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J. Biol. Chem., Vol. 275, Issue 46, 36197-36203, November 17, 2000
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From the Cancer Research Campaign Growth Factor Group, School of
Biosciences, University of Birmingham, Edgbaston,
Birmingham B15 2TT, United Kingdom
Received for publication, May 30, 2000, and in revised form, August 15, 2000
Interleukin-11 (IL-11) is a member of the gp130
family of cytokines. These cytokines drive the assembly of multisubunit
receptor complexes, all of which contain at least one molecule of the
transmembrane signaling receptor gp130. IL-11 has been shown to induce
gp130-dependent signaling through the formation of a high
affinity complex with the IL-11 receptor (IL-11R) and gp130.
Site-directed mutagenesis studies have identified three distinct
receptor binding sites of IL-11, which enable it to form this high
affinity receptor complex. Here we present data from
immunoprecipitation experiments, using differentially tagged forms of
ligand and soluble receptor components, which show that multiple copies
of IL-11, IL-11R, and gp130 are present in the receptor complex.
Furthermore, it is demonstrated that sites II and III of IL-11 are
independent gp130 binding epitopes and that both are essential for
gp130 dimerization. We also show that a stable high affinity complex of
IL-11, IL-11R, and gp130 can be resolved by nondenaturing
polyacrylamide gel electrophoresis, and its composition verified by
second dimension denaturing polyacrylamide gel electrophoresis. Results
indicate that the three receptor binding sites of IL-11 and the Ig-like domain of gp130 are all essential for this stable receptor complex to
be formed. We therefore propose that IL-11 forms a hexameric receptor
complex composed of two molecules each of IL-11, IL-11R, and gp130.
Interleukin-11 (IL-11)1
is a secreted polypeptide cytokine, which has been shown to exhibit
in vitro biological effects on a diverse range of cell types
including hemopoietic cells, hepatocytes, adipocytes, neurons, and
osteoblasts (reviewed in Ref. 1). In vivo administration of
IL-11 results in the stimulation of megakaryopoeisis and increased
platelet counts (2). Recombinant human IL-11 is now used for the
treatment of chemotherapy-induced thrombocytopenia (3). IL-11 also has
clinical potential for the treatment of several disorders including
chemotherapy induced oral mucositis (4), Crohn's disease (5), and
rheumatoid arthritis (6). Transgenic deletion of the gene
encoding the specific IL-11 receptor (IL-11R) in mice has
revealed an important role for IL-11 in embryonic implantation. Female
mice deficient in the IL-11R are infertile because of defective
decidualization, following implantation of the embryo (7, 8).
IL-11 is a member of the gp130 family of cytokines. These cytokines
drive the assembly of multisubunit receptor complexes, which initiates
intracellular signal transduction pathways. In all cases, the receptor
complexes contain at least one copy of the signal transducer
glycoprotein gp130 (9). Other cytokines belonging to this family
include interleukin-6 (IL-6), leukemia inhibitory factor (LIF),
oncostatin M (OSM), ciliary neurotrophic factor (CNTF),
cardiotrophin-1, and a viral homologue of IL-6 encoded by the Kaposi's
sarcoma-associated herpesvirus. Each of these cytokines exerts its
action by either homo- or heterodimerization of gp130, which leads to
the stimulation of signaling cascades via protein kinases belonging to
the Janus kinase, mitogen-activated protein kinase, and Src families
(10-13).
The gp130 cytokines exhibit both overlapping and unique biological
activities in vitro and in vivo (reviewed in Ref.
14). The signal exerted by a cytokine and therefore the biological response depends on the exact composition of the signaling receptor complex. Signaling specificity of the gp130 cytokines is conferred by
the use of ligand-specific receptors. Specific receptors for IL-6 (15),
IL-11 (16, 17), and CNTF (18) have been identified. These receptors are
not directly involved in cytoplasmic signaling, but their function is
to promote the formation of a high affinity complex between the
respective ligand and gp130. These ligand specific receptors and gp130
are all members of the hemopoietic family of receptors (reviewed in
Ref. 19), characterized by the presence of a cytokine binding homology
domain (CHD).
The CHD, of approximately 200 amino acids, comprises two fibronectin
type III domains (D1 and D2), with four positionally conserved cysteine
residues in the first domain and a WSXWS motif (where
X is any amino acid) in the second domain (20). The crystal structure of the CHD of gp130 revealed that the two fibronectin type
III domains exhibit an approximate L-shape (21), and mutagenesis studies have identified residues in the hinge region that are important
for ligand binding (22-24). In addition to the CHD, gp130 and all
known receptors that bind to the gp130 family of cytokines also contain
an amino-terminal domain predicted to adopt a seven- The gp130 cytokines share a common four- IL-11 has been shown to have three distinct receptor binding sites
analogous in location to sites I, II, and III of IL-6 (32). Site I
enables IL-11 to bind to IL-11R, while sites II and III both mediate
binding to gp130. Taken together with the finding that IL-11 signaling
requires IL-11R and gp130, but not LIF receptor (LIFR) or OSM receptor
(OSMR) (16, 39), it is predicted that IL-11 forms a signaling complex
in a manner analogous to that of IL-6. However, published work
regarding the composition and stoichiometry of the IL-11 receptor
complex has, as yet, not been conclusive. Neddermann et al.
(40) reported a pentameric IL-11 receptor complex consisting of two
IL-11, two IL-11R, and one gp130. They suggested that gp130
homodimerization is not involved in IL-11-mediated signaling and that
another, as yet unidentified, signaling receptor component is required.
Furthermore, Grotzinger et al. (41) have suggested that the
IL-11 receptor complex may be a tetramer, consisting of one IL-11, one
IL-11R, and two gp130 molecules (41). Here we report findings from
in vitro immunoprecipitation experiments and gel shift
assays, which clearly demonstrate that the IL-11 receptor complex is a
hexamer, consisting of two molecules each of IL-11, IL-11R, and gp130.
Plasmid Constructs--
The design and construction of
pIG/mIL-11R-Fc, pIG/mgp130-Fc, and pGEX/mIL-11 plasmids (IL-11 wild
type, R111A/L115A, and W147A) has been described previously (32, 39).
The pIG/mgp130(Ig
pIG/mIL-11R-Myc and pIG/mgp130-Myc, which encode IL-11R and gp130
ectodomains with COOH-terminal Myc tags, were derived from pIG/mIL-11R-Fc and pIG/mgp130-Fc (39) by subcloning. For both, the
region encoding the Fc region of human IgG1, bounded by
Eco4711 and NotI, was replaced with a 401-base
pair Eco4711/NotI fragment from
pIG/mLIFR-poly(Asn)-Myc3 that
encodes six Asn residues followed by the Myc antibody epitope (EEQKLISEEDL).
pGEX/HA-IL-11 was constructed as follows. The sequence encoding the
hemagglutinin (HA) tag (YPYDVPDYA) was added to the 5' end of the IL-11
coding region by PCR, using a 5' primer encoding a BamHI
restriction site and the HA tag, and a 3' primer encoding an
EcoRI restriction site. The PCR product was then subcloned as a 571-base pair BamHI/EcoRI fragment into
pGEX-3C (42).
pCDNA3/IL-11R-HA(3C)Fc was generated by the addition of the HA tag
coding sequence at the 3' end of IL-11R by PCR. The IL-11R-ectodomain coding region was amplified using a 5' primer encoding an
EcoRI restriction site, and a 3' primer encoding the HA tag
and a BamHI restriction site. The PCR fragment was then
subcloned as a 1137-base pair EcoRI/BamHI
fragment into
pcDNA3-3C-Fc.4
Expression and Purification of Proteins--
Murine IL-11R-Fc,
gp130-Fc, gp130(Ig
Proteins were analyzed by SDS-PAGE followed by staining with Coomassie
Brilliant Blue R250, or Western blotting and detection with antisera.
For Western blotting, proteins were transferred onto polyvinylidene
difluoride (Millipore) using a standard protocol (45). Membranes were
then blocked overnight in PBS, 3% BSA and subjected to immunodetection
using antisera diluted in blocking buffer. Blots were developed using
Super Signal West-Pico enhanced chemiluminescence (ECL) (Pierce).
Biotinylation of Proteins--
IL-11 was modified by
biotinylation on Co-immunoprecipitation of Differentially Tagged Cytokine-Receptor
Complexes--
Slightly different strategies were adopted for
co-immunoprecipitation of the different components of the IL-11
receptor complex. For immunoprecipitation of bIL-11·HA-IL-11
complexes, equimolar concentrations (100 nM) of HA-IL-11,
bIL-11, gp130, and IL-11R were mixed together in various combinations,
in a total volume of 500 µl of binding buffer (PBS, 1% BSA, 0.05%
Tween 20). Mixtures were incubated for 3 h at room temperature at
which point, NeutrAvidin-agarose (Pierce) (10 µl) was added
and then agitated for 16-18 h at 4 °C.
For immunoprecipitation of complexes containing Myc-tagged components,
5 µl of anti-Myc monoclonal antibody (clone 9E10, BABCo) was first
immobilized on 8 µl of Protein G-Sepharose (Amersham Pharmacia
Biotech), in a final volume of 500 µl of binding buffer. The resin
was then used to immunoprecipitate gp130-Myc from 500 µl of 293T
conditioned medium. This "loaded" resin was then added to 500 µl
of binding buffer containing equimolar concentrations (100 nM) of IL-11, IL-11R, and bgp130, in various combinations, and incubated for 16-18 h at 4 °C with agitation. Similarly,
IL-11R-Myc was immunoprecpitated using resin coated with anti-Myc
monoclonal antibody and then added to 500 µl of binding buffer
containing equimolar concentrations (100 nM) of IL-11,
IL-11R-HA, and gp130 or bgp130, in various combinations, and incubated
for 16-18 h at 4 °C with agitation.
Following all immunoprecipitation reactions, complexes were harvested
by centrifugation, extensively washed with PBS, 0.1% Tween 20, and
resuspended in 20 µl of SDS-PAGE loading buffer (300 mM
Tris, pH 6.8, 600 mM dithiothreitol, 12% SDS, 0.6%
bromphenol blue, 30% glycerol). The immunoprecipitated proteins were
then resolved by SDS-PAGE, Western-blotted, and detected using a mouse anti-HA monoclonal antibody (clone 12CA5, Roche Molecular Biochemicals) or streptavidin-HRP conjugate, followed by ECL.
Nondenaturing PAGE and Second Dimension Denaturing
PAGE--
Equimolar concentrations of IL-11 and soluble receptor
components were mixed together, in various combinations, in a total volume of 16 µl of PBS, 0.05% Tween 20. Complexes were allowed to
form for a minimum of 4 h at 18-22 °C. 4 µl of native gel
loading buffer (120 mM Tris, pH 6.8, 745 mM
glycine, 50% glycerol, 0.5% bromphenol blue) was then added and each
sample loaded onto a 4-20% Tris-glycine gel (Novex). Electrophoresis
was then carried out at 15 mA for 2 h in native running buffer (24 mM Tris, 149 mM glycine). Proteins were
detected using either Coomassie Brilliant Blue R250 or silver staining
(46).
For second dimension SDS-PAGE, Coomassie-stained bands were excised
from the gel and soaked in SDS loading buffer (62.5 mM Tris, pH 6.8, 5% 2-mercaptoethanol, 2% SDS, 0.1% bromphenol blue, 10% glycerol) for 5 min. The proteins were then resolved by SDS-PAGE using a 12% polyacrylamide gel and detected by silver staining (46).
Multiple Copies of gp130, IL-11R, and IL-11 Are Present in the
IL-11 Receptor Complex--
IL-11-mediated signaling has been shown to
require both IL-11R and gp130 (16, 32, 39). A specific interaction
between IL-11 and the IL-11R has been demonstrated, and a soluble form of IL-11R has been shown to promote the formation of a high affinity complex between IL-11 and gp130 (39). To assess the stoichiometry of
this high affinity IL-11 receptor complex immunoprecipitation experiments using differentially tagged receptor components, similar to
the assays used by Paonessa et al. (38), were carried out. Each component of the receptor complex was labeled with two different tags. Receptor complexes were then immunoprecipitated using one tag and
examined by Western blot analysis to determine whether the second tag
could be detected. The ability to co-precipitate differentially tagged
forms of a protein indicated the presence of two copies of that protein
in the receptor complex.
To examine the number of gp130 molecules in the IL-11 receptor complex,
Myc-tagged gp130 was first immobilized on Sepharose beads coated with
anti-Myc monoclonal antibody. Immunoprecipitations were then carried
out using various combinations of IL-11, IL-11R, and biotinylated gp130
(bgp130). Following SDS-PAGE and Western blotting, immunoprecipitated
bgp130 was detected using streptavidin-HRP conjugate. The results, as
shown in Fig. 1, indicate that bgp130 (which migrates with an approximate molecular mass of 97 kDa) was
co-precipitated with gp130-Myc, in the presence of IL-11 and IL-11R
(see lane 1). In the absence of either IL-11R or
IL-11, immunoprecipitated bgp130 could not be detected (see
lanes 2 and 4). These results show
that at least two copies of gp130 are present in the IL-11 receptor
complex and that both IL-11 and IL-11R are required for gp130
dimerization.
A similar approach, using Myc-tagged IL-11R and HA-tagged IL-11R, was
used to investigate the number of IL-11R molecules present in the IL-11
receptor complex. Following immunoprecipitations, using immobilized
IL-11R-Myc and various combinations of IL-11, gp130, and IL-11R-HA, the
presence of the latter was detected using anti-HA antiserum. The
results, as shown in Fig. 2, show that
IL-11R-HA (which migrates with an approximate molecular mass of 45 kDa)
was co-precipitated with IL-11R-Myc, but only in the presence of both
IL-11 and gp130 (see lane 3). This indicates that
the high affinity IL-11 receptor complex contains at least two copies
of IL-11R.
To examine the number of IL-11 molecules in the IL-11 receptor complex,
biotinylated IL-11 (bIL-11) was first immobilized on
NeutrAvidin-agarose. Immunoprecipitations were then carried out using
various combinations of IL-11R, gp130, and HA-tagged IL-11. The
presence of HA-IL-11 in the immunoprecipitates was detected using
anti-HA antiserum. The results, as shown in Fig. 3, show that HA-IL-11 (which migrates
with an approximate molecular mass of 22 kDa) was co-precipitated with
bIL-11, but only in the presence of both IL-11R and gp130 (see
lane 1). This indicates that at least two copies
of IL-11 are present in the high affinity IL-11 receptor complex. The
complex thus contains multiple copies of IL-11, IL-11R, and gp130.
IL-11 Site II and Site III Mutants Are Unable to Dimerize
gp130--
Immunoprecipitation experiments, similar to those described
above, were also used to examine the ability of IL-11 mutants to form
high affinity receptor complexes. It has previously been shown that
both the site II mutant, R111A/L115A, and the site III mutant, W147A,
exhibit reduced binding to gp130 and hence reduced biological activity,
while maintaining normal affinity for IL-11R (32). Immunoprecipitation
assays were performed using immobilized gp130-Myc and various
combinations of bgp130, IL-11R, and wild type or mutant bIL-11. By
using both biotinylated ligand and bgp130, this enabled us to examine
the ability of the IL-11 mutants to bind to gp130-Myc in the presence
of IL-11R, and also the ability of the mutants to co-precipitate
bgp130. The results, as shown in Fig.
4A, confirm those described
earlier, i.e. bgp130 is only co-precipitated with gp130-Myc
in the presence of IL-11R and wild type IL-11 (see lane
1). Neither the site II mutant, R111A/L115A, nor the site
III mutant, W147A, were able to dimerize gp130, as bgp130 was not
co-precipitated with gp130-Myc in the presence of IL-11R (Fig.
4A, see lanes 5 and 6).
However, the fact that biotinylated mutant ligand was detected (see
lanes 5 and 6) indicates that both of
the IL-11 mutants were co-precipitated with gp130-Myc, in the presence
of IL-11R, even though a second molecule of gp130 was not detected.
These results provide evidence that sites II and III of IL-11 are
independent gp130 binding sites and that both sites are required for
the dimerization of gp130. The results suggest that both the site II
mutant and the site III mutant, although unable to dimerize gp130, can
bind a single molecule of gp130 in the presence of IL-11R. This was
confirmed by the co-precipitation of bgp130 with IL-11R-Myc by the two
mutants, as shown in Fig. 4B. These results indicate that
mutation of one gp130 binding site (either site II or site III) does
not affect the other gp130 binding site, which remains free and intact
to bind a single molecule of gp130. If IL-11 binds to IL-11R with a 1:1
stoichiometry, this indicates that the two mutants formed trimeric
complexes, consisting of one molecule each of IL-11, IL-11R, and gp130.
A Stable Complex of IL-11, IL-11R, and gp130 Can Be Resolved by
Nondenaturing PAGE--
The results described above, together with the
fact that a complex of IL-11 and soluble IL-11R can mediate signaling
by association with gp130 (39), suggest that interactions between IL-11
and the extracellular regions of gp130 and IL-11R are sufficient for the formation of a high affinity receptor complex. A stable complex formed between IL-11 and soluble forms of IL-11R and gp130 can be
resolved by nondenaturing PAGE. Equimolar quantities (1 µM) of IL-11, soluble IL-11R, and soluble gp130 were
mixed together in various combinations, incubated to allow complexes to
form, and subjected to nondenaturing PAGE. The results, as shown in Fig. 5A, show that a complex
of IL-11, IL-11R, and gp130 can be resolved as a discrete band (see
lane 1), which was not be detected if any one of
the three components was absent. IL-11R and gp130 alone were detected
as single bands following nondenaturing PAGE, as indicated in Fig.
5A. Free IL-11 does not migrate into the gel, because of its
high isoelectric value (predicted to be 11.7). A complex of IL-11 and
IL-11R was also detected as a faint band, which had migrated further
into the gel compared with the IL-11·IL-11R·gp130 complex (see Fig.
5A, lane 2). However, this
IL-11·IL-11R complex was only observed if high concentrations (1 µM) of recombinant protein were used. If lower
concentrations (in the nanomolar range) of recombinant protein were
used, only the high affinity IL-11·IL-11R·gp130 complex could be
detected (see Fig. 6). This is probably
because complexes of IL-11 and IL-11R dissociate more easily compared with ternary complexes containing IL-11, IL-11R, and gp130. IL-11 has
been previously shown to bind gp130 in the presence of IL-11R with
higher affinity compared with binding IL-11R alone (16, 39).
The high affinity complex resolved by nondenaturing PAGE (labeled as
band 1* in Fig. 5A) was predicted to
contain IL-11, IL-11R, and gp130 because in the absence of either one
of the components it could not be detected. The composition of the
complex was confirmed by second dimension SDS-PAGE. The results, as
shown in Fig. 5B, indicate that IL-11, IL-11R, and gp130
were all present in the ternary complex, which resolved as a discrete
band during nondenaturing PAGE. Similarly, the composition of the
IL-11·IL-11R complex (labeled as band 2* in
Fig. 5A) was confirmed using this method (see Fig. 5B).
IL-11 Site II and Site III Mutants Are Unable to Form a Stable
Ternary Receptor Complex--
To further investigate the stoichiometry
of the ternary receptor complex, observed as a discrete band following
nondenaturing PAGE, the ability of IL-11 mutants to form such a complex
was examined. The results described earlier indicate that the site II
mutant, R111A/L115A, and the site III mutant, W147A, are both unable to
dimerize gp130, although they can bind a single molecule of gp130 in
the presence of IL-11R. The ability of these two mutants to form a
stable receptor complex was therefore examined using nondenaturing
PAGE. Equimolar concentrations (300 nM) of IL-11, IL-11R,
and gp130 were mixed together, incubated, and subjected to
nondenaturing PAGE. Receptor complexes were then visualized using
silver staining (46). The results, as shown in Fig. 6, were consistent
with those described above, i.e. a complex of IL-11 wild
type, IL-11R, and gp130 was observed as a single discrete band (see
lane 1), which could not be detected if either
IL-11R or gp130 were absent. A complex of IL-11 and IL-11R was not
detectable using these concentrations of recombinant protein (300 nM).
The results in Fig. 6 also show that both the site II mutant,
R111A/L115A, and the site III mutant, W147A, were unable to efficiently
form a stable receptor complex co-migrating with that of IL-11 wild
type. The receptor complexes formed by the site II mutant (see
lane 5) include a very faint band co-migrating with the ternary complex formed by IL-11 wild type, but also a second
complex, which has migrated further into the gel. This second complex
appears to co-migrate with a dimer of IL-11 R111A/L115A and IL-11R,
observed in lane 6. However, the intensity of the band is stronger in the presence of gp130 (compare lanes
5 and 6), which, together with the earlier
results from immunoprecipitation experiments, indicate that this band
is a trimer. The fact that a dimer of IL-11 R111A/L115A and IL-11R was
detected, while a dimer of IL-11 wild type and IL-11R was not
detectable, correlates with the fact that the site II mutant has a
4-fold increase in affinity for IL-11R compared with IL-11 wild type,
as described previously (32). The results in Fig. 6 also show that the
site III mutant, W147A, was unable to form a stable receptor complex co-migrating with that of IL-11 wild type during nondenaturing PAGE.
Instead, a single band that migrated further into the gel was detected
(see lane 7). This band was not detected in the
absence of gp130 (see lane 8), which suggests
that it represents a trimeric receptor complex, as opposed to a dimer
of IL-11 W147A and IL-11R.
The results described here from nondenaturing PAGE, and the
immunoprecipitation experiments described earlier, suggest that the
single discrete band formed by IL-11 wild type, IL-11R, and gp130 (as
seen in lanes 1 of Figs. 5A and 6)
represents a hexamer. Trimeric receptor complexes can also be detected
as single bands although they co-migrate with dimers of IL-11·IL-11R
and, like the dimers, they appear to be less stable than the hexamer.
The fact that the site II mutant exhibited a significant reduction in
its ability to form a hexamer, compared with IL-11 wild type (i.e small
amounts of hexamer were detected), while the site III mutant was unable
to form a hexamer correlates with the observed biological activities of
these two mutants. That is, R111A/L115A shows more than a 10-fold
reduction in biological activity, compared with IL-11 wild type, while
the activity of W147A is completely abolished, as described previously
(32).
The Ig-like Domain of gp130 Is Required for a Stable Ternary
Complex of IL-11, IL-11R, and gp130 to Be Formed--
The ability of a
gp130 mutant, lacking the Ig-like domain, to form a stable receptor
complex was also examined using nondenaturing PAGE. Various
combinations of IL-11 wild type, IL-11R, and either wild type or the Ig
deletion mutant of gp130 were mixed together, incubated, and subjected
to nondenaturing PAGE. Receptor complexes were then visualized using
silver staining (46). The results, as shown in Fig.
7, show that a complex of IL-11, IL-11R,
and the Ig deletion mutant of gp130 was detectable as a band, which migrated further into the gel, compared with the hexamer formed by
IL-11, IL-11R, and wild type gp130. This gp130(Ig Cytokines mediate their biological effects through the formation
of oligomeric receptor complexes, which initiates intracellular signaling. The nature of this signal, and the resulting biological response, depends on the specificity and affinity of the interactions between cytokines and their receptors. Understanding how cytokines recognize and engage receptors is therefore an important issue in
understanding biological function. Information regarding the mechanism
by which a cytokine exerts a response can also aid the manipulation of
cytokine signaling; for example, in the generation of agonists and/or
antagonists which could have therapeutic value. Both the cytokines and
the receptors of the gp130 family share common structural features, and
general patterns of receptor engagement are now emerging. This study
contributes to our understanding of how this family of cytokines form
multisubunit receptor complexes.
Current evidence suggests that the gp130 family of cytokines initiate
intracellular signaling through either homo- or heterodimerization of
gp130. IL-11 has previously been shown to specifically interact with
the IL-11R and gp130 (39). Furthermore, cells expressing these two
receptors are responsive to IL-11 (32). It has also been shown that
IL-11 can mediate a biological response through interaction with a
soluble form of the IL-11R and full-length gp130, a response which does
not require LIFR or OSMR (16, 39). These results suggest that IL-11
mediates signal transduction through gp130 homodimerization, but
published data regarding the composition and stoichiometry of the
ternary IL-11 receptor complex has as yet not been conclusive. From
immunoprecipitation experiments, similar to those reported here,
Neddermann et al. (40) described a pentameric receptor
complex consisting of two IL-11, two IL-11R, and one gp130. IL-6, on
the other hand, has been shown to form a hexameric receptor complex,
consisting of two molecules each of IL-6, IL-6R, and gp130 (37,
38).
The results described here from immunoprecipitation experiments
show that multiple copies of gp130 are present in the IL-11 receptor
complex. Homodimerization of gp130 was demonstrated to require both
IL-11 and IL-11R. Furthermore, it was shown that multiple copies of
both IL-11 and IL-11R are also present in the IL-11 receptor complex.
The high affinity IL-11 receptor complex therefore contains at least
two copies each of IL-11, IL-11R, and gp130 and since ligand-mediated
homodimerization of gp130 is clearly sufficient for signal transduction
to be initiated, as demonstrated for IL-6, we propose that the IL-11
receptor complex is a hexamer (depicted in Fig.
8), although we cannot formally rule out
the possibility of larger complexes. The fact that wild type IL-11 was
shown to induce gp130 homodimerization, in the presence of IL-11R,
contradicts previous published results (40). The formation of a ternary
receptor complex containing at least two molecules of gp130, observed
here, excludes the requirement for a novel signaling receptor component
as proposed by Neddermann et al. (40).
Further evidence supporting the hexameric model was obtained using two
mutant forms of IL-11, R111A/L115A and W147A, the activities of which
have previously been reported (32). Results from immunoprecipitation experiments revealed that neither the site II mutant, R111A/L115A, nor
the site III mutant, W147A, were able to dimerize gp130. The fact that
both of these mutants were able to bind a single molecule of gp130 in
the presence of soluble IL-11R shows that sites II and III of IL-11 are
independent gp130 binding sites. IL-11 has been shown to interact with
the IL-11R through site I (32), and assuming IL-11 binds to the IL-11R
with a 1:1 stoichiometry, this suggests that the mutants formed
trimeric complexes consisting of one molecule each of IL-11, IL-11R,
and gp130.
The results presented here from nondenaturing PAGE analysis confirm
that interactions between IL-11 and the extracellular domains of IL-11R
and gp130 are sufficient to form a stable ternary complex. A complex of
IL-11, IL-11R, and gp130 was resolved by PAGE under nondenaturing
conditions and its composition verified by second dimension denaturing
PAGE. A complex of IL-11 and IL-11R was also detected, although it
appeared to be less stable than the ternary IL-11 receptor complex.
Similarly, the predicted IL-11·IL-11R·gp130 trimers formed by both
the IL-11 site II and site III mutants appeared to be much less stable
than the ternary IL-11 receptor complex. This, together with the
observation that IL-11 wild type did not form a stable complex with
gp130 in the absence of IL-11R and that fact that IL-11 binds the
IL-11R through site I (32), shows that all three binding sites of IL-11
are required to drive the formation of a stable ternary receptor complex.
It has recently been proposed that the Ig-like domain of gp130 is
involved in the interaction of gp130 with ligands that induce homodimerization of gp130, namely IL-6 and IL-11 (47, 48). The evidence
presented here clearly shows that the Ig-like domain of gp130 is
essential for IL-11 to form a high affinity hexameric complex with
IL-11R and gp130. It is predicted that the Ig-like domain of gp130
interacts with site III of IL-11, as shown in Fig. 8. Results from
experiments examining a series of human/murine LIFR chimeras show that
the recognition site for OSM and LIF lies in the Ig-like domain of the
LIFR (49).5 This suggests
that the Ig-like domain of signaling receptors, belonging to the gp130
family, represents a common motif for binding to site III of the
ligand. There is strong evidence, from mutagenesis studies, to suggest
that the gp130 recognition epitope for site II of the ligands lies in
the hinge region of the CHD (22, 28, 48). The existence of two ligand
binding epitopes of gp130, and the evidence presented here that shows
IL-11 has two independent gp130 binding sites, strongly supports the
hexameric model depicted in Fig. 8.
The experimental data reported here clearly shows that IL-11, like IL-6
(50), forms a stable hexameric receptor complex in vitro,
via trimer intermediates. Recently, Grotzinger et al. (41)
have proposed that a tetrameric IL-6 receptor complex, not the hexamer,
is responsible for initiating signal transduction. They suggest, on the
basis of modeling studies, that the arrangement of one IL-6, one IL-6R,
and two gp130 molecules in a tetramer is more favorable for dimerizing
gp130 in such a way that signal transduction can be initiated, and that
at high concentrations of IL-6 there is a conformational shift from
functional tetramers to inactive hexamers. The data presented here do
not provide any evidence for the existence of tetramers.
Nondenaturing PAGE analysis of IL-11 receptor complexes revealed only
one stable ternary species, which, based on the results of
immunoprecipitation experiments, was predicted to be a hexamer. If
IL-11 is able to form both stable tetrameric and hexameric receptor
complexes, why were they not both detected following nondenaturing
PAGE? Even with an excess of gp130, only one stable receptor complex
was observed following nondenaturing PAGE (results not shown). The work
presented here also favors the idea that a hexameric receptor complex
is formed by means of intermediate trimeric species. These results do
not exclude the possibility that active tetramers exist and it seems
likely that analysis of the signaling receptor complexes in live cells
will be required for decisive testing of this proposal.
From the evidence presented here, it is clear that IL-11, like IL-6,
forms a hexameric receptor complex in vitro. It is predicted that IL-11 binds the IL-11R though site I, the CHD of gp130 through site II and the Ig-like domain of gp130 through site III. This is
analogous to the way in which IL-6 is thought to bind the IL-6R and two
molecules of gp130, hence forming a hexameric receptor complex, which
suggests that the hexameric model is common to ligands that drive the
homodimerization of gp130.
We thank Dr. Lisa McGovern for discussion of
the manuscript.
*
This work was supported by Cancer Research Campaign grants
and a Cancer Research Campaign studentship from 1996 to 1999 (to V. A. B.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
Current address: Walter and Elisa Hall Inst. for Medical Research
and the Rotary Bone Marrow Research Laboratories, Royal Melbourne
Hospital, Parkville, Victoria, Australia 3050.
¶
Current address: Genesis Research and Development Corp.,
Parnell, Auckland, New Zealand.
Published, JBC Papers in Press, August 17, 2000, DOI 10.1074/jbc.M004648200
2
Deller, M. C., Hudson, K. R., Ikemizu, S.,
Bravo, J., Jones, F. Y., and Heath, J. K. (2000) Structure
8, 863-874.
3
K. R. Hudson, unpublished data.
4
M. A. Hall, unpublished data.
5
K. Chobotova, K. R. Hudson, and J. K. Heath, submitted for publication.
The abbreviations used are:
IL-11, interleukin-11;
R, receptor;
IL-6, interleukin-6;
LIF, leukemia
inhibitory factor;
OSM, oncostatin M;
CNTF, ciliary neurotrophic
factor;
CHD, cytokine binding homology domain;
Ig, immunoglobulin;
m
(prefix), murine;
Fc, constant region of human IgG;
PCR, polymerase
chain reaction;
PAGE, polyacrylamide gel electrophoresis;
BSA, bovine
serum albumin;
PBS, phosphate-buffered saline;
HRP, horseradish
peroxidase;
b (prefix), biotinylated;
HA, hemagglutinin.
Interleukin-11 Signals through the Formation of a Hexameric
Receptor Complex*
,§,
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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INTRODUCTION
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INTRODUCTION
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DISCUSSION
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-stranded immunoglobulin-like conformation in their extracellular region (Ig-like domain).
-helix bundle fold.
Crystal structures have been determined for LIF (25), CNTF (26),
IL-6 (27), and OSM.2 Detailed
structural analysis and mutagenesis studies of the gp130 family of
cytokines have revealed clear patterns of receptor engagement (reviewed
in Ref. 29). It is now apparent that receptor binding epitopes are
conserved among the gp130 cytokines. Three receptor binding sites have
been identified for IL-6 (30, 31), IL-11 (32), and CNTF (33, 34)
(termed sites I, II, and III). Sites I and II are analogous to the two
receptor binding sites identified for human growth hormone (35). In
contrast, LIF and OSM have been shown to have two binding sites (sites
II and III), which enable them to form trimeric receptor complexes
(36).2 IL-6 is known to form a hexameric receptor complex
consisting of two molecules each of IL-6, IL-6R, and gp130 (37,
38).
EXPERIMENTAL PROCEDURES
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DISCUSSION
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)Fc plasmid was derived from
pIG/mgp130-Fc (39) by a PCR overlap technique. Two DNA fragments
upstream and downstream of the region encoding the
NH2-terminal Ig-like domain of gp130 were generated by PCR,
using two external primers and two internal primers with overlapping
ends (the sequences of all primers used are available on request). The
two DNA fragments were then combined in a subsequent PCR reaction with
the two external primers, which amplified the fusion product of the two
fragments. This fusion product was then cloned back into pIG/mgp130-Fc,
therefore replacing the region encoding the Ig-like domain of gp130.
)Fc, IL-11R-HA-Fc, IL-11R-Myc, and
gp130-Myc were expressed in human embryonic kidney 293T cells (43) by
transient transfection, as described previously (39). Conditioned media
containing Fc fusion receptors were then subjected to Protein A
affinity chromatography and receptor ectodomains were released by
on-column cleavage with the human rhinovirus protease 3C (44).
Conditioned media containing Myc-tagged proteins were stored at
20 °C until required. IL-11, wild type and mutants, and HA-tagged
IL-11 were expressed as glutathione S-transferase fusion
proteins in Escherichia coli (strain JM109). Details of
induction, purification using glutathione-Sepharose (Amersham Pharmacia
Biotech) and cleavage using human rhinovirus protease 3C, are as
described previously for leukemia inhibitory factor (36).
-amino groups of lysine residues using biotin
amidocaproate N-hydroxysuccinimide (Sigma) following a
published protocol (32). gp130 was biotinylated on oxidized
oligosaccharides using biotin-hydrazide (Pierce) as follows; gp130 was
first buffer-exchanged into phosphate/EDTA buffer (100 mM
sodium phosphate, pH 6.0, 5 mM EDTA) and treated with 20 mM sodium m-periodate for 20 min at 4 °C in
the dark. gp130 was then buffer exchanged into fresh phosphate/EDTA
buffer and reacted with an equimolar quantity of biotin-hydrazide for 16-18 h at 4 °C. Dialysis against PBS was carried out to remove unbound biotin. Biotinylated proteins were examined by SDS-PAGE followed by Western blotting and detection with streptavidin-HRP conjugate (Amersham Pharmacia Biotech) and ECL.
RESULTS
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DISCUSSION
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View larger version (40K):
[in a new window]
Fig. 1.
Immunoprecipitation of gp130-Myc
complexes. gp130-Myc was immobilized on resin and incubated with
combinations of bgp130, IL-11, and IL-11R (100 nM amounts
of each). After incubation and washing, bound components were analyzed
by SDS-PAGE, followed by Western blotting. Detection was carried out
using streptavidin-HRP conjugate (diluted 1 in 4,000) and ECL.
View larger version (41K):
[in a new window]
Fig. 2.
Immunoprecipitation of IL-11R-Myc
complexes. IL-11R-Myc was immobilized on resin and incubated with
combinations of IL-11R-HA, gp130, and IL-11 (100 nM amounts
of each). After incubation and washing, bound components were analyzed
by SDS-PAGE followed by Western blotting. Detection was carried out
using a biotinylated anti-HA monoclonal antibody (diluted 1 in 5,000)
followed by streptavidin-HRP conjugate (diluted 1 in 5,000) and
ECL.
View larger version (16K):
[in a new window]
Fig. 3.
Immunoprecipitation of bIL-11 complexes.
Combinations of bIL-11, HA-IL-11, IL-11R, and gp130 were mixed together
and incubated (100 nM amounts of each). Complexes were then
immunoprecipitated using NeutrAvidin-agarose. After washing, bound
components were analyzed by SDS-PAGE followed by Western blotting.
Detection was carried out using an anti-HA monoclonal antibody (diluted
1 in 5,000), followed by sheep anti-mouse HRP conjugate (diluted 1 in
5,000) and ECL.
View larger version (11K):
[in a new window]
Fig. 4.
Immunoprecipitation of gp130-Myc and
IL-11R-Myc complexes formed by IL-11 mutants. A,
gp130-Myc was immobilized on resin and incubated with combinations of
bgp130, IL-11R, and bIL-11 (100 nM amounts of each).
B, IL-11R-Myc was immobilized on resin and incubated with
combinations of bgp130 and bIL-11 (100 nM amounts of each).
WT represents wild type, while 
2 and
3 represent the site II mutant R111A/L115A and the site
III mutant W147A, respectively. After incubation and washing, bound
components were analyzed by SDS-PAGE followed by Western blotting.
Detection was carried out using streptavidin-HRP conjugate (diluted 1 in 4,000) and ECL.
View larger version (17K):
[in a new window]
Fig. 5.
Nondenaturing PAGE and second dimension
SDS-PAGE of IL-11 receptor complex. A, native PAGE.
Equimolar concentrations (1 µM) of IL-11, IL-11R, and
gp130 were mixed together in various combinations. After incubation,
complexes were subjected to nondenaturing PAGE. Proteins were detected
using Coomassie stain. B, SDS-PAGE. Bands 1* and 2* (see
Fig. 5A) were excised from the Coomassie-stained gel, soaked
in SDS loading buffer, and subjected to SDS-PAGE. Proteins were
detected by silver staining.
View larger version (30K):
[in a new window]
Fig. 6.
Nondenaturing PAGE of receptor complexes
formed by IL-11 mutants. Equimolar concentrations (300 nM) of IL-11, IL-11R, and gp130 were mixed together in
various combinations. WT represents wild type, while
2 and 3 represent the site II mutant
R111A/L115A and the site III mutant W147A, respectively. After
incubation, complexes were subjected to nondenaturing PAGE and
detection was carried out using silver staining (46).
)
receptor complex co-migrates with the receptor complex formed by IL-11
W147A, IL-11R, and gp130 (results not shown) and is therefore predicted
to be a trimeric receptor complex.
View larger version (36K):
[in a new window]
Fig. 7.
Nondenaturing PAGE of IL-11 receptor
complexes formed by an Ig deletion mutant of gp130. Equimolar
concentrations (300 nM) of IL-11, IL-11R, and gp130 or
gp130(Ig ) were mixed together in various combinations.
After incubation, complexes were subjected to nondenaturing PAGE and
detection was carried out using silver staining (46).
DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (12K):
[in a new window]
Fig. 8.
Schematic representation of the compositions
and stoichiometries of IL-11 receptor complexes. Data reported
here provide evidence for IL-11·IL-11R dimers (A),
IL-11·IL-11R·gp130 trimers formed by both site II and site III
mutants of IL-11 (B), and the hexameric receptor complex
(C). The IL-11, IL-11R and gp130 components are shown
in red, blue, and green, respectively.
This model illustrates the interactions between the three receptor
binding sites of IL-11, IL-11R, and two epitopes of gp130, the CHD and
the Ig-like domain (Ig).
ACKNOWLEDGEMENT
FOOTNOTES
These authors contributed equally to this work and should both be
considered first authors.
To whom correspondence should be addressed. Tel.:
44-0-121-414-7533; Fax: 44-0-121-414-3983; E-mail:
j.k.heath@bham.ac.uk.
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H. Plun-Favreau, D. Perret, C. Diveu, J. Froger, S. Chevalier, E. Lelievre, H. Gascan, and M. Chabbert Leukemia Inhibitory Factor (LIF), Cardiotrophin-1, and Oncostatin M Share Structural Binding Determinants in the Immunoglobulin-like Domain of LIF Receptor J. Biol. Chem., July 11, 2003; 278(29): 27169 - 27179. [Abstract] [Full Text] [PDF]
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