSTITUTION
OF BAND 3,
THE ERYTHROCYTE ANION Alonzo
H. Ross and Harden
Stauffer Laboratory Stanford University, Received
December
EXCHANGE PROTEIN M. McConnell
for Physical Chemistry Stanford, California 94305
7,1976
SUMMARY: Band 3, the erythrocyte membrane protein thought to be responsible for anion transport, was purified to near homogeneity using a Concanavalin A affinity column. Band 3 was then combined with egg lecithin, erythrocyte lipid, cholesterol, and glycophorin, the major erythrocyte sialoglycoprotein, to form vesicles capable of The transport activity was sensitive to rapid sulfate transport. prior treatment of the erythrocytes with pyridoxal phosphate-NaBH4, a potent inhibitor of anion transport in these cells.
Studies
INTRODUCTION: suggested
that
protein,
is
hypothesis a crude cyte for
band
with
3, a 100,000
responsible
for
rich
structure
band
a lectin
affinity
combined
it
vesicles
capable
transport
Abbreviations:
column
with
to treatment
in band
3 have
other
by pyridoxal in
intact
weight anion
see ref.
protein
human
red
sulfate
band blood
4 for
(5,6,7,8). 3 to near cell
transport.
phosphate-NaBH4,
integral
(1,2).
This
a review
with of erythro-
Several
methods
We have
employed
homogeneity,
and
(RBC) components The activity a potent
have
membrane
of transport
nomenclature).
been reported
of transport
transport
reconstitution
3 (3;
to purify
of rapid
molecular
by the
and membrane
isolating
inhibitors
erythrocyte
was strengthened extract
specific
to form is
inhibitor
sensitive of anion
RBC (9).
amount of protein dissolved A-U., absorbance unit, 1 ml buffer which would give an absorbance of 1.0 278 nm; DTAB, dodecyl trimethyl ammonium bromide; RBC, red blood cell.
Copyright 0 1977 by Academic AN rights of reproduction in any
Press, Inc. form reserved.
1318
ISSN
in at
0006-291X
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALS AND METHODS: Egg lecithin was prepared by the method of Singleton et al. (10). RBC lipid was isolated from ghosts by successive extraction with 2:l chloroform methanol, 1:2 chloroform methanol, and 7:l chloroform methanol saturated with 28% ammonium hydroxide. Non-lipid material was removed with the Folch washing procedure (11). Glycophorin prepared by the method of Marchesi and Andrews (12) was the gift of E. J. Luna and J. T. Lewis. Dodecyl trimethyl ammonium bromide (DTAB) was synthesized according to Hong and Hubbell (13). Phosphate was assayed by the method of Ames (14), cholesterol by the method of Zlatkis and Zak (15), and protein by the Lowry method (16) (adding 0.1 ml 4% SDS to each tube). Bound pyridoxamine phosphate was assayed by its fluorescence (9). a-Methylmannoside from Pfanstiehl Laboratories was used because of its low absorbance at 278 nm. Sodium dodecyl sulfate polyacrylamide electrophoresis gels were run and stained according to Steck and Yu (17). Erythrocyte ghosts were prepared from outdated RBCs (type 0' from the Stanford Blood Bank) (18). Prior to lysis some of the cells were treated with pyridoxal phosphate and NaBH4 using 20 mM pyridoxal phosphate and 100 mM NaBH4 (9). Polyacrylamide gel electrophoresis was used to check for proteolysis by the NaBH4. Following lysis, the ghosts were washed twice with 3 vols of 15 mM histidine pH 6.6 and then lyophilized. The freeze-dried ghosts were resuspended at lo-15 mg/ml in 100 mM DTAB, 1 mM dithiothreitol, 15 mM histidine pH 6.6, and vigorously stirred for l-l.5 hrs. Insoluble material was removed by centrifugation at 67,500 xg for 30 min. The white pellet was discarded, the yellow supernatant was mixed with a concentrated divalent cation solution. The resulting mixture contained 1 mM CaC12, 1 mM MgC12, 1 mM MnC12. Band 3 was purified by affinity chromatography using a Pharmacia Concanavalin A Sepharose 4B column similar to that used by Findlay (8). Approximately 2 ml of column material was equilibrated with 100 mM DTAB, 1 mM CaC12, 1 mM MgC12, 1 mM MnC12, 15 mM histidine pH 6.6 in a 5 ml pipette. The extract from 20-40 mg ghosts was added to the column followed by a 25 ml rinse with the same buffer. The protein was We collected eluted with 100 mM a-methylmannoside in the same buffer. 2.7 ml column fractions and measured protein content by absorbance at 278 nm. The column was shielded from light during separation of pyridoxal phosphate-treated band 3. Band 3 was reconstituted by a method closely analogous to that of Hong and Hubbell (13) for rhodopsin, and Grant and McConnell (19) for glycophorin. Egg lecithin and RBC lipid at a molar ratio 86:14 were dried from ethanol with a stream of Ar and then placed under vacuum The lipid and lyophilized glycophorin were disfor several hours. Cholesterol dispersed in 100 mM DTAB and solved in column buffer. eluted band 3 were added to give a final composition of 0.79 mM egg 0.13 mM RBC lipid, 0.45 mM cholesterol, 71 pg/ml glycophorin, lecithin, The molar ratios for band 3, glycoand 0.005 A.U. band 3 (Q4 Vg)/ml. phorin, and total lipid were 1:27:29,000. The solution was incubated dialysed against on ice under Ar for 4-5 hrs, and then exhaustively 10 mM sodium phosphate, 2 mM NaCl, 2 mM Na2S04, 1 mM EDTA, 0.1 mM To avoid lipid oxidation, the dialysis buffer dithiothreitol pH 6.6. During dialysis, solutions was continuously aerated with nitrogen. containing pyridoxamine phosphate-band 3 were shielded from light. Lipid protein aggregates were eliminated by 2 or 3 10 min centrifuThe vesicles were harvested from gations (1325 xg) following dialysis. the low speed centrifugation supernatant by centrifugation at 60,000 xg for 45 min. were suspended To study uptake of radioactive compounds, vesicles
1319
BIOCHEMICAL
Vol. 74, No. 4, 1977
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FRACTION
Figure
1.
NUMBER
Elution profile of band 3 from Concanavalin A affinity The three arrows indicate the addition of the column. solubilized ghosts, the rinse buffer, and the cr-methylmannoside solution.
in dialysis buffer (~2 mM phospholipid) with the radioactive compound, at 23 "C, and at suitable intervals 10 ~1 aliquots were diluted with 5 ml 14.4 mM sodium phosphate, 2 mM NaCl pH 6.6, passed over a 0.22 or 0.45 u Millipore filter, and then washed on the filter with an additional 5 ml solution. The filters were dried and then counted in 10 ml Aquasol (New England Nuclear). Filters were washed with H20 and soaked in the wash buffer prior to use. Incorporation of the protein into the vesicles was checked on a 6 cm 5-15% linear sucrose gradient. The samples were layered on the top of the gradient and centrifuged at 297,000 xg for 7-12 hrs. The protein and lipid content of fractions collected from the bottom of the tube were assayed using the Lowry Assay and 14C-phospholipid. RESULTS: affinity
chromatography
contaminating protein
retained (Fig.
protein has been
by the 1).
This
assigned
figure
gel (Fig.
to the
3 assuming
band
by lectin
3 with
very
solubilized
was eluted
of the
detergent 88,000
little
ghost with
ct-methyl-
by dialysis
daltons
as the
represents
an upper
limit
to the
since
3 itself
might
be phosphor-
band
electrophoresis 2).
band
of total
A column
removal
phospholipids
>90% pure
fraction
band
followed
homogeneous
Concanavalin
per
Polyacrylamide is
nearly
Following
weight.
of contaminating
of RBC ghosts
The small
2-7 phosphates
molecular
ylated.
gave
lipid.
mannoside we found
DTAB solubilization
showed that
The minor 3 dimer
1320
(7).
high
molecular
The identity
the
number
eluted
weight
band
of the
con-
Vol. 74, No. 4, 1977
Figure
2.
taminants
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Gel electrophoresis of column eluate. The eluate was dialysed against distilled water and then 0.1% SDS prior to electrophoresis in order to eliminate the DTAB. The gel shown in the upper tracing was stained with Coomassie Blue and the lower gel with periodic acid-Schiff reagent. The right edge of the trace represents the leading edge Roughly of the tracking dye, and the bar is 0.1 A.U. 20 pg protein was applied to each gel.
varied
with
the preparation.
Glycophorin
and band 4.2 were
by dialysis
of
the most common. Lipid
protein
vesicles
During
the dialysis
peared
and had to be eliminated
vesicles
in the
large
were formed
supernatant
aggregates
of
lipid
the DTAB.
and protein
by low speed centrifugation.
contained
1321
16-36% of
the
total
also
apThe
phospholipid
BIOCHEMICAL
Vol. 74, No. 4, 1977
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
20. zN iI,. !--&Oa-
<00 tL+ Oo FRACTION 8
4
Figure
3.
Sucrose gradient Percent of total Assay and percent
12
16
20
NUMBER
profiles of reconstituted vesicles. b the Lowry protein was measured of total lipid with 1 i C-phospholipid.
30 TIME
Figure
4.
cholesterol
protein
into
content
tein
Lipid
were nearly
vesicles all
could
but
in
little
be loaded
with
all
formed the
tried
with
mole
was verified
Nearly
We originally alone,
35
40
45
N)
was 23-28
the vesicles
ultracentrifugation. 3).
(MI
Uptake of SO4' (01, sucrose (A.), and Na+ (0) by the reconstituted vesicles. Each point for SO4' uptake represents an average of two runs.
and the
(Fig.
0
top
by sucrose
of in
the the
S04=,
protein same
density banded
manner
but
of
gradient with
the
lacking
lipid pro-
fraction.
to reconstitute success.
The incorporation
%.
band
Even though
egg lecithin
1322
band
3 with
egg lecithin
egg lecithin 3 vesicles
vesicles gave
low pro-
BIOCHEMICAL
Vol. 74, No. 4, 1977
tected
volumes
method or the
(O-O.7
pl/mg
ion exchange
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
phospholipid)
with
column method of Michaelson
The problem
was not
caused by the vesicles
since
filters
retained
0.22~
cholesterol,
phospholipid.
effective
than
shows that data
The halftime
by the
vesicles
observing sulfate
to the very
sucrose
degree.
for
Ghosts 4.4 million
prepared
prepared
doxal intact
volume
the
These
was
retained
of uptake
shows that since
nonspecifically
find
4
vesicles
of radioactivity
the completion
internal
Fig.
or Na+.
glycophorin
it
was
we are
is unlikely
to the membrane
endpoint
4 we calculated
for
Na' due to its
the Na+ uptakes
with
control
using
pyridoxal
using
the
about
per ghost.
phosphates
60% greater
band 3 (average
The purified
per band 3 molecule.
of
than
3 pairs
that
band 3 took for
a band 3 associated
a potent
The transport inhibitor
erythrocytes. 1323
is
vesicles
of reconstitutions). sulfate
homogeneous band 3, glycophorin,
and egg lecithin.
phosphate-NaBH4,
molecules
RBC contained
phosphate-NaBH4-treated
We have observed nearly
phosphate-treated
pyridoxamine
a halftime
DISCUSSION:
cholesterol,
the
was more
we have carried
The experiment
phosphate
1.5-2.5
with with
transport
following
from pyridoxal
pyridoxamine
prepared
up sulfate
by lipid
would bind
In Fig.
to 1.5-
sulfate.
band 3 contained Vesicles
reconstitutions
filter vesicles
components
sucrose
(20).
of RBC lipid,
volumes
three
than
the fraction
We did not
slow uptake.
endpoint
into
and sucrose
same
five
and sulfate.
uptake
with
any one or two components.
that
times
the
the addition
of all
up much faster
found
through
the protected
SO4' uptake
at long
actual
of
of the
for
We also
the same for
that
the addition
S04= was taken
25-30 min.
raised
that
The addition
are representative
out.
We found
and glycophorin
6.0 pl/mg
passinq
filter
and Raftery
80-95% of the radioactivity
14C phospholipid.
containing
the Millipore
RBC lipid,
sensitive
of anion
anion
transport
to pyriin
Vol. 74, No. 4, 1977
At present vesicles the
it
with
for
sulfate
transport
transport data
the
per
molecule 0.27
are
sulfate
for
sulfates/set/band
volume
specific
interaction
may stabilize specific
through
membrane
interaction
complex --et al.
suggested (23)
activity
strengthens
in
found in the
and provides
(21) (2)
of
solution.
phos-
have used
we
Ho
to make a rough Using
0.07
of
Since
RBC per ml packed a flux
by the
study
reported.
our vesicles.
lOlo
of uptake
No complete
similar
their
com-
values
RBC and lo6
band
phosphates/set/band
Our experimental
the
other
RBC components
a nonspecific
with
the
quite
rate
3
3
result
is
3 molecule.
know whether
protected
RBC.
transport
flux
a 2 mM phosphate
the
has been
on phosphate
RBC, we calculate
We do not
tein
in an intact
Vmax and Km and assuming
molecules
port
to compare
of
and Guidotti's with
difficult
activity
and sulfate
parison
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the
saturation
phate
is
BIOCHEMICAL
band
3.
that
and reduce
da Silva
a whole
a good
the
protein
of band system
(band
was required
for
the
or through negative
charges A
3) (glycophorin) (22).
Also,
to reconstitute extract.
Gasko trans-
Our study
3 as an anion
studying
a
permeability.
and Nicolson
RBC ghost
identification
large
nonspecific
with
RBC lipid
effect
Glycophorin's
is consistent by Pinto
physical
increase
transport
interactions
pro-
between
RBC components. ACKNOWLEDGEMENTS: We are grateful to Drs. R. D. Simoni and W. H. Huestis for many helpful discussions and for the use of their equipment. Alonzo Ross is the recipient of a National Science Foundation Graduate Fellowship. This research has been supported by the National Science Foundation Grant nos. BMS 75-02381 and BMS 75-02381 AOl. It has benefited from facilities made available to Stanford University by the Advanced Research Projects Agency through the Center for Materials Research. REFERENCES 1.
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