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Characterization of specific binding sites for PAF in the iris and ciliary body of rabbit
Vol.
160,
No.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
1, 1969
Pages
April 14, 1969
CHARACTERIZATION IN THE M.T.
Domingo,
OF SPECIFIC IRIS
AND
P.E.
Chabrier,
N . J - Van
BINDING
CILIARY
BODY
J.L.
Haeringem
lnstitut
Henri
PAF
Delft,
N-L.
Verbeij,
P. Braquet*
Beaufour
1, avenue
des Tropiques
91952
ULIS,
LES
FOR
OF RABBIT
Van
and
SITES
250-256
France
Received January 13, 1989 The protective effect exerted by BN 52021 a specific PAP-receptor antagonist in experimentally induced ocular inflammatory disorders led us to investigate the possible presence of specific receptors for PAP in rabbit iris and ciliary body. Two classes of P?IF binding sites were found in isolated iris and ciliary process of pigmented rabbit eyes : a high affinity site Kdl = 4.9 + 0.47 nM, Bmax, = 3.17 + 0.50 pmoles/mg protein, a low affinity sites K& = 11.6 + 0.33 nM, Bmax, = 12.46 + 2.3 pmolesjmg protein for iris. The specific binding was not affected by lyso-PAP the biologically inactive precursor and metabolite of PAF, up to 10-6M . inhibition by unlabelled PAP demonstrated a biphasic curve partially a&agonized by BN 52021. The present results demonstrate the presence of specific binding sites for PAP in rabbit eyes which could mediate the action of this mediator in eye inflammatory processes and explain the protective effect observed with BN 52021.
Q 1989
Academic
Platelet rylcholine)
factor
(PAF,
is an ether-linked
released
and from
endothelials
platelets
cells
exocytosis
muscle
in and
Il.
neutrophils
2, (5).
appropriately and
PAF
also
induces
in various 3).
PAF
(6).
It induces
neutrophils,
increases
inflammatory,
is synthetized
macrophages
stimulated.
platelets
In vivo
contraction
failure
when
involved
disorders
(41,
(8)
1 -O-alkyl-2-acetyl-sn-glycerol-phospho-
phospholipid
respiratory
thrombocytopenia.
(7)
and
aggregation and
leukopenia
vascular
permeability,
bronchoconstriction
hypotension,
and
smooth and
renal
(9,101. The
of its
availability
proposed One
potent
and
aggregation * To
Inc.
activating
cardiovascular
and
Press,
whom
0006-291X/89
of specific
role
such (11)
antagonists
in pathophysiological
compound,
selective
PAF
the
PAF and
correspondence
has
models
ginkgolide
antagonist been should
for
be addressed.
250
the
investigation
of inflammation.
BN 52021, PAF
demonstrated
$1.50
Copyright 0 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
has allowed
induced to exert
has been platelet
described and
a protective
as a
neutrophil effect
in
BIOCHEMICAL
Vol. 160, No. 1, 1989
various
experimental
cardiac
models
anaphylaxis Recently
infiltration (18).
and and
breakdown
rabbit
the
blood
Furthermore, deleterious
vivo
electroretinogram These PAF binding
sites
in eye
led
sites
inflammation,
in
induced
amplitude
eye.
‘H-PAF
and
BN 52021
the
and
ciliary
pulmonary
and
irradiation rats the of
the
the
in two
leukocyte
immune
keratitis (IOP)
and
(19). dramatic
beta-wave
and of
the
(20).
possible
present
block
pressure
by BN 52021 The
to by
intraocular
us to examine
MATERIALS
shown
after laser diabetic
inhibited
rabbit iris
been
of
the
(12.13)
(16,171.
cornea,
rise
in
is also
observations using
acute
shock
has
in the
decrease
(ERG)
recognition
52021
aqueous barrier alloxan-induced
in
ex
endotoxin ischemia
BN
formation
prevent
of the
brain
eye,
edema
to
including
(14,15),
in
AND BIOPHYSICAL RESEARCH COMMUNlCATtONS
study of the
presence
of
characterized main
areas
specific PAF
implicated
body. AND
METHODS
Materials
Synthetic tritiated PAF (3H-PAF) with a specific activity of 59.5 Ci per mmole was purchased from New England Nuclear (DuPont de Nemours, France). Unlabelled PAF and lyso-PAF were purchased from Calbiochem (France), in solubilized in ethanol and stored at - 20° C. BN 52021 was solubilized heparin (Roche) were purchased from Coger DMSO. Pentobarbital (Clin-Midy), Industries (France). Tissue
preparation
Pigmented rabbits (either sex) were injected with heparin (1 000 UI per rabbit) 5 minutes prior to sacrifice by an overdose of pentobarbital. Eyes were enucleated and placed into ice cold 50 mM tris-HCl buffer pH 1.4, containing 10 mMMgCl,, 2 mNEDTA, 50 UI per ml trasylol and lo-'M PMSF. The perfused prior to dissection in order to remove the eyes were arterially blood of anterior segment. The iris and ciliary body were carefully dissected out and homogenized using a dounce homogenizer. The homogenates were filtered through 2 layers of gauze and centrifugated twice at 40 000 g for 20 minutes. The pellets were resuspended in the homogenization buffer and assayed for protein content using BIORAD protein assay reagent and bovine serum albumin as the standard. The
binding
assay
40 to 70 ug of protein was added to a final volume of 1 ml of 10 mMtris HCl buffer, containing MgCl, 5 mM, BSA 0.025 %, trasylol 50 UI per ml, PMSF 10-4M, pH 7 in plastic tubes containing 3H-PAF (lo-'1) with or without 10-6M unlabelled PAF (for nonspecific binding), lyso-PAF or the PAF-receptor antagonist BN 52021. The incubation was carried out for 40 minutes at 25O C. The unbound ligand was separated from the bound by immediate filtration through Whatman GF/B fiber-Filters presoaked 24 hrs in the binding buffer and using the BRANDEL vacuum system (Brandel, Biomedical Research and Development Laboratories Gathersburg MD/USA). The assay tubes and filters were washed 3 times with 3 ml of precooled binding buffer. The filters were placed into polyethylene vials containing 10 ml of liquid scintillation fluid (instagel, Packard). The radioactivity was measured using a 45 % efficiency LEB counter. The specific binding was calculated as previously described (21). Binding data were analyzed by Scatchard method using the computerized programm of VINDIMIAN et al. (22). 251
Vol. 160, No. 1, 1989
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
In some experiments the stability of the tritiated ligand was analysed after 40 minutes incubation and extraction from the reaction mixture using the solvent system, chloroform : methanol, 2 : 1 and separation on T.L.C. silica plates (Prolabo SIL Gz5 UV 250) using a chloroform : methanol : ammonia, 70 : 35 : 7. system. In our binding conditions intact 3H-PAF represented 93 % of the total radioactivity recovered from the plates. RESULTS Binding
of 3H-PAF
- Saturation ciliary
study
body
and
a function protein
both
in
concentration
was
linear
body,
and
and
ciliary
of
the
specific
biphasic
of
‘H-PAF
saturation nM
- Competition was
assessed
PAF
receptor
a
(Figure
second
study
: The
step the
BN
52021,
in
to
of the
about
first binding
compete
to iris PAF, with
% of of
as
the
total
increasing
demonstrated
reached
observed
of unlabelled to
20
10D8M)
step
and
binding
of 10 to 90 ug of
function
x
iris
specific
range
a
1.4
in cornea,
The
the
was
was
ability
found
two.
as
1) . The
specificity
by determining antagonist
8 10”’
was
latter
binding
(from
isotherm
and
binding
in the
iris
Study
concentrations
specific
characterized
of protein
binding.
4-5
: ‘H-PAF was
a maximum
at
10.8
and
ciliary
lyso-PAF
‘H-PAF
a at nM. body
and
binding.
A ll10 9. z_ i-f E
B7.
0 II 2.7 3.9 45 5.4 6.3 7.2 9.1 9 89 10.9 11.712.9 “H-PAF (nM ) Figure 1 The binding 13.5 nM. performed BSA 0.025
in iris at 25OC. - Typical saturation isotherm for 'H-PAP binding was performed over radioligand concentration range of 1 nM to Each point is the average of triplicate and n = 4. The assay was 50 UI per ml and in tris 10 mM, MgC12 5 mM, PMSF 10-4M, trasylol % pH 7 buffer. 252
the As
BIOCHEMICAL
Vol. 160, No. 1, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
100
[ANTAGONIST 1 Figure unlabelled average
shown
2
-
Inhibition
PAF (O-O), triplicate
of
in figure
A biphasic binding
2,
partially
Scatchard competition
plot studies
(1-3
nM) binding and lyso-PAF ; n = 4.
no displacement
displacement was
of 'H-PAF BN 52021 M) determinations
curve displaced analysis demonstrated
of
was observed
MgCl,
at
with
was observed
with
(60 %I by
BN 52021.
the
binding
data
a curvilinear
3H-PAF Figure3 10 mM, buffer, n = 4.
to (w).
BOUND
lyso-PAF
unlabelled from
PAF both
distribution
by the
up to
106M.
and
‘H-PAF
saturation (Figure
and 3).
(nM )
Scatchard analysis of 'H-PAF binding to iris 5 mM, PMSF 10-‘M, trasylol 50 UI per ml, 25V. Each point is the average of triplicate
253
iris homogenate Each point is
homogenate in tris BSA 0.025 % pH 7 determinations ;
A
Vol. 160, No. 1, 1969
BIOCHEMICAL
a
10
I5
20
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
25
30
35
40
45
56
50
60
(Min)
TIME
Figure 4 - Typical association and dissociation kinetic curve of 'H-PAF binding in iris or ciliary body. The experiment was performed at 25°C in tris 10 mM, MgCl? 5 mM, PMSF 10-4M, trasylol 50 UI per ml and bovine serum albumin 0.025 % pH I buffer.
high
affinity
and for
site
a low iris
affinity
- Kinetic
site
study
(Kd2
: As
of ‘H-PAF
within
the C.
mixture
+ 0.47
nM Bmax,
= 11.6
shown
(l-3
first
by
nM)
25 minutes
An
excess
at
30
reversibility was
= 4.9
+ 0.33
nM,
= 3.17
2 0.5
pmole/mg
Bmax2
= 12.46
+ 2.3
protein pmole/mg
; n=5).
binding 25O
(Kd,
of
min
and
45
binding
after
45 min.
kinetic and
of reaction
unlabelled
of the
observed
the
to iris
and
PAF
(1
of
the
min (about
curve
ciliary
(Figure
body
remained 000
fold)
time
41,
reached
specific state
stable
up
to 60 min
added
to
the
course
50 %) at 30 min.
the
a steady
showed
whereas
reaction a
no
at
partial
reversibility
DISCUSSION The here
3H-PAF
binding
demonstrate The
70-80
the
percent but
for
lung
human
brain
tissue
Specific PAF,
over
experiments, binding
in the
of PAF in
is comparable tissue
or
the
crude
binding the
range a
two
characteristics.
rabbit
iris
tissues
platelet low
to the
20-25
preparation
is low
membrane
specific
that
ciliary
body
reported
sites.
in these
rabbit
possible
and
recognition
to the
(24)
nonspecific
on
binding
binding
I21 1. It is also
concentrations increased
presence
of specific
% of specific
conditions,
studies
binding
used
to the buffer
binding
which
for
compared the
same
(30-40
% specific melanin,
in
these
8)
described
described
is present tissues,
for
in high
might
have
binding. as a function of step
8.10-l’
of increasing to
14.10-‘M
saturation
Results
have
isotherm,
of saturation 254
concentrations shown
from
suggesting
experiments
of
were
labelled
replicated
heteregenous confirmed
by
BIOCHEMICAL
Vol. 160, No. 1, 1989 displacement
studies
Displacement
by
where
unlabelled
scatchard
analysis
revealed
described
by a two
component
In
the
Kd, = 4.9 component protein.
iris,
the
the
two
PAF
presented
binding
a
curvilinear
steps
easier
to
inhibition
distribution,
computerized
binding
were
a biphasic
describe.
curve.
which
The
was
better
analysis.
characteristics
of
the
first
component
were
= 3.17 pmol/mg protein and for the second -+ 0.47 nM and Bmax, Kd2 = 11.6 + 0.33 nM associated with Bmax2 = 12.46 pmol/mg
Similar
nM Bmax
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
results
= 3.41
1
were
obtained
2 1 pmol/mg
and
for
Kd2
ciliary
= 24.4
body
with
+ 0.91
Kd,
= 5.7 + 0.09
nM Bmax2
= 16.6
+ 0.51
pmol I mg . In our
study,
experiments 52021,
using up
differed
from
that
did
maximum only
PAF
partial
the
course
45
This
dissociation. site
associated
medium
was
The several
not
significantly
presence
inflammatory conjunctiva
Given pressure
and
the
due
to the
(19).
PAF
is
also
suggest
study
rabbit
iris
inflammation.
and
ciliary
How
these
inflammation distinct
same receptor
types site
by its
serum chick
PAF
however
binding
two
these
different
to be clarified. 2.55
many in
rat
by to
of
into
upon
a
inhibit
in
intraocular the
laser
aqueous irradiation
stimulation eye
with
function
and
binding
site
mediated.
main
of
rise by
retina
of
whether
in
(18).
barrier
body,
classes
the
since
antagonized
proteins
aqueous
the
to
in
PAF
reported
the
may be receptor
two
time
binding
PAF of
keratitis
implicate
effect
or
a
expected
of
also
inhibits
of
blood
results
and
associated
of PAF 3 H-PAF
was
response was
subclasses
two
be
injections
of two
receptor
remains
dose
coexistence
processes, of
low
also
embryo
These the
participation
in immune
leakage of the
that
shows
the
52021
drug
subsequent
(25).
and
Our
edema
the
noticeably
experiments,
since
in eyes
inflammatory
cornea1
BN
assay.
sites
Local
BN
produced
ligand
in our
(23).
disruption
neurotransmitters pathology
and
to
In kinetic
to disapearence bound
binding
marked
preventively,
humor
two
a
infiltration
the
eye.
and
‘H-PAF
BN 52021
appeared
curve.
demonstrated the
antagonist
leukocyte
during
in
elicitated
PAF-receptor
in
have
processes
of
specific
PAF.
to inhibit
with
60 % and
degradated
of PAF
studies
obtained
may be attributed
a captation
of
failed
%) was observed at 35 min of the 3 the H-PAF binding was resistant
incubation
property
analog
by competition
monophasic and only partial. In fact, 3 H-PAF binding in these tissues. The
about I50
assessed
inactive
competition
binding
min
with
recent
was
of the
of the
after
:
it was
was
Lyso-PAF
curve
completely
step
dissociation
biologically
since
obtained
first
binding
antagonist.
inhibition
inhibit
inhibition
with
The
of PAF
not
of the
the
receptor
to 10m6M.
52021
specificity
lyso-PAF,
a specific
binding BN
the
areas
of PAF involved
in
sites
interact
with
two
subclasses
conformational
ocular PAF
represent states
of the
Vol. 160, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACKNOWLEDGMENT The
authors
wish
to thank
Mr
Moumen
Mohamed
for
technical
help.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23.
24. 25.
Henson, P.M., and Pinckard, R.N. (1977) Monogr. Allergy. 12, 13-26. Baranes, J., Hellegouarch, A., Le Hegarat, M., Viossat, I., Auguet M ., Chabrier, P.E., Clostre, F., and Braquet, P. (1986) Pharmacoi. Res. Commun. 18, 717-737. Vargaftig, B.B., Lefort. J ., Chignard, M., and Benveniste, J. (1980) Eur. J. of Pharmacol. 65, 185-192. Vargaftig, B.B., Chignard. M., Benveniste, J. (1981) Ann. N.Y. Acad. Sci. 370, 119. Pinckard, R.N., Mac Manus, L.M., Hanahan, D.J. (1982) Adv. Inflamm. Res. 4, 147. Jouvin-Marche, E., Ninio, E., Beaurain, G., Ten&, C., Niaudet P., Benveniste, J. (1984) J. lmmunol. 133, 892. Snyder, F. (1985) Med. Res. Rev. 5, 107. Bussolino, F.. Biffignaudi, P., and Arese, P. (1986) Acta Haematol. 75, 129. Pirotzky, E.. Ninio, E.. Bidault, J., Pfister, P., and Benveniste. J. (1984) Lab. invest. 51, 567-572. Schlondorff, D., Goldwasser, P., Neuwirth, R., Satriano, J.A., and Clay, K.L. (1986) Am. J. of Physiosol. 250, F-1123-1127. (1987) Drugs of the future. J.R. Prous Science Braquet, P. Publishers. 12(7), 643-699. Etienne, A., Hecquet, F., Soulard, C., Spinnewyn, B., Clostre, F., and Braquet, P. (1985) Agents and Actions. 17, 368-370. Wallace, J.L., Steel, G., Whittle, B.J.R., Lagente, V., and Vargaftig B. B. ( 1987) Castroenterol . Braquet, P., Guinot, P., and Touvay, C. In Platelets PAF and asthma (M. Smith-Schumann, G. Menz and C. Page, Ed. ), Agents and Actions, Suppl. 21, pp.97. Birkhaiiser Verlag, Base1 Boston. Berti, F. Rossoni, G. (1987) In The Cinkgolides : Chemistry, biology, pharmacology and clinical sciences (P. Braquet. Ed. ), Methods and findings in experimental and clinical pharmacol. Spinnewyn, B., Blavet, N., Clostre, F., Bazan, N., and Braquet, P. (1987) Prostaglandins. 34(3), 337-350. Kriegeistein, J., Beck, T., and Seibert, A. (1986) Life science. 39. 2327-2334. and Van Haeringen N.J. (1987) In Cinkgolides : Verbey N.L.J., Chemistry, biology, pharmacology and clinical sciences (P. Braquet. Ed.), Methods and findings in experimental and clinical pharmacology. Verbey, N.L. J., Braquet, P. and, Van Haeringen, N. J. (1987) Satellite Meet Rec. Adv. Platelet activating factor (Sept. 3-5 Brisbane). Daly, M.. Droy, M.T., Bonhomme, B., Ruchoux, M.M.. Braquet, P.. and Meyniel, G. (1989) Neurochem. pathol. (In press). Domingo, M.T., Spinnewyn, B., Chabrier, P-E., and P. Braquet. (1988) BBRC. 151(2), 730-736. Vindimian, E., Robaut, C., and Fillion, G. (1983) Applied Biochem. 5. 261-268. Domingo, M.T., Chabrier, P.E. Dray, F., and Braquet. P. (1988) In and clinical biology, pharmacology Ginkgolides : Chemistry, perspectives (P. Braquet, Ed. 1, J. R. Prous science (Publishers). 1, 79-84. Shen, T.Y. (1985) BBRC. 128(2). 972979. Hwang, S.B., Lam, M.H., Bussolino, F., Cremo, F., Tetta, C., Pescarmona, G.P., and Camussi C. (1986) JBC. 261, 16502-16508.
256
160,
No.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BIOCHEMICAL
1, 1969
Pages
April 14, 1969
CHARACTERIZATION IN THE M.T.
Domingo,
OF SPECIFIC IRIS
AND
P.E.
Chabrier,
N . J - Van
BINDING
CILIARY
BODY
J.L.
Haeringem
lnstitut
Henri
PAF
Delft,
N-L.
Verbeij,
P. Braquet*
Beaufour
1, avenue
des Tropiques
91952
ULIS,
LES
FOR
OF RABBIT
Van
and
SITES
250-256
France
Received January 13, 1989 The protective effect exerted by BN 52021 a specific PAP-receptor antagonist in experimentally induced ocular inflammatory disorders led us to investigate the possible presence of specific receptors for PAP in rabbit iris and ciliary body. Two classes of P?IF binding sites were found in isolated iris and ciliary process of pigmented rabbit eyes : a high affinity site Kdl = 4.9 + 0.47 nM, Bmax, = 3.17 + 0.50 pmoles/mg protein, a low affinity sites K& = 11.6 + 0.33 nM, Bmax, = 12.46 + 2.3 pmolesjmg protein for iris. The specific binding was not affected by lyso-PAP the biologically inactive precursor and metabolite of PAF, up to 10-6M . inhibition by unlabelled PAP demonstrated a biphasic curve partially a&agonized by BN 52021. The present results demonstrate the presence of specific binding sites for PAP in rabbit eyes which could mediate the action of this mediator in eye inflammatory processes and explain the protective effect observed with BN 52021.
Q 1989
Academic
Platelet rylcholine)
factor
(PAF,
is an ether-linked
released
and from
endothelials
platelets
cells
exocytosis
muscle
in and
Il.
neutrophils
2, (5).
appropriately and
PAF
also
induces
in various 3).
PAF
(6).
It induces
neutrophils,
increases
inflammatory,
is synthetized
macrophages
stimulated.
platelets
In vivo
contraction
failure
when
involved
disorders
(41,
(8)
1 -O-alkyl-2-acetyl-sn-glycerol-phospho-
phospholipid
respiratory
thrombocytopenia.
(7)
and
aggregation and
leukopenia
vascular
permeability,
bronchoconstriction
hypotension,
and
smooth and
renal
(9,101. The
of its
availability
proposed One
potent
and
aggregation * To
Inc.
activating
cardiovascular
and
Press,
whom
0006-291X/89
of specific
role
such (11)
antagonists
in pathophysiological
compound,
selective
PAF
the
PAF and
correspondence
has
models
ginkgolide
antagonist been should
for
be addressed.
250
the
investigation
of inflammation.
BN 52021, PAF
demonstrated
$1.50
Copyright 0 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
has allowed
induced to exert
has been platelet
described and
a protective
as a
neutrophil effect
in
BIOCHEMICAL
Vol. 160, No. 1, 1989
various
experimental
cardiac
models
anaphylaxis Recently
infiltration (18).
and and
breakdown
rabbit
the
blood
Furthermore, deleterious
vivo
electroretinogram These PAF binding
sites
in eye
led
sites
inflammation,
in
induced
amplitude
eye.
‘H-PAF
and
BN 52021
the
and
ciliary
pulmonary
and
irradiation rats the of
the
the
in two
leukocyte
immune
keratitis (IOP)
and
(19). dramatic
beta-wave
and of
the
(20).
possible
present
block
pressure
by BN 52021 The
to by
intraocular
us to examine
MATERIALS
shown
after laser diabetic
inhibited
rabbit iris
been
of
the
(12.13)
(16,171.
cornea,
rise
in
is also
observations using
acute
shock
has
in the
decrease
(ERG)
recognition
52021
aqueous barrier alloxan-induced
in
ex
endotoxin ischemia
BN
formation
prevent
of the
brain
eye,
edema
to
including
(14,15),
in
AND BIOPHYSICAL RESEARCH COMMUNlCATtONS
study of the
presence
of
characterized main
areas
specific PAF
implicated
body. AND
METHODS
Materials
Synthetic tritiated PAF (3H-PAF) with a specific activity of 59.5 Ci per mmole was purchased from New England Nuclear (DuPont de Nemours, France). Unlabelled PAF and lyso-PAF were purchased from Calbiochem (France), in solubilized in ethanol and stored at - 20° C. BN 52021 was solubilized heparin (Roche) were purchased from Coger DMSO. Pentobarbital (Clin-Midy), Industries (France). Tissue
preparation
Pigmented rabbits (either sex) were injected with heparin (1 000 UI per rabbit) 5 minutes prior to sacrifice by an overdose of pentobarbital. Eyes were enucleated and placed into ice cold 50 mM tris-HCl buffer pH 1.4, containing 10 mMMgCl,, 2 mNEDTA, 50 UI per ml trasylol and lo-'M PMSF. The perfused prior to dissection in order to remove the eyes were arterially blood of anterior segment. The iris and ciliary body were carefully dissected out and homogenized using a dounce homogenizer. The homogenates were filtered through 2 layers of gauze and centrifugated twice at 40 000 g for 20 minutes. The pellets were resuspended in the homogenization buffer and assayed for protein content using BIORAD protein assay reagent and bovine serum albumin as the standard. The
binding
assay
40 to 70 ug of protein was added to a final volume of 1 ml of 10 mMtris HCl buffer, containing MgCl, 5 mM, BSA 0.025 %, trasylol 50 UI per ml, PMSF 10-4M, pH 7 in plastic tubes containing 3H-PAF (lo-'1) with or without 10-6M unlabelled PAF (for nonspecific binding), lyso-PAF or the PAF-receptor antagonist BN 52021. The incubation was carried out for 40 minutes at 25O C. The unbound ligand was separated from the bound by immediate filtration through Whatman GF/B fiber-Filters presoaked 24 hrs in the binding buffer and using the BRANDEL vacuum system (Brandel, Biomedical Research and Development Laboratories Gathersburg MD/USA). The assay tubes and filters were washed 3 times with 3 ml of precooled binding buffer. The filters were placed into polyethylene vials containing 10 ml of liquid scintillation fluid (instagel, Packard). The radioactivity was measured using a 45 % efficiency LEB counter. The specific binding was calculated as previously described (21). Binding data were analyzed by Scatchard method using the computerized programm of VINDIMIAN et al. (22). 251
Vol. 160, No. 1, 1989
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
In some experiments the stability of the tritiated ligand was analysed after 40 minutes incubation and extraction from the reaction mixture using the solvent system, chloroform : methanol, 2 : 1 and separation on T.L.C. silica plates (Prolabo SIL Gz5 UV 250) using a chloroform : methanol : ammonia, 70 : 35 : 7. system. In our binding conditions intact 3H-PAF represented 93 % of the total radioactivity recovered from the plates. RESULTS Binding
of 3H-PAF
- Saturation ciliary
study
body
and
a function protein
both
in
concentration
was
linear
body,
and
and
ciliary
of
the
specific
biphasic
of
‘H-PAF
saturation nM
- Competition was
assessed
PAF
receptor
a
(Figure
second
study
: The
step the
BN
52021,
in
to
of the
about
first binding
compete
to iris PAF, with
% of of
as
the
total
increasing
demonstrated
reached
observed
of unlabelled to
20
10D8M)
step
and
binding
of 10 to 90 ug of
function
x
iris
specific
range
a
1.4
in cornea,
The
the
was
was
ability
found
two.
as
1) . The
specificity
by determining antagonist
8 10”’
was
latter
binding
(from
isotherm
and
binding
in the
iris
Study
concentrations
specific
characterized
of protein
binding.
4-5
: ‘H-PAF was
a maximum
at
10.8
and
ciliary
lyso-PAF
‘H-PAF
a at nM. body
and
binding.
A ll10 9. z_ i-f E
B7.
0 II 2.7 3.9 45 5.4 6.3 7.2 9.1 9 89 10.9 11.712.9 “H-PAF (nM ) Figure 1 The binding 13.5 nM. performed BSA 0.025
in iris at 25OC. - Typical saturation isotherm for 'H-PAP binding was performed over radioligand concentration range of 1 nM to Each point is the average of triplicate and n = 4. The assay was 50 UI per ml and in tris 10 mM, MgC12 5 mM, PMSF 10-4M, trasylol % pH 7 buffer. 252
the As
BIOCHEMICAL
Vol. 160, No. 1, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
100
[ANTAGONIST 1 Figure unlabelled average
shown
2
-
Inhibition
PAF (O-O), triplicate
of
in figure
A biphasic binding
2,
partially
Scatchard competition
plot studies
(1-3
nM) binding and lyso-PAF ; n = 4.
no displacement
displacement was
of 'H-PAF BN 52021 M) determinations
curve displaced analysis demonstrated
of
was observed
MgCl,
at
with
was observed
with
(60 %I by
BN 52021.
the
binding
data
a curvilinear
3H-PAF Figure3 10 mM, buffer, n = 4.
to (w).
BOUND
lyso-PAF
unlabelled from
PAF both
distribution
by the
up to
106M.
and
‘H-PAF
saturation (Figure
and 3).
(nM )
Scatchard analysis of 'H-PAF binding to iris 5 mM, PMSF 10-‘M, trasylol 50 UI per ml, 25V. Each point is the average of triplicate
253
iris homogenate Each point is
homogenate in tris BSA 0.025 % pH 7 determinations ;
A
Vol. 160, No. 1, 1969
BIOCHEMICAL
a
10
I5
20
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
25
30
35
40
45
56
50
60
(Min)
TIME
Figure 4 - Typical association and dissociation kinetic curve of 'H-PAF binding in iris or ciliary body. The experiment was performed at 25°C in tris 10 mM, MgCl? 5 mM, PMSF 10-4M, trasylol 50 UI per ml and bovine serum albumin 0.025 % pH I buffer.
high
affinity
and for
site
a low iris
affinity
- Kinetic
site
study
(Kd2
: As
of ‘H-PAF
within
the C.
mixture
+ 0.47
nM Bmax,
= 11.6
shown
(l-3
first
by
nM)
25 minutes
An
excess
at
30
reversibility was
= 4.9
+ 0.33
nM,
= 3.17
2 0.5
pmole/mg
Bmax2
= 12.46
+ 2.3
protein pmole/mg
; n=5).
binding 25O
(Kd,
of
min
and
45
binding
after
45 min.
kinetic and
of reaction
unlabelled
of the
observed
the
to iris
and
PAF
(1
of
the
min (about
curve
ciliary
(Figure
body
remained 000
fold)
time
41,
reached
specific state
stable
up
to 60 min
added
to
the
course
50 %) at 30 min.
the
a steady
showed
whereas
reaction a
no
at
partial
reversibility
DISCUSSION The here
3H-PAF
binding
demonstrate The
70-80
the
percent but
for
lung
human
brain
tissue
Specific PAF,
over
experiments, binding
in the
of PAF in
is comparable tissue
or
the
crude
binding the
range a
two
characteristics.
rabbit
iris
tissues
platelet low
to the
20-25
preparation
is low
membrane
specific
that
ciliary
body
reported
sites.
in these
rabbit
possible
and
recognition
to the
(24)
nonspecific
on
binding
binding
I21 1. It is also
concentrations increased
presence
of specific
% of specific
conditions,
studies
binding
used
to the buffer
binding
which
for
compared the
same
(30-40
% specific melanin,
in
these
8)
described
described
is present tissues,
for
in high
might
have
binding. as a function of step
8.10-l’
of increasing to
14.10-‘M
saturation
Results
have
isotherm,
of saturation 254
concentrations shown
from
suggesting
experiments
of
were
labelled
replicated
heteregenous confirmed
by
BIOCHEMICAL
Vol. 160, No. 1, 1989 displacement
studies
Displacement
by
where
unlabelled
scatchard
analysis
revealed
described
by a two
component
In
the
Kd, = 4.9 component protein.
iris,
the
the
two
PAF
presented
binding
a
curvilinear
steps
easier
to
inhibition
distribution,
computerized
binding
were
a biphasic
describe.
curve.
which
The
was
better
analysis.
characteristics
of
the
first
component
were
= 3.17 pmol/mg protein and for the second -+ 0.47 nM and Bmax, Kd2 = 11.6 + 0.33 nM associated with Bmax2 = 12.46 pmol/mg
Similar
nM Bmax
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
results
= 3.41
1
were
obtained
2 1 pmol/mg
and
for
Kd2
ciliary
= 24.4
body
with
+ 0.91
Kd,
= 5.7 + 0.09
nM Bmax2
= 16.6
+ 0.51
pmol I mg . In our
study,
experiments 52021,
using up
differed
from
that
did
maximum only
PAF
partial
the
course
45
This
dissociation. site
associated
medium
was
The several
not
significantly
presence
inflammatory conjunctiva
Given pressure
and
the
due
to the
(19).
PAF
is
also
suggest
study
rabbit
iris
inflammation.
and
ciliary
How
these
inflammation distinct
same receptor
types site
by its
serum chick
PAF
however
binding
two
these
different
to be clarified. 2.55
many in
rat
by to
of
into
upon
a
inhibit
in
intraocular the
laser
aqueous irradiation
stimulation eye
with
function
and
binding
site
mediated.
main
of
rise by
retina
of
whether
in
(18).
barrier
body,
classes
the
since
antagonized
proteins
aqueous
the
to
in
PAF
reported
the
may be receptor
two
time
binding
PAF of
keratitis
implicate
effect
or
a
expected
of
also
inhibits
of
blood
results
and
associated
of PAF 3 H-PAF
was
response was
subclasses
two
be
injections
of two
receptor
remains
dose
coexistence
processes, of
low
also
embryo
These the
participation
in immune
leakage of the
that
shows
the
52021
drug
subsequent
(25).
and
Our
edema
the
noticeably
experiments,
since
in eyes
inflammatory
cornea1
BN
assay.
sites
Local
BN
produced
ligand
in our
(23).
disruption
neurotransmitters pathology
and
to
In kinetic
to disapearence bound
binding
marked
preventively,
humor
two
a
infiltration
the
eye.
and
‘H-PAF
BN 52021
appeared
curve.
demonstrated the
antagonist
leukocyte
during
in
elicitated
PAF-receptor
in
have
processes
of
specific
PAF.
to inhibit
with
60 % and
degradated
of PAF
studies
obtained
may be attributed
a captation
of
failed
%) was observed at 35 min of the 3 the H-PAF binding was resistant
incubation
property
analog
by competition
monophasic and only partial. In fact, 3 H-PAF binding in these tissues. The
about I50
assessed
inactive
competition
binding
min
with
recent
was
of the
of the
after
:
it was
was
Lyso-PAF
curve
completely
step
dissociation
biologically
since
obtained
first
binding
antagonist.
inhibition
inhibit
inhibition
with
The
of PAF
not
of the
the
receptor
to 10m6M.
52021
specificity
lyso-PAF,
a specific
binding BN
the
areas
of PAF involved
in
sites
interact
with
two
subclasses
conformational
ocular PAF
represent states
of the
Vol. 160, No. 1, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACKNOWLEDGMENT The
authors
wish
to thank
Mr
Moumen
Mohamed
for
technical
help.
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