- Email: [email protected]
H+-exchanger by an antagonist of muscarinic acetylcholine receptors
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 157, No. 3, 1988
Pages 92]-929
December 30, 1988
INHIBITION BY
AN
AND
LABELING
ANTAGONIST
OF
OF
THE
RAT
MUSCARINIC
T. Friedrich*
Na÷/H+-EXCHANGER
RENAL
ACETYLCHOLINE
RECEPTORS
and G. Burckhardt**
*Department of Medical Chemistry,
Kyoto University Faculty of Medicine,
Kyoto 606, Japan **Max-Planck-Institut
f~r Biophysik,
D-6000 Frankfurt 70, FRG
Received November 4, 1988
A covalently binding label for muscarinic acetylcholine receptors, propylbenzilylcholine mustard (PrBCM), irreversibly inhibits the Na+/H + exchanger in rat renal brush-border membrane vesicles. Substrates of the antiporter, Na + and Li +, as well as inhibitors, amiloride, 5-(N-ethyl-N-isopropyl)amiloride (EIPA) and propranolol, protect the antiporter from inactivation by PrBCM. With [3H]PrBCM a band with an app. M r of 65 kDa is predominantly labeled. Amiloride protects this band from labeling with [3H]PrBCM and [14C]N,N'-dicyclohexylcarbodiimide (DCCD) proving its identity with the renal Na+/ H + exchanger. Our data reveal a specific interaction of PrBCM with the Na+/H + exchanger and suggest structural relations between antiporter and receptors. © 1988 Academic
Press,
A comparison ceptors
of amino acid sequences revealed
(adrenoceptors),
driven H+-pump, have arisen proteins
Inc.
muscarinic
rhodopsin,
belong
from a common
acetylcholine
to a family
ancestral
receptor
are sites for glycosylation,
tic residues
in helix
receptors,
of membrane gene.
Common
for signal
ular masses in SDS polyacrylamide
re-
and the light-
proteins
that may
features
of these
seven membrane-spanning
II and helix III as putative
interaction with G-proteins
B-adrenoceptors
that e- and B-adrenergic
helices,
aspar-
ligand binding sites, and
transduction
(I). The apparent molec-
gels of the fully glycosylated e- (2,3) and
(4-6) and of the muscarinic
acetylcholine
receptor
(7) range
between 62 and 70 kDa. Recently, and
amiloride
~-adrenoceptors
cells
has
from
shown
to decrease
vascular
smooth
(8,9), and to the purified e2-adrenoceptor
sides blocking epithelial in
been
liver,
a variety
of
cells
(11,12). The action e2-adrenoceptor are closely relation
Na + channels,
including
of amiloride
amiloride
proximal as well
has led to the speculation
related,
are data
if not
showing
identical
tubule
921
of ligands
to e-
platelets,
renal
from porcine brain inhibits
(10). Be-
Na+/H + exchangers
cells of mammalian
kidneys
as of Na + and H + with the purified that receptor and Na+/H + exchanger
proteins
an inhibition
binding muscles,
(10).
In
support
of Na+/H + exchanger
of
such
a
by an ~2 adren-
0006-291X/88 $1.50 Copyright © 1988 by Academic Press, ~c. All r~h~ of reproduction in any form reserved.
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ergic agonist,
clonidine
(13),
and alprenolol
(14). Moreover,
and by B-adrenergic
antagonists,
the rat renal Na+/H + exchanger can be specifi-
cally labeled with a photolabile ligand for S-adrenoceptors, pindolol-diazirine acetylcholine
(14).
receptors
propranolol
Finally,
similar
to
[125I]iodocyano-
adrenoceptors
and
muscarinic
the rat renal Na+/H + exchanger has an app. molecular
mass of 65 kDa (15) and is glycosylated (Friedrich, unpublished). In
this
contribution
we wish
to
demonstrate
that
the
renal
Na+/H + ex-
changer reacts with propylbenzilylcholine mustard (PrBCM), a covalently binding ligand for the muscarinic
acetylcholine
receptor
changer and several members of the G protein-coupled number of ligands
suggesting
structural
relations.
(16). Thus, receptor
Na+/H + ex-
family
share a
Part of the results have
been published in abstract form (14).
METHODS
Vesicle preparation. Renal brush-border membrane vesicles from male Wistar rats (180 g) were prepared according to Biber et al. (17) by a Mg2+-precipi tation method. The vesicles were taken up in 100 mM TMACI, 50 mM KCl, 5 mM Hepes/Tris, pH 7.0, and stored in liquid nitrogen at a protein concentration of 10 mg/ml. Protein was determined according to Bradford (18) using bovine serum albumin as a standard. Basolateral membrane vesicles were prepared by a Percoll density gradient separation technique (19).
Irreversible inhibition of Na+/H + exchange with PrBCM and DCCD. Brush-border vesicles were rapidly thawed and diluted to a final protein concentration of 3.33 mg/ml. The vesicle suspension was preincubated with buffers and inhibitors for 30 minutes and then PrBCM or DCCD were added from ethanol stocks for further 30 minutes. The reaction was stopped by dilution of the vesicle suspension into 35 ml of 100 mM NaCI, 50 mM KCI, 5mM Hepes/Tris, pH 7.0, followed by centrifugation in a Sorvall SS34 rotor for 20 min at 20,000 rpm. The pellet was resuspended in the same buffer used to stop the reaction.
Determination of Na+/H + exchanger activity. Brush-border membrane vesicles (25 ~g protein) loaded with 100 mM NaCI, 50 mM KCI, 5 mM Hepes/Tris, pH 7.0, were diluted into I ml of 100 mM TMACI, 50 mM KCI, 5 mM Hepes/Tris, pH 7.0, containing 2.5 ~M valinomycin (to clamp the membrane potential to zero) and 6 ~M acridine orange (to monitor intravesicular acidification). Na + efflux via the Na+/H + exchanger acidifies the vesicle interior causing intravesicular accumulation of acridine orange and a decrease in its absorption. The absorption decrease was monitored in a Shimadzu UV 300 dual wavelength spectrophotometer (Kyoto, Japan) at 492 nm using 540 nm as reference wavelength. Na+/H + exchanger activity is expressed as rates of absorption decrease recorded within the first 10 seconds.
Labeling of membrane proteins with [3H]PrBCM and [14C]DCCD. Aliquots of brush-border membrane vesicles and basolateral membrane vesicles (1 mg of protein each) were labeled with [3H]PrBCM (125 nmol = 0.42 ~ o i / i ) or [14C]DCCD (2.5 nmol = 0.0083 mmol/l) at a protein concentration of 3.33 mg/ml for 30 min at room temperature in the presence or absence of inhibitors as indicated in the legends of the figures. After labeling the vesicles were washed as indicated above and the pellet was left on ice for further 3 hours. Then, the proteins were dissolved by shaking for 30 min in O'Farrell's sample buffer (20). Portions containing 0.5 mg dissolved proteins were then directly applied to SDS-polyacrylamide gel electrophoresis.
922
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and determination of the radioactivity. SDS-PAGE was performed in glas rods. Total acrylamide concentration was 8.5%. Molecular mass standards were phosphorylase b (94 kDa), albumin (67 kDa), ovalbumin (43 kDa) and carboanhydrase (30 kDa). The apparent molecular mass of labeled proteins was determined from plots of ig M r vs migration distance which were linear for the applied marker proteins (r 2 >0.98). The gels were fixed with 12.5% trichloroacetic acid, stained with Coomassie Brilliant Blue R 250, and destained in 250 ml ethanol, 50 ml acetic acid, 700 ml water. After scanning the gels were cut into 2 m m slices and treated with 0.5 ml Protosol overnight. Thereafter, scintillation fluid was added to determine the radioactivity contained in each sample. Materials. All chemicals were of analytical grade and obtained from commercial sources. PrBCM and [3H]PrBCM (60 Ci/mmol = 2220 GBq/mmol) were obtained from NEN. DCCD was obtained from Aldrich, [14C]DCCD (54 Ci/mol = 2 GBq/mol from Amersham. Amiloride and derivatives were synthetized as described by Cragoe et al. (21). Protosol was obtained from NEN. Before use, 75 ml water was added to 500 ml Protosol. RESULTS
AND
DISCUSSION
In order to test whether PrBCM interacts
with the renal Na+/H + exchanger,
brush-border membrane vesicles were preincubated without or with 0.5 mM PrBCM for 30 min at room temperature. Then, unreacted PrBCM was removed by washing and the vesicles were pending Na+-loaded
loaded with Na +. Na+/H + exchange was initiated by sus-
vesicles
in a Na+-free
as an indicator of intravesicular
buffer
the decrease of acridine orange absorbance cles as compared
to controls
containing
acidification.
Figure
acridine
I, left,
orange
shows
is slower in PrBCM-treated
(pretreatment without PrBCM).
This
that vesi-
result dem-
onstrates the partial irreversible inhibition of the Na+/H + exchanger following treatment with PrBCM. The degree of irreversible (Na+/H +
exchange
is
faster)
presence of amiloride Figure
I, right,
when
vesicles
were
exhibits
the dependence
I mM PrPCM is required for half-maximal decreases
gesting Na+/H +
the inhibition
a competition exchanger.
carboxyl
with
PrBCM
in
the
on PrBCM concentration of irre-
These
group reagent,
At 30 min preincubation time,
inhibition
of the antiporter.
at 0.5 mM PrBCM more
for a common results
or
are
comparable
to
in
binding
data
twofold
higher
sites
obtained
at the
with
the
(DCCD), which inactiv-
an amiloride-protectable
approximately
Amilo-
than at I mM PrBCM sug-
closely related
N,N'-dicyclohexylcarbodiimide
ates the Na+/H + exchanger compared to DCCD,
treated
is decreased
(Figure I, left, middle trace).
versible inactivation of the Na+/H + exchanger.
ride
inhibition
manner
(15,22,23).
As
of PrBCM
are
concentrations
required to produce an equivalent degree of irreversible inhibition. Besides
amiloride
(0.5 mM,
ethyl-N-isoproyl)amiloride renal
Na+/H +
exchanger
the substrates
adrenergic
antagonist,
1) also the high-affinity
analog 5-(N-
(EIPA, 0.05 mM) affords some protection of the rat
from
Similarly,
Figure
irreversible
of the Na+/H +
propranolol,
inactivation
exchanger,
protect
the
by PrBCM
Na + and Li +,
antiporter
(Table
I).
and the B-
partially.
The
same compounds were effective in protecting the Na+/H + exchanger from inactivation
by DCCD
(14,15).
These results 923
suggest
that,
similar
to DCCD,
PrBCM
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
=
5
X I==
<~ ¢~
-0,02
v
~> 3
with
40 ,--
-0,04
; 0.5raM
30'
PIBCM
without
0 4,J
~
L.
g2 e-
30';0.5mM PIBCM + 0.5 mM Amiloride
AMILORIDE
e~ L) x
o -0,06
+=1
e~ • e o n t zol
+ Z
-0,08 0
o:s
1
Time
(mln)
i
PrBCM concentration
(ml)
Figure I . Irreversible inhibition of Na+/H + exchange by PrBCM and protection by amiloride. Left: Rat renal b r u s h - b o r d e r membrane vesicles were incubated without (control) or with 0.5 mM PrBCM for 30 min in the absence or presence of 0.5 mM amiloride. Thereafter, v e s i c l e s were washed, loaded with Na +, and suspended in a N a + - f r e e b u f f e r c o n t a i n i n g acridine orange. The absorption loss of acridine orange was measured at 492 nm as a function of time. Right: Vesicles were incubated for 30 min with different concentrations of P r B C M in the presence or absence of 0.5 mM amiloride. The initial rate of absorption loss is plotted as a function of the PrBCM concentration.
Table I Protection of Na+/H + exchange from irreversible inhibition by PrBCM
PrBCM
(mM)
cation
(mM)
inhibitor (mM)
activity
(AABS/min-mg)
0
TMA +
(100)
-
5.11
0.5
TMA +
(100)
-
3.09 + 0.1
+ 0.35
p
-
<0.001"
0.5
Na +
(100)
-
3.77 + 0.2
<0.001"*
0.5
Li +
(100)
-
3.94 + 0.3
<0.001"*
0.5
TMA +
(100)
propranolol
(0.5)
3.86 + 0.23
<0.001.*
0.5
TMA +
(100)
(0.05)
3.53 + 0.14
<0.001.*
EIPA
Rat renal b r u s h - b o r d e r membrane vesicles were incubated with 0.5 mM PrBCM for 30 min in the presence of the indicated cations and inhibitors. After w a s h i n g and Na + loading of the vesicles, Na+/H + e x c h a n g e r activity was d e t e r m i n e d by m e a s u r i n g the rate of acridine orange absorbance decrease, AABS/min.mg protein. The table shows means + s t a n d a r d deviations from 5 determinations. TMA +, tetramethylammonium; *, s i g n i f i c a n t l y d i f f e r e n t from control (0 mM PrBCM); **, s i g n i f i c a n t l y d i f f e r e n t from the value obtained w i t h 0.5 mM PrBCM, 100 mM TMA + (no inhibitors).
924
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
interacts with the antiporter directly
at, or close
to, the cation and inhi-
bitor (amiloride) binding site. Since PrBCM and DCCD are hydrophobic, sume
that both reagents
amino
acid
residues
in
inactivate
we as-
the Na+/H + exchanger by binding to acidic
a hydrophobic
molecular
environment.
Interestingly,
also in the muscarinic acetylcholine receptor PrBCM and DCCD interact with a carboxylic highly
group
embedded
deeply
conserved
aspartic
acid
located
within
the
in
the molecule
thought
hydrophobic,
(16).
to be involved
membrane
spanning
In
adrenoceptors
a
in ligand binding is
helices
(I).
Comparable
reactivity towards hydrophobic reagents
and overlapping
ligand specificities
suggest
protein-coupled
receptors
that
Na+/H +
exchanger
and
G
may
share
molecular properties within their ligand binding sites. After
having
demonstrated
a
covalent,
PrBCM to the rat renal Na+/H + exchanger, proteins
are
labeled
with
[3H]PrBCM.
amiloride-protectable
To
this
renal brush-border membrane vesicles with separated
thereafter
panel, open symbols)
the
membrane
binding
of
we next investigated which membrane end we
either
polyeptides
incubated aliquots of
[3H]PrBCM or
by
SDS-PAGE.
[14C]DCCD and Figure
2
(top
shows that [3H]PrBCM is mainly incorporated into a broad
band with an apparent molecular mass of 65 kDa. The same band is labeled with [14C]DCCD (closed symbols). other protein bands
[14C]DCCD, however, is less specific as it label~
as well
(Figure I, and ref. 15). Figure 1, bottom panel,
reveals that amiloride decreased the incorporation of [3H]PrBCM as well as of [14C]DCCD into the 65 kDa band. the
labeling
previous
of
notion
this
band
Sodium,
(data
not
EIPA and propranolol
shown)
which
is
also decreased
compatible
with
our
(15) that a membrane protein with an apparent mass of 65 kDa
is identical to the renal Na+/H + exchanger. As a control we also labeled basolateral membrane vesicles with [3H]PrBCM. These membrane vesicles proximal tubule cells opposed
to
the
originate
from the contraluminal
and are not equipped with
brush-border
membrane,
they
(blood)
side of the
a Na+/H + exchanger
possess
~-
and
(24). As
B-adrenoceptors
(25-28). Figure 3, top panel, shows that after affinity labeling of rat renal basolateral membranes
[3H]PrBCM is incorporated mainly into two bands corres-
ponding to apparent molecular masses
of 89 kDa and 67 kDa. Amiloride depres-
ses strongly the labeling of the 67 kDa band, but leaves the incorporation of radioactivity into the 89 kDa band virtually unchanged. [3H]PrBCM branes cross
labeling patterns of brush-border
(Figure
A comparison
of the
2) and basolateral
mem-
(Figure 3) reveals a clearly different pattern. This finding rules out contaminations
of
membranes
and
proves
that
the
labeled
originates from the brush-border membranes whereas the labeled
65
kDa band
89 kDa and 67
kDa bands are constituents of the basolateral membrane. The
[3H]PrBCM-labeled
89 kDa band in basolateral membranes may be identi-
cal to a band of similar mass labeled previously with
[14C]DCCD and thought
to be identical to the a-subunit of the (Na++K+)-ATPase
(15). Labeling of the
925
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
94000 67000
8O0O
43~
14C]DCCD 500
-
Aml lorlde
[3HI PrBCM 6000 2
- 200
C~ -
bOO0
e~
-I00
2000
0
°
~
8000
wlth
[
300
•200
8 -
4000
-100 2000
t
i
0
i
i
2 4 Mlgratlon
i
i
6 8 Dlstance
0
I0 (cm)
12
Figure 2. Double-labeling of renal brush-border membrane proteins with [3H]PrBCM and [14C]DCCD and protection by amiloride. I mg vesicles were incubated with 0.125 nmol [3H]PrBCM and 2.5 nmol [14C]DCCD for 30 min in the absence (top panel)
or presence
of
0.5 mM
amiloride
(bottom panel).
After washing,
membrane proteins were separated by SDS-gelelectrophoresis. The gels were cut into 2 mm slices and radioactivity was determined. Closed symbols and left ordinate, incorporation of [3H]PrBCM; open symbols, incorporation of [14C]DCCD.
purified
~-subunit
with
PrBCM
been
tested
ments
are n e c e s s a r y
PrBCM-labeled The
to be
that
of
similarly when
the
irine
to d e f i n i t e l y
the
labeled
clarified.
the
Na+/H +
small,
Its
branes
of the prove
kDa
apparent
exchanger
or d i s p r o v e
the e - s u b u n i t 67
band
of the in
molecular
labeled
photolabile
S-adrenergic
antagonist,
is not i d e n t i c a l
identical
was used
to
the
we
to
feel
label that
exchanger.
926
Thus,
more
nor
has
experi-
of the [3H]-
(Na++K+)-ATPase.
is
membranes
slightly membranes
in m o l e c u l a r
renal the
to the 65 kDa band Na+/H +
demonstrated
the identity
in b r u s h - b o r d e r
difference
Therefore,
been
basolateral mass
reproducible,
(14).
not
(Na++K+)-ATPase.
but
(ICYP-diazirine),
membranes
not
of
has h i t h e r t o
an i n h i b i t o r
89 kDa band with
nature
also
as
[3H]PrBCM
remains
higher
than
(65 kDa).
masses
was
A
found
[125I]iodocyanopindolol-diazbrush-border
67 k D a
band
in b r u s h - b o r d e r Different
and
basolateral
in b a s o l a t e r a l membranes
amount
of
mem-
and thus
incorporated
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
,
i
i
94000
67000
, 43000
without
,C
~ ~
10~-
with Amllorlde
51100-
0
~
,
0
t
2 Rlgratlo
l
i
l
6
8
10
12
(cm)
Distance
Figure 3. Labeling of renal basolateral membrane proteins with [3H]PrBCM and protection by amiloride. I mg vesicles were labeled with 0.125 nmol [3H]PrBCM for 30 min. They were further treated as described in the legend to Figure 2.
radioactivity labeling
of
amiloride,
and
different
the
67
kDa
to
be
reflects
whether
and
greater
specific
labeling
[3H]PrBCM
as
67 kDa
to compare labels
and
specificity
radioactivity
the
reflect band
[14C]DCCD,
for
the
rat
label
than
[14C]DCCD.
does
of [14C]DCCD,
the
much
(Figure
I):
amounts
to approximately
The
are found with useful
maximal
incorporation 300 cpm/gel
[3H]PrBCM. for
Thereby,
further
(the
0.5
mM
also suggest that
distinct
proteins.
It
membranes
(25-28).
Na+/H + exchanger.
renal In
Na+/H +
addition,
less counts
of
[14C]DCCD whereas
exchanger due
with
to the low
are incorporated
into close
[125I]ICYP-diazirine and
Both,
into
(not shown) and [3H]PrBCM
slice,
characterization
by
[125I]iodocyanopindolol-di-
renal
[3H]PrBCM,
amiloride
depressed
in basolateral
the 65 kDa band as compared to [125I]ICYP-diazirine
prove
towards
completely
located in this membrane
it is worthwhile
[125I]ICYP-diazirine much
of
nearly
67 kDa and 65 kDa bands
established
the adrenoceptors
Finally azirine
being
that of the 65 kDa band only partially reduced)
both [3H]PrBCM-labeled needs
sensitivity
band
the
65
kDa
band
to 5000 cpm/slice
and [3H]PrBCM should
purification
of
the
renal
Na+/H + exchanger. Taken choline
together, receptor,
our
data
rat renal Na+/H + exchanger ing site,
and specifically
an inhibitor
show
that
a ligand
propylbenzilylcholine
of the
Na+/H +
probably labels
mustard
close
for
the
(PrBCM),
to or directly
the related membrane
exchanger,
amiloride,
927
with
muscarinic interacts
acetylwith
the
at the cation bindprotein.
Reaction
adrenoceptors
of
(8-I 0)
Vol. 157, No. 3, 1988
and,
conversely,
acetylcholine structural
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of ligands
receptor
features
of
with
the
antiporter
the
ligand
binding
Na+/H + exchanger
has
smilarly
to
receptors
Based
the
on
the
number
for adrenoceptors
a comparable
of
molecular
(Friedrich,
similarities
exchanger belongs to the family
Determination
Na+/H + exchanger
will
of
the
provide
(this
be
(15)
amino
basis
the
and
speculated
acid
common
rat
renal
is glycosylated
Burckhardt:
are comparable
primary the
indicates
Moreover,
mass
Sablotni,
it may
study)
sites.
of G protein-coupled
ly, parts of the molecular architecture proteins.
(13,14) and for the muscarinic
unpublished).
that
receptors.
the Na+/H + Alternative-
in otherwise unrelated sequence
to distinguish
of
between
the these
renal pos-
sibilities.
ACKNOWLEDGEMENTS
The
authors
thank
Drs.
Y. Mori
and K.
J. Ullrich
for valuable
This work was supported by the Deutsche Forschungsgemeinschaft
discussions.
(SFB169/A2).
REFERENCES
I. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16.
17. 18. 19. 20.
Dohlman, H. G., Caron, M. G., and Lefkovitz, R. (1987) Biochemistry 26, 2657-2664 Repaske, M. G., Nunnari, J. M., and Limbird, L. E. (1987) J. Biol. Chem. 262, 12381-12386 Convents, A., DeBaker, J.-P., Van Driesche, E., Convents, D., Beekmans, S., and Vauquelin, G. (1988) FEBS Letters 234, 480-484 Bahout, S. W., and Malbon, C. C. (1987) Biochem. J. 248, 557-566 Kaveri, S. V., Cervantes-Olivier, P., Delavier-Klutchko, C. and Strosberg, A. (1987) Eur. J. Biochem. 167, 449-456 Stiles, G. L. (1985) Arch. Biochem. Biophys. 237, 65-71 Haga, K., and Haga, T. (1985) J. Biol. Chem. 260, 7927-7935 Hiussinger, D., Brodde, O.-E., and Starke, K. (1987) Biochem. Pharmacol. 36, 3509-3515 Howard, M. J., Mullen, M. D., and Insel, P. A, (1987) Am. J. Physiol. 253, F21-F25 Nunnari, J. M., Repaske, M. G., Brandon, S., Cragoe, E. J. Jr., and Limbird, L. E. (1987) J. Biol. Chem. 262, 12387-12392 Frelin, C., Vigne, P., Barbry, P., and Lazdunski, M. (1987) Kidney Int. 32, 785-793 Aronson, P. S. (1983) Am. J. Physiol. 245, F647-F659 Ganapathy, M. E., Leibach, F. H., Mahesh, V. B., Devoe, L. D., and Ganapathy, V. (1986) Biochem. Pharmacol. 35, 3989-3994 Friedrich, T., and Burckhardt, G. (1988) Biol. Chem. Hoppe-Seyler 369, 817 (Abstract) Friedrich, T., Sablotni, J., and Burckhardt, G. (1986) J. Membrane Biol. 94, 253-266 Wheatley, M., Hulme, E. C., Birdsall, N. J. M., Curtis, C. A. M., Eveleigh, P., Pedder, E. K., and Poyer, D. (1988) TIPS February Suppl. 19-24 Biber, J., Stieger, B., Haase, W., and Murer, H. (1981) Biochim. Biophys. Acta 647, 169-176 Bradford, M. M. (1976) Anal. Biochem. 72, 248-254 L6w, I., Friedrich, T., and Burckhardt, G. (1984) Am. J. Physiol. 246, F334-F342 O'Farrell, P. H. D. (1975) J. Biol. Chem. 250, 4007-4021
928
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
21. Cragoe, E. J. Jr., Woltersdorf, O. W., Bicking, J. B., Kwong, S. F., and Jones, J. H. (1967) J. Med. Chem. 10, 66-75 22. Igarashi, P., and Aronson, P. S. (1987) J. Biol. Chem. 262, 860-868 23. Kinsella, J. L., Wehrle, J., Wilkins, N., and Sacktor, B. (1987) J. Biol. Chem. 262, 7092-7097 24. Sabolic, I., and Burckhardt, G. (1983) Biochim. Biophys. Acta 734, 210220 25. Matsushima, Y., Akanabe, S., and Ito, K. (1986) Biochem. Pharamacol. 35, 2593-2600 26. Matsushima, Y., Akabane, S., Kawamura, M., and Ito, K. (1987) Japan. J. Pharmacol. 45, 284-287 27. Sundaresan, P. R., Fortin, T. L., and Kelvic, S. L. (1987) Am. J. Physiol. 253, F848-F856 28. Sundaresan, P. R., Guarnaccia, M. M., and Izzo, J. L. Jr. (1987) Am. J. Physiol. 253, F1063-FI067
929
Vol. 157, No. 3, 1988
Pages 92]-929
December 30, 1988
INHIBITION BY
AN
AND
LABELING
ANTAGONIST
OF
OF
THE
RAT
MUSCARINIC
T. Friedrich*
Na÷/H+-EXCHANGER
RENAL
ACETYLCHOLINE
RECEPTORS
and G. Burckhardt**
*Department of Medical Chemistry,
Kyoto University Faculty of Medicine,
Kyoto 606, Japan **Max-Planck-Institut
f~r Biophysik,
D-6000 Frankfurt 70, FRG
Received November 4, 1988
A covalently binding label for muscarinic acetylcholine receptors, propylbenzilylcholine mustard (PrBCM), irreversibly inhibits the Na+/H + exchanger in rat renal brush-border membrane vesicles. Substrates of the antiporter, Na + and Li +, as well as inhibitors, amiloride, 5-(N-ethyl-N-isopropyl)amiloride (EIPA) and propranolol, protect the antiporter from inactivation by PrBCM. With [3H]PrBCM a band with an app. M r of 65 kDa is predominantly labeled. Amiloride protects this band from labeling with [3H]PrBCM and [14C]N,N'-dicyclohexylcarbodiimide (DCCD) proving its identity with the renal Na+/ H + exchanger. Our data reveal a specific interaction of PrBCM with the Na+/H + exchanger and suggest structural relations between antiporter and receptors. © 1988 Academic
Press,
A comparison ceptors
of amino acid sequences revealed
(adrenoceptors),
driven H+-pump, have arisen proteins
Inc.
muscarinic
rhodopsin,
belong
from a common
acetylcholine
to a family
ancestral
receptor
are sites for glycosylation,
tic residues
in helix
receptors,
of membrane gene.
Common
for signal
ular masses in SDS polyacrylamide
re-
and the light-
proteins
that may
features
of these
seven membrane-spanning
II and helix III as putative
interaction with G-proteins
B-adrenoceptors
that e- and B-adrenergic
helices,
aspar-
ligand binding sites, and
transduction
(I). The apparent molec-
gels of the fully glycosylated e- (2,3) and
(4-6) and of the muscarinic
acetylcholine
receptor
(7) range
between 62 and 70 kDa. Recently, and
amiloride
~-adrenoceptors
cells
has
from
shown
to decrease
vascular
smooth
(8,9), and to the purified e2-adrenoceptor
sides blocking epithelial in
been
liver,
a variety
of
cells
(11,12). The action e2-adrenoceptor are closely relation
Na + channels,
including
of amiloride
amiloride
proximal as well
has led to the speculation
related,
are data
if not
showing
identical
tubule
921
of ligands
to e-
platelets,
renal
from porcine brain inhibits
(10). Be-
Na+/H + exchangers
cells of mammalian
kidneys
as of Na + and H + with the purified that receptor and Na+/H + exchanger
proteins
an inhibition
binding muscles,
(10).
In
support
of Na+/H + exchanger
of
such
a
by an ~2 adren-
0006-291X/88 $1.50 Copyright © 1988 by Academic Press, ~c. All r~h~ of reproduction in any form reserved.
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ergic agonist,
clonidine
(13),
and alprenolol
(14). Moreover,
and by B-adrenergic
antagonists,
the rat renal Na+/H + exchanger can be specifi-
cally labeled with a photolabile ligand for S-adrenoceptors, pindolol-diazirine acetylcholine
(14).
receptors
propranolol
Finally,
similar
to
[125I]iodocyano-
adrenoceptors
and
muscarinic
the rat renal Na+/H + exchanger has an app. molecular
mass of 65 kDa (15) and is glycosylated (Friedrich, unpublished). In
this
contribution
we wish
to
demonstrate
that
the
renal
Na+/H + ex-
changer reacts with propylbenzilylcholine mustard (PrBCM), a covalently binding ligand for the muscarinic
acetylcholine
receptor
changer and several members of the G protein-coupled number of ligands
suggesting
structural
relations.
(16). Thus, receptor
Na+/H + ex-
family
share a
Part of the results have
been published in abstract form (14).
METHODS
Vesicle preparation. Renal brush-border membrane vesicles from male Wistar rats (180 g) were prepared according to Biber et al. (17) by a Mg2+-precipi tation method. The vesicles were taken up in 100 mM TMACI, 50 mM KCl, 5 mM Hepes/Tris, pH 7.0, and stored in liquid nitrogen at a protein concentration of 10 mg/ml. Protein was determined according to Bradford (18) using bovine serum albumin as a standard. Basolateral membrane vesicles were prepared by a Percoll density gradient separation technique (19).
Irreversible inhibition of Na+/H + exchange with PrBCM and DCCD. Brush-border vesicles were rapidly thawed and diluted to a final protein concentration of 3.33 mg/ml. The vesicle suspension was preincubated with buffers and inhibitors for 30 minutes and then PrBCM or DCCD were added from ethanol stocks for further 30 minutes. The reaction was stopped by dilution of the vesicle suspension into 35 ml of 100 mM NaCI, 50 mM KCI, 5mM Hepes/Tris, pH 7.0, followed by centrifugation in a Sorvall SS34 rotor for 20 min at 20,000 rpm. The pellet was resuspended in the same buffer used to stop the reaction.
Determination of Na+/H + exchanger activity. Brush-border membrane vesicles (25 ~g protein) loaded with 100 mM NaCI, 50 mM KCI, 5 mM Hepes/Tris, pH 7.0, were diluted into I ml of 100 mM TMACI, 50 mM KCI, 5 mM Hepes/Tris, pH 7.0, containing 2.5 ~M valinomycin (to clamp the membrane potential to zero) and 6 ~M acridine orange (to monitor intravesicular acidification). Na + efflux via the Na+/H + exchanger acidifies the vesicle interior causing intravesicular accumulation of acridine orange and a decrease in its absorption. The absorption decrease was monitored in a Shimadzu UV 300 dual wavelength spectrophotometer (Kyoto, Japan) at 492 nm using 540 nm as reference wavelength. Na+/H + exchanger activity is expressed as rates of absorption decrease recorded within the first 10 seconds.
Labeling of membrane proteins with [3H]PrBCM and [14C]DCCD. Aliquots of brush-border membrane vesicles and basolateral membrane vesicles (1 mg of protein each) were labeled with [3H]PrBCM (125 nmol = 0.42 ~ o i / i ) or [14C]DCCD (2.5 nmol = 0.0083 mmol/l) at a protein concentration of 3.33 mg/ml for 30 min at room temperature in the presence or absence of inhibitors as indicated in the legends of the figures. After labeling the vesicles were washed as indicated above and the pellet was left on ice for further 3 hours. Then, the proteins were dissolved by shaking for 30 min in O'Farrell's sample buffer (20). Portions containing 0.5 mg dissolved proteins were then directly applied to SDS-polyacrylamide gel electrophoresis.
922
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and determination of the radioactivity. SDS-PAGE was performed in glas rods. Total acrylamide concentration was 8.5%. Molecular mass standards were phosphorylase b (94 kDa), albumin (67 kDa), ovalbumin (43 kDa) and carboanhydrase (30 kDa). The apparent molecular mass of labeled proteins was determined from plots of ig M r vs migration distance which were linear for the applied marker proteins (r 2 >0.98). The gels were fixed with 12.5% trichloroacetic acid, stained with Coomassie Brilliant Blue R 250, and destained in 250 ml ethanol, 50 ml acetic acid, 700 ml water. After scanning the gels were cut into 2 m m slices and treated with 0.5 ml Protosol overnight. Thereafter, scintillation fluid was added to determine the radioactivity contained in each sample. Materials. All chemicals were of analytical grade and obtained from commercial sources. PrBCM and [3H]PrBCM (60 Ci/mmol = 2220 GBq/mmol) were obtained from NEN. DCCD was obtained from Aldrich, [14C]DCCD (54 Ci/mol = 2 GBq/mol from Amersham. Amiloride and derivatives were synthetized as described by Cragoe et al. (21). Protosol was obtained from NEN. Before use, 75 ml water was added to 500 ml Protosol. RESULTS
AND
DISCUSSION
In order to test whether PrBCM interacts
with the renal Na+/H + exchanger,
brush-border membrane vesicles were preincubated without or with 0.5 mM PrBCM for 30 min at room temperature. Then, unreacted PrBCM was removed by washing and the vesicles were pending Na+-loaded
loaded with Na +. Na+/H + exchange was initiated by sus-
vesicles
in a Na+-free
as an indicator of intravesicular
buffer
the decrease of acridine orange absorbance cles as compared
to controls
containing
acidification.
Figure
acridine
I, left,
orange
shows
is slower in PrBCM-treated
(pretreatment without PrBCM).
This
that vesi-
result dem-
onstrates the partial irreversible inhibition of the Na+/H + exchanger following treatment with PrBCM. The degree of irreversible (Na+/H +
exchange
is
faster)
presence of amiloride Figure
I, right,
when
vesicles
were
exhibits
the dependence
I mM PrPCM is required for half-maximal decreases
gesting Na+/H +
the inhibition
a competition exchanger.
carboxyl
with
PrBCM
in
the
on PrBCM concentration of irre-
These
group reagent,
At 30 min preincubation time,
inhibition
of the antiporter.
at 0.5 mM PrBCM more
for a common results
or
are
comparable
to
in
binding
data
twofold
higher
sites
obtained
at the
with
the
(DCCD), which inactiv-
an amiloride-protectable
approximately
Amilo-
than at I mM PrBCM sug-
closely related
N,N'-dicyclohexylcarbodiimide
ates the Na+/H + exchanger compared to DCCD,
treated
is decreased
(Figure I, left, middle trace).
versible inactivation of the Na+/H + exchanger.
ride
inhibition
manner
(15,22,23).
As
of PrBCM
are
concentrations
required to produce an equivalent degree of irreversible inhibition. Besides
amiloride
(0.5 mM,
ethyl-N-isoproyl)amiloride renal
Na+/H +
exchanger
the substrates
adrenergic
antagonist,
1) also the high-affinity
analog 5-(N-
(EIPA, 0.05 mM) affords some protection of the rat
from
Similarly,
Figure
irreversible
of the Na+/H +
propranolol,
inactivation
exchanger,
protect
the
by PrBCM
Na + and Li +,
antiporter
(Table
I).
and the B-
partially.
The
same compounds were effective in protecting the Na+/H + exchanger from inactivation
by DCCD
(14,15).
These results 923
suggest
that,
similar
to DCCD,
PrBCM
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
=
5
X I==
<~ ¢~
-0,02
v
~> 3
with
40 ,--
-0,04
; 0.5raM
30'
PIBCM
without
0 4,J
~
L.
g2 e-
30';0.5mM PIBCM + 0.5 mM Amiloride
AMILORIDE
e~ L) x
o -0,06
+=1
e~ • e o n t zol
+ Z
-0,08 0
o:s
1
Time
(mln)
i
PrBCM concentration
(ml)
Figure I . Irreversible inhibition of Na+/H + exchange by PrBCM and protection by amiloride. Left: Rat renal b r u s h - b o r d e r membrane vesicles were incubated without (control) or with 0.5 mM PrBCM for 30 min in the absence or presence of 0.5 mM amiloride. Thereafter, v e s i c l e s were washed, loaded with Na +, and suspended in a N a + - f r e e b u f f e r c o n t a i n i n g acridine orange. The absorption loss of acridine orange was measured at 492 nm as a function of time. Right: Vesicles were incubated for 30 min with different concentrations of P r B C M in the presence or absence of 0.5 mM amiloride. The initial rate of absorption loss is plotted as a function of the PrBCM concentration.
Table I Protection of Na+/H + exchange from irreversible inhibition by PrBCM
PrBCM
(mM)
cation
(mM)
inhibitor (mM)
activity
(AABS/min-mg)
0
TMA +
(100)
-
5.11
0.5
TMA +
(100)
-
3.09 + 0.1
+ 0.35
p
-
<0.001"
0.5
Na +
(100)
-
3.77 + 0.2
<0.001"*
0.5
Li +
(100)
-
3.94 + 0.3
<0.001"*
0.5
TMA +
(100)
propranolol
(0.5)
3.86 + 0.23
<0.001.*
0.5
TMA +
(100)
(0.05)
3.53 + 0.14
<0.001.*
EIPA
Rat renal b r u s h - b o r d e r membrane vesicles were incubated with 0.5 mM PrBCM for 30 min in the presence of the indicated cations and inhibitors. After w a s h i n g and Na + loading of the vesicles, Na+/H + e x c h a n g e r activity was d e t e r m i n e d by m e a s u r i n g the rate of acridine orange absorbance decrease, AABS/min.mg protein. The table shows means + s t a n d a r d deviations from 5 determinations. TMA +, tetramethylammonium; *, s i g n i f i c a n t l y d i f f e r e n t from control (0 mM PrBCM); **, s i g n i f i c a n t l y d i f f e r e n t from the value obtained w i t h 0.5 mM PrBCM, 100 mM TMA + (no inhibitors).
924
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
interacts with the antiporter directly
at, or close
to, the cation and inhi-
bitor (amiloride) binding site. Since PrBCM and DCCD are hydrophobic, sume
that both reagents
amino
acid
residues
in
inactivate
we as-
the Na+/H + exchanger by binding to acidic
a hydrophobic
molecular
environment.
Interestingly,
also in the muscarinic acetylcholine receptor PrBCM and DCCD interact with a carboxylic highly
group
embedded
deeply
conserved
aspartic
acid
located
within
the
in
the molecule
thought
hydrophobic,
(16).
to be involved
membrane
spanning
In
adrenoceptors
a
in ligand binding is
helices
(I).
Comparable
reactivity towards hydrophobic reagents
and overlapping
ligand specificities
suggest
protein-coupled
receptors
that
Na+/H +
exchanger
and
G
may
share
molecular properties within their ligand binding sites. After
having
demonstrated
a
covalent,
PrBCM to the rat renal Na+/H + exchanger, proteins
are
labeled
with
[3H]PrBCM.
amiloride-protectable
To
this
renal brush-border membrane vesicles with separated
thereafter
panel, open symbols)
the
membrane
binding
of
we next investigated which membrane end we
either
polyeptides
incubated aliquots of
[3H]PrBCM or
by
SDS-PAGE.
[14C]DCCD and Figure
2
(top
shows that [3H]PrBCM is mainly incorporated into a broad
band with an apparent molecular mass of 65 kDa. The same band is labeled with [14C]DCCD (closed symbols). other protein bands
[14C]DCCD, however, is less specific as it label~
as well
(Figure I, and ref. 15). Figure 1, bottom panel,
reveals that amiloride decreased the incorporation of [3H]PrBCM as well as of [14C]DCCD into the 65 kDa band. the
labeling
previous
of
notion
this
band
Sodium,
(data
not
EIPA and propranolol
shown)
which
is
also decreased
compatible
with
our
(15) that a membrane protein with an apparent mass of 65 kDa
is identical to the renal Na+/H + exchanger. As a control we also labeled basolateral membrane vesicles with [3H]PrBCM. These membrane vesicles proximal tubule cells opposed
to
the
originate
from the contraluminal
and are not equipped with
brush-border
membrane,
they
(blood)
side of the
a Na+/H + exchanger
possess
~-
and
(24). As
B-adrenoceptors
(25-28). Figure 3, top panel, shows that after affinity labeling of rat renal basolateral membranes
[3H]PrBCM is incorporated mainly into two bands corres-
ponding to apparent molecular masses
of 89 kDa and 67 kDa. Amiloride depres-
ses strongly the labeling of the 67 kDa band, but leaves the incorporation of radioactivity into the 89 kDa band virtually unchanged. [3H]PrBCM branes cross
labeling patterns of brush-border
(Figure
A comparison
of the
2) and basolateral
mem-
(Figure 3) reveals a clearly different pattern. This finding rules out contaminations
of
membranes
and
proves
that
the
labeled
originates from the brush-border membranes whereas the labeled
65
kDa band
89 kDa and 67
kDa bands are constituents of the basolateral membrane. The
[3H]PrBCM-labeled
89 kDa band in basolateral membranes may be identi-
cal to a band of similar mass labeled previously with
[14C]DCCD and thought
to be identical to the a-subunit of the (Na++K+)-ATPase
(15). Labeling of the
925
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
94000 67000
8O0O
43~
14C]DCCD 500
-
Aml lorlde
[3HI PrBCM 6000 2
- 200
C~ -
bOO0
e~
-I00
2000
0
°
~
8000
wlth
[
300
•200
8 -
4000
-100 2000
t
i
0
i
i
2 4 Mlgratlon
i
i
6 8 Dlstance
0
I0 (cm)
12
Figure 2. Double-labeling of renal brush-border membrane proteins with [3H]PrBCM and [14C]DCCD and protection by amiloride. I mg vesicles were incubated with 0.125 nmol [3H]PrBCM and 2.5 nmol [14C]DCCD for 30 min in the absence (top panel)
or presence
of
0.5 mM
amiloride
(bottom panel).
After washing,
membrane proteins were separated by SDS-gelelectrophoresis. The gels were cut into 2 mm slices and radioactivity was determined. Closed symbols and left ordinate, incorporation of [3H]PrBCM; open symbols, incorporation of [14C]DCCD.
purified
~-subunit
with
PrBCM
been
tested
ments
are n e c e s s a r y
PrBCM-labeled The
to be
that
of
similarly when
the
irine
to d e f i n i t e l y
the
labeled
clarified.
the
Na+/H +
small,
Its
branes
of the prove
kDa
apparent
exchanger
or d i s p r o v e
the e - s u b u n i t 67
band
of the in
molecular
labeled
photolabile
S-adrenergic
antagonist,
is not i d e n t i c a l
identical
was used
to
the
we
to
feel
label that
exchanger.
926
Thus,
more
nor
has
experi-
of the [3H]-
(Na++K+)-ATPase.
is
membranes
slightly membranes
in m o l e c u l a r
renal the
to the 65 kDa band Na+/H +
demonstrated
the identity
in b r u s h - b o r d e r
difference
Therefore,
been
basolateral mass
reproducible,
(14).
not
(Na++K+)-ATPase.
but
(ICYP-diazirine),
membranes
not
of
has h i t h e r t o
an i n h i b i t o r
89 kDa band with
nature
also
as
[3H]PrBCM
remains
higher
than
(65 kDa).
masses
was
A
found
[125I]iodocyanopindolol-diazbrush-border
67 k D a
band
in b r u s h - b o r d e r Different
and
basolateral
in b a s o l a t e r a l membranes
amount
of
mem-
and thus
incorporated
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
,
i
i
94000
67000
, 43000
without
,C
~ ~
10~-
with Amllorlde
51100-
0
~
,
0
t
2 Rlgratlo
l
i
l
6
8
10
12
(cm)
Distance
Figure 3. Labeling of renal basolateral membrane proteins with [3H]PrBCM and protection by amiloride. I mg vesicles were labeled with 0.125 nmol [3H]PrBCM for 30 min. They were further treated as described in the legend to Figure 2.
radioactivity labeling
of
amiloride,
and
different
the
67
kDa
to
be
reflects
whether
and
greater
specific
labeling
[3H]PrBCM
as
67 kDa
to compare labels
and
specificity
radioactivity
the
reflect band
[14C]DCCD,
for
the
rat
label
than
[14C]DCCD.
does
of [14C]DCCD,
the
much
(Figure
I):
amounts
to approximately
The
are found with useful
maximal
incorporation 300 cpm/gel
[3H]PrBCM. for
Thereby,
further
(the
0.5
mM
also suggest that
distinct
proteins.
It
membranes
(25-28).
Na+/H + exchanger.
renal In
Na+/H +
addition,
less counts
of
[14C]DCCD whereas
exchanger due
with
to the low
are incorporated
into close
[125I]ICYP-diazirine and
Both,
into
(not shown) and [3H]PrBCM
slice,
characterization
by
[125I]iodocyanopindolol-di-
renal
[3H]PrBCM,
amiloride
depressed
in basolateral
the 65 kDa band as compared to [125I]ICYP-diazirine
prove
towards
completely
located in this membrane
it is worthwhile
[125I]ICYP-diazirine much
of
nearly
67 kDa and 65 kDa bands
established
the adrenoceptors
Finally azirine
being
that of the 65 kDa band only partially reduced)
both [3H]PrBCM-labeled needs
sensitivity
band
the
65
kDa
band
to 5000 cpm/slice
and [3H]PrBCM should
purification
of
the
renal
Na+/H + exchanger. Taken choline
together, receptor,
our
data
rat renal Na+/H + exchanger ing site,
and specifically
an inhibitor
show
that
a ligand
propylbenzilylcholine
of the
Na+/H +
probably labels
mustard
close
for
the
(PrBCM),
to or directly
the related membrane
exchanger,
amiloride,
927
with
muscarinic interacts
acetylwith
the
at the cation bindprotein.
Reaction
adrenoceptors
of
(8-I 0)
Vol. 157, No. 3, 1988
and,
conversely,
acetylcholine structural
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of ligands
receptor
features
of
with
the
antiporter
the
ligand
binding
Na+/H + exchanger
has
smilarly
to
receptors
Based
the
on
the
number
for adrenoceptors
a comparable
of
molecular
(Friedrich,
similarities
exchanger belongs to the family
Determination
Na+/H + exchanger
will
of
the
provide
(this
be
(15)
amino
basis
the
and
speculated
acid
common
rat
renal
is glycosylated
Burckhardt:
are comparable
primary the
indicates
Moreover,
mass
Sablotni,
it may
study)
sites.
of G protein-coupled
ly, parts of the molecular architecture proteins.
(13,14) and for the muscarinic
unpublished).
that
receptors.
the Na+/H + Alternative-
in otherwise unrelated sequence
to distinguish
of
between
the these
renal pos-
sibilities.
ACKNOWLEDGEMENTS
The
authors
thank
Drs.
Y. Mori
and K.
J. Ullrich
for valuable
This work was supported by the Deutsche Forschungsgemeinschaft
discussions.
(SFB169/A2).
REFERENCES
I. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16.
17. 18. 19. 20.
Dohlman, H. G., Caron, M. G., and Lefkovitz, R. (1987) Biochemistry 26, 2657-2664 Repaske, M. G., Nunnari, J. M., and Limbird, L. E. (1987) J. Biol. Chem. 262, 12381-12386 Convents, A., DeBaker, J.-P., Van Driesche, E., Convents, D., Beekmans, S., and Vauquelin, G. (1988) FEBS Letters 234, 480-484 Bahout, S. W., and Malbon, C. C. (1987) Biochem. J. 248, 557-566 Kaveri, S. V., Cervantes-Olivier, P., Delavier-Klutchko, C. and Strosberg, A. (1987) Eur. J. Biochem. 167, 449-456 Stiles, G. L. (1985) Arch. Biochem. Biophys. 237, 65-71 Haga, K., and Haga, T. (1985) J. Biol. Chem. 260, 7927-7935 Hiussinger, D., Brodde, O.-E., and Starke, K. (1987) Biochem. Pharmacol. 36, 3509-3515 Howard, M. J., Mullen, M. D., and Insel, P. A, (1987) Am. J. Physiol. 253, F21-F25 Nunnari, J. M., Repaske, M. G., Brandon, S., Cragoe, E. J. Jr., and Limbird, L. E. (1987) J. Biol. Chem. 262, 12387-12392 Frelin, C., Vigne, P., Barbry, P., and Lazdunski, M. (1987) Kidney Int. 32, 785-793 Aronson, P. S. (1983) Am. J. Physiol. 245, F647-F659 Ganapathy, M. E., Leibach, F. H., Mahesh, V. B., Devoe, L. D., and Ganapathy, V. (1986) Biochem. Pharmacol. 35, 3989-3994 Friedrich, T., and Burckhardt, G. (1988) Biol. Chem. Hoppe-Seyler 369, 817 (Abstract) Friedrich, T., Sablotni, J., and Burckhardt, G. (1986) J. Membrane Biol. 94, 253-266 Wheatley, M., Hulme, E. C., Birdsall, N. J. M., Curtis, C. A. M., Eveleigh, P., Pedder, E. K., and Poyer, D. (1988) TIPS February Suppl. 19-24 Biber, J., Stieger, B., Haase, W., and Murer, H. (1981) Biochim. Biophys. Acta 647, 169-176 Bradford, M. M. (1976) Anal. Biochem. 72, 248-254 L6w, I., Friedrich, T., and Burckhardt, G. (1984) Am. J. Physiol. 246, F334-F342 O'Farrell, P. H. D. (1975) J. Biol. Chem. 250, 4007-4021
928
Vol. 157, No. 3, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
21. Cragoe, E. J. Jr., Woltersdorf, O. W., Bicking, J. B., Kwong, S. F., and Jones, J. H. (1967) J. Med. Chem. 10, 66-75 22. Igarashi, P., and Aronson, P. S. (1987) J. Biol. Chem. 262, 860-868 23. Kinsella, J. L., Wehrle, J., Wilkins, N., and Sacktor, B. (1987) J. Biol. Chem. 262, 7092-7097 24. Sabolic, I., and Burckhardt, G. (1983) Biochim. Biophys. Acta 734, 210220 25. Matsushima, Y., Akanabe, S., and Ito, K. (1986) Biochem. Pharamacol. 35, 2593-2600 26. Matsushima, Y., Akabane, S., Kawamura, M., and Ito, K. (1987) Japan. J. Pharmacol. 45, 284-287 27. Sundaresan, P. R., Fortin, T. L., and Kelvic, S. L. (1987) Am. J. Physiol. 253, F848-F856 28. Sundaresan, P. R., Guarnaccia, M. M., and Izzo, J. L. Jr. (1987) Am. J. Physiol. 253, F1063-FI067
929