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Identification of specific high affinity sites for the estradiol receptor in the erythrocyte cytoskeleton
vol. 103, No. 2,198l
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
30, 1981
November
IDENTIFICATION
OF SPECIFIC
HIGH AFFINITY SITES FOR THE ESTRADIOL RECEPTOR IN THE ERYTRROCYTE CYTOSKELETON
Giovanni
Alfred0
Puca and Vincenzo
Sica
First Medical School, University di Patologia generale, Via S. Andrea delle Dame, 2, 80138 Naples, Italy
Istituto Received
September
682-689
of Naples,
4,1981
SUMMARY. The possible relationship of the soluble, "cytosolic" estradiol receptor with complex membranous and cytoskeletal structures of the cell matrix has been studied using a model erythrocyte.system. Extraction of erythrocyte ghosts with a nonionic detergent (Triton X-100) under conditions that yield a cytoskeletal matrix reveals the presence of a limited number (less than 100) of specific sites having high affinity (kd lo-' M) for the estradiol-receptor complex. The interaction between the estradiol receptor and the cytoskeleton is critically dependent on temperature and it is improved by 25 mM KC1 or NaCl and by 2.5 mM MgC12. The data suggest that the estradiol receptor, which has been generally considered to be freely "soluble" in the cytoplasm, may actually be physiologically associated in an integral manner with a complex cytoskeletal network in the cell cytoplasm.
INTRODUCTION. as being target
Steroid
water-soluble cells,
hormone
macromolecules,
waiting
for
the arrival
of the hormone-receptor
complex
changes
the
This
which
determine
mechanism
and most
more than
of this
10 years
Recently this
the cytosol
since
(of
water-soluble Increasing
of a specific leads
dogma"
have been
interpreted
model
at least
target
cells)
molecule
(2-5).
of steroid
one of its of the
of the
receptor
intricate
0006-291X/81/220682-08$01.00/0 Copyright 0 1981 by Academic Press, Inc. All rights of reproduction in any form reserved.
major
682
of their Formation
molecule. conformational
the
action
of this
or addressed (see Ref.
question
hormones, model.
during
and serious
points,
i.e.,
as an unrestrained,
nature
the
the
1).
the validity
action,
and complex
compartment.
of steroid
on the basis
which
considered
to the nuclear
proposed
have been published
awareness
for
was first
cytoplasm
to putative
have not been elucidated this
been
hormone
of the receptor
dogma of the mechanism concerning
in the
"central
thesis
much data
central
be raised
data
have generally
floating
presumably
transfer
has become the
experimental
Many aspects
receptors
of
doubtgmust presence
in
freely
of the ultrastruc-
Vol. 103, No. 2,1981
tural
BIOCHEMICAL
organization
of the
various
cytoplasmic
closely
related This
(6).
importance
in cellular
The present uterus with
interacts components
be considered
organized
functions
with
high
of more complex
steroid
of the
receptors
network
and functional
evidence
that
may be
of structural unit
elements
of fundamental
the estrogen
and in a specific
erythrocyte
cytoskeletal
model
eucaryotic
of integration
hormone
microscopic
affinity
as a simplified
degree
COMMUNICATIONS
(7-15).
provide
of the
that
a morphological
studies
RESEARCH
and the high
suggests
to a highly forms
BIOPHYSICAL
cytoplasm
elements
network
AND
system
of calf
and saturable
system; for
receptor
manner
the latter
exploring
may generally
cytoskeletal
properties
cells.
MATERIALS AND METHODS. 17B-Estradiol-2,4,6,7-t4 (84 to 110 Ci/mmol) was from Amersham. Cow blood erythrocyte ghosts and cytoskeleton were prepared as described by Bennett (16,17); these were resuspended with phosphate buffer at a protein concentration of 3 to 10 mg/ml, diluted 1:l (v:v) with 99% glycerol and stored at -70° until used. Calf uterine cytosol was prepared as previously described (18) except that only phosphate buffer (7.5 mM phosphate buffer, pH 7.5) instead of Tris-HCl EDTA and dithiothreitol buffer was used. The assay of specific binding activity of cytosol was performed by the Dextran-coated charcoal method (19). The binding of the [%]estradiol-receptor complex to erythrocyte ghosts and cytoskeletons was performed in duplicate. Calf uterine cytosol was preincubated for 10 min at 20° in a total volume of 0.4 ml of phosphate buffer with 2.5 pmoles of [3H]estradiol, 12.5 pmoles KC1 and 1.25 pmoles MgC12. The reaction was started by adding 0.1 ml of cytoskeleton or ghost suspension (0.25 to 2 mg of protein) and followed either for 2 hours at 20” or for 30 min at 30°. Parallel tests were performed in the presence of 1 x 10m6 M unlabeled estradiol. The reaction was stopped by adding 10 ml of ice-cold phosphate buffer. Samples were centrifuged at 30,000 x g for 20 min at 4O and the pellets were washed three times. The final pellet was resuspended with 1 ml of phosphate buffer and assayed for radioactivity. The values obtained in the presence of unlabeled hormone were subtracted from the total.
Specific
RESULTS. -in erythrocyte These
sites
(Fig.
1).
cyte
membranes, are only
membranes
with
erythrocyte the
ghosts
with This
but
detected
The maximal
concentrations. the
binding
number
1% Triton
sites only
or cytoskeleton
extraction
of binding X-100
(20).
estradiol of calf
appears
and does not
uterine
is used
the uterine
with
with
detergent
hormone
of erythro-
higher
operationally
cytosol
cytosol.
by treatment
increase
The tritiated
683
can be detected
of the membranes
sites
procedure
if
radioactive
in the presence
after
extraction
“cytoskeleton”
for
detergent
to prepare does not
is omitted,
if
associate the
Vol. 103, No. 2,198l
BIOCHEMICAL
AND
0.25
BIOPHYSICAL
0.50
0.75
1.00
TRITON
RESEARCH
1.25
X-100,
COMMUNICATIONS
1.50
%
Fig. 1. Efrect of extracting erythrocyte ghosts with Triton X-100 on the appearance of specific binding of [%]estradiol-receptor complex. Erythrocyte ghosts were extracted for 15 min at 0" with the indicated concentrations of Triton X-100. After extraction, the ghosts were centrifuged and washed four times with phosphate buffer. The pellets were resuspended at a final protein concentration of 12 q g per ml with phosphate buffer. Aliquots of 0.1 ml were then incubated for two hours at 20“ with 0.2 ml of calf uterine cytosol, previously labeled with [%l]estradgol.
cytosol
is
tissue
(e.g.,
(e.g.,
albumin,
for
inactivated liver,
Binding
(Fig.
of the
inherent
of calf
uterine
subsequent
at O" (dotted
decrease ionic
about
association with
cytosol
with
binding line,
2 hours
receptor
erythrocyte
30° cannot
estradiol-receptor
proteins sites
be considered
than
for
of other
therefore of the
from a non-target.
to be a
cytoskeleton.
is time
and temperature
be used easily
complex.
because
Preincubation
at 20° does not
[3H]estradiol-receptor
complex
in important
ways by KC1 or NaCl.
change
to the cytoskeleton
2).
is
affected
three-fold
higher
no specific
cytoskeleton
the hormone
of the Fig.
with
to the
higher
of the
a cytosol
amounts
components
Temperatures
if
similar
must
receptor
instability
the binding
strengths
This
estradiol
2).
The interaction increases
is used or if
interaction of the
(30 min at 600),
imraunoglobulins)
are used.
receptor-mediated
the
thymus)
ovalbumin,
estradiol
dependent
by heating
in the presence
but
not
than
to values 1 M (Fig.
below 3A).
684
of 25 mM KCl; those
higher
seen without
In the presence
Binding
concentrations KCl,
even at
of 25 mM KCl,
Ca++
BIOCHEMICAL
Vol. 103, No. 2.1981
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
MINUTES
Fig. 2. Time course of binding of estradiol-receptor complex to erythrocyte cytoskeleton. Erythrocyte cytoskeleton was incubated with 0.1 ml of calf uterine cytosol. Incubations were carried out at O" (a), lo0 (o), ZOO (A) and 30° (A). At the indicated times the reaction was stopped by adding cold phosphate buffer and the binding was measured. The dotted line represents the binding at 20°.
at
4O after
preincubation
of
the
estradiol-receptor
complex
for
2 hr
(up to 5 mM) has no stimulatory effect, while 5 mM Mn++ slightly increases the ++ binding. Mg stimulates the binding substantially, with an optimal concentration at 2.5 mM (Fig.
3B).
The binding
of the
the concentration ml,
provided
shown). that
the
affinity
suggest
the
(Fig.
presence
affinity
4A).
and quantity component
number
of these
high
that the
4B).
From the
1 mg of cytoskeletal cytoskeleton
affinity data
the
(Fig. is
about sites
described protein
from one erythrocyte
receptor
interaction analyses
of binding 4A).
is
is not is
without in figure corresponds appears
685
related
limiting
kept
appears
sites
modifying
to bind
while
markedly
constant
in
of the
substantially
the dissociation
5 x 10'
and
experiments
4B, and independently to about
per
to be saturable
differing
Mg++ increases
to
(not
constant
of such saturation
The dissociation
10ms M.
linearly
of 100 to 1000 pg protein
concentration
Scatchard
of two classes
affinity
(Fig.
cytoskeleton
increased,
higher
range
of estradiol
when the is
complex
in the
concentration
receptor
of high
their
of cytoskeleton
However,
of the
[%]estradiol-receptor
the constant determining
erythrocytes,
a maximum of 50 to 100
vol. 103, No. 2,1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
I
I 100
I 200
I 300
COMMUNICATIONS
I
I
r
6
8
IO
I
I 400
2
4
KCI , mM
MgCl2
,mM
Fig.83. Effect of increasing concentrations of KC1 and MgClz on the binding A. Erythrocyte of [ Hlestradiol-receptor complex to erythrocyte cytoskeleton. cytoskeleton was incubated for 2 hr at 20° with 0.2 ml of calf uterine cytosol cytoskeleton and calf with the indicated concentration of KCl. B. Erythrocyte uterine cytosol were incubated in phosphate buffer containing 25 mM KC1 and the indicated concentration of MgClz.
molecules
of estradiol-receptor
is bound
per
forms
studied
separately,
the native
affinity
to the
lost
the ability
of estradiol
to these
of the
a discreet
Triton
shells.
sites, molecules
might to factors which
while
receptor
those
forms
uterine
to erythrocyte
lipid
bilayer
and finite
are
removed
of binding
of the erythrocyte
to steric
can be removed
(data
localization hindrance
by the
detergent.
686
fact not
controlled (18)
found ghosts
the
binding
shown). displays
almost
detergent,
associated to bind
or to their is
the
the estradiol binding
occupancy certain,
Triton with
of the putative
It
have
when many of the proteins
the nonionic is
and
great
that
complex
However, with
with
after
the
estradiol-receptor
be due to an internal related
unaltered
(18)
or by trypsin
despite
ghosts.
amount
The inability
is
binds
obtained
protease
cytoskeleton
are prepared
receptor
forms
uterine
to the
The calf
binding
X-100,
receptor
one mole of estradiol
receptor
8 S form of the
Ca++ -dependent
to bind
DISCUSSION.
and most
of the estradiol
cytoskeleton,
by the
no specific
that
mole of receptor.
When the various
proteolysis
assuming
complex,
by other
however,
that
BIOCHEMICAL
Vol. 103, No. 2,198l
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
‘H t,RfCtPTOR
COMPLEX BOUND ;lO%~
3H-EiRECEPTOR
COMPLEX
[lo-'M]
Fig. 4. Effect of increasing the concentration of [3H]estradiol-receptor complex on the binding of erythrocyte cytoskeleton. Erythrocyte cytoskeleton was incubated for 2 hr at ZOO with different amounts of calf uterine cytosol. The binding was carried out in the presence of 25 mH KC1 alone (A) or in the presence of 25 mM KC1 and 2 mM MgClz (B). Inserts: Scatchard plots of the data.
these
sites
membrane. also
are very The strong
suggests
temperature
the
facilitate
of the the
residual
changes,
or it
Alternatively, arrangements Saturation
dependence
is not
might
simply
analysis
since
binding
might
receptor
it
proteins
of the
modificatidn cytosol
at low temperature the need
might
induce
of the
receptor disrupt
receptor-cytoskeletal
This
organization.
heating
essential
687
on temperature
of a necessary
prior
may actively
of the erythrocyte
binding
cytoskeletal
reflect
access
of the
cytoskeleton
to cytoskeletons
components,
low temperatures of structural
an "open"
(21)
facilitate
the
a manifestation
requirement
membrane
with
of estradiol for
receptor
subsequent
The temperature
of the
associated
requirement
effect
or activation
2).
strongly
for
for
(Fig.
increased
necessary to its necessary
does not
fluidity
conformational binding
site.
organizational
binding. interaction
reveals
the
Vol. 103, No. 2,1981
presence
BIOCHEMICAL
of a very
sites
per
major
protein
ankyrin,
erythrocyte
4.1)
the
components
Similar
systems
estrogen
primarily the (24)
in
that
cytoplasm. cytoskeletal
cells.
very
Thus,
it
exist
constitutes
a highly approaches
interactions
cells,
for
is
model elsewhere to those
conceivable
Although
could of action
the
and high
explain
the hormone-dependent
high also
exist
cytosol
(3-5),
cytoskeletal
in
is
and that matrix
of the cell
analogous
adenylate
affinity
water-
in the
network
demonstrated
data hormones
traditional
and preparation of a complex
affinity
membrane.
here
found
the
++ Mg .
for
that
described
strength
manner,
of steroid
demonstrate
that
actin,
ionic
in part
microtrabecular
have recently
one of the
3, spectrin,
of specific
receptor
as part
organized
that
of the erythrocyte
homogenization
--in situ
binding
to be selective
which
8 S estradiol
of tissue
normally
matrix
similar
affinity
band
existence
the general
of the native,
Similar
the
COMMUNICATIONS
in a nonspecific
appears
to be published sites
an artefact
receptors
target
with
binding
nature
for
of high
the binding.
interaction
evidence
may exist
100)
(e.g.,
for
of binding
RESEARCH
the possibility
cytoskeleton
in the cytoskeletal
Results
target
than
excludes
may be responsible
contradictory
cytoskeletal
soluble
of the
provide
binding
22-31).
(less
This
enhancement
data
apparently
ghost.
BIOPHYSICAL
receptor-cytoskeletal
cation-dependent These
number
components
band
influences
(2-5,
limited
AND
cyclase
erythrocyte system
(32-34).
ACKNOWLEDGEMENTS. The authors thank Drs. Naji Sahyoun and Vann Bennett for their helpful advice. This work was supported by the Progetto Finalizzato: Controllo della Crescita Neoplastica, by a grant from the Wellcome Research Laboratories, RTP, North Carolina and the National Institute of Health Contract No. NOl-CB-64074.
REFERENCES 1. 2. 2: 5. 6. 7.
Gorski, J., and Gannon, F. (1976) AM. Rev. Physiol. 37, 425-450. Pietras, R.J., and Szego, C.M. (1979) J. Steroid Biochem. 11, 1471-1483. Pietras, R.J., and &ego, C.M. (1980) Biochem. J. 191, 743-760. Pietras, R.J., and &ego, C.M. (1977) Nature 265, 69-72. Pietras, R.J. (1981) 63rd Annual Meeting of the Endocrine Society, Abstract 849, p 295. Batten, E.B., Aalberg, J.J., and Anderson, E. (1980) Cell 21, 885-895. Wolosewick, J.J. and Porter, K.R. (1979) J. Cell. Biol. 82, 114-139.
688
Vol. 103. No. 2.1981
a. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19.
20,
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Edelman, G. (1976) Science 192, 218-226. Crossin, K.L., and Corney, D.H. (1981) Cell 23, 61-71. DePetris, S., and Raff, M.C. (1972) Eur. J. Immun. 2, 523-535. Porter, K.R. (1976) in Cell Motility (Goldman, R., Pollard, 'I., and Rosenbaum, J. eds) pp. l-28 Cold Spring Harbor Laboratory, New York. Goldstein, J.L., Anderson, R.G.W., and Brown, H.S. (1979) Nature 279, 679484. Eckert, B.S., Koons, S.J., Schantz, A.W., and Zobel, C.R. (1980) J. Cell. Biol. 86, l-5. Cervera, M., Dreyfuss, G., and Penman, S. (1981) Cell 2, 113-120. Giannattasio, G., Zanini, A., Rosa, P., Meldolesi, J., Margolis, R.K., and Margolis, R.V. (1980) J. Cell. Biol. 86, 273-277. Bennett, V., and Stenbuck, P.J. (1979) J. Biol. Chem. 254, 2533-2541. Bennett, V., and Stenbuck, P.J. (1979) Nature 280, 468-473. Puca, G.A., Nola, E., Sica, V., and Bresciani, F. (1972) Biochemistry 11, 4157-4165. Sanborn, B.M., Ramanth Rao, B., and Korenman, S.G. (1971) Biochemistry IO, 4955-4965. Yu, J., Fishman, D.A., and Steck, T.L. (1973) J. Supramolec. Strut I, 233-248.
21. 22. 23. 24. 25.
Jensen, E.V., and DeSombre, Jackson, V., and Chalkely, Barrack, E.R., and Coffey, Parikh, I., Anderson, W.L., 10266-10270. Milgrom, E., Atger, M., and 320,
26. 27. 28. 29. 30. 31. 32. 33. 34.
E.R. (1973) Science 182, 126-134. R. (1974) J. Biol. Chem. 249, 1615-1626. D.S. (1980) J. Biol. Chem. 255, 7265-7275. and Neame, P. (1980) J. Biol. Chem. 255, Baulieu,
E-E.
(1973)
Biochim.
Biophys.
Acta
267-283.
Nenci, I., Fabris, G., Marchetti, E., and Marzola, A. (1980) Virchows Arch. B Cell Path. 32, 139-145. Munck, A., and Brinck-Johnes, T. (1968) J. Biol. Chem. 263, 5556-5565. Noteboom, W.D., and Gorski, J. (1965) Arch. Biochim. Biophys. 111, 559-568 Harrison, R.W., Fairfield, S., and Orth, D.N. (1974) Biochem. Ephys. Res. Con-us. 6l, 1262-1267. Suyemitsu, T., and Terayame, H. (1975) Endocrinology 96, 1499-1508. Baulieu, E.E., Godeau, F., Schorderet, M., and Schorderet-Slatkine, S. (1978) Nature 275, 593-598. Sahyoun, N.E., Levine, H., Davis, J., Hebdon, G.M., and Cuatrecasas, P., (1981) Proc. Natl. Acad. Sci., USA, in press. Sahyoun, N.E., Levine, H., Hebdon, G-M., Hemadah, R., and Cuatrecasas, P ., (1981) Proc. Natl. Acad. Sci., USA, 7S, 2359-2362. Sahyoun, N.E., Levine, H., Hebdon, G.M., Khouri, R., and Cuatrecasas, P., (1981) Biochem. Biophys. Res. Commun. 101, 1003-1010.
689
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
30, 1981
November
IDENTIFICATION
OF SPECIFIC
HIGH AFFINITY SITES FOR THE ESTRADIOL RECEPTOR IN THE ERYTRROCYTE CYTOSKELETON
Giovanni
Alfred0
Puca and Vincenzo
Sica
First Medical School, University di Patologia generale, Via S. Andrea delle Dame, 2, 80138 Naples, Italy
Istituto Received
September
682-689
of Naples,
4,1981
SUMMARY. The possible relationship of the soluble, "cytosolic" estradiol receptor with complex membranous and cytoskeletal structures of the cell matrix has been studied using a model erythrocyte.system. Extraction of erythrocyte ghosts with a nonionic detergent (Triton X-100) under conditions that yield a cytoskeletal matrix reveals the presence of a limited number (less than 100) of specific sites having high affinity (kd lo-' M) for the estradiol-receptor complex. The interaction between the estradiol receptor and the cytoskeleton is critically dependent on temperature and it is improved by 25 mM KC1 or NaCl and by 2.5 mM MgC12. The data suggest that the estradiol receptor, which has been generally considered to be freely "soluble" in the cytoplasm, may actually be physiologically associated in an integral manner with a complex cytoskeletal network in the cell cytoplasm.
INTRODUCTION. as being target
Steroid
water-soluble cells,
hormone
macromolecules,
waiting
for
the arrival
of the hormone-receptor
complex
changes
the
This
which
determine
mechanism
and most
more than
of this
10 years
Recently this
the cytosol
since
(of
water-soluble Increasing
of a specific leads
dogma"
have been
interpreted
model
at least
target
cells)
molecule
(2-5).
of steroid
one of its of the
of the
receptor
intricate
0006-291X/81/220682-08$01.00/0 Copyright 0 1981 by Academic Press, Inc. All rights of reproduction in any form reserved.
major
682
of their Formation
molecule. conformational
the
action
of this
or addressed (see Ref.
question
hormones, model.
during
and serious
points,
i.e.,
as an unrestrained,
nature
the
the
1).
the validity
action,
and complex
compartment.
of steroid
on the basis
which
considered
to the nuclear
proposed
have been published
awareness
for
was first
cytoplasm
to putative
have not been elucidated this
been
hormone
of the receptor
dogma of the mechanism concerning
in the
"central
thesis
much data
central
be raised
data
have generally
floating
presumably
transfer
has become the
experimental
Many aspects
receptors
of
doubtgmust presence
in
freely
of the ultrastruc-
Vol. 103, No. 2,1981
tural
BIOCHEMICAL
organization
of the
various
cytoplasmic
closely
related This
(6).
importance
in cellular
The present uterus with
interacts components
be considered
organized
functions
with
high
of more complex
steroid
of the
receptors
network
and functional
evidence
that
may be
of structural unit
elements
of fundamental
the estrogen
and in a specific
erythrocyte
cytoskeletal
model
eucaryotic
of integration
hormone
microscopic
affinity
as a simplified
degree
COMMUNICATIONS
(7-15).
provide
of the
that
a morphological
studies
RESEARCH
and the high
suggests
to a highly forms
BIOPHYSICAL
cytoplasm
elements
network
AND
system
of calf
and saturable
system; for
receptor
manner
the latter
exploring
may generally
cytoskeletal
properties
cells.
MATERIALS AND METHODS. 17B-Estradiol-2,4,6,7-t4 (84 to 110 Ci/mmol) was from Amersham. Cow blood erythrocyte ghosts and cytoskeleton were prepared as described by Bennett (16,17); these were resuspended with phosphate buffer at a protein concentration of 3 to 10 mg/ml, diluted 1:l (v:v) with 99% glycerol and stored at -70° until used. Calf uterine cytosol was prepared as previously described (18) except that only phosphate buffer (7.5 mM phosphate buffer, pH 7.5) instead of Tris-HCl EDTA and dithiothreitol buffer was used. The assay of specific binding activity of cytosol was performed by the Dextran-coated charcoal method (19). The binding of the [%]estradiol-receptor complex to erythrocyte ghosts and cytoskeletons was performed in duplicate. Calf uterine cytosol was preincubated for 10 min at 20° in a total volume of 0.4 ml of phosphate buffer with 2.5 pmoles of [3H]estradiol, 12.5 pmoles KC1 and 1.25 pmoles MgC12. The reaction was started by adding 0.1 ml of cytoskeleton or ghost suspension (0.25 to 2 mg of protein) and followed either for 2 hours at 20” or for 30 min at 30°. Parallel tests were performed in the presence of 1 x 10m6 M unlabeled estradiol. The reaction was stopped by adding 10 ml of ice-cold phosphate buffer. Samples were centrifuged at 30,000 x g for 20 min at 4O and the pellets were washed three times. The final pellet was resuspended with 1 ml of phosphate buffer and assayed for radioactivity. The values obtained in the presence of unlabeled hormone were subtracted from the total.
Specific
RESULTS. -in erythrocyte These
sites
(Fig.
1).
cyte
membranes, are only
membranes
with
erythrocyte the
ghosts
with This
but
detected
The maximal
concentrations. the
binding
number
1% Triton
sites only
or cytoskeleton
extraction
of binding X-100
(20).
estradiol of calf
appears
and does not
uterine
is used
the uterine
with
with
detergent
hormone
of erythro-
higher
operationally
cytosol
cytosol.
by treatment
increase
The tritiated
683
can be detected
of the membranes
sites
procedure
if
radioactive
in the presence
after
extraction
“cytoskeleton”
for
detergent
to prepare does not
is omitted,
if
associate the
Vol. 103, No. 2,198l
BIOCHEMICAL
AND
0.25
BIOPHYSICAL
0.50
0.75
1.00
TRITON
RESEARCH
1.25
X-100,
COMMUNICATIONS
1.50
%
Fig. 1. Efrect of extracting erythrocyte ghosts with Triton X-100 on the appearance of specific binding of [%]estradiol-receptor complex. Erythrocyte ghosts were extracted for 15 min at 0" with the indicated concentrations of Triton X-100. After extraction, the ghosts were centrifuged and washed four times with phosphate buffer. The pellets were resuspended at a final protein concentration of 12 q g per ml with phosphate buffer. Aliquots of 0.1 ml were then incubated for two hours at 20“ with 0.2 ml of calf uterine cytosol, previously labeled with [%l]estradgol.
cytosol
is
tissue
(e.g.,
(e.g.,
albumin,
for
inactivated liver,
Binding
(Fig.
of the
inherent
of calf
uterine
subsequent
at O" (dotted
decrease ionic
about
association with
cytosol
with
binding line,
2 hours
receptor
erythrocyte
30° cannot
estradiol-receptor
proteins sites
be considered
than
for
of other
therefore of the
from a non-target.
to be a
cytoskeleton.
is time
and temperature
be used easily
complex.
because
Preincubation
at 20° does not
[3H]estradiol-receptor
complex
in important
ways by KC1 or NaCl.
change
to the cytoskeleton
2).
is
affected
three-fold
higher
no specific
cytoskeleton
the hormone
of the Fig.
with
to the
higher
of the
a cytosol
amounts
components
Temperatures
if
similar
must
receptor
instability
the binding
strengths
This
estradiol
2).
The interaction increases
is used or if
interaction of the
(30 min at 600),
imraunoglobulins)
are used.
receptor-mediated
the
thymus)
ovalbumin,
estradiol
dependent
by heating
in the presence
but
not
than
to values 1 M (Fig.
below 3A).
684
of 25 mM KCl; those
higher
seen without
In the presence
Binding
concentrations KCl,
even at
of 25 mM KCl,
Ca++
BIOCHEMICAL
Vol. 103, No. 2.1981
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
MINUTES
Fig. 2. Time course of binding of estradiol-receptor complex to erythrocyte cytoskeleton. Erythrocyte cytoskeleton was incubated with 0.1 ml of calf uterine cytosol. Incubations were carried out at O" (a), lo0 (o), ZOO (A) and 30° (A). At the indicated times the reaction was stopped by adding cold phosphate buffer and the binding was measured. The dotted line represents the binding at 20°.
at
4O after
preincubation
of
the
estradiol-receptor
complex
for
2 hr
(up to 5 mM) has no stimulatory effect, while 5 mM Mn++ slightly increases the ++ binding. Mg stimulates the binding substantially, with an optimal concentration at 2.5 mM (Fig.
3B).
The binding
of the
the concentration ml,
provided
shown). that
the
affinity
suggest
the
(Fig.
presence
affinity
4A).
and quantity component
number
of these
high
that the
4B).
From the
1 mg of cytoskeletal cytoskeleton
affinity data
the
(Fig. is
about sites
described protein
from one erythrocyte
receptor
interaction analyses
of binding 4A).
is
is not is
without in figure corresponds appears
685
related
limiting
kept
appears
sites
modifying
to bind
while
markedly
constant
in
of the
substantially
the dissociation
5 x 10'
and
experiments
4B, and independently to about
per
to be saturable
differing
Mg++ increases
to
(not
constant
of such saturation
The dissociation
10ms M.
linearly
of 100 to 1000 pg protein
concentration
Scatchard
of two classes
affinity
(Fig.
cytoskeleton
increased,
higher
range
of estradiol
when the is
complex
in the
concentration
receptor
of high
their
of cytoskeleton
However,
of the
[%]estradiol-receptor
the constant determining
erythrocytes,
a maximum of 50 to 100
vol. 103, No. 2,1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
I
I 100
I 200
I 300
COMMUNICATIONS
I
I
r
6
8
IO
I
I 400
2
4
KCI , mM
MgCl2
,mM
Fig.83. Effect of increasing concentrations of KC1 and MgClz on the binding A. Erythrocyte of [ Hlestradiol-receptor complex to erythrocyte cytoskeleton. cytoskeleton was incubated for 2 hr at 20° with 0.2 ml of calf uterine cytosol cytoskeleton and calf with the indicated concentration of KCl. B. Erythrocyte uterine cytosol were incubated in phosphate buffer containing 25 mM KC1 and the indicated concentration of MgClz.
molecules
of estradiol-receptor
is bound
per
forms
studied
separately,
the native
affinity
to the
lost
the ability
of estradiol
to these
of the
a discreet
Triton
shells.
sites, molecules
might to factors which
while
receptor
those
forms
uterine
to erythrocyte
lipid
bilayer
and finite
are
removed
of binding
of the erythrocyte
to steric
can be removed
(data
localization hindrance
by the
detergent.
686
fact not
controlled (18)
found ghosts
the
binding
shown). displays
almost
detergent,
associated to bind
or to their is
the
the estradiol binding
occupancy certain,
Triton with
of the putative
It
have
when many of the proteins
the nonionic is
and
great
that
complex
However, with
with
after
the
estradiol-receptor
be due to an internal related
unaltered
(18)
or by trypsin
despite
ghosts.
amount
The inability
is
binds
obtained
protease
cytoskeleton
are prepared
receptor
forms
uterine
to the
The calf
binding
X-100,
receptor
one mole of estradiol
receptor
8 S form of the
Ca++ -dependent
to bind
DISCUSSION.
and most
of the estradiol
cytoskeleton,
by the
no specific
that
mole of receptor.
When the various
proteolysis
assuming
complex,
by other
however,
that
BIOCHEMICAL
Vol. 103, No. 2,198l
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
‘H t,RfCtPTOR
COMPLEX BOUND ;lO%~
3H-EiRECEPTOR
COMPLEX
[lo-'M]
Fig. 4. Effect of increasing the concentration of [3H]estradiol-receptor complex on the binding of erythrocyte cytoskeleton. Erythrocyte cytoskeleton was incubated for 2 hr at ZOO with different amounts of calf uterine cytosol. The binding was carried out in the presence of 25 mH KC1 alone (A) or in the presence of 25 mM KC1 and 2 mM MgClz (B). Inserts: Scatchard plots of the data.
these
sites
membrane. also
are very The strong
suggests
temperature
the
facilitate
of the the
residual
changes,
or it
Alternatively, arrangements Saturation
dependence
is not
might
simply
analysis
since
binding
might
receptor
it
proteins
of the
modificatidn cytosol
at low temperature the need
might
induce
of the
receptor disrupt
receptor-cytoskeletal
This
organization.
heating
essential
687
on temperature
of a necessary
prior
may actively
of the erythrocyte
binding
cytoskeletal
reflect
access
of the
cytoskeleton
to cytoskeletons
components,
low temperatures of structural
an "open"
(21)
facilitate
the
a manifestation
requirement
membrane
with
of estradiol for
receptor
subsequent
The temperature
of the
associated
requirement
effect
or activation
2).
strongly
for
for
(Fig.
increased
necessary to its necessary
does not
fluidity
conformational binding
site.
organizational
binding. interaction
reveals
the
Vol. 103, No. 2,1981
presence
BIOCHEMICAL
of a very
sites
per
major
protein
ankyrin,
erythrocyte
4.1)
the
components
Similar
systems
estrogen
primarily the (24)
in
that
cytoplasm. cytoskeletal
cells.
very
Thus,
it
exist
constitutes
a highly approaches
interactions
cells,
for
is
model elsewhere to those
conceivable
Although
could of action
the
and high
explain
the hormone-dependent
high also
exist
cytosol
(3-5),
cytoskeletal
in
is
and that matrix
of the cell
analogous
adenylate
affinity
water-
in the
network
demonstrated
data hormones
traditional
and preparation of a complex
affinity
membrane.
here
found
the
++ Mg .
for
that
described
strength
manner,
of steroid
demonstrate
that
actin,
ionic
in part
microtrabecular
have recently
one of the
3, spectrin,
of specific
receptor
as part
organized
that
of the erythrocyte
homogenization
--in situ
binding
to be selective
which
8 S estradiol
of tissue
normally
matrix
similar
affinity
band
existence
the general
of the native,
Similar
the
COMMUNICATIONS
in a nonspecific
appears
to be published sites
an artefact
receptors
target
with
binding
nature
for
of high
the binding.
interaction
evidence
may exist
100)
(e.g.,
for
of binding
RESEARCH
the possibility
cytoskeleton
in the cytoskeletal
Results
target
than
excludes
may be responsible
contradictory
cytoskeletal
soluble
of the
provide
binding
22-31).
(less
This
enhancement
data
apparently
ghost.
BIOPHYSICAL
receptor-cytoskeletal
cation-dependent These
number
components
band
influences
(2-5,
limited
AND
cyclase
erythrocyte system
(32-34).
ACKNOWLEDGEMENTS. The authors thank Drs. Naji Sahyoun and Vann Bennett for their helpful advice. This work was supported by the Progetto Finalizzato: Controllo della Crescita Neoplastica, by a grant from the Wellcome Research Laboratories, RTP, North Carolina and the National Institute of Health Contract No. NOl-CB-64074.
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RESEARCH
COMMUNICATIONS
Edelman, G. (1976) Science 192, 218-226. Crossin, K.L., and Corney, D.H. (1981) Cell 23, 61-71. DePetris, S., and Raff, M.C. (1972) Eur. J. Immun. 2, 523-535. Porter, K.R. (1976) in Cell Motility (Goldman, R., Pollard, 'I., and Rosenbaum, J. eds) pp. l-28 Cold Spring Harbor Laboratory, New York. Goldstein, J.L., Anderson, R.G.W., and Brown, H.S. (1979) Nature 279, 679484. Eckert, B.S., Koons, S.J., Schantz, A.W., and Zobel, C.R. (1980) J. Cell. Biol. 86, l-5. Cervera, M., Dreyfuss, G., and Penman, S. (1981) Cell 2, 113-120. Giannattasio, G., Zanini, A., Rosa, P., Meldolesi, J., Margolis, R.K., and Margolis, R.V. (1980) J. Cell. Biol. 86, 273-277. Bennett, V., and Stenbuck, P.J. (1979) J. Biol. Chem. 254, 2533-2541. Bennett, V., and Stenbuck, P.J. (1979) Nature 280, 468-473. Puca, G.A., Nola, E., Sica, V., and Bresciani, F. (1972) Biochemistry 11, 4157-4165. Sanborn, B.M., Ramanth Rao, B., and Korenman, S.G. (1971) Biochemistry IO, 4955-4965. Yu, J., Fishman, D.A., and Steck, T.L. (1973) J. Supramolec. Strut I, 233-248.
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Nenci, I., Fabris, G., Marchetti, E., and Marzola, A. (1980) Virchows Arch. B Cell Path. 32, 139-145. Munck, A., and Brinck-Johnes, T. (1968) J. Biol. Chem. 263, 5556-5565. Noteboom, W.D., and Gorski, J. (1965) Arch. Biochim. Biophys. 111, 559-568 Harrison, R.W., Fairfield, S., and Orth, D.N. (1974) Biochem. Ephys. Res. Con-us. 6l, 1262-1267. Suyemitsu, T., and Terayame, H. (1975) Endocrinology 96, 1499-1508. Baulieu, E.E., Godeau, F., Schorderet, M., and Schorderet-Slatkine, S. (1978) Nature 275, 593-598. Sahyoun, N.E., Levine, H., Davis, J., Hebdon, G.M., and Cuatrecasas, P., (1981) Proc. Natl. Acad. Sci., USA, in press. Sahyoun, N.E., Levine, H., Hebdon, G-M., Hemadah, R., and Cuatrecasas, P ., (1981) Proc. Natl. Acad. Sci., USA, 7S, 2359-2362. Sahyoun, N.E., Levine, H., Hebdon, G.M., Khouri, R., and Cuatrecasas, P., (1981) Biochem. Biophys. Res. Commun. 101, 1003-1010.
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