(Received for publication, April 3, 1997)
From the Roche Research Gent, F. Hoffmann-La Roche & Co., B-9000 Gent, Belgium, ¶ Millenium Pharmaceuticals Inc.,
Cambridge, Massachusetts 02139, and
Gene Technologies, F. Hoffmann-La Roche Ltd., CH-4002 Basel, Switzerland
The leptin receptor is a class I transmembrane protein with either a short or a long cytoplasmic domain. Using chemical cross-linking we have analyzed the binding of leptin to its receptor. Cross-linking of radiolabeled leptin to different isoforms of the leptin receptor expressed on COS-1 cells reveals leptin receptor monomer, homodimer, and oligomer complexes. Cotransfection of the long and short form of the leptin receptor did not provide any evidence for the formation of heterodimer complexes. Soluble forms consisting of either the entire extracellular domain or the two cytokine receptor homologous domains of the leptin receptor were purified to homogeneity from recombinant baculovirus-infected insect cells by leptin affinity chromatography. Gel filtration chromatography showed that these proteins exist in a dimeric form. Analysis of the complex formed between soluble leptin receptor and leptin by native polyacrylamide gel electrophoresis, and data obtained from the amino acid composition of the complex provide direct evidence that the extracellular domain of the leptin receptor binds leptin in a 1:1 ratio.
Leptin, the product of the obese gene (1), is a 146-amino acid
protein secreted by fat cells into the bloodstream. Administration of
recombinant leptin to ob/ob mice, which are deficient in the production of leptin, causes a reduction in food intake and weight loss
(2-4). Threading analysis has shown that the structure of leptin
resembles that of 4-helical bundle cytokines (5). It is therefore not
surprising that the molecular cloning of the leptin receptor
(LepR)1 cDNA revealed that it belongs
to the cytokine receptor family (6). High affinity binding sites for
leptin were first discovered to be present on the choroid plexus of
mice and rats (7-9). Both obese Zücker (fa/fa) rats
(10-12) and db/db mice (13, 14), which have a mutation in
the LepR gene, still showed leptin binding to the choroid plexus,
indicating that these mutations do not affect the ligand binding
capacity (7-9). An alternative spliced receptor for leptin having a
longer cytoplasmic domain has been described to be absent in the
db/db mouse (13, 14). In situ hybridization
experiments revealed that this longer form, thought to be the signaling
receptor, is present in the hypothalamus (15), and experiments using
radiolabeled leptin demonstrated clear binding to the arcuate nucleus
and median eminence of the hypothalamus (16). Moreover, RNase
protection experiments showed that among the many tissues examined, the
hypothalamus has the highest ratio of long versus short
isoform of the LepR (17). Most studies on the LepR are focused on its
central action, although recent findings indicate a possible role for
the LepR in hematopoiesis (18). Both the levels of neuropeptide Y- and
corticotrophin-releasing hormone mRNA in the hypothalamus are
affected by leptin (19, 20), and leptin induces c-fos
expression in the paraventricular nucleus of the hypothalamus (21).
Studies on the effects of leptin in fasting animals (22), and the
observation that infertility of ob/ob mice can be corrected
after leptin administration (23) underscore the importance of leptin
for the release of pituitary hormones regulated by the hypothalamus.
Little is known on the mechanism of signal transduction by the LepR.
Transient transfection of the long isoform (LF) of the LepR into COS-1
cells and hepatoma cell lines has been used to identify the STATS
activated by leptin (17, 24). Recently, it was demonstrated that leptin
only induces the activation of STAT3 in the hypothalamus of
ob/ob and wild-type mice, and no STAT activation could be
detected in the other tissues tested (25). The capacity of leptin to
modulate the synaptic transmission in the arcuate nucleus (26) perhaps
indicates that only relevant neuronal cell lines derived from the
leptin-responsive hypothalamus cells will be useful for revealing the
mechanism of signal transduction by the LepR and for understanding the
eventual role of other mediators such as glucose, insulin, and
glucocorticoids in leptin signaling. The extracellular part of the LepR
contains 820 amino acids and includes two immunoglobulin-cytokine
receptor homologous (CRH) regions followed by two fibronectin III-like domains (see Fig. 5). As for other members of the cytokine receptor family, it was suggested that dimerization of the cytoplasmic region of
the LepR is required for signal transduction. Chimeras consisting of
the extracellular domain of the G-CSF receptor and the cytoplasmic
domain of the LepR were able to activate a reporter in HepG2 cells
after treatment with G-CSF (27). Moreover, transfection into BAF/3
cells of a plasmid construct encoding a full-length LepR, or a chimera
consisting of the extracellular domain of the human growth hormone
receptor fused to the cytoplasmic domain of the LepR (18), was able to
transfer leptin or growth hormone-dependent proliferation
to these cells. It has been shown (27) that only weak dominant negative
inhibition of LepR LF-mediated receptor activation was obtained when
the LepR SF was co-expressed.
In this study we have analyzed the binding properties of leptin to its receptor and the oligomerization of the LepR through chemical cross-linking. Using cross-linking, we were unable to demonstrate the presence of heterodimeric complexes between the LepR LF and SF. This suggests that the different isoforms of the LepR remain segregated at the cell surface as dimers and oligomers. We show that recombinant soluble LepR exists as a dimer in solution, supporting the hypothesis that membrane-bound LepR exists as a preformed dimer. Analysis of the LepR-leptin complex by native polyacrylamide gel electrophoresis and determination of the amino acid composition demonstrated that the LepR binds leptin in a 1:1 ratio.
The source of the COS-1 cell line and the Spodoptera frugiperda (Sf9) cell line has been described (28). Recombinant human leptin was purified from the supernatant of baculovirus-infected Sf9 cells using a monoclonal antibody (2A5) coupled to Hydrazide-Avidgel (BioProbe International Inc.). Murine and human leptin were also produced in Escherichia coli and purified from the periplasmic space after osmotic shock.2 Radioiodination of leptin was performed with IODO-GEN (Pierce). The cross-linking reagents bis(sulfosuccinimidyl) suberate and DSS were purchased from Pierce.
Construction of Vectors, Expression, and PurificationPlasmid pMET7 constructs containing the human LepR
LF, SF, and different C-terminal truncations of the hLepR have been
described (27). The cDNA encoding the entire extracellular domain
of the mouse LepR (smLepR) was synthesized by introducing a stop codon before the transmembrane region of the mouse LepR cDNA (6). For
this a polymerase chain reaction amplification was performed using
plasmid pMET7-mLepR(SF), an upstream oligonucleotide (5 AGATGATGTGTCAGAAATTCT 3
) and a downstream oligonucleotide (5
ATTCACTTGTCGATAGCATCTTTGGTG 3
). Similarly, smLepRForm2, having a stop
codon introduced after the second CRH domain, was also generated by
polymerase chain reaction (using the same upstream oligonucleotide as
for smLepR, and a downstream oligonucleotide 5
ATTCATTCAGGCCCTCTCATAGGAACT 3
). The polymerase chain reaction products
were subcloned into the BstXI site of plasmid pCDM8 using BstXI adaptors. Next the XbaI-NotI
fragment derived from the pCDM8 clone was ligated into the
XbaI-NotI cleaved baculovirus transfer vector
pVL1393. For expression in Sf9 cells, homologous recombination with
linearized AcNP viral DNA (BaculoGold, Pharmingen) was used. The
different soluble mLepR proteins were purified by leptin affinity chromatography. For this, recombinant E. coli human leptin
was coupled to NHS-activated Sepharose 4 Fast Flow (Pharmacia Biotech Inc.) as described by the manufacturer. After application of the recombinant baculovirus-insect cell supernatant containing 0.1% Triton
X-100, the bound protein was eluted with 50 mM
diethylamine, pH 11, neutralized with 1 M
NaH2PO4, and concentrated using a Centricon 30 concentrator (Amicon, Inc., Beverly, MA).
COS-1 cells were transfected with the plasmid DNA constructs encoding the LepR using the DEAE transfection protocol as described previously (28). For cross-linking, the transfected COS-1 cells were suspended using Cell Dissociation Buffer (Life Technologies, Inc.) and incubated with 3 nM 125I-human leptin in COS-1 culture medium (Dulbecco's minimal essential medium, 10% fetal calf serum) during 4 h at 4 °C. Next, the cells were washed three times with ice-cold phosphate-buffered saline, and subsequently cross-linker was added to a final concentration of 1 mM. The samples were incubated on ice for 30 min, the reaction was stopped by addition of 50 mM glycine, and the cells were lysed using 1% Triton X-100 in phosphate-buffered saline containing a protease inhibitor mixture (Boehringer Mannheim). After 10 min on ice, the samples were centrifuged, and the supernatants were analyzed by SDS-PAGE and autoradiography. For immunoprecipitation of the hLepR LF, the Triton X-100 lysates of the transfected COS-1 cells were treated for 1 h at 4 °C with Protein A-Sepharose armed with rabbit preimmune serum. The supernatants were then incubated overnight with 5 µg of affinity purified rabbit antiserum directed against a 15-amino acid peptide (amino acid position 970-984) corresponding to the cytoplasmic domain of the hLepR (GTEVTYEDESQRQPF). Immune complexes were captured with Protein A-Sepharose and analyzed by SDS-PAGE. For gel filtration chromatography of smLepR and smLepRForm2, alone or in the presence of leptin, a total volume of 0.10 ml was applied to a Superdex 200 (Pharmacia, prep grade) column (0.9 × 57 cm) and run at 4 °C, at 0.25 ml/min in phosphate-buffered saline containing 0.05% sodium azide and 0.01% Tween 20. Native PAGE was as described (28).
Determination of N-terminal Amino Acid Sequence and Total Amino Acid CompositionThe smLepR-human leptin complex purified by gel exclusion chromatography was subjected to automated Edman degradation on an ABI (Applied Biosystems, Foster City, CA) 491 Procise sequencer. For total amino acid analysis of the smLepR, human leptin, and the complex, the protein samples were subjected to gas-phase hydrolysis with 6 M HCl at 110 °C for 30 h. The hydrolysates were dissolved in 25 µl of 0.25 M borate buffer, pH 8.8 (Hewlett-Packard), and analyzed on an AminoQuant amino acid analyzer (Hewlett-Packard) equipped with pre-column ortho-phthaldialdehyde and 9-fluorenylmethylchloroformate derivatization. The modified residues were chromatographed on a reversed-phase high performance liquid chromatography column (Hewlett-Packard) and eluted with a linear gradient of 0-60% acetonitrile in 0.20% sodium acetate, pH 7.2. Amino acid standards 100, 25, and 10 pmol (Hewlett-Packard) were run in parallel with the samples.
Chimeras
between the LepR and G-CSFR has provided evidence that the LepR signals
through homodimerization (27). To directly show that leptin binds to
receptor homodimers, chemical cross-linking studies were performed.
125I-Labeled human leptin was bound and cross-linked onto
COS-1 cells transfected with plasmid pMET7-hLepR, encoding the long
form of the human leptin receptor (full length), or encoding the human leptin receptor containing a truncation of the cytoplasmic domain to
the specified amino acid (868,
965,
1065, and
1115).
Analysis of the cross-linked complexes formed (Fig. 1)
showed that a covalently linked receptor-ligand complex was formed
migrating as a broad band corresponding to a position that increased in
molecular mass when the cytoplasmic tail increased in length (150-180
kDa). This value corresponds to one LepR molecule cross-linked to
leptin (monomer LepR complex). Cross-linked leptin was also observed at
a position twice the molecular mass of the monomer LepR complex, corresponding to a homodimer LepR complex. Both complexes disappeared in the presence of excess cold leptin (not shown). Furthermore, oligomer LepR complexes can be detected which almost did not enter the
gel. This result shows that leptin can be cross-linked to dimeric and
oligomeric LepR complexes, suggesting that the LepR is triggered
through homodimers and/or oligomers. We next investigated whether
leptin could be cross-linked to a heterodimer LepR complex. For this,
COS-1 cells were transfected with a mixture of plasmids pMET7-hLepR(SF)
and pMET7-hLepR(LF) encoding the short form and long form of the human
LepR, respectively, followed by binding of 125I-labeled
leptin and chemical cross-linking. Analysis of the cell lysates (Fig.
2A) shows that no extra band could be
detected between the leptin cross-linked LepR SF homodimer
(d) and the leptin cross-linked LepR LF homodimer
(d) in the lane corresponding to the COS-1 cells transfected
with the mixture of both plasmids. We therefore used specific
immunoprecipitation of the LepR LF using an antibody directed against
the cytoplasmic domain of the human LepR to try to identify a
heterodimeric complex. Fig. 2B shows that by using this
approach we could not find any evidence for the existence of a leptin
cross-linked heterodimer hLepR complex. This result supports a model
whereby the LepR long and short isoforms remain segregated when
co-expressed and could perhaps explain why signaling by the LepR LF
appears to be only modestly susceptible to dominant negative repression
by the LepR SF (27).
The Extracellular Domain of the LepR Forms Homodimers
The
entire extracellular domains of the mouse LepR (smLepR) and smLepR
lacking the membrane proximal 200 amino acids containing the two
fibronectin-like domains (smLepRForm2) were expressed in
baculovirus-infected insect cells and purified from the culture fluid
using leptin-affinity chromatography. Analysis of the eluted material
by SDS-PAGE under reducing and non-reducing conditions showed that this
single purification step resulted in homogeneous proteins having a
molecular mass of 95 and 75 kDa, respectively (Fig.
3A). This indicated that these soluble LepR
forms expressed in insect cells are not extensively glycosylated
(smLepR: 811 amino acids, predicted molecular mass 91.433 Da;
smLepRForm2: 624 amino acids, predicted molecular mass 69.467 Da). Both
proteins behaved as dimers when analyzed by gel filtration
chromatography. As shown in Fig. 3B, the proteins eluted at
a position corresponding to a molecular mass of 230 and 150 kDa,
respectively, as well as material having a higher molecular mass. This
elution pattern suggested that the purified smLepR existed mainly as a
dimer, which is not linked by disulfide bridges. As observed for
soluble G-CSFR (29), it is possible that the dimeric and oligomeric forms of smLepR were generated upon the ligand affinity purification step. However, chromatography of [35S]methionine-labeled
smLepR concentrated from the baculovirus supernatant also migrated as a
dimer (not shown) indicating that the formation of a dimer is an
intrinsic property of the receptor molecule in solution. Contamination
of leptin in the smLepR preparations was not observed, and the proteins
were fully competent for binding leptin (see below). These results
indicate that the Ig-CRH modules of smLepR are responsible for the
observed dimerization and raise the possibility that the membrane-bound
LepR exists as a preformed dimer. This would then suggest that
signaling by the LepR is not triggered by a ligand-induced
dimerization. To examine whether the purified smLepR was still capable
of binding leptin, we analyzed mixtures of both proteins by gel
filtration chromatography. Fig. 4 shows that the complex
between smLepR and 125I-labeled leptin, incubated at a
molar ratio of 10:1, eluted mainly as a dimer at almost the same
position as the unlabeled smLepR (Fig. 3B). When the
mixtures were made in the presence of a 200-fold excess of cold leptin,
the binding of the 125I-labeled leptin to the smLepR was
competed.
Characterization of the smLepR-Leptin Complex and Stoichiometry of Binding
Further evidence that the majority of the smLepR and smLepRForm2 molecules were capable of binding leptin was obtained by analyzing the LepR-leptin complex formation by native polyacrylamide gel electrophoresis. Fig. 5 shows that when increasing amounts of human leptin are added to a constant amount of smLepR or smLepRForm2, a new band is detected due to the formation of a receptor-ligand complex. When all smLepR or smLepRForm2 is complexed (large arrow), free leptin starts to appear at the bottom of the gel. For both the smLepR and the smLepRForm2, the molar amount of leptin required to drive all the soluble receptor into a complex was equal to the molar amount of soluble receptor present. This means that leptin binds to the soluble LepR in a 1:1 molar ratio, indicating that one molecule of leptin binds to one molecule of smLepR. Since we have shown that the soluble LepR exists in solution as a dimer, this result suggests a receptor-ligand stoichiometry of 2:2. Further evidence for this was obtained by N-terminal amino acid sequencing and analysis of the amino acid composition of the smLepR-leptin complex. SmLepR was mixed with an excess of human leptin, and the complex was purified by gel exclusion chromatography. N-terminal sequencing of this complex indicated an equal molar ratio of the released N terminus amino acid of leptin (valine) and the N terminus of smLepR (Table I). Interestingly, only 5% of the N-terminal amino acids of the smLepR in the complex corresponded to the predicted signal sequence cleavage site (glutamine), whereas 60% of the N-terminal amino acid sequence corresponded to a cleavage that is situated two amino acid residues upstream of the predicted cleavage site (Table I). Table I also shows the total amino acid composition determined for human leptin, smLepR, and for the purified complex between the two proteins. A good agreement was observed with the experimental and predicted values for the receptor and the ligand, and for the complex, if a stoichiometry of 1:1 is assumed. From these results we conclude that the leptin receptor binds leptin with a stoichiometry of 1:1.
|
To further
investigate the stoichiometry of leptin binding, we performed chemical
cross-linking of radiolabeled human leptin to the smLepR and analyzed
the formed complexes by SDS-PAGE. Fig. 6A
shows that a covalently linked receptor-ligand complex migrated as a
doublet at a position corresponding to 110-130 kDa. This value
corresponds to the smLepR monomer (95 kDa) cross-linked to leptin. A
homodimer LepR complex formed by cross-linking 125I-leptin
to two smLepR molecules was also visible at a position corresponding to
200-250 kDa. As expected, cross-linking of 125I-leptin
could be inhibited with excess cold human leptin and was absent in the
absence of cross-linker. That a doublet is formed upon cross-linking
leptin to the receptor monomer was more evident when
125I-mouse leptin was cross-linked to the smLepR using DSS
as a cross-linker (Fig. 6B). A clear doublet was detected of
which the upper band was less intense. The band migrating at a position
corresponding to 69 kDa is a radiolabeled contaminant present in the
mouse leptin preparation. To explain the results of the cross-linking
of leptin to smLepR, three models for the complex can be proposed, as
schematically represented in Fig. 7. In these models,
the smLepR exists as a preformed homodimer that is able to bind two
leptin molecules (stoichiometry 2:2). In model 1, which resembles the
model proposed for the G-CSF·G-CSFR complex (31), one leptin molecule
interacts with only one smLepR molecule, and each CRH module (I and II) contributes to the binding affinity. The doublet of the monomeric smLepR observed after cross-linking could then represent one leptin molecule and one receptor monomer having different mobilities during
electrophoresis due to cross-linking at one single point versus cross-linking to two distinct regions of the receptor
monomer. Since the doublet corresponds to a difference in molecular
mass of around 15 kDa, i.e. one leptin molecule, it is also
possible that in model 1 the two leptin molecules are sufficiently
close for a cross-linking event to happen between them, giving rise to
a smLepR monomer to which one and two leptin molecules are covalently
attached. In models 2 and 3, each leptin binds to both smLepR monomers
in the complex, and the two CRH modules of the receptor monomer
interact with two different leptin molecules. Here the observed
cross-linked doublet could have arisen through cross-linking of one and
two leptin molecules per smLepR monomer. It is unlikely that each CRH
module would present a binding surface that would twice match a binding
surface on a leptin molecule. We therefore favor model 3, where two
receptor monomers are arranged antiparallel to each other in the dimer,
and where each leptin interacts with two different CRH modules each
coming from a separate smLepR monomer. At this moment we cannot exclude
any of these models. Expression of the separate CRH modules and
mutagenesis of both the receptor and leptin might help to determine the
correct model.
Both short and long isoforms of the LepR are present in the brain and in peripheral tissues (17). The identification of the LepR splicing defect in db/db mice (13) demonstrated that the long form of the LepR is responsible for the observed metabolic changes induced by leptin in ob/ob mice. We have shown previously that like the receptors for other cytokines such as erythropoietin, G-CSF, and growth hormone, the LepR probably also signals through homo-oligomerization (27). In this report we show through chemical cross-linking of leptin that both the long and short isoforms of the LepR expressed on COS-1 cells exist as homodimer and homo-oligomer complexes. The observation that the expressed extracellular domain of the LepR is a dimer suggests that the membrane-bound receptor might also exist as a preformed homodimer complex in the absence of leptin. It was previously suggested that dominant negative repression by the LepR SF isoform could be responsible for the observed lack of leptin-induced STAT activation in peripheral tissues (25), in contrast to the hypothalamus where the LepR LF isoform is more abundant. However, the LepR SF inhibited only slightly the signaling of the LepR LF when both are co-expressed (27). This is in contrast to the G-CSFR, where as predicted for receptor activation through ligand-induced homodimerization, a signaling deficient homodimerization partner inhibits the signaling of the full-length G-CSFR, probably through heterodimerization. Hetero-oligomerization between different co-expressed receptor mutants has been observed for other receptors that exist as stable dimers, such as the Na+/H+ exchanger (30). Here we showed that chemical cross-linking of leptin to COS-1 cells transfected with both LepR isoforms gave no evidence for heterodimer formation. These data therefore suggest that the LepR may exist as preformed homo-oligomer complexes and that the different isoforms do not mix at the cell surface when co-expressed. We can only speculate why the LepR does not form heterodimer complexes when both are co-expressed in the same cell. Possibly, accessory proteins associate with the cytoplasmic tail of the LepR LF preventing it to associate with the LepR SF, or vice versa. Alternatively, dimerization could occur prior to the time when receptors are free to diffuse in the endoplasmic reticulum membrane, allowing dimerization with their nearest neighbor only. Such a mechanism would favor the formation of homodimers rather than heterodimers. A third possibility is that the two forms are specifically sorted to different cellular compartments before being transported to the plasma membrane. When BAF/3 cells are transfected with a receptor chimera consisting of the mLepR extracellular domain fused to the cytoplasmic domain of the human gp130 receptor chain, all cells become growth factor-independent.3 This observation indicates that constitutive activation of the gp130 is obtained through ligand-independent dimerization of the LepR and again suggests that the LepR is present at the cell membrane as a homodimer.
We have expressed the extracellular domain of the LepR in insect cells. This protein (smLepR) was purified as a dimer after leptin affinity and gel filtration chromatography. Gel filtration of in vivo labeled smLepR (not shown) indicated that smLepR is secreted as a dimer in the supernatant of the insect cells and supports our view that the LepR extracellular domain exhibits self-association into dimers and oligomers in the absence of leptin. After gel filtration the smLepR-leptin complex eluted mainly at a position of a molecular mass corresponding to a homodimer complex. The smLepR was fully competent for leptin binding as demonstrated by native polyacrylamide gel electrophoresis. From these experiments, and from the determined total amino acid composition of the complex, we calculated a stoichiometry of one leptin molecule per sLepR molecule (or two leptin molecules per sLepR dimer). Analysis of the cross-linked products between leptin and smLepR by SDS-PAGE again showed evidence for the presence of a receptor homodimer complex. Our results are in agreement with a model where, as for the G-CSFR (31), dimerization of the LepR occurs through receptor-receptor interaction. In contrast to the G-CSFR, however, dimerization of the LepR is not induced by ligand. Further work will be required to determine whether, as for G-CSFR, each leptin receptor molecule in the dimer interacts with only one molecule of ligand (model 1) or whether they can interact with both ligand molecules (models 2 and 3). Our results are in agreement with the findings of Nakashima et al. (32), who demonstrated that the membrane-bound LepR is present as homo-oligomers in the absence of leptin. Elucidation of the mechanism of segregation between the different isoforms may help to understand the mechanism of leptin-induced receptor activation in the hypothalamus.
We thank T. Tuypens, A. Verhee, I. Faché, F. Van Houtte, and J. Bostoen for their excellent technical assistance. We also thank Prof. W. Fiers, Dr. M. Steinmetz, Dr. L. Tartaglia, Dr. P. Burn, and Dr. A. Campfield for their advice throughout this work.