- Email: [email protected]
Reversible inhibition of intercellular junctional communication by glycyrrhetinic acid
vol.
134,
No.
January
14,
1, 1986
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1986
Pages
REVERSIBLE INHIBITION
OF INTERCELLULAR JUNCTIONAL COMMUNICATIONBY GLYCYRRHETINIC ACID
James S. Davidson, Department
of
Chemical
29-36
Ingrid
M. Baumgarten and Eric
H. Harley
Pathology, University of Cape Tom Medical Observatory 7925, South Africa
School,
Received November 14, 1985
Intercellular gap-junctional communication was measured using metabolic co-operation in co-cultures of argininosuccinate synthetase-deficient and argininosuccinate lyase-deficient human fibroblasts. 18- Q-glycyrrhetinic acid (AGA) was found to inhibit communication by more than 95% at concentrations as up to 100 uM ware not cytotoxic over a period of 2 low as 2 uM. Concentrations hours. Communication inhibition was of rapid onset and was readily reversible. Communication remained continuously yet reversibly blocked in cells cultured in the presence of AGA for 20 days. The related compounds 18-p -glycyrrhetinic acid and carbenoxolone also caused communication inhibition. The effect is probably not mediated via mineralocorticoid or glucocorticoid receptors since aldosterone and glucocorticoids had no effect on communication. AGA thus has properties of a useful inhibitor in the study of intercellular junctional communication. 0 1986 Academic Press, Inc.
Gap junctions
INTRODUCTION: molecules
directly
the cytoplasmic measuring
cells
between
junctional
of the urea cycle
(3).
argininosuccinate
lyase-deficient
citrulline
into into
14C-citrulline via
by
junctions of
ratio
lines
derived
fibroblasts
from patients
simultaneous
able
with
is
no detectable
incorporation
for any added compound.
nor
to convert
of argininosuccinate
types
incorporate
between cells transfer
of 3H-phenylalanine
via
the
Serves
Thus the 14C-citrulline/3H-
of the mutant cells
that compounds could
inborn errors
to incorporate
of the two cell
1) and there
for
human
synthetase-deficient are
linking
system
in cultured
enzymes are required
both
the transfer (Fig.
aqueous channels A convenient
(IJC)
argininosuccinate
in co-cultures
Because of the possiblity
(1,2).
However co-cultures
efficiently
The rate
cells
the exchange of small
forming
by
conrnunication
protein , since
as an index of toxicity phenylalanine
Neither
arginine.
intercellular
medium (3).
in contact ,
uses two mutant cell
14C-citrulline
to mediate
of adjacent
compartments
intercellular
fibroblasts
are thought
inhibit
is a measure of IJC. one of the enzymatic 0006-291X/86 $1.50
29
Copyright 0 1986 AN rights of reproduction
b-v Academic Press, Inc. in any form reserved.
Vol.
134,
No.
BIOCHEMICAL
1, 1986
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
CIT 1 ASA
ASA
1 ARG * protein ASS-
Fig. 1.
steps
ASL-
Principle of assay of intercellular junctional conmunication. ASA = argininosuccinate: ARG = arginine. CIT = citrulline;
in citrulline
metabolism , it
is also
compounds on normal human fibroblasts
(4).
Gap-junctional pharmacological
investigate (4,10), that
intercellular inhibition
by
inhibition retinoids
several
by
classes study
acid
to monitor
has previously pesticides
phorbol
esters
(AGA) and the related
acid and carbenoxolone
the effects
is known to be susceptible of compounds (5-9).
organochlorine
(11) and tumor-promoting
18-a-glycyrrhetinic
18-fl-glycyrrhetinic
of IJC
necessary
communication
model used in the present
fibroblast
CELLS
NORMAL
are novel
of
to
The human
been employed to and related (11).
compounds
Here we report
compounds inhibitors
of IX.
MATERIALS AND METHODS wre obtained from Sigma Chemical Co. : Chemicals : The following acid, prednisolone, lupeol 18-Cr-glycyrrhetinic acid (AGA) , 18-fl-glycyrrhetinic and betulin. Glycyrrhizic acid was obtained from Aldrich Chemical Co. Cholesterol and hydrocortisone were from BDH Chemicals Ltd. Carbenoxolone sodium ws a kind gift from Berk Pharmaceuticals (Pty) Ltd. AGA, in dimethyl 18-/3-glycyrrhetinic acid, lupeol and betulin were dissolved sulfoxide (CNSO). Glycyrrhizic acid and carbenoxolone wre dissolved in water. The remaining chemicals were dissolved in ethanol. Final solvent concentration was 0.5% or less and appropriate solvent controls were included in each experiment. A fresh stock solution of AGA was prepared immediately before each experiment, as it us found that stored solutions had increased cytotoxicity. [Carbamoyl-14C]citrulline and [2,3-3H]phenylalanine were from the Radiochemical Centre, Amersham. of the human mutant fibroblast cell Metabolic co-operation assay : The origins lines were as described (3). They were maintained on Dulbecco’s Minimal Essential Medium (DMEM, Gibco) with 10% fetal calf serum (Gibco) in 4% 03 at of co-cultures and the assay of IJC viere as described t 4,10). 37oc. Preparation Briefly, trypsinised suspensions of the two cell types were mixed in equal proportions, plated at high density (confluent or subconfluent) and incubated for 18-22 hours. The co-cultures ware then incubated in labelling medium containing radioisotopes and test chemical(s). Where the labelling medium was time was 2 hours, hepes-buffered saline (medium B in ref. 4) incubation 14C-citrulline was used at 0.25 uCi/ml and 3H-phenylalanine at 0.6 uCi/ml. Where the cells were labelled in growth medium (DMEM with l0% fetal calf serum) 4C-citrulline at 1 uCi/m.l and 3H-phenylalanine incubation time was 5 hours with 30
Vol.
134,
No.
BIOCHEMICAL
1, 1986
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
After labelling, radioactivity in acid-insoluble cellular material 2 uCi/ml. was determined as described (10). All experiments were performed in duplicate Each point shown is the mean and repeated at least once with similar results. of duplicate wells, Bars on the figures are of a length equal to the difference betwaen duplicates and are omitted where this difference was less than 5%.
at
RESULTS: Exposure incorporation indicating
to AGA caused a dose-dependent
in co-cultures
of mutant cells,
that AGA inhibits
LJC in this
inhibition
but not in normal cells
human fibroblast
medium, IJC as measured by citrulline/phenylalanine inhibited overall
by 97% at 2 uM AGA. protein
synthesis,
as 100 uM over a 2-hour period. contrast
microscopy In the presence
communication
during
No
unaffected
morphological
a 2-hour exposure
of 10% serum, higher
inhibition
(Fig.
of 0.5% bovine serum albumin
2b).
A
similar
(not shown),
similar
dose-response
rounding-up
(20 h) of cultures curves
of the cells
concentrations
2.
or with
effect
suggesting
to AGA before
phenylalanine
fetal 31
phase
to elicit
was seen in the presence that AGA binds
in inhibiting
10% dialysed
by
to up to 100 uM AGA.
to albumin,
IJC. labelling
produced
2 (data not shown). incorporation,
calf
serum (b).
very However
indicating
Inhibition of communicationby AGA. co-cultures (O,O ) and nom1 cells (D ,O ) wre labelled for 2 hours in mediumB containing AGAat the indicated concentrations without serum (a),
ws
as high
a
Fig.
2a),
reflecting
changes were apparent
to those shown in Fig.
and decreased
by
ratio,
doses of AGA were required
and that such bound AGA is not effective Longer exposure
incorporation,
(Fig.
In serum-free
system.
incorporation
3H-phenylalanine
was essentially
of 14C-citrulline
Vol.
134,
No.
1, 1986
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Table 1 Freincubation 0.3-i
Wash
31i-phenylalanine cpm
Labelling 2h
21045 20996
4050 4309
19.2 20.5
AGA 30 uM
19922 20292
59 59
0.3 0.3
wxihed with serun
INSO 0.5%
20661 20497
3532 3845
17.1 18.8
wshed
D4SO 0.5%
19465 19344
148 112
0.8 0.6
not b&5hd
AGA30uM
not
kashad
AGA
uM
30
%/4-l ratio x 100
EMSO0.5%
mso 0.5%
AGA30uM
l*C-citrulline cpn
without serum
Reversibility of conxmmication inhibition by AGA. 20 hours after platin9,co-culture.s were preincubated in medium B(hepes-buffered saline) with or without AGAas indicated. After 30 min the cells were washed 3 times with median B with or without 10% dialysed serum, or not washed, as indicated. Labelling with radioisotopes ma for 2h in serum-free median B with or without XA. Results for duplicate veils are shown.
cellular
toxicity,
occurred
30 uM in serum-free Camnunication with
wshed
signs
inhibition
cultures
of cellular
proliferate
partitions
strongly
into
by
AGA WM insufficient
as control
coxnnunication the lipid
by washing
the monolayers
showed nearly
cultures.
suggesting
phase of cell
after
shown in Fig.
showed no
used,
for
serum-free that
AGA
up to 20 days during 17 days (Fig.
communication
3).
inhibition
32
cells
continuous
For this
type
For example,
10%
serum,
whereas
100 uM, the rate of increase
by 24% compared to control
to
membranes.
3, where the medium contained
to induce complete
since
a degree of
and continued
Washing with
inhibition,
reversible
as great
Such washed cultures
microscopy,
was maintained
WH rapid,
the dose of AGA KM found to be critical.
At the concentration
number was slowed
labelling
of AGA above
10% serum.
The rate of reversal
phase-contrast
inhibition
experiment,
in the experiment
was toxic.
damage
to AGA and was still
of long-term
1).
not exposed to AGA.
to reverse
Communication exposure
before
at the same rate
medium failed
to concentrations
by AGA was reversible
serum (Table
immediately
IJC as control
20 h exposure
medium and above 150 uM in medium with
medium containing
cultures
after
(data not shown).
75
uM
150 uM
of cell
Vol.
134,
No.
BIOCHEMICAL
1, 1986
A number of compounds with to inhibit
water-soluble with
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Effect of continuous long-term exposure to AM. Co-cUltureS were platad cn day 1 and cultured in growth medium (INEN plus 10% fetal calf serum) with l00 uM AGA (0) or vehicle only (0.3% CtSW, 0 ) from the time of plating. Tha medium was renewed every 3 days. On day 17 sane wells (0) which had been grown on AGA+nadiumwere washed twice with growth medium and replaced with medium without AGA. Caballing 'k~s for 5h in growth medium.
Fig. 3.
ability
AND
IJC.
acid
carbenoxolone
curves
were more toxic
related
18-fl-glycyrrhetinic
derivative,
dose-response
structures
very similar
than AGA at the higher
(Fig.
to AGA. However, doses.
: +\./“-”
Glycyrrhizic
acid,
a glycoside
\
60-
+\o
.
t
40-
1,.
\ I
23 .r Carbenoxolone
O 6O-.-.-I-. . IO ,
2030 ,,
6oKm
0d’j Glycyrrhizic Spironolsctona
AIM
16 acid
3b PM NM
Fig. 4. Effect co co-cultures of carbanoxolone (a), glyccyrrhizic acid (b; 0 ,O) and spironolactone (b: n ,o ). Experimental conditions as for Fig. 2a. 33
IX
both of these compounds
-o\ A
60-
their
and the
b
100. .--+
o-l-ilm o
(not shown)
for
4a) ware both able to inhibit
a
20
to AGA were tested
I&
of
Vol.
134,
No.
1, 1986
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Table 2 Pre-treatment (20h)
Labelling medium (2h)
14C-citru11ine/3H-phenylalanine ratio x 100
Normal medium II II I TPA 1000 rig/ml II II II
vehicle only TPA AGA TPA + AGA vehicle only TPA AGA TPA + AGA
28.2 + 0.7 11.0 + 0.4 0.6 7 0.3 0.37 0.1 30.2 T 0.0 30.1? 1.4 1.2 T 0.4 1.0 T - 0.1 Inhibition or ]unctlonal connnunication by AGA in co-cultures refractory to phorbol ester-induced inhibition. Cultures were made refractory to phorbol esters by exposure to 1000 rig/ml TPA for 20h prior to labelling. They were uashed twice with medium with 10% serum and once with serum-free medium, and labelled for 2h in serum-free medium B in the presence of TPA (66 @nl) and/or AGA (10 uM). Results are mean + difference of duplicate walls.
18-B-glycyrrhetinic (Fig.
acid had no effect
on IJC at concentrations
(50 uM), spironolactone
(100 uN), prednisolone
4b). Aldosterone
hydrocortisone
(100 uM), 7-deoxycholate
(30 UM) and betulin concentrations
addition,
(30 uM) all
showed no tendency
the dose-response
the inhibitory
simultaneous
presence
spironolactone
curve
effect
for
(100 uM), (100 uM), lupeol
to inhibit
IJC at
, which were the highest
spironolactone
is shown in Fig.
of AGA (10 uM) was not diminished
of a tenfold
excess
tested.
of the mineralocorticoid
4b.
by the antagonist
(100 uM) (data not shown).
Tumor-promoting acetate)
(60 uM), cholesterol
up to those shown in brackets
For example,
this
up to 100 uM
phorbol
have been previously
co-culture
system
of TPA results
(11).
esters
shown to induce a partial However,
in a refractory
to phorbol
ester
(11).
refractory
to TPA retained
such as TPA (12~0-tetradecanoylphorbol-13-
state
prolonged in which
exposure
the cells
As shown in Table 2, co-cultures their
sensitivity
inhibition
of IJC in
to high concentrations are no longer which
responsive
had been made
to AGA-induced cotununication
inhibition.
DISCUSSION: related
The present
results
compounds 18-P-glycyrrhetinic
demonstrate
inhibition
of IJC by AGA and the
acid and carbenoxolone, 34
in a human
In
Vol.
f
134,
BIOCHEMICAL
No. 1, 1986
ibroblast
Of these,
system.
were investigated
than that
representative
However AGA wx
less
cytotoxic
synthesis
indicating
that AGA acts
new
for
was readily
medium.
junctions.
20 days with
provided
root,
only a minor slowing
receptors
anti-inflammatory
for which glycyrrhetinic affinity junctional
comnunication.
diminished
by
ability
of AGA to inhibit
mineralocorticoid Another
activate therefore
exposure
protein represent
junction-regulatory
kinase
esters
acids
activity
(12,13). receptors,
also have low but demonstrable
tested
had any inhibitory
communication
inhibition
not to be mediated
of inhibiting
capable
such as TPA (5-7,11),
C (16).
effect by
AGA uas not
antagonist. either
on
Thus the
by
IJC are the which are thought
Ccanmunication inhibition
pharmacological mechanism.
for
receptors.
group of substances phorbol
of peptic
and affinity
to a mineralocorticoid
IJC appears
or glucocorticoid
tumor-promoting
from the
may be mediated via glucocorticoid
In addition,
simultaneous
chosen.
(18-fl-glycyrrhetinic
mineralocorticoid
None of the steroids
(13,14,15).
continuously
acid are derived
structure
of
proliferation,
used in the treatment
and glycyrrhizic
to be due
medium was carefully
glabra , and carbenoxolone
properties
onset
the re-opening
could be maintained
acid and glycyrrhizic
and intrinsic
effect
with
is too rapid
of the rate of cell
is a derivative
by its
the cells
reflect
must
of AGA in the culture
Glycyrrhizia
mineralocorticoid
of IJC.
not only on new junction
by washing
inhibition
as retinoic
AGA uas of rapid
rate of reversal
These compounds have steroid-like
Their
properties
of inhibitors
by
gap junctions, reversible
Communication
sodium hemisuccinate)
ulcer.
inhibition
The observed
AGA, 18-@-glycyrrhetinic
acid
and its
(10) which are the most
classes
alone , and therefore
the concentration
liquorice
COMMUNICATIONS
than these compounds , as assessed
on existing
formation
junction
existing
cytotoxic
of tetraphenylboron
Communication
rate.
Inhibition
albumin-containing to
RESEARCH
of IJC was of the same order
compounds of two other
on protein
formation.
AGA was the least
of AGA as an inhibitor
(11) and greater
potent
BIOPHYSICAL
in detail.
The potency acid
AND
activation
However,
esters
of a physiological
co-cultures 35
by phorbol
to
which had been made
may
Vol.
134,
No.
1, 1986
BIOCHEMICAL
refractory
to TPA remained sensitive
probably
does not act via the protein
We conclude
that
AGA is a novel
AND
to the effect kinase
via steroid
receptors
and lack
of toxicity
of AGA should make it
of junctional
or protein
RESEARCH
COMMUNICATIONS
of AGA, indicating
of IJC, an action
kinase
C.
a useful
which
The reversibility
2. 3. 4. 5.
investigative
tool
cotmnunication.
Hertzberg, E.L., Lawrence/ T.S.1 and Gilula, N.B. (1981) Ann. Rev. Physiol. 43, 479491. Loewanstein, W.R. (1981) Physiol. Rev. 61, 829-913. Davidson, J.S., Baumgarten, I.M., and Harley, E.H. (1984) Exp. Cell. Res. 150, 367-378. Davidson, J.S., Baumgarten, I.M., and Harley, E.H. (1985) Cancer Res. 45, 515-519. Yotti, L.P., Chang, C.C., and Trosko, J.E. (1979) Science 206, 1089-1091.
6. 7. 8. 9. 10. 11. 12. 13. 14.
15. 16.
Fitzgerald, D.J., and Murray, A.W. (1980) Cancer Res. 40, 2935-2937. Enomoto, T., Sasaki, Y., Shiba, Y., Kanno/ Y.# and Yamasaki, H. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 5628-5632. Williams, G.M., Telang, S., and Tong, C. (1981) Cancer L&t. 11, 339-344. Tsushimoto, G., Trosko, J.E., Chang, C.C., and Austr S.D. (1982) Carcinogenesis 3, 181-185. Davidson, J.S., Baumgarten, I.M., and Harley, E.H. Biochim. Biophys. Acta, in press. Davidson, J.S., Bauqarten, I.M., and Harley, E.H. (1985) Carcinogenesis 6, 645-650. * . Armanini, D., Karbowiak, I., Krozowski, Z., Funder, J.W., and Adam, W.R. (1982) Endocrinology 111, 1683-1686. Armanini, D., Ihrbowiak, I., and Funder, J.W. (1983) Clin. Endocrinol. 19, 609-612. Molhuysan, J.A.# Gerbrandy, J., DeVeries, L.A.# Dejong, J.C., Lenstra, J.B., Turner, K.P., and Borst, J.G.G. (1950) Lancet 259, 381-386. E., Ogihara, Y., Ogawar S., Okada, K., Amagaya, S.# Sugishita, and Aizawa, T. (1984) J. Pharm. Dyn. 7, 923-928. Nishizuka, Y. (1984) Nature 308, 693-698.
36
AGA
is not of action
REFERENCES 1.
that
C pathway.
inhibitor
mediated
study
BIOPHYSICAL
in the
134,
No.
January
14,
1, 1986
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1986
Pages
REVERSIBLE INHIBITION
OF INTERCELLULAR JUNCTIONAL COMMUNICATIONBY GLYCYRRHETINIC ACID
James S. Davidson, Department
of
Chemical
29-36
Ingrid
M. Baumgarten and Eric
H. Harley
Pathology, University of Cape Tom Medical Observatory 7925, South Africa
School,
Received November 14, 1985
Intercellular gap-junctional communication was measured using metabolic co-operation in co-cultures of argininosuccinate synthetase-deficient and argininosuccinate lyase-deficient human fibroblasts. 18- Q-glycyrrhetinic acid (AGA) was found to inhibit communication by more than 95% at concentrations as up to 100 uM ware not cytotoxic over a period of 2 low as 2 uM. Concentrations hours. Communication inhibition was of rapid onset and was readily reversible. Communication remained continuously yet reversibly blocked in cells cultured in the presence of AGA for 20 days. The related compounds 18-p -glycyrrhetinic acid and carbenoxolone also caused communication inhibition. The effect is probably not mediated via mineralocorticoid or glucocorticoid receptors since aldosterone and glucocorticoids had no effect on communication. AGA thus has properties of a useful inhibitor in the study of intercellular junctional communication. 0 1986 Academic Press, Inc.
Gap junctions
INTRODUCTION: molecules
directly
the cytoplasmic measuring
cells
between
junctional
of the urea cycle
(3).
argininosuccinate
lyase-deficient
citrulline
into into
14C-citrulline via
by
junctions of
ratio
lines
derived
fibroblasts
from patients
simultaneous
able
with
is
no detectable
incorporation
for any added compound.
nor
to convert
of argininosuccinate
types
incorporate
between cells transfer
of 3H-phenylalanine
via
the
Serves
Thus the 14C-citrulline/3H-
of the mutant cells
that compounds could
inborn errors
to incorporate
of the two cell
1) and there
for
human
synthetase-deficient are
linking
system
in cultured
enzymes are required
both
the transfer (Fig.
aqueous channels A convenient
(IJC)
argininosuccinate
in co-cultures
Because of the possiblity
(1,2).
However co-cultures
efficiently
The rate
cells
the exchange of small
forming
by
conrnunication
protein , since
as an index of toxicity phenylalanine
Neither
arginine.
intercellular
medium (3).
in contact ,
uses two mutant cell
14C-citrulline
to mediate
of adjacent
compartments
intercellular
fibroblasts
are thought
inhibit
is a measure of IJC. one of the enzymatic 0006-291X/86 $1.50
29
Copyright 0 1986 AN rights of reproduction
b-v Academic Press, Inc. in any form reserved.
Vol.
134,
No.
BIOCHEMICAL
1, 1986
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
CIT 1 ASA
ASA
1 ARG * protein ASS-
Fig. 1.
steps
ASL-
Principle of assay of intercellular junctional conmunication. ASA = argininosuccinate: ARG = arginine. CIT = citrulline;
in citrulline
metabolism , it
is also
compounds on normal human fibroblasts
(4).
Gap-junctional pharmacological
investigate (4,10), that
intercellular inhibition
by
inhibition retinoids
several
by
classes study
acid
to monitor
has previously pesticides
phorbol
esters
(AGA) and the related
acid and carbenoxolone
the effects
is known to be susceptible of compounds (5-9).
organochlorine
(11) and tumor-promoting
18-a-glycyrrhetinic
18-fl-glycyrrhetinic
of IJC
necessary
communication
model used in the present
fibroblast
CELLS
NORMAL
are novel
of
to
The human
been employed to and related (11).
compounds
Here we report
compounds inhibitors
of IX.
MATERIALS AND METHODS wre obtained from Sigma Chemical Co. : Chemicals : The following acid, prednisolone, lupeol 18-Cr-glycyrrhetinic acid (AGA) , 18-fl-glycyrrhetinic and betulin. Glycyrrhizic acid was obtained from Aldrich Chemical Co. Cholesterol and hydrocortisone were from BDH Chemicals Ltd. Carbenoxolone sodium ws a kind gift from Berk Pharmaceuticals (Pty) Ltd. AGA, in dimethyl 18-/3-glycyrrhetinic acid, lupeol and betulin were dissolved sulfoxide (CNSO). Glycyrrhizic acid and carbenoxolone wre dissolved in water. The remaining chemicals were dissolved in ethanol. Final solvent concentration was 0.5% or less and appropriate solvent controls were included in each experiment. A fresh stock solution of AGA was prepared immediately before each experiment, as it us found that stored solutions had increased cytotoxicity. [Carbamoyl-14C]citrulline and [2,3-3H]phenylalanine were from the Radiochemical Centre, Amersham. of the human mutant fibroblast cell Metabolic co-operation assay : The origins lines were as described (3). They were maintained on Dulbecco’s Minimal Essential Medium (DMEM, Gibco) with 10% fetal calf serum (Gibco) in 4% 03 at of co-cultures and the assay of IJC viere as described t 4,10). 37oc. Preparation Briefly, trypsinised suspensions of the two cell types were mixed in equal proportions, plated at high density (confluent or subconfluent) and incubated for 18-22 hours. The co-cultures ware then incubated in labelling medium containing radioisotopes and test chemical(s). Where the labelling medium was time was 2 hours, hepes-buffered saline (medium B in ref. 4) incubation 14C-citrulline was used at 0.25 uCi/ml and 3H-phenylalanine at 0.6 uCi/ml. Where the cells were labelled in growth medium (DMEM with l0% fetal calf serum) 4C-citrulline at 1 uCi/m.l and 3H-phenylalanine incubation time was 5 hours with 30
Vol.
134,
No.
BIOCHEMICAL
1, 1986
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
After labelling, radioactivity in acid-insoluble cellular material 2 uCi/ml. was determined as described (10). All experiments were performed in duplicate Each point shown is the mean and repeated at least once with similar results. of duplicate wells, Bars on the figures are of a length equal to the difference betwaen duplicates and are omitted where this difference was less than 5%.
at
RESULTS: Exposure incorporation indicating
to AGA caused a dose-dependent
in co-cultures
of mutant cells,
that AGA inhibits
LJC in this
inhibition
but not in normal cells
human fibroblast
medium, IJC as measured by citrulline/phenylalanine inhibited overall
by 97% at 2 uM AGA. protein
synthesis,
as 100 uM over a 2-hour period. contrast
microscopy In the presence
communication
during
No
unaffected
morphological
a 2-hour exposure
of 10% serum, higher
inhibition
(Fig.
of 0.5% bovine serum albumin
2b).
A
similar
(not shown),
similar
dose-response
rounding-up
(20 h) of cultures curves
of the cells
concentrations
2.
or with
effect
suggesting
to AGA before
phenylalanine
fetal 31
phase
to elicit
was seen in the presence that AGA binds
in inhibiting
10% dialysed
by
to up to 100 uM AGA.
to albumin,
IJC. labelling
produced
2 (data not shown). incorporation,
calf
serum (b).
very However
indicating
Inhibition of communicationby AGA. co-cultures (O,O ) and nom1 cells (D ,O ) wre labelled for 2 hours in mediumB containing AGAat the indicated concentrations without serum (a),
ws
as high
a
Fig.
2a),
reflecting
changes were apparent
to those shown in Fig.
and decreased
by
ratio,
doses of AGA were required
and that such bound AGA is not effective Longer exposure
incorporation,
(Fig.
In serum-free
system.
incorporation
3H-phenylalanine
was essentially
of 14C-citrulline
Vol.
134,
No.
1, 1986
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Table 1 Freincubation 0.3-i
Wash
31i-phenylalanine cpm
Labelling 2h
21045 20996
4050 4309
19.2 20.5
AGA 30 uM
19922 20292
59 59
0.3 0.3
wxihed with serun
INSO 0.5%
20661 20497
3532 3845
17.1 18.8
wshed
D4SO 0.5%
19465 19344
148 112
0.8 0.6
not b&5hd
AGA30uM
not
kashad
AGA
uM
30
%/4-l ratio x 100
EMSO0.5%
mso 0.5%
AGA30uM
l*C-citrulline cpn
without serum
Reversibility of conxmmication inhibition by AGA. 20 hours after platin9,co-culture.s were preincubated in medium B(hepes-buffered saline) with or without AGAas indicated. After 30 min the cells were washed 3 times with median B with or without 10% dialysed serum, or not washed, as indicated. Labelling with radioisotopes ma for 2h in serum-free median B with or without XA. Results for duplicate veils are shown.
cellular
toxicity,
occurred
30 uM in serum-free Camnunication with
wshed
signs
inhibition
cultures
of cellular
proliferate
partitions
strongly
into
by
AGA WM insufficient
as control
coxnnunication the lipid
by washing
the monolayers
showed nearly
cultures.
suggesting
phase of cell
after
shown in Fig.
showed no
used,
for
serum-free that
AGA
up to 20 days during 17 days (Fig.
communication
3).
inhibition
32
cells
continuous
For this
type
For example,
10%
serum,
whereas
100 uM, the rate of increase
by 24% compared to control
to
membranes.
3, where the medium contained
to induce complete
since
a degree of
and continued
Washing with
inhibition,
reversible
as great
Such washed cultures
microscopy,
was maintained
WH rapid,
the dose of AGA KM found to be critical.
At the concentration
number was slowed
labelling
of AGA above
10% serum.
The rate of reversal
phase-contrast
inhibition
experiment,
in the experiment
was toxic.
damage
to AGA and was still
of long-term
1).
not exposed to AGA.
to reverse
Communication exposure
before
at the same rate
medium failed
to concentrations
by AGA was reversible
serum (Table
immediately
IJC as control
20 h exposure
medium and above 150 uM in medium with
medium containing
cultures
after
(data not shown).
75
uM
150 uM
of cell
Vol.
134,
No.
BIOCHEMICAL
1, 1986
A number of compounds with to inhibit
water-soluble with
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Effect of continuous long-term exposure to AM. Co-cUltureS were platad cn day 1 and cultured in growth medium (INEN plus 10% fetal calf serum) with l00 uM AGA (0) or vehicle only (0.3% CtSW, 0 ) from the time of plating. Tha medium was renewed every 3 days. On day 17 sane wells (0) which had been grown on AGA+nadiumwere washed twice with growth medium and replaced with medium without AGA. Caballing 'k~s for 5h in growth medium.
Fig. 3.
ability
AND
IJC.
acid
carbenoxolone
curves
were more toxic
related
18-fl-glycyrrhetinic
derivative,
dose-response
structures
very similar
than AGA at the higher
(Fig.
to AGA. However, doses.
: +\./“-”
Glycyrrhizic
acid,
a glycoside
\
60-
+\o
.
t
40-
1,.
\ I
23 .r Carbenoxolone
O 6O-.-.-I-. . IO ,
2030 ,,
6oKm
0d’j Glycyrrhizic Spironolsctona
AIM
16 acid
3b PM NM
Fig. 4. Effect co co-cultures of carbanoxolone (a), glyccyrrhizic acid (b; 0 ,O) and spironolactone (b: n ,o ). Experimental conditions as for Fig. 2a. 33
IX
both of these compounds
-o\ A
60-
their
and the
b
100. .--+
o-l-ilm o
(not shown)
for
4a) ware both able to inhibit
a
20
to AGA were tested
I&
of
Vol.
134,
No.
1, 1986
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Table 2 Pre-treatment (20h)
Labelling medium (2h)
14C-citru11ine/3H-phenylalanine ratio x 100
Normal medium II II I TPA 1000 rig/ml II II II
vehicle only TPA AGA TPA + AGA vehicle only TPA AGA TPA + AGA
28.2 + 0.7 11.0 + 0.4 0.6 7 0.3 0.37 0.1 30.2 T 0.0 30.1? 1.4 1.2 T 0.4 1.0 T - 0.1 Inhibition or ]unctlonal connnunication by AGA in co-cultures refractory to phorbol ester-induced inhibition. Cultures were made refractory to phorbol esters by exposure to 1000 rig/ml TPA for 20h prior to labelling. They were uashed twice with medium with 10% serum and once with serum-free medium, and labelled for 2h in serum-free medium B in the presence of TPA (66 @nl) and/or AGA (10 uM). Results are mean + difference of duplicate walls.
18-B-glycyrrhetinic (Fig.
acid had no effect
on IJC at concentrations
(50 uM), spironolactone
(100 uN), prednisolone
4b). Aldosterone
hydrocortisone
(100 uM), 7-deoxycholate
(30 UM) and betulin concentrations
addition,
(30 uM) all
showed no tendency
the dose-response
the inhibitory
simultaneous
presence
spironolactone
curve
effect
for
(100 uM), (100 uM), lupeol
to inhibit
IJC at
, which were the highest
spironolactone
is shown in Fig.
of AGA (10 uM) was not diminished
of a tenfold
excess
tested.
of the mineralocorticoid
4b.
by the antagonist
(100 uM) (data not shown).
Tumor-promoting acetate)
(60 uM), cholesterol
up to those shown in brackets
For example,
this
up to 100 uM
phorbol
have been previously
co-culture
system
of TPA results
(11).
esters
shown to induce a partial However,
in a refractory
to phorbol
ester
(11).
refractory
to TPA retained
such as TPA (12~0-tetradecanoylphorbol-13-
state
prolonged in which
exposure
the cells
As shown in Table 2, co-cultures their
sensitivity
inhibition
of IJC in
to high concentrations are no longer which
responsive
had been made
to AGA-induced cotununication
inhibition.
DISCUSSION: related
The present
results
compounds 18-P-glycyrrhetinic
demonstrate
inhibition
of IJC by AGA and the
acid and carbenoxolone, 34
in a human
In
Vol.
f
134,
BIOCHEMICAL
No. 1, 1986
ibroblast
Of these,
system.
were investigated
than that
representative
However AGA wx
less
cytotoxic
synthesis
indicating
that AGA acts
new
for
was readily
medium.
junctions.
20 days with
provided
root,
only a minor slowing
receptors
anti-inflammatory
for which glycyrrhetinic affinity junctional
comnunication.
diminished
by
ability
of AGA to inhibit
mineralocorticoid Another
activate therefore
exposure
protein represent
junction-regulatory
kinase
esters
acids
activity
(12,13). receptors,
also have low but demonstrable
tested
had any inhibitory
communication
inhibition
not to be mediated
of inhibiting
capable
such as TPA (5-7,11),
C (16).
effect by
AGA uas not
antagonist. either
on
Thus the
by
IJC are the which are thought
Ccanmunication inhibition
pharmacological mechanism.
for
receptors.
group of substances phorbol
of peptic
and affinity
to a mineralocorticoid
IJC appears
or glucocorticoid
tumor-promoting
from the
may be mediated via glucocorticoid
In addition,
simultaneous
chosen.
(18-fl-glycyrrhetinic
mineralocorticoid
None of the steroids
(13,14,15).
continuously
acid are derived
structure
of
proliferation,
used in the treatment
and glycyrrhizic
to be due
medium was carefully
glabra , and carbenoxolone
properties
onset
the re-opening
could be maintained
acid and glycyrrhizic
and intrinsic
effect
with
is too rapid
of the rate of cell
is a derivative
by its
the cells
reflect
must
of AGA in the culture
Glycyrrhizia
mineralocorticoid
of IJC.
not only on new junction
by washing
inhibition
as retinoic
AGA uas of rapid
rate of reversal
These compounds have steroid-like
Their
properties
of inhibitors
by
gap junctions, reversible
Communication
sodium hemisuccinate)
ulcer.
inhibition
The observed
AGA, 18-@-glycyrrhetinic
acid
and its
(10) which are the most
classes
alone , and therefore
the concentration
liquorice
COMMUNICATIONS
than these compounds , as assessed
on existing
formation
junction
existing
cytotoxic
of tetraphenylboron
Communication
rate.
Inhibition
albumin-containing to
RESEARCH
of IJC was of the same order
compounds of two other
on protein
formation.
AGA was the least
of AGA as an inhibitor
(11) and greater
potent
BIOPHYSICAL
in detail.
The potency acid
AND
activation
However,
esters
of a physiological
co-cultures 35
by phorbol
to
which had been made
may
Vol.
134,
No.
1, 1986
BIOCHEMICAL
refractory
to TPA remained sensitive
probably
does not act via the protein
We conclude
that
AGA is a novel
AND
to the effect kinase
via steroid
receptors
and lack
of toxicity
of AGA should make it
of junctional
or protein
RESEARCH
COMMUNICATIONS
of AGA, indicating
of IJC, an action
kinase
C.
a useful
which
The reversibility
2. 3. 4. 5.
investigative
tool
cotmnunication.
Hertzberg, E.L., Lawrence/ T.S.1 and Gilula, N.B. (1981) Ann. Rev. Physiol. 43, 479491. Loewanstein, W.R. (1981) Physiol. Rev. 61, 829-913. Davidson, J.S., Baumgarten, I.M., and Harley, E.H. (1984) Exp. Cell. Res. 150, 367-378. Davidson, J.S., Baumgarten, I.M., and Harley, E.H. (1985) Cancer Res. 45, 515-519. Yotti, L.P., Chang, C.C., and Trosko, J.E. (1979) Science 206, 1089-1091.
6. 7. 8. 9. 10. 11. 12. 13. 14.
15. 16.
Fitzgerald, D.J., and Murray, A.W. (1980) Cancer Res. 40, 2935-2937. Enomoto, T., Sasaki, Y., Shiba, Y., Kanno/ Y.# and Yamasaki, H. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 5628-5632. Williams, G.M., Telang, S., and Tong, C. (1981) Cancer L&t. 11, 339-344. Tsushimoto, G., Trosko, J.E., Chang, C.C., and Austr S.D. (1982) Carcinogenesis 3, 181-185. Davidson, J.S., Baumgarten, I.M., and Harley, E.H. Biochim. Biophys. Acta, in press. Davidson, J.S., Bauqarten, I.M., and Harley, E.H. (1985) Carcinogenesis 6, 645-650. * . Armanini, D., Karbowiak, I., Krozowski, Z., Funder, J.W., and Adam, W.R. (1982) Endocrinology 111, 1683-1686. Armanini, D., Ihrbowiak, I., and Funder, J.W. (1983) Clin. Endocrinol. 19, 609-612. Molhuysan, J.A.# Gerbrandy, J., DeVeries, L.A.# Dejong, J.C., Lenstra, J.B., Turner, K.P., and Borst, J.G.G. (1950) Lancet 259, 381-386. E., Ogihara, Y., Ogawar S., Okada, K., Amagaya, S.# Sugishita, and Aizawa, T. (1984) J. Pharm. Dyn. 7, 923-928. Nishizuka, Y. (1984) Nature 308, 693-698.
36
AGA
is not of action
REFERENCES 1.
that
C pathway.
inhibitor
mediated
study
BIOPHYSICAL
in the