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The β-adrenergic receptor of turkey erythrocyte membranes: Conformational modification by β-adrenergic agonists
Vol. 86, No. 4, 1979
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
Pages
February 28, 1979
1311-1318
THE B-ADRENERGIC RECEPTOR OF TURKEY ERYTHROCYTE MEMBRANES : CONFORMATIONAL MODIFICATION G. VAUQUELINx:
S. BOTTAR?,
x Biochemical
BY B-ADPENERGX
0. DURIEU",
Pathology,
Instituut
65
Paardenstraat,
B-1640
' Molecular
Immunology,
Universite Received
December
29,
C. KLUTCHKO',
VII,
and A.D.
Moleculaire
Biologie,
St.-Genesius-Rode,
Institut
Paris
AGONISTS
de Recherches Place
Jussieu
STROSBERGXo
V.U.B.,
Belgium Biologie
2, Paris,
Moleculaire, France
1978
SUMMARY. The d-adrenergic receptors of turkey erythrocyte membranes have beenidentified by the specific binding of the radiolabeled antagonist (-)-/3H[--dihydroalprenolol. Pretreatment of these membranes with either the alkylating a ent N-ethylmaleimide or with !.3-adrenergic agonists does not affect (-)- 'i 3H I - dihydroalprenolol binding to the receptor sites. However, the simultaneous presence of both types of products causes a 50 % decline in the number of binding sites. A less pronounced decline occurs when the membranes are pretreated with N-ethylmaleimide in presence of the I-)phenylephrine, and no decline in the presence of the partial agonist antagonist (-)-I HI-dihydroalprenolol. $ -adrenergic agonists thus appear to induce a conformational change of their receptor, with results in an increased susceptibility to inactivation by N-ethylmaleimide.
Adenylate the specific membrane,
cyclase
ligands
characterization
ties
requires
to B-adrenergic
several
receptors
steps
on the cell
of the signal to the enzyme and finally an The recent availability of radiolabeled AMP production.
in cyclic
f3-adrenergic
easily
by catecholamines
of the hormone
the transmission
increase
Whereas
activation
binding
such as (-j-13H1-
of the
occupation
are
adenylate physiological
usually
8-adrenergic
of these
be determined
§
G.V. is Aangesteld Onderzoek, Belgium.
&
Nonstandard abbreviations NEM, N-ethylmaleimide.
method
in tissues
Navorser
by binding
the agonist
by determining
in cell
enables
(6).
In this
of the Nationaal
and analogs or antagonist
the ability
membranes(3,5)
a direct
studies.(l,2j
by catecholamines (3,4),
indirectly
activation
responses
receptors
@receptors
by this
studied
cyclase
dihydroalprenolol
proper-
to induce
or by evaluating report,
can
we show that
the 8-adre-
Fonds voor Wetenschappelijk
: 13H/- DHA, (-)-13HI-dihydroalprenolol; 0006-291X/79/041311-08$01.00/0 1311
Copyright @ 1979 by Academic Press, Inc. All rights of reproduction in anyform reserved.
:
Vol. 86, No. 4, 1979
nergic
receptors
by the reagent antagonrsts, two types gic
BIOCHEMICAL
of turkeyerythrocytemembranes N-ethylmaleimide
providing
for
of compounds
receptors
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
can be rapidly
in the presence a new direct
and confirming
in a different
method that
they
of agonists, to distinguish interact
with
inactivated but
not of
between
these
the S-adrener-
way.
EXPERIMENTAL PROCEDURE. MATERIALS. The following were obtained as gifts (-)-isoproterenol bitartrate (Sterling Winthrop) and phentolamine (Ciba-Geigy). (-)-Phenylephrine was purchased from Sigma Chemical Co.; pyrocatechol and N-ethylmaleimide were from Fluka. AG.(-)-13HI-dihydroalprenolol (33 Ci/ mmol) was obtained from New England Nuclear Corp.
:
membranes were Preparation of turkey erythrocyte membranes : Erythrocyte orenared according to @ve and Sutherland (7). suspended in 10 mM Tris* HCI (pH 7.4)/145 & NaCl/2 mM MgC12 containing IO&% (vol/vol) glycerol, and stored in liquid nitrogen until use. Nucleated ghosts were obtained by hemolysis of erythrocytes in 5 mM Tris-HCl(pH 7.4)/2 mM MgC12. Protein determinations were performed by the procedure of Lowry et al(8) usingbovine serum albumin as the standard. Membrane pretreatment with N-ethylmaleimide (NEM) & : Ghosts or membranes were vreincubated with NEM and washed as follows : Preincubation : 2 mg of membrane protein was preincubated with the indicated concentrations of NEM and adrenergic ligands at 30°C for 12 min. in 75 mM Tris-HCl(pH 7.4)/25 mM MgC12 (buffer A) in a final volume of I ml. Then, the reaction medium was immediately transferred into a 1.5 ml. Eppendorf micro test tube and centrifugated for 1 min in an Eppendorf centrifuge (1200 rpm) at 20°C. the preincubated membranes Washing : After removal of the supernatant, were resuspended into 1 ml. of buffer A, and centrifugated for I min. This washing step was repeated once. A
Binding of (-)-13HlDHA & to pretreated ghosts or membranes was performed as published elsewhere (9). In all figures and tables, bound (->-13H/DHA refers to-specific binding : i.e. binding of tracer displaced by 25 pM (+)-alprenolol. Data are mean at least 6 measurements, standard deviation less than 6 %. Ascending thin-layer chromatography : Equal volumes of 40 mM (-)-isoproterenol and 40 mM NEM (in buffer A) were mixed, and incubated for 12 5 1~.1 of the (-)-isoproterenol and NEM solutions and 10 ~1 of min. at 30°C. the (-)-isoproterenol plus NEM solution were spotted on the same silicagel thin-layer chromatographic plate (20 x 20 cm, pre-coated, from Merck). After elution with ethyl acetate/formic acid/water (17/2/l), plates were exposed to iodine vapors. Isoproterenol : brown spot, RF = 0.28; NEM : no colour; isoproterenol plus NEM : brown spot : RF = 0.28. RESULTS .
The radiolabeled
antagonist
(-)-13Hl-
DHA has been
shown to bind
to the Sl-adrenergic receptors of turkey erythrocytemembranes with high specificity and affinity, and with fast association and dissociation kinetics at 30°C (9). Binding occurs to a single class of non-cooperative sites with an equilibrium shown in figure 1, bound gic
agonists
( with
dissociation constant (KD) of 8 to 12 nM. As (-)-13HlDHA is completely displaced by 6-adrener-
the order
of potencies
1312
: (-)-isoproterenol
= (*)-proto-
Vol. 8.5, No. 4, 1979
BiOCHEMlCAl
DRUG
AND BIOPHYSJCAL RESEARCH COMMUNICATIONS
CONCENTRATION
(-Log
M 1
Fig.]. Competition of various drugs with (-)-13HlDHA for binding to the B-adrenergic receptor of turkey erythrocyte membranes. Membranes(2 mg/ml) are incubated with 10 nM of (-)-13HlDHA for 10 min. at 3O'C in the presence of increasing concentrations of drug.Control binding refers to binding of (-)-13H/DHA in the absence of competitor (0.11 pmol/mg protein).
kylol
> (-)-norepinephrine
receptor),
2
(-)-epinephrine,
and by the partial
phentolamine
agonist
and the non-bioactive
typical
for
(-)-phenylephrine. catechol
a Hl-adrenergic
The o-blocker weak or no displace-
produces
ment. In contrast the
fil-receptor
with
of turkey
zation
upon prolonged
Binding
of (-)-13H/-
by prior
treatment pretreatment
(-)-isoproterenol
erythrocyte
exposure
membranes
with
of the membranes
of
of a variety
to al-adrenergic
of the membranes produces
plot
receptors
DHA to the 6 -adrenergic
However, A Scatchard
the fi-adrenergic
show desensiti(Table
NEM either
a 55 % drop
(-)-13H/-
does not agonists receptors
with in
of tissues,
is not (Table
(-)-13Hl-
DHA binding
binding
affected
I and 2).
NEM in the presence
DHA saturation
1) (lo-13),
of (Table
experiments,
1).
reveals
that this drop is due to a decline in the number of receptor sites, and that the affinity of the tracer for the remaining receptors is not affected (unpublished observations). affected by improved washing membranes washing,
(i.e. instead
washing
The number of inactivated receptors of the NEM plus (-)-isoproterenol-treated
followed
of washing
only,
by incubation Table
1313
1).
with
buffer
Inactivation
is not
and a second is
apparently
Vol. 86, No. 4, 1979
Table
BIOCHEMICAL
1: (-)-
proterenol
13Hland/or
to membranes
after
treatment
with
preincubation
with:
preincubation
Second
- a)
(-)-
preincubation
13H(Hi-
NEti
of
Table binding. -
44
NEM
90
Membranes ((-)-isoproterenol twice with buffer,
with
10 nM
to membranes buffer
the
(-)-13Hl-
treated
(2 mg/ml) : 0.1 uM, preincubated
indicated DHA
with
95
is
are NEM
compounds, measured.
buffer
preincubated with the indica: 0.1 mM) for 12 minutes for a second time at the
and washed
Control
2:
Effect
of
various
buffer
preincubated
in
presence
or
- DHA binding
: 0.1 UM PM a)) , KD = 0.12
(-)-phenylephrine ( partial
: 0.1 mM agonist , KD = 0.094
I3HH(- DHA ( antagonist
:
:
1 mM
, KD = 0.26
: 1 mM ( non-bioactive
, KD.>0.5
of
NEM on
NEM
NEM
:
pretreated
with
KD-values
irreversible.
buffer
were
98
93
53
94
81
105
92
104
98
98
93
mN ) mM )
Neither
of with
causes
a pronounced
receptors
are
are
previousely
treatment
Therefore,
compounds
as
treatment
treatment,
both
in the presence and incubated membranes
only.
determined
subsequent
(-)-13Hl-DHA
IO l&M
100
Membranes (2 mg/ml) are pretreated with various drugs or absence of NEM for 12 min. at 30°C, washed twice with buffer with 10 nM (-)j3HIDHA. Control binding refers to binding to
and
buffer. binding
mM )
IO nM , KD = IO nM )
( a-antagonist
absence
no
only
phcntolamine
washing
to
( % control)to:
with:
(-)-isoproterenol ( agonist
a)
with
refers
only.
drugs
(-)-13Hl
catechol
twice
binding
only
Membranes
(-)-
45
(-)-isoproterenol
same concentration a)
+ NEM -
+ NEM
(-)-isoproterenol
Binding
103
(-)-isoproterenol
(-)-isoproterenol
)
103
NEM -
DHA bound
( % control
(-)-isoproterenol
ted compounds at 30°C, washed
(-)-iso-
NEM.
Membrane First
DHA binding
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
only
simultaneously
described
membranes
the
(9).
with
(-)-isoproterenol,
reduction inactivated
in by
present.
1314
(-)-l%lNEM and
NEM or
followed the
DHA binding (-)-isoproterenol
by reverse (Table
1). when
Vol.
86,
No.
BIOCHEMICAL
4, 1979
AND
PREINCUBATION
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
TIME(MINUTES)
Fig.2. Inactivation of &adrenergic receptors by NEM plus (-)-isoproteren01 : time dependence. Membranes (2 mgfml) are pretreated with 0.025 uM (-)-isoproterenol plus NEM (50 uM : (o---o) , 0.1 mM : (o--o) , 1 mM : (o--f))), or with 0.05 pM (-)-isoproterenol plus 50 uM NEM : (x-x) , for different periods of time at 30°C. Then membranes are washed twice with buffer and binding of 10 nM (-)-13HlDHA measured. (B) is binding to membranes preInsert : Semi-logarithmic representation. treated with NEM plus (-)-isoproterenol for the time (t). The apparent first-order rate constant of inactivation (kob) is defined by equation : In (B/100) = - kob.t.
The effect of NEM plus . . The krnetlc data, presented erythrocyte
membranes
with
50 nM NEM plus decrease
0.025
PM (-)-
a time
sites.
When the number of binding sites is plotted the decrease appears to be related 2, inset), time.
The apparent
(k,b)
approximates
0.022
twice
by doubling
0.046
min- I) or NEM (k,b
cubation
Pretreatment
the
in the number
is time- and dosethat pretreatment
duces (Fig.
- dependent
(-)-isoproterenol 2, indicate
in Fig.
= 0.044
of the membranes
of either
isoproterenol
of (-)-13Hl-
pro-
DHA binding
on a logarithmic scale linearly to the prein-
first-order rate constant -1 min . The rate of inactivation
concentration
depende,nt. of turkey
for
the inactivation increases
(-)-isoproterenol
about
(k,b
=
min-l). with
(-)-isoproterenol
(0.025
I,JM)
in the presence of a high concentration of NEM (1 mM), causes inactivation of about 50 % of the receptor sites within less than 1 min (i.e. the time in the experimenrequired for a first washing of the membranes, as described tal procedure). remains constant Higher
concentrations
After this rapid upon prolonging
the amount of receptor decline, the preincubation for at least
of (-)-isoproterenol
(0.1
131.5
sites 15 min
(Fig.
uM) and NEM (10 mM) do not
2).
Vol.
86,
No.
4, 1979
BIOCHEMICAL
affect the remaining receptors 5, 10 and 15 min preincubation, respectively
AND
in either the
54, 48, and 48 % for
ghosts.
Accordingly,
membrane
purfication
BIOPHYSICAL
membranes
(-)-13Hl-
ghosts.
activity
for
still nucleated
(-)-isoproterenol
factors
After
is
and 52, 52 and 57 % for
of NEM or
the limiting
COMMUNICATIONS
or nucleated
DHA binding
membranes,
the concentration are not
RESEARCH
or the
the extent
of inactiva-
tion. Inactivation is
in part
of the B-adrenergic
mimicked
lephrine,
but
not
in the presence
The concentrations to their pied
for
either
(-)-13Hl-
receptors
their
specific
cyte
(14,15)
ceptors
(as defined
the agonist
modification
observed
by thin-layer
that
these
Binding
cyte
membranes
inactivate
may cause
of the receptors
processes
can be summarized H
where
H is
receptor
+
towards by the
ReH.R'
the agonist;
respectively.
R, H.R'
and r the
The irreversible
step
probably due to the formation of covalent The kinetic data (Fig. 2) agree with tors.
both
relationship
between
NE&! and (-)-isoproterenol
[HR'] = [H]
).
The lack
the rate (at
of decline
and receptors.
1316
likely erythro-
in this
set
and inactivated of reactions
(Table
1)
bonds between NEM and the recepthe proposed scheme by showing a
submaximal in
is
:
of inactivation (-)-13Hl-
consecutive treatment of the membranes with.the may be explained by the reversible interaction
it
in an increased by NEM. Both
*r agonist-bound
free,
is
linear
resulting
scheme NEM
As a
of turkey
(inactivation)
following
1 ).
and
in a synergistic
receptors
change,
erythro-
of the re-
the reagent
(Table
receptor
alkylation
of two types
by NEM has not been
and Methods),
to the f31-adrenergic
of
of turkey
when both
molecule
B-adrenergic
types
in the number
simultaneously
a conformational
sensitivity
catechol
of these
receptors
sites)
(Materials
the
of agonists
occu-
desensitization
neither
decrease
(-)-isoproterenol
chromatography
compounds
fashion.
a marked
are present
of the
equal
conditions,
various
cause
(IO-12),
DHA binding
(-)-isoproterenol
chemical
agonists
the @I-adrenergic is
by (-)-13Hl-
2).
tested
or the non-bioactive
tissues
affect there
2, were
compounds
NEM inactivates
and @-adrenergic
However,
(-)-pheny-
DHA (Table
the same preincubation
agent
in several
independently
membranes.
isoproterenol
to the membranes.
the alkylating
receptors
of compounds
Under
(-)-13Hl-
the three
phentolamine
DHA binding
DISCUSSION : Although hormone
sites.
(-)agonist
used in table
so that
the a-antagonist
do not affect
ligands
the receptor,
50 % of the receptor
by NEM plus
of the partial
of the antagonist
of the B-adrenergic
KD-value
NEM plus
receptors
by NEM in the presence
and the
concentrations, DHA binding reagent between
concentration
of
where activity
after
and the agonist (Table @-adrenergic agonists
I),
Vol.
86,
No.
There changes
BIOCHEMICAL
4, 1979
are
some striking are closely 1 and ref.
duce adenylate
cyclase
ability
than
to sensitize
in presence
of the antagonist
Recently, formation
Cassel
between
involves
GTP-ase
proterenol
than
by NEM in
in its
ligands
NEM inactivates
(-)-isoproterenol(Fig.
2).
of B-adrenergic
receptors,
or the dissociation red as possible conclude
which
reagent
can form
covalent
bonds
We observed recently that of 8-adrenergic receptors
fact
argued
for
types
formation
is
tion tor
by NEM.
a different of ligands.
induced receptor,
with
sites
type
cyclase
all
the
results
of agonists
is
observation.
(->-13Hl-
interaction
be conside-
At present, by NEM.
increases antagonists(g). that
the affiThis the receptor
a change
is now under
sensitivity change
1.
3. 4. 5.
to the
of the recep-
investigation.
HABER E. and WRENN S. (1976) Physiological Revs., 56, 317-338. LEFKOWITZ R.J., LIMBIRD L.E., MUKHERJEE C. and CARON M.G., (1976) Biochim. Biophys. Acta., 457, l-39. MUKHERJEE C., CARON M.G., MULLIKIN D. and LEFKOWITZ R.J. (1976) Mol. Pharmacol., 11, 16-31. BROWN E.M., FEDAK S.A., WOODARD C.J. and AURBACH G.D., (1976) J. Biol. Chem., 251, 1239-1246. LEVITZKY A., SEVILLA N., ATLAS D. and STEER M.L. (1975) J. Mol. Biol. Chem., jy7, 35-53.
1317
of con-
to inactiva-
REFERENCES :
2.
we
This groups(lg).
not of antagonists
the conformational
of
molecule,
might
between
suggest
DHA categories
or imidazole
selectively not for
but
receptor
this
receptor
alkylated
by the increased
activation,
of (-)-iso-
represented
inactivation.
of molecular
between
erythrocytes
in the presence
on a single
sulphydryl-,amino-
The present
as indicated
explain
by agonists
but
of in-
The catecholamine-
of two equally
solubilization for agonists
by the binding
The relationship
and the adenylate
with
of the B-receptor
nity
and both
interact
of the partial
moiety
5)
transmission
in turkey
no more than half
receptor-complexes
significant
of the @-adrenergic might
of two binding
interpretations
can not
the
to NEM in presence
agonists
The existence
of binary
2 and ref. cyclase
to
by NEM.
and not
that
The inactivation
of B-adrenergic
related
(-)-isoproterenol
GTP-ase(l7).
was more sensitive
the S-adrenergic
sites(Fig.l),
S-adrenergic
and adenylate
absence.
the presence
Although
(Table
of a membrane-bound
activity
that
to inactivation
(-)-phenylephrine,
have reported
the S-receptors
closely
of the agonist
(-)-13Hl-DHA
conformational suggesting
is
receptors
in presence
and Selinger
the activation
stimulated
activity)
the B-adrenergic agonist
activation,
processes are fast and reversible of B-adrenergic ligands to in-
(intrinsic
of the partial
COMMUNICATIONS
agonist-induced
cyclase
: i) Both The ability
activation
is more pronounced
in presence
binding
related 16) ii)
RESEARCH
between
and adenylate
both phenomena (Fig. 2, Table their
BIOPHYSICAL
similarities
of the S-receptors
Inactivation
AND
Vol. 86, No. 4, 1979
6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FURCHGOTT R.F. (1970) Fed. Proc., 29, 1352-1361 Biophys. Acta., 127, 347-354. @YE I., SUTHERLAND E.W. (1966) BiocEm. LOWRY O.H., ROSEBROUGH N.J., FARR A.L. and RANDALL R.J. (1951) J. Biol. Chem., 193, 265-275. VAUQUELIN G., GEYNET P., HANOUNE J. and STROSBERG A.D. (1977) Acad. Sci. USA., 76, 3710-3714. Proc. Natl. MUKHERJEE C. and LEFKOWITZ R.J. (1976) Proc. Natl. Acad. Sci. USA., 12, 1494-1498. KEBABIAN J.W., ZATZ M., ROMERO J.E. and AKELROD J. (1975) Proc. Natl. Acad. Sci. USA., 11, 3735-3739. Chem., SHEAR M., INSEL P-A., MELMON K.L. and COFFIN0 P. (1976) J. Biol. 251, 7572-7576. HANSKI E. and LEVITZKY A. (1978) Life Sciences, 22, 53-60. SALMAN K.N., CHAI H.S., MILLER D.D. and PATIL P.N. (1976) Eur. J. Pharmacol., 36, 41-48. (1975) Proc. Natl. Acad. Sci. USA., 11, SIMON E.J. and GROTH J. 2404-2407. BLR H.P. (1974) Mol. Pharm., '0, 597-604. Biophys. Acta., 452, 538-551. CASSEL C. and SELINGER Z. (1976) Biochim. J., 2, SMYTH D.G., BLUMENFELD 0.0. and KONIGSBERG W. (1964) Biochim. 589-595.
1318
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
Pages
February 28, 1979
1311-1318
THE B-ADRENERGIC RECEPTOR OF TURKEY ERYTHROCYTE MEMBRANES : CONFORMATIONAL MODIFICATION G. VAUQUELINx:
S. BOTTAR?,
x Biochemical
BY B-ADPENERGX
0. DURIEU",
Pathology,
Instituut
65
Paardenstraat,
B-1640
' Molecular
Immunology,
Universite Received
December
29,
C. KLUTCHKO',
VII,
and A.D.
Moleculaire
Biologie,
St.-Genesius-Rode,
Institut
Paris
AGONISTS
de Recherches Place
Jussieu
STROSBERGXo
V.U.B.,
Belgium Biologie
2, Paris,
Moleculaire, France
1978
SUMMARY. The d-adrenergic receptors of turkey erythrocyte membranes have beenidentified by the specific binding of the radiolabeled antagonist (-)-/3H[--dihydroalprenolol. Pretreatment of these membranes with either the alkylating a ent N-ethylmaleimide or with !.3-adrenergic agonists does not affect (-)- 'i 3H I - dihydroalprenolol binding to the receptor sites. However, the simultaneous presence of both types of products causes a 50 % decline in the number of binding sites. A less pronounced decline occurs when the membranes are pretreated with N-ethylmaleimide in presence of the I-)phenylephrine, and no decline in the presence of the partial agonist antagonist (-)-I HI-dihydroalprenolol. $ -adrenergic agonists thus appear to induce a conformational change of their receptor, with results in an increased susceptibility to inactivation by N-ethylmaleimide.
Adenylate the specific membrane,
cyclase
ligands
characterization
ties
requires
to B-adrenergic
several
receptors
steps
on the cell
of the signal to the enzyme and finally an The recent availability of radiolabeled AMP production.
in cyclic
f3-adrenergic
easily
by catecholamines
of the hormone
the transmission
increase
Whereas
activation
binding
such as (-j-13H1-
of the
occupation
are
adenylate physiological
usually
8-adrenergic
of these
be determined
§
G.V. is Aangesteld Onderzoek, Belgium.
&
Nonstandard abbreviations NEM, N-ethylmaleimide.
method
in tissues
Navorser
by binding
the agonist
by determining
in cell
enables
(6).
In this
of the Nationaal
and analogs or antagonist
the ability
membranes(3,5)
a direct
studies.(l,2j
by catecholamines (3,4),
indirectly
activation
responses
receptors
@receptors
by this
studied
cyclase
dihydroalprenolol
proper-
to induce
or by evaluating report,
can
we show that
the 8-adre-
Fonds voor Wetenschappelijk
: 13H/- DHA, (-)-13HI-dihydroalprenolol; 0006-291X/79/041311-08$01.00/0 1311
Copyright @ 1979 by Academic Press, Inc. All rights of reproduction in anyform reserved.
:
Vol. 86, No. 4, 1979
nergic
receptors
by the reagent antagonrsts, two types gic
BIOCHEMICAL
of turkeyerythrocytemembranes N-ethylmaleimide
providing
for
of compounds
receptors
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
can be rapidly
in the presence a new direct
and confirming
in a different
method that
they
of agonists, to distinguish interact
with
inactivated but
not of
between
these
the S-adrener-
way.
EXPERIMENTAL PROCEDURE. MATERIALS. The following were obtained as gifts (-)-isoproterenol bitartrate (Sterling Winthrop) and phentolamine (Ciba-Geigy). (-)-Phenylephrine was purchased from Sigma Chemical Co.; pyrocatechol and N-ethylmaleimide were from Fluka. AG.(-)-13HI-dihydroalprenolol (33 Ci/ mmol) was obtained from New England Nuclear Corp.
:
membranes were Preparation of turkey erythrocyte membranes : Erythrocyte orenared according to @ve and Sutherland (7). suspended in 10 mM Tris* HCI (pH 7.4)/145 & NaCl/2 mM MgC12 containing IO&% (vol/vol) glycerol, and stored in liquid nitrogen until use. Nucleated ghosts were obtained by hemolysis of erythrocytes in 5 mM Tris-HCl(pH 7.4)/2 mM MgC12. Protein determinations were performed by the procedure of Lowry et al(8) usingbovine serum albumin as the standard. Membrane pretreatment with N-ethylmaleimide (NEM) & : Ghosts or membranes were vreincubated with NEM and washed as follows : Preincubation : 2 mg of membrane protein was preincubated with the indicated concentrations of NEM and adrenergic ligands at 30°C for 12 min. in 75 mM Tris-HCl(pH 7.4)/25 mM MgC12 (buffer A) in a final volume of I ml. Then, the reaction medium was immediately transferred into a 1.5 ml. Eppendorf micro test tube and centrifugated for 1 min in an Eppendorf centrifuge (1200 rpm) at 20°C. the preincubated membranes Washing : After removal of the supernatant, were resuspended into 1 ml. of buffer A, and centrifugated for I min. This washing step was repeated once. A
Binding of (-)-13HlDHA & to pretreated ghosts or membranes was performed as published elsewhere (9). In all figures and tables, bound (->-13H/DHA refers to-specific binding : i.e. binding of tracer displaced by 25 pM (+)-alprenolol. Data are mean at least 6 measurements, standard deviation less than 6 %. Ascending thin-layer chromatography : Equal volumes of 40 mM (-)-isoproterenol and 40 mM NEM (in buffer A) were mixed, and incubated for 12 5 1~.1 of the (-)-isoproterenol and NEM solutions and 10 ~1 of min. at 30°C. the (-)-isoproterenol plus NEM solution were spotted on the same silicagel thin-layer chromatographic plate (20 x 20 cm, pre-coated, from Merck). After elution with ethyl acetate/formic acid/water (17/2/l), plates were exposed to iodine vapors. Isoproterenol : brown spot, RF = 0.28; NEM : no colour; isoproterenol plus NEM : brown spot : RF = 0.28. RESULTS .
The radiolabeled
antagonist
(-)-13Hl-
DHA has been
shown to bind
to the Sl-adrenergic receptors of turkey erythrocytemembranes with high specificity and affinity, and with fast association and dissociation kinetics at 30°C (9). Binding occurs to a single class of non-cooperative sites with an equilibrium shown in figure 1, bound gic
agonists
( with
dissociation constant (KD) of 8 to 12 nM. As (-)-13HlDHA is completely displaced by 6-adrener-
the order
of potencies
1312
: (-)-isoproterenol
= (*)-proto-
Vol. 8.5, No. 4, 1979
BiOCHEMlCAl
DRUG
AND BIOPHYSJCAL RESEARCH COMMUNICATIONS
CONCENTRATION
(-Log
M 1
Fig.]. Competition of various drugs with (-)-13HlDHA for binding to the B-adrenergic receptor of turkey erythrocyte membranes. Membranes(2 mg/ml) are incubated with 10 nM of (-)-13HlDHA for 10 min. at 3O'C in the presence of increasing concentrations of drug.Control binding refers to binding of (-)-13H/DHA in the absence of competitor (0.11 pmol/mg protein).
kylol
> (-)-norepinephrine
receptor),
2
(-)-epinephrine,
and by the partial
phentolamine
agonist
and the non-bioactive
typical
for
(-)-phenylephrine. catechol
a Hl-adrenergic
The o-blocker weak or no displace-
produces
ment. In contrast the
fil-receptor
with
of turkey
zation
upon prolonged
Binding
of (-)-13H/-
by prior
treatment pretreatment
(-)-isoproterenol
erythrocyte
exposure
membranes
with
of the membranes
of
of a variety
to al-adrenergic
of the membranes produces
plot
receptors
DHA to the 6 -adrenergic
However, A Scatchard
the fi-adrenergic
show desensiti(Table
NEM either
a 55 % drop
(-)-13H/-
does not agonists receptors
with in
of tissues,
is not (Table
(-)-13Hl-
DHA binding
binding
affected
I and 2).
NEM in the presence
DHA saturation
1) (lo-13),
of (Table
experiments,
1).
reveals
that this drop is due to a decline in the number of receptor sites, and that the affinity of the tracer for the remaining receptors is not affected (unpublished observations). affected by improved washing membranes washing,
(i.e. instead
washing
The number of inactivated receptors of the NEM plus (-)-isoproterenol-treated
followed
of washing
only,
by incubation Table
1313
1).
with
buffer
Inactivation
is not
and a second is
apparently
Vol. 86, No. 4, 1979
Table
BIOCHEMICAL
1: (-)-
proterenol
13Hland/or
to membranes
after
treatment
with
preincubation
with:
preincubation
Second
- a)
(-)-
preincubation
13H(Hi-
NEti
of
Table binding. -
44
NEM
90
Membranes ((-)-isoproterenol twice with buffer,
with
10 nM
to membranes buffer
the
(-)-13Hl-
treated
(2 mg/ml) : 0.1 uM, preincubated
indicated DHA
with
95
is
are NEM
compounds, measured.
buffer
preincubated with the indica: 0.1 mM) for 12 minutes for a second time at the
and washed
Control
2:
Effect
of
various
buffer
preincubated
in
presence
or
- DHA binding
: 0.1 UM PM a)) , KD = 0.12
(-)-phenylephrine ( partial
: 0.1 mM agonist , KD = 0.094
I3HH(- DHA ( antagonist
:
:
1 mM
, KD = 0.26
: 1 mM ( non-bioactive
, KD.>0.5
of
NEM on
NEM
NEM
:
pretreated
with
KD-values
irreversible.
buffer
were
98
93
53
94
81
105
92
104
98
98
93
mN ) mM )
Neither
of with
causes
a pronounced
receptors
are
are
previousely
treatment
Therefore,
compounds
as
treatment
treatment,
both
in the presence and incubated membranes
only.
determined
subsequent
(-)-13Hl-DHA
IO l&M
100
Membranes (2 mg/ml) are pretreated with various drugs or absence of NEM for 12 min. at 30°C, washed twice with buffer with 10 nM (-)j3HIDHA. Control binding refers to binding to
and
buffer. binding
mM )
IO nM , KD = IO nM )
( a-antagonist
absence
no
only
phcntolamine
washing
to
( % control)to:
with:
(-)-isoproterenol ( agonist
a)
with
refers
only.
drugs
(-)-13Hl
catechol
twice
binding
only
Membranes
(-)-
45
(-)-isoproterenol
same concentration a)
+ NEM -
+ NEM
(-)-isoproterenol
Binding
103
(-)-isoproterenol
(-)-isoproterenol
)
103
NEM -
DHA bound
( % control
(-)-isoproterenol
ted compounds at 30°C, washed
(-)-iso-
NEM.
Membrane First
DHA binding
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
only
simultaneously
described
membranes
the
(9).
with
(-)-isoproterenol,
reduction inactivated
in by
present.
1314
(-)-l%lNEM and
NEM or
followed the
DHA binding (-)-isoproterenol
by reverse (Table
1). when
Vol.
86,
No.
BIOCHEMICAL
4, 1979
AND
PREINCUBATION
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
TIME(MINUTES)
Fig.2. Inactivation of &adrenergic receptors by NEM plus (-)-isoproteren01 : time dependence. Membranes (2 mgfml) are pretreated with 0.025 uM (-)-isoproterenol plus NEM (50 uM : (o---o) , 0.1 mM : (o--o) , 1 mM : (o--f))), or with 0.05 pM (-)-isoproterenol plus 50 uM NEM : (x-x) , for different periods of time at 30°C. Then membranes are washed twice with buffer and binding of 10 nM (-)-13HlDHA measured. (B) is binding to membranes preInsert : Semi-logarithmic representation. treated with NEM plus (-)-isoproterenol for the time (t). The apparent first-order rate constant of inactivation (kob) is defined by equation : In (B/100) = - kob.t.
The effect of NEM plus . . The krnetlc data, presented erythrocyte
membranes
with
50 nM NEM plus decrease
0.025
PM (-)-
a time
sites.
When the number of binding sites is plotted the decrease appears to be related 2, inset), time.
The apparent
(k,b)
approximates
0.022
twice
by doubling
0.046
min- I) or NEM (k,b
cubation
Pretreatment
the
in the number
is time- and dosethat pretreatment
duces (Fig.
- dependent
(-)-isoproterenol 2, indicate
in Fig.
= 0.044
of the membranes
of either
isoproterenol
of (-)-13Hl-
pro-
DHA binding
on a logarithmic scale linearly to the prein-
first-order rate constant -1 min . The rate of inactivation
concentration
depende,nt. of turkey
for
the inactivation increases
(-)-isoproterenol
about
(k,b
=
min-l). with
(-)-isoproterenol
(0.025
I,JM)
in the presence of a high concentration of NEM (1 mM), causes inactivation of about 50 % of the receptor sites within less than 1 min (i.e. the time in the experimenrequired for a first washing of the membranes, as described tal procedure). remains constant Higher
concentrations
After this rapid upon prolonging
the amount of receptor decline, the preincubation for at least
of (-)-isoproterenol
(0.1
131.5
sites 15 min
(Fig.
uM) and NEM (10 mM) do not
2).
Vol.
86,
No.
4, 1979
BIOCHEMICAL
affect the remaining receptors 5, 10 and 15 min preincubation, respectively
AND
in either the
54, 48, and 48 % for
ghosts.
Accordingly,
membrane
purfication
BIOPHYSICAL
membranes
(-)-13Hl-
ghosts.
activity
for
still nucleated
(-)-isoproterenol
factors
After
is
and 52, 52 and 57 % for
of NEM or
the limiting
COMMUNICATIONS
or nucleated
DHA binding
membranes,
the concentration are not
RESEARCH
or the
the extent
of inactiva-
tion. Inactivation is
in part
of the B-adrenergic
mimicked
lephrine,
but
not
in the presence
The concentrations to their pied
for
either
(-)-13Hl-
receptors
their
specific
cyte
(14,15)
ceptors
(as defined
the agonist
modification
observed
by thin-layer
that
these
Binding
cyte
membranes
inactivate
may cause
of the receptors
processes
can be summarized H
where
H is
receptor
+
towards by the
ReH.R'
the agonist;
respectively.
R, H.R'
and r the
The irreversible
step
probably due to the formation of covalent The kinetic data (Fig. 2) agree with tors.
both
relationship
between
NE&! and (-)-isoproterenol
[HR'] = [H]
).
The lack
the rate (at
of decline
and receptors.
1316
likely erythro-
in this
set
and inactivated of reactions
(Table
1)
bonds between NEM and the recepthe proposed scheme by showing a
submaximal in
is
:
of inactivation (-)-13Hl-
consecutive treatment of the membranes with.the may be explained by the reversible interaction
it
in an increased by NEM. Both
*r agonist-bound
free,
is
linear
resulting
scheme NEM
As a
of turkey
(inactivation)
following
1 ).
and
in a synergistic
receptors
change,
erythro-
of the re-
the reagent
(Table
receptor
alkylation
of two types
by NEM has not been
and Methods),
to the f31-adrenergic
of
of turkey
when both
molecule
B-adrenergic
types
in the number
simultaneously
a conformational
sensitivity
catechol
of these
receptors
sites)
(Materials
the
of agonists
occu-
desensitization
neither
decrease
(-)-isoproterenol
chromatography
compounds
fashion.
a marked
are present
of the
equal
conditions,
various
cause
(IO-12),
DHA binding
(-)-isoproterenol
chemical
agonists
the @I-adrenergic is
by (-)-13Hl-
2).
tested
or the non-bioactive
tissues
affect there
2, were
compounds
NEM inactivates
and @-adrenergic
However,
(-)-pheny-
DHA (Table
the same preincubation
agent
in several
independently
membranes.
isoproterenol
to the membranes.
the alkylating
receptors
of compounds
Under
(-)-13Hl-
the three
phentolamine
DHA binding
DISCUSSION : Although hormone
sites.
(-)agonist
used in table
so that
the a-antagonist
do not affect
ligands
the receptor,
50 % of the receptor
by NEM plus
of the partial
of the antagonist
of the B-adrenergic
KD-value
NEM plus
receptors
by NEM in the presence
and the
concentrations, DHA binding reagent between
concentration
of
where activity
after
and the agonist (Table @-adrenergic agonists
I),
Vol.
86,
No.
There changes
BIOCHEMICAL
4, 1979
are
some striking are closely 1 and ref.
duce adenylate
cyclase
ability
than
to sensitize
in presence
of the antagonist
Recently, formation
Cassel
between
involves
GTP-ase
proterenol
than
by NEM in
in its
ligands
NEM inactivates
(-)-isoproterenol(Fig.
2).
of B-adrenergic
receptors,
or the dissociation red as possible conclude
which
reagent
can form
covalent
bonds
We observed recently that of 8-adrenergic receptors
fact
argued
for
types
formation
is
tion tor
by NEM.
a different of ligands.
induced receptor,
with
sites
type
cyclase
all
the
results
of agonists
is
observation.
(->-13Hl-
interaction
be conside-
At present, by NEM.
increases antagonists(g). that
the affiThis the receptor
a change
is now under
sensitivity change
1.
3. 4. 5.
to the
of the recep-
investigation.
HABER E. and WRENN S. (1976) Physiological Revs., 56, 317-338. LEFKOWITZ R.J., LIMBIRD L.E., MUKHERJEE C. and CARON M.G., (1976) Biochim. Biophys. Acta., 457, l-39. MUKHERJEE C., CARON M.G., MULLIKIN D. and LEFKOWITZ R.J. (1976) Mol. Pharmacol., 11, 16-31. BROWN E.M., FEDAK S.A., WOODARD C.J. and AURBACH G.D., (1976) J. Biol. Chem., 251, 1239-1246. LEVITZKY A., SEVILLA N., ATLAS D. and STEER M.L. (1975) J. Mol. Biol. Chem., jy7, 35-53.
1317
of con-
to inactiva-
REFERENCES :
2.
we
This groups(lg).
not of antagonists
the conformational
of
molecule,
might
between
suggest
DHA categories
or imidazole
selectively not for
but
receptor
this
receptor
alkylated
by the increased
activation,
of (-)-iso-
represented
inactivation.
of molecular
between
erythrocytes
in the presence
on a single
sulphydryl-,amino-
The present
as indicated
explain
by agonists
but
of in-
The catecholamine-
of two equally
solubilization for agonists
by the binding
The relationship
and the adenylate
with
of the B-receptor
nity
and both
interact
of the partial
moiety
5)
transmission
in turkey
no more than half
receptor-complexes
significant
of the @-adrenergic might
of two binding
interpretations
can not
the
to NEM in presence
agonists
The existence
of binary
2 and ref. cyclase
to
by NEM.
and not
that
The inactivation
of B-adrenergic
related
(-)-isoproterenol
GTP-ase(l7).
was more sensitive
the S-adrenergic
sites(Fig.l),
S-adrenergic
and adenylate
absence.
the presence
Although
(Table
of a membrane-bound
activity
that
to inactivation
(-)-phenylephrine,
have reported
the S-receptors
closely
of the agonist
(-)-13Hl-DHA
conformational suggesting
is
receptors
in presence
and Selinger
the activation
stimulated
activity)
the B-adrenergic agonist
activation,
processes are fast and reversible of B-adrenergic ligands to in-
(intrinsic
of the partial
COMMUNICATIONS
agonist-induced
cyclase
: i) Both The ability
activation
is more pronounced
in presence
binding
related 16) ii)
RESEARCH
between
and adenylate
both phenomena (Fig. 2, Table their
BIOPHYSICAL
similarities
of the S-receptors
Inactivation
AND
Vol. 86, No. 4, 1979
6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FURCHGOTT R.F. (1970) Fed. Proc., 29, 1352-1361 Biophys. Acta., 127, 347-354. @YE I., SUTHERLAND E.W. (1966) BiocEm. LOWRY O.H., ROSEBROUGH N.J., FARR A.L. and RANDALL R.J. (1951) J. Biol. Chem., 193, 265-275. VAUQUELIN G., GEYNET P., HANOUNE J. and STROSBERG A.D. (1977) Acad. Sci. USA., 76, 3710-3714. Proc. Natl. MUKHERJEE C. and LEFKOWITZ R.J. (1976) Proc. Natl. Acad. Sci. USA., 12, 1494-1498. KEBABIAN J.W., ZATZ M., ROMERO J.E. and AKELROD J. (1975) Proc. Natl. Acad. Sci. USA., 11, 3735-3739. Chem., SHEAR M., INSEL P-A., MELMON K.L. and COFFIN0 P. (1976) J. Biol. 251, 7572-7576. HANSKI E. and LEVITZKY A. (1978) Life Sciences, 22, 53-60. SALMAN K.N., CHAI H.S., MILLER D.D. and PATIL P.N. (1976) Eur. J. Pharmacol., 36, 41-48. (1975) Proc. Natl. Acad. Sci. USA., 11, SIMON E.J. and GROTH J. 2404-2407. BLR H.P. (1974) Mol. Pharm., '0, 597-604. Biophys. Acta., 452, 538-551. CASSEL C. and SELINGER Z. (1976) Biochim. J., 2, SMYTH D.G., BLUMENFELD 0.0. and KONIGSBERG W. (1964) Biochim. 589-595.
1318