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Erythrocyte membrane proteins and adenosine triphosphatase activity
BIOCHEMICAL
Vol. 55, No. 3,1973
AND BlOF’HYSlCAl
RESEARCH COMMUNICATIONS
ERYTHROCYTEMEMBRANEPROTEINSANDADENOSINE TRIPHOSPHATASEACTIVITY Yohtalou
Tashima
Department of Biochemistry, Saitama Medical College Moroyama, Iruma-gun, Saitama, 350-04, Japan Received
October
9,1973
Erythrocytemembranewas treatedfromoutside with crude mold prot ease, and the membrane proteins were analyzed on acrylamide-gelelectrophoresis inthepresence of sodiumdodecyl sulfate. Band-ID protein, in the region of an intermediate of Na-K-ATPase, was digested almost completely, although approximately 80% of the ATPase activity was retained by the treated membranes. It is concludedthatband-ID protein is not the Na-K-ATPase intermediate, although they co-electrophorese. SUMMARY
A number of
INTRODUCTION
investigators’-’
of acrylamide-gelelectrophoresis membranes to develop the
lipid
layer
membrane, band-III to the inner of band-III This
protein During
models
protein5*‘,
the course EC 3.6.1.3),
labeled
[y-“PJATP,
radioactive band-ID
the
from the outer
was suggested
Na-K-ATPase
The molecular
of ATPhydrolysisby apeptide
Na-K-ATPase(ATP
component
in the presence
of the
*y6.
of Na+ and Mg++ 7.
is detectedonthe
digestion
band-III
of the
region
erythrocyte
is attacked protein
used is:
Copyright 0 1973 by Academic Press, Inc. AI1 rights of reproduchbn in any form reserved.
is
one of
the
The of the
membrane With milder
selectively”,
SDS, sodium dodecyl 630
phos-
enzyme can be
and
components
molecule.
*The abbreviation
weight
to 105,000
of the ATPase and loss of structureg.
that
of the
membrane surface
to be 89,000
digestionconditions,band-ID protein it
in
polypeptide3.
Trypsin
causes inactivation
proteins
One ofthemajorproteins
of the ce113p<
phosphorylatedpeptide protein’.
results
solubilizederythrocyte
arrangementofthe
has been reported
phohydrolase with
for
extends
membrane surface
is a single
of
inSDS*
of the membrane.
protein
have used the
sulfate.
of
Vol. 55, No. 3,1973
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
;0, ‘f LOH 36,000 0’ i x 5 GluOH zz 53,ooo
‘-
-L
Origin El
A
Electrophorogram of erythrocyte membrane proteins, from Fig. 1 erythrocytes treated(A) and not treated(B) with"lytic enzyme-3". Membrane sampleswereprepared and electrophoresed in 0.1% SDS on 7.5 % acrylamide gel as described in MATERIALS AND METHODS. The gel was loaded with about 1OOug of membrane protein. Gel were scanned at 570 nm after staining. Arrows show the mobility of proteinswithknownmolecularweight; cytochrome c(Cyt.C),glutamate dehydrogenase(GluDH), lactate dehydrogenase(LDH) andphosphorylasea(Phos-a). In an attempt
to
membrane,
proteaseswere
possible
to digest
Na-K-ATPase MATERIALS
separate
the
three
plasma times
intact
the
erythrocyte
membrane.
It
significant
was
loss
activity. Crude
The crude
enzyme
and acetone
and buffy with
enzyme
containing
proteases
was purchased
MEMBRANE PREPARATION. the
from
band-IUproteinwithout
B-1,3-glucanase,"lyticenzyme-3':
fractionation
enzymes
appliedtothe
AND METHODS
(Tokyo).
the
coat
&155M
was obtained
fromKyowaHakkoCo. by ammonium
fractionation
from
Human blood
(50ml)was
were sodium
removed. phosphate
631
and
sulfate
mold. centrifuged,
The cells buffer,
and
were washed
pH7.4,
and
of
BIOCHEMICAL
Vol. 55, No. 3, 1973
0 “Lyilc
AND BIOPHYSICAL
20
40
enzyme-3”
fig/ml
60
RESEARCH COMMUNICATIONS
80
preincubatlon
mliture
Fig. 2 Effects of hydrolysis of membrane preparation on ATPase activity. Erythrocyte membrane suspension(3.2mgprotein/ml) was mixed with 60ulof "lyticenzyme-3"(0-.8Ong),and incubated for 20 minutes at 37', followed by centrifugation at 156,SOOxg for 30 minutes. The precipitate was suspended in 1 ml of 1 mM EDTA,pH 7.0. 0.1 ml of each was used for the ATPase assay. The assay method is described in the legend of Table 1.
finally
suspended
cells at
in
40mlof
the
(10ml)weretreatedwiththe"lytic 37'.
with
the
The treated phosphate
were performed isolated
protein
membranes
per
cells
were
buffer.
of
The washed
with
3 h
and washed once
and membrane
twice
mg) for
preparation
co-workers".
The
O.SmM EDTA-Tris,
solutiontogivel-2
pH 7.5,
mgofmembrane
ml. OF MEMBRANE.
an equal
of 2% SDS solution
volume
and incubated
in boiling
SDS ACRYLAMIDE-GEL
blue
The membrane
water
suspension
containing 2 minutes.
ELECTROPHORESIS.
The
Calibration
curves
weightswithdisulfidebonds was used
for
the
staining
632
was added
0.4% mercaptoethanol,
for
employed.
known molecular
brilliant
off
Dodge and his
EDTA-buffer
SOLLJBILIZATION
0sborn"was
centrifuged
Hemolysis
were washed
in the
buffer. enzyme-3"(1
by the method
and suspended
of
phosphate
method
of Weber
were obtainedwith reduced. of protein.
and
proteins Coomassie
BIOCHEMICAL
Vol. 55, No. 3,1973
Table
1.
Effects
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of Hydrolysis
Pretreated
of
Intact
Cells
on ATPases.
Activity Na-K-ATPase Mg-ATPase
with
(pmoles
Pi/mg/h)
None “lytic
enzyme-3”
0.34 0.31
0.85 0.82
None “lytic
enzyme-3”
0.46 0.32
0.73 0.88
None pronase
0.28 0.30
0.27 0.30
None trypsin
0.34 0.06
0.25 0.14
ATPase activity was assayed in a final volume of 1 ml, containing 14OmM NaCl, 14mM KCl, 5mM MgClz, O.SmM EDTA, 3mMATP, and SOmMTris buffer, pH 7.5, in the presence or the absence of 0.2mM ouabain Incubation was for 1 hr at 37“. Mg-ATPase: the activitymeasured with ouabain, Na-K-ATPase: activity withoutouabainminus activity with ouabain.
INORGANIC deproteinization assay
step,
medium
of Fiske
after
the
(Xlml
for
presence
of
of
followedby
determination
large
eliminate
was added
analysis
No turbiditywas
the
to
5% SDS solution
incubation,
and SubbaRow13.
was successful in
In order
PHOSPHATE DETERMINATION.
inorganic
amountsofprotein
to
each
by the method
observed. of
the
This
method
phosphate
even
(Tashima,
manuscript
in
preparation). PROTEIN
DETERMINATION.
was used. Pi per
The method
The specific
mg protein
per
activity
of Lowry of ATPase
and his
co-workers14
was defined
as umoles
hour.
RESULTS AND DESCUSSION
After
treatment
of intact
erythrocytemembrane
fractionwas
by SDS-acrylamide control
sample
viously1,2,5. the
treated
cells
gel gave
the
prepared,
approximately and -IV
pattern
disappeared most
633
the
and analyzed
As shown in Fig. same
Band-awasthe
"lyticenzyme-3",
solubilized,
electrophoresis.
Band-ID samples.
with
1, the
as reported almost
prominentofthe
completely
prein
new bands.
BIOCHEMICAL
Vol. 55, No. 3,1973
Its
molecular
-V were not
weight
was approximately
changed
remarkably.
distinct
bands in the
that
the
proteins
with
molecular After
region
weights
as shown inTable on K+ was not
The pretreated
than
and -V.
were
digested
1.
with
averaged
remarkably
It
no
appeared
to peptides
the “lytic
enzyme-3”,the
80% of the
The p-nitrophenylphosphatase
changed
and
band-V.
of erythrocytes activity
-II
sample yielded
bands-II
and -IV
smaller
Na-K-ATPase
Bands-I,
43,000.
between
on bands-ID
treatment
remaining
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
control
values,
activity
by the pretreatment
depending (Data
are not
shown). The average Cl8units
specific
activity
of Na-K-ATPase
per mg membrane protein.
Band- III protein
or 30% 5 of the whole membrane proteins specific
activity
stained
of the ATPase as counts
2le.
ATPase,
specific
If
all
of band-III
digestion
inthecharacteristics didnotchange
of band-III If
the effects
solution
and did
to be unrelated
the Na-K-ATPases
III protein quantity
would
would would
alter
it
constitute
is l6
of Na-K-
enzyme-3”
or of ouabain
stabilityofthe
ATPase
NaI. Thus, themajor
component
to the Na-K-ATPase. kidney
activity,
can be estimated
be responsible
protein
The “lytic
the
fromerythrocyte, specific
The
cause some change
K’concentration
(pH 8.5) or in 1.6M
appears
SOO’5T18),
not
on the gel.
were a component
protein
of Na+and
assumed to have similar (above
protein
this
15% 2
activityofkidney’5,
of the ATPase activity.
on the ATPase activity, in alkaline
of
represents
per mg band-III
less than 5.6, WhichislowerthanNa-K-ATPase or brain”
was from Cl3 to
for
and brain
as counts
that
less
permgprotein
than
l.1 %of the band-
the ATPase activity.
a negligible
band on the
are
This
SDS-acrylamide
gel electrophorogram. In
contrast
to
membrane preparationswas
the
intact foundto
cells,
digestion
cause a rapid
634
loss
of
erythrocyte
of Na-K-ATPase
BIOCHEMICAL
Vol. 55, No. 3,1973
activity, gel
as shown in Fig.
AND BIOPHYSICAL
2, and a loss
was observed of pronase
-IV
under were
inactivated
bands
similar
on the
ACKNOWLEDGMENTS
invaluable
faces
the
1).
The effects
of the"lyticenzyme-3".
strongly.
might
toproteases
(See Table
In
all
The resistance
proteases protein
conditions
to those
were attacked.
K-ATPase
her
surfaceoferythrocytes
identical
Na-K-ATPase
nonspecific
for
distinct
electrophorograms. The specificityoftheouter
and
of
RESEARCH COMMUNICATIONS
suggest outside
cases,
of the that
a very
of the
cell.
The auther
is grateful
technical
assistance.
to Miss
Trypsin mainly
ATPase small
Nobuko
bands-III activity area
to of Na-
Yoshimura
REFERENCES
Trayer H.R.,Nozaki Y.,Reynolds J.A.,Tanford C., J.Biol.Chem., 246, 4485 (1971) Bretscher M.S., J. Mol. Biol., 58, 775 (1971) : Bretscher M.S., J. Mol. Biol., 59, 351 (1971) D.M. ,Glossmann H., J. Biol. Chem., 246, 6335 (1971) 4 Neville 5 Wallach D.F.H., Biochim. Biophys. Acta, 265, 61 (1972) 6 Steck T.L.,Fairbanks G.,Wallach D.F.H., Biochem., 10, 2617 (1971) 7 Bader H.,Post R.L.,Bond G.H., Biochim. Biophys. Acta, 150, 41 (1968) G., Proc. Natl. Acad. Sci. USA, 69,1216 (1972) 8 Avruch J.,Fairbanks G.E., Proc. Natl. Acad. Sci. USA, 58, 991 (1967) 9 MarchesiV.T.,Palade 10 Avouch J.,Price H.D.,Martin D.B.,CarterJ.R., Biochim. Biophys. Acta, 1
291,
494
(1973)
11 Dodge J.T.,Mitchell C.,Hanahan D.J., Arch. Biochem. Biophys., 100, 119 (1963) 12 Weber K.,Osborn M., J. Biol. Chem., 244, 4406 (1969) J. Biol. Chem., 66, 375 (1925) 13 Fiske C.H.,SubbaRow Y., A.L.,Randall R.J., J. Biol. Chem., 14 Lowry O.H.,Rosebrough N.J.,Farr 193, 265 (1951) 15 J&-gensen P.L.,Skou J.C.,Solomonson L.P., Biochim. Biophys. Acta, 233, 381 (1971) J. Biol. Chem., 16 Kyte J., 246, 4157 (1971) T.D.,Dahl J.L.,Perdue J.F.,Hokin L.E., 17 Uesugi S.,Dulak N.C.,Dixon J.F.,Hexm J. Biol. Chem., 246, 531 (1971) 18 Nakao T.,Nakao M.,Nagai F.,Kawai K.,Fujihira Y.,Hara Y.,FujitaM., J. Biochem., 72, 1061 (1972)
635
Vol. 55, No. 3,1973
AND BlOF’HYSlCAl
RESEARCH COMMUNICATIONS
ERYTHROCYTEMEMBRANEPROTEINSANDADENOSINE TRIPHOSPHATASEACTIVITY Yohtalou
Tashima
Department of Biochemistry, Saitama Medical College Moroyama, Iruma-gun, Saitama, 350-04, Japan Received
October
9,1973
Erythrocytemembranewas treatedfromoutside with crude mold prot ease, and the membrane proteins were analyzed on acrylamide-gelelectrophoresis inthepresence of sodiumdodecyl sulfate. Band-ID protein, in the region of an intermediate of Na-K-ATPase, was digested almost completely, although approximately 80% of the ATPase activity was retained by the treated membranes. It is concludedthatband-ID protein is not the Na-K-ATPase intermediate, although they co-electrophorese. SUMMARY
A number of
INTRODUCTION
investigators’-’
of acrylamide-gelelectrophoresis membranes to develop the
lipid
layer
membrane, band-III to the inner of band-III This
protein During
models
protein5*‘,
the course EC 3.6.1.3),
labeled
[y-“PJATP,
radioactive band-ID
the
from the outer
was suggested
Na-K-ATPase
The molecular
of ATPhydrolysisby apeptide
Na-K-ATPase(ATP
component
in the presence
of the
*y6.
of Na+ and Mg++ 7.
is detectedonthe
digestion
band-III
of the
region
erythrocyte
is attacked protein
used is:
Copyright 0 1973 by Academic Press, Inc. AI1 rights of reproduchbn in any form reserved.
is
one of
the
The of the
membrane With milder
selectively”,
SDS, sodium dodecyl 630
phos-
enzyme can be
and
components
molecule.
*The abbreviation
weight
to 105,000
of the ATPase and loss of structureg.
that
of the
membrane surface
to be 89,000
digestionconditions,band-ID protein it
in
polypeptide3.
Trypsin
causes inactivation
proteins
One ofthemajorproteins
of the ce113p<
phosphorylatedpeptide protein’.
results
solubilizederythrocyte
arrangementofthe
has been reported
phohydrolase with
for
extends
membrane surface
is a single
of
inSDS*
of the membrane.
protein
have used the
sulfate.
of
Vol. 55, No. 3,1973
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
;0, ‘f LOH 36,000 0’ i x 5 GluOH zz 53,ooo
‘-
-L
Origin El
A
Electrophorogram of erythrocyte membrane proteins, from Fig. 1 erythrocytes treated(A) and not treated(B) with"lytic enzyme-3". Membrane sampleswereprepared and electrophoresed in 0.1% SDS on 7.5 % acrylamide gel as described in MATERIALS AND METHODS. The gel was loaded with about 1OOug of membrane protein. Gel were scanned at 570 nm after staining. Arrows show the mobility of proteinswithknownmolecularweight; cytochrome c(Cyt.C),glutamate dehydrogenase(GluDH), lactate dehydrogenase(LDH) andphosphorylasea(Phos-a). In an attempt
to
membrane,
proteaseswere
possible
to digest
Na-K-ATPase MATERIALS
separate
the
three
plasma times
intact
the
erythrocyte
membrane.
It
significant
was
loss
activity. Crude
The crude
enzyme
and acetone
and buffy with
enzyme
containing
proteases
was purchased
MEMBRANE PREPARATION. the
from
band-IUproteinwithout
B-1,3-glucanase,"lyticenzyme-3':
fractionation
enzymes
appliedtothe
AND METHODS
(Tokyo).
the
coat
&155M
was obtained
fromKyowaHakkoCo. by ammonium
fractionation
from
Human blood
(50ml)was
were sodium
removed. phosphate
631
and
sulfate
mold. centrifuged,
The cells buffer,
and
were washed
pH7.4,
and
of
BIOCHEMICAL
Vol. 55, No. 3, 1973
0 “Lyilc
AND BIOPHYSICAL
20
40
enzyme-3”
fig/ml
60
RESEARCH COMMUNICATIONS
80
preincubatlon
mliture
Fig. 2 Effects of hydrolysis of membrane preparation on ATPase activity. Erythrocyte membrane suspension(3.2mgprotein/ml) was mixed with 60ulof "lyticenzyme-3"(0-.8Ong),and incubated for 20 minutes at 37', followed by centrifugation at 156,SOOxg for 30 minutes. The precipitate was suspended in 1 ml of 1 mM EDTA,pH 7.0. 0.1 ml of each was used for the ATPase assay. The assay method is described in the legend of Table 1.
finally
suspended
cells at
in
40mlof
the
(10ml)weretreatedwiththe"lytic 37'.
with
the
The treated phosphate
were performed isolated
protein
membranes
per
cells
were
buffer.
of
The washed
with
3 h
and washed once
and membrane
twice
mg) for
preparation
co-workers".
The
O.SmM EDTA-Tris,
solutiontogivel-2
pH 7.5,
mgofmembrane
ml. OF MEMBRANE.
an equal
of 2% SDS solution
volume
and incubated
in boiling
SDS ACRYLAMIDE-GEL
blue
The membrane
water
suspension
containing 2 minutes.
ELECTROPHORESIS.
The
Calibration
curves
weightswithdisulfidebonds was used
for
the
staining
632
was added
0.4% mercaptoethanol,
for
employed.
known molecular
brilliant
off
Dodge and his
EDTA-buffer
SOLLJBILIZATION
0sborn"was
centrifuged
Hemolysis
were washed
in the
buffer. enzyme-3"(1
by the method
and suspended
of
phosphate
method
of Weber
were obtainedwith reduced. of protein.
and
proteins Coomassie
BIOCHEMICAL
Vol. 55, No. 3,1973
Table
1.
Effects
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of Hydrolysis
Pretreated
of
Intact
Cells
on ATPases.
Activity Na-K-ATPase Mg-ATPase
with
(pmoles
Pi/mg/h)
None “lytic
enzyme-3”
0.34 0.31
0.85 0.82
None “lytic
enzyme-3”
0.46 0.32
0.73 0.88
None pronase
0.28 0.30
0.27 0.30
None trypsin
0.34 0.06
0.25 0.14
ATPase activity was assayed in a final volume of 1 ml, containing 14OmM NaCl, 14mM KCl, 5mM MgClz, O.SmM EDTA, 3mMATP, and SOmMTris buffer, pH 7.5, in the presence or the absence of 0.2mM ouabain Incubation was for 1 hr at 37“. Mg-ATPase: the activitymeasured with ouabain, Na-K-ATPase: activity withoutouabainminus activity with ouabain.
INORGANIC deproteinization assay
step,
medium
of Fiske
after
the
(Xlml
for
presence
of
of
followedby
determination
large
eliminate
was added
analysis
No turbiditywas
the
to
5% SDS solution
incubation,
and SubbaRow13.
was successful in
In order
PHOSPHATE DETERMINATION.
inorganic
amountsofprotein
to
each
by the method
observed. of
the
This
method
phosphate
even
(Tashima,
manuscript
in
preparation). PROTEIN
DETERMINATION.
was used. Pi per
The method
The specific
mg protein
per
activity
of Lowry of ATPase
and his
co-workers14
was defined
as umoles
hour.
RESULTS AND DESCUSSION
After
treatment
of intact
erythrocytemembrane
fractionwas
by SDS-acrylamide control
sample
viously1,2,5. the
treated
cells
gel gave
the
prepared,
approximately and -IV
pattern
disappeared most
633
the
and analyzed
As shown in Fig. same
Band-awasthe
"lyticenzyme-3",
solubilized,
electrophoresis.
Band-ID samples.
with
1, the
as reported almost
prominentofthe
completely
prein
new bands.
BIOCHEMICAL
Vol. 55, No. 3,1973
Its
molecular
-V were not
weight
was approximately
changed
remarkably.
distinct
bands in the
that
the
proteins
with
molecular After
region
weights
as shown inTable on K+ was not
The pretreated
than
and -V.
were
digested
1.
with
averaged
remarkably
It
no
appeared
to peptides
the “lytic
enzyme-3”,the
80% of the
The p-nitrophenylphosphatase
changed
and
band-V.
of erythrocytes activity
-II
sample yielded
bands-II
and -IV
smaller
Na-K-ATPase
Bands-I,
43,000.
between
on bands-ID
treatment
remaining
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
control
values,
activity
by the pretreatment
depending (Data
are not
shown). The average Cl8units
specific
activity
of Na-K-ATPase
per mg membrane protein.
Band- III protein
or 30% 5 of the whole membrane proteins specific
activity
stained
of the ATPase as counts
2le.
ATPase,
specific
If
all
of band-III
digestion
inthecharacteristics didnotchange
of band-III If
the effects
solution
and did
to be unrelated
the Na-K-ATPases
III protein quantity
would
would would
alter
it
constitute
is l6
of Na-K-
enzyme-3”
or of ouabain
stabilityofthe
ATPase
NaI. Thus, themajor
component
to the Na-K-ATPase. kidney
activity,
can be estimated
be responsible
protein
The “lytic
the
fromerythrocyte, specific
The
cause some change
K’concentration
(pH 8.5) or in 1.6M
appears
SOO’5T18),
not
on the gel.
were a component
protein
of Na+and
assumed to have similar (above
protein
this
15% 2
activityofkidney’5,
of the ATPase activity.
on the ATPase activity, in alkaline
of
represents
per mg band-III
less than 5.6, WhichislowerthanNa-K-ATPase or brain”
was from Cl3 to
for
and brain
as counts
that
less
permgprotein
than
l.1 %of the band-
the ATPase activity.
a negligible
band on the
are
This
SDS-acrylamide
gel electrophorogram. In
contrast
to
membrane preparationswas
the
intact foundto
cells,
digestion
cause a rapid
634
loss
of
erythrocyte
of Na-K-ATPase
BIOCHEMICAL
Vol. 55, No. 3,1973
activity, gel
as shown in Fig.
AND BIOPHYSICAL
2, and a loss
was observed of pronase
-IV
under were
inactivated
bands
similar
on the
ACKNOWLEDGMENTS
invaluable
faces
the
1).
The effects
of the"lyticenzyme-3".
strongly.
might
toproteases
(See Table
In
all
The resistance
proteases protein
conditions
to those
were attacked.
K-ATPase
her
surfaceoferythrocytes
identical
Na-K-ATPase
nonspecific
for
distinct
electrophorograms. The specificityoftheouter
and
of
RESEARCH COMMUNICATIONS
suggest outside
cases,
of the that
a very
of the
cell.
The auther
is grateful
technical
assistance.
to Miss
Trypsin mainly
ATPase small
Nobuko
bands-III activity area
to of Na-
Yoshimura
REFERENCES
Trayer H.R.,Nozaki Y.,Reynolds J.A.,Tanford C., J.Biol.Chem., 246, 4485 (1971) Bretscher M.S., J. Mol. Biol., 58, 775 (1971) : Bretscher M.S., J. Mol. Biol., 59, 351 (1971) D.M. ,Glossmann H., J. Biol. Chem., 246, 6335 (1971) 4 Neville 5 Wallach D.F.H., Biochim. Biophys. Acta, 265, 61 (1972) 6 Steck T.L.,Fairbanks G.,Wallach D.F.H., Biochem., 10, 2617 (1971) 7 Bader H.,Post R.L.,Bond G.H., Biochim. Biophys. Acta, 150, 41 (1968) G., Proc. Natl. Acad. Sci. USA, 69,1216 (1972) 8 Avruch J.,Fairbanks G.E., Proc. Natl. Acad. Sci. USA, 58, 991 (1967) 9 MarchesiV.T.,Palade 10 Avouch J.,Price H.D.,Martin D.B.,CarterJ.R., Biochim. Biophys. Acta, 1
291,
494
(1973)
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