From the Departement de Pharmacologie, Faculté de Médecine, Université de Montréal, Montréal, Québec H3C 3J7, Canada
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ABSTRACT |
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Natriuretic peptide receptor-A
(NPR-A), a particulate guanylyl cyclase receptor, is composed of an
extracellular domain (ECD) with a ligand binding site, a transmembrane
spanning, a kinase homology domain (KHD), and a guanylyl cyclase
domain. Atrial natriuretic peptide (ANP) and brain natriuretic peptide
(BNP), the natural agonists, bind and activate the receptor leading to
cyclic GMP production. This receptor has been reported to be
spontaneously dimeric or oligomeric. In response to agonists, the
KHD-mediated guanylate cyclase repression is removed, and it is assumed
that ATP binds to the KHD. Since NPR-A displays a pair of juxtamembrane cysteines separated by 8 residues, we hypothesized that the removal of
one of those cysteines would leave the other unpaired and reactive, thus susceptible to form an interchain disulfide bridge and to favor
the dimeric interactions. Here we show that
NPR-AC423S mutant, expressed mainly as a covalent
dimer, increases the affinity of pBNP for this receptor by enhancing a
high affinity binding component. Dimerization primarily depends on ECD
since a secreted NPR-A C423S soluble ectodomain (ECDC423S)
also documents a covalent dimer. ANP binding to the unmutated ECD
yields up to 80-fold affinity loss as compared with the membrane receptor. However, the ECD C423S mutation restores a high binding affinity. Furthermore, C423S mutation leads to cellular constitutive activation (20-40-fold) of basal catalytic production of cyclic GMP by
the full-length mutant. In vitro particulate guanylyl
cyclase assays demonstrate that NPR-AC423S displays an
increased sensitivity to ATP treatment alone and that the effect of ANP + ATP joint treatment is cumulative instead of synergistic. Finally,
the cellular and particulate guanylyl cyclase assays indicate that the
receptor is desensitized to agonist stimulation. We conclude the
following: 1) dimers are functional units of NPR-A guanylyl cyclase
activation; and 2) agonists are inducing dimeric contact of the
juxtamembranous region leading to the removal of the KHD-mediated
guanylyl cyclase repression, hence allowing catalytic activation.
Particulate guanylyl cyclases are an expanding family of single
transmembrane domain signaling receptors of which the natriuretic peptide receptors (NPRs)1 are
the best studied examples (1). Three different subtypes of natriuretic
peptide receptors have been identified. Two of these receptors, NPR-A
and NPR-B, represent fully functional particulate guanylyl cyclases.
They respond to natriuretic peptides (ANP, BNP, and CNP) by catalyzing
the intracellular production of cGMP. NPR-A is stimulated by both ANP
and BNP, whereas NPR-B is stimulated by CNP (1-3). cGMP is mediating
the effects of NPRs on diuresis, vasorelaxation, and inhibition of the
renin-angiotensin-aldosterone system (1, 3). The third receptor, called
NPR-C or the clearance receptor, has only a small intracellular domain
lacking the guanylyl cyclase function. NPR-C is a disulfide-bridged
dimer that has nearly equal binding affinity for all natriuretic
peptides (4, 5). This receptor internalizes natriuretic peptides
through a fast intracellular cycle process (6) and might also be
involved in signal transduction (7).
NPR-A is a ~130-kDa protein that displays a typical particulate
guanylyl cyclase structure with four structural domains as follows: an
extracellular domain (ECD) with a ligand-binding site, a transmembrane
domain, a kinase homology domain (KHD), and a guanylyl cyclase domain
(GC) (1). The current model for ligand activation of NPRs includes
concerted natriuretic peptide and ATP-dependent regulation
of guanylyl cyclase activity (8). According to this model, the signal
transduction occurs through five sequential steps. 1) The binding of
the natriuretic peptide to ECD induces a conformational change. 2) This
modification corresponds to a signal that migrates through the
transmembrane domain. 3) The KHD responds to this signal by adopting a
conformation that allows ATP binding. 4) ATP binding has two major
effects in derepressing the guanylyl cyclase activity and increasing
the off-rate of ANP from the receptor. 5) Subsequent desensitization
results from reduction in phosphorylation state of the KHD (9).
Several authors (10-12) initially hypothesized that the guanylyl
cyclase activity of NPRs must require at least receptor dimerization. This anticipation was based on the observation that adenylyl and guanylyl cyclases require two catalytic subunits for activity. In
addition, x-ray crystallographic studies and modeling have established
that both subunits contribute to the catalytic domain of these cyclases
(13). Another important observation was provided by cross-linking
studies of ANP on NPR-A which demonstrated that high affinity binding
is associated with receptor dimers (14). Hence, one can reasonably
think that NPR-A dimer constitutes a basic functional unit for guanylyl
cyclase activity.
Other studies have demonstrated the occurrence of spontaneous
(ligand-independent) NPR-A non-covalent dimers or oligomers. For
instance, co-immunoprecipitation studies of hNPRA constructs tagged with different epitopes led to identification of spontaneously formed dimers (15). On the other hand, two studies have described ligand-independent disulfide-bridged NPR-A tetramers (16, 17). Iwata
et al. (16) detected the presence of cross-linked tetramers in membrane preparations from bovine adrenal cortex. It was argued, however, that such disulfide linkage may arise from an artifact of
preparation (15). Another study identified covalently linked tetramers
in HEK 293 cells stably expressing hNPR-A and determined that the
intracellular part of the molecule was essential for the linkage
(17).
Another subject of active research has been on the involvement of the
intracellular and/or the extracellular portions of the receptor in the
dimerization process. One group demonstrated by co-immunoprecipitation,
using full-length and truncated hNPR-A, that the extracellular domain
is directly implicated in receptor dimerization process (15). Other
studies using gel filtration instead of co-immunoprecipitation
concluded that the intracellular portion is also involved in receptor
dimerization (18). Furthermore, it was shown that this interaction is
mediated by a hinge region located between the KHD and GC regions (18,
19).
Within the natriuretic peptide receptor family, NPR-C represents an
exception in different ways as follows: it has a singular structure; it
lacks catalytic activity and ligand specificity; and it acts as a
clearance receptor (1, 4, 6). An interesting feature of NPR-C resides
in its disulfide-linked homodimeric structure. The five NPR-C
cysteines, all lying in the extracellular domain, have been well
studied (4, 20). Mutational studies of these cysteines indicated that
the first four cysteines are joined sequentially, forming the
Cys104-Cys132 and the
Cys209-Cys257 loops and that the fifth cysteine
Cys469 (juxtamembranous) is part of an inter-chain
disulfide bridge (4). In addition, a splicing NPR-C isoform (NPR-C6),
which exists in minor abundancy, displays an accessory and adjacent juxtamembranous cysteine also contributing to interchain disulfide bridge (21).
Interestingly, considerable sequence homologies are present in the
extracellular domain between the NPRs, and the conservation of spacing
between the cysteine residues is remarkable. Following these
observations, we studied alignment of the juxtamembranous regions of
the NPRs with all the known particulate guanylyl cyclases (Fig.
1). This comparison shows two invariant
cysteines spaced by 6-8 residues, except for the following: 1) the
guanylin receptor (GC-C) where no cysteine is found; and 2) the NPR-C
receptor where the first juxtamembranous cysteine is absent. From these
observations, it is easily conceivable that these two conserved
juxtamembranous cysteines are forming an intrachain bridge precluding
inter-chain disulfide linkage of receptor dimers. In the case of NPR-C,
the absence of the first juxtamembranous cysteine (equivalent to
Cys423 in NPR-A) would leave a free and reactive cysteine
and would permit inter-chain linkage of the second (Cys469
of NPR-C, equivalent to Cys432 in NPR-A).
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Alignment of the juxtamembrane region of the
particulate guanylate cyclases and of natriuretic peptide
receptors. Amino acid sequences obtained from NCBI Data base for
rat GC-A, -B, -D, -E, -F, and NPR-C were aligned with Pileup (GCG
software) followed by manual adjustment. The sequence of the
juxtamembrane region of all known GC and NPR from varying species were
then added and manually aligned. The juxtamembrane region shown
corresponds to amino acids 411-435 of NPR-A at the end of exon 6 and
six residues prior to the postulated transmembrane domain. GC-C
(guanylin receptor) sequences that have no juxtamembrane cysteine
and that could not be properly aligned with other GC are not shown in
this figure. AP, Arbaua puntulata; SP,
Strongylocentrotus purpuratus; HP, Hemicentrotus
pulcherrimus.
In this study, we tested this hypothesis by mutating the first
juxtamembranous cysteine (Cys423) of rat (r)NPR-A leaving
the second (Cys432) unpaired and reactive in expectation of
formation of interchain bridge alike in NPR-C. Interestingly, it turned
out to be the case, and furthermore, this covalent dimer mimics the
agonist-induced activation process by constitutively activating the receptor.
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EXPERIMENTAL PROCEDURES |
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Construction of NPR-A Mutants-- rNPR-A mutants were engineered in the expression vector pBK-Neo (Stratagene). The rNPR-A HT-ECD mutant was constructed by inserting a SalI site at codon positions 437-439 using the mutagenesis kit from CLONTECH with the mutagenic primer 5'-CCAAGACCACTTGTCGACACTGGAGGTT-3'. Transmembrane and intracellular corresponding regions of this mutant were eliminated by a SalI/Asp718 codigestion. A synthetic linker (complementary oligonucleotides 5'-TCGACACTGAGATCTCATCACCATCACCATCACTAG-3' and 5'-GTACCTAGTGATGGTGATGGTGATGAGATCTCAGTG-3') was ligated to complete the construction. This linker, including SalI and Asp718 cohesive ends, was composed of a BglII site followed by a hexa-histidine coding sequence and a stop codon. The SalI mutation resulted in a codon change of Phe437 to Leu, thus the Phe437 codon was restored by mutagenesis using the oligonucleotide 5'-CCAAGACCACTTTTCGACACTGAG-3'. The final construct included all the extracellular sequence up to Leu440 followed by Arg-Ser (His)6. HT-ECDC423S and rNPR-AC423S were obtained by mutating the Cys423 codon in Ser using the mutagenic primer 5'-CGTCCCTAAATCTGGCTTTGACAATG-3'. The construction and the mutations were confirmed by sequencing on the two strands using the Sequenase kit from U. S. Biochemical Corp.
Cell Culture-- The human embryonal kidney cell line 293 (American Type Culture Collection) was grown in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum and 100 units of penicillin/streptomycin in a 5% CO2 incubator at 37 °C. For the cyclic GMP stimulation experiments, cells of the NPR-A, NPR-AC423S, and Neo clones were seeded at 105 cells/well onto 24-well cluster plates. Experiments were performed when the cells reached confluence.
Transient and Stable Expression in HEK 293 Cells-- Transient expression of the HT-ECD, HT-ECDC423S, rNPR-A and rNPR-AC423S was obtained by transfection using the CaHPO4 precipitation as described elsewhere (22). For stable expression of the rNPR-A, rNPR-AC423S, and HT-ECD, clones were selected in 600 µg/ml G-418 (Geneticin, Boehringer Mannheim) in culture medium. For the control, clones were selected after transfection with pBK-Neo.
Membrane Preparations--
Membranes for the binding studies
were prepared as follow. 72 h post-transfection, the cells were
rinsed twice with phosphate-buffered saline and lysed in ice-cold
homogenization buffer (10 mM Tris, pH 7.4, 2 mM
EDTA containing 106 M aprotinin,
10
6 M pepstatin, 10
6
M leupeptin, 10
5 M pefabloc).
Cells were first homogenized with a Polytron homogenizer followed by
further homogenization in a Teflon glass potter. The homogenate was
centrifuged for 30 min at 35,000 × g. The pellet was
resuspended and washed twice in the same buffer. Finally, membranes
were resuspended in ice-cold freezing buffer (50 mM Tris,
pH 7.4, 0.1 mM EDTA, 250 mM sucrose, 1 mM MgCl2, and the proteases inhibitors), frozen
in liquid nitrogen, and stored at
80 °C. For the particulate
guanylyl cyclase studies, membranes were prepared from the stable
clones (rNPR-A, rNPR-AC423S, and Neo) according to a
similar procedure. In that case, homogenization and freezing were
performed in 50 mM HEPES, pH 7.4, containing 20% glycerol,
50 mM NaCl, 10 mM NaPO4, 0.1 M NaF, 1 mM Na3VO4 and
the proteases inhibitors. The protein concentration was determined using the BCA protein assay kit (Pierce).
Purification of Secreted rNPR-A Extracellular Mutants-- HT-ECD was purified from cell culture medium of a stably expressing clone. For HT-ECDC423S, HEK 293 cells were transiently transfected, and culture supernatant was collected 72 h post-transfection. Supernatants were dialyzed twice against 60 volumes of 50 mM sodium phosphate buffer, pH 7.4, containing 0.3 M NaCl. After adding 16% glycerol the dialysate was aliquoted and frozen in liquid nitrogen.
For purification, an aliquot (typically 20 ml) was slowly thawed at 4 °C. The sample, to which was added a final concentration of 20 mM imidazole, pH 7.4, was gently mixed batchwise overnight with 0.2 ml of Ni-NTA agarose gel (Qiagen). After the incubation, the gel suspension was packed on a column and washed with 10 volumes of sodium phosphate buffer, pH 7.4, containing 0.3 M NaCl and 20 mM imidazole. Elution of HT-ECD or HT-ECDC423S was done with 10 volumes of the same buffer containing 500 mM imidazole.
Receptor Binding Assays-- 125I-rANP was prepared using the lactoperoxidase method. Briefly, rat ANP (3 nmol) was mixed with 100 ng of lactoperoxidase and 1 mCi of Na125I in a volume of 40 µl of 0.1 N sodium acetate buffer, pH 5.6. The reaction was started by adding 5 µl (3 nmol) of H2O2. The incubation was carried out for 5 min at 22 °C. The addition of H2O2 was repeated twice with a 5-min incubation each time. The mono-iodinated product was purified by reverse phase-high pressure liquid chromatography as described elsewhere (23). Binding to membranes was performed at 4 °C for 22 h in 1 ml of binding buffer (50 mM Tris, pH 7.4, 0.1 mM EDTA, 5 mM MnCl2, and 0.5% bovine serum albumin). Competition experiments were done by incubation of 3-5 µg of HEK 293 membrane with 10 fmol of 125I-rANP and increasing concentration of non-radioactive peptides. Bound 125I-rANP was separated from free ligand by filtration on GF/C filters precoated with 1% polyethyleneimine. The binding to purified HT-ECD and HT-ECDC423S was performed at 4 °C for 22 h in 0.1 ml of binding buffer (50 mM sodium phosphate buffer, pH 7.4, 1 mM EDTA, 0.1% bovine serum albumin, 0.05% lysozyme). For competition studies, 10 fmol (for HT-ECDC423S) or 100 fmol (for HT-ECD) of 125I-rANP and increasing amounts of competing peptide were added to the reaction mixture. Bound 125I-rANP was separated from free by adding of 0.1 ml of ice-cold dextran-coated charcoal equilibrated in the same buffer. After vigorous vortexing and centrifugation at 12,000 × g for 2 min, 0.1 ml of the supernatant was measured in a gamma counter.
Whole Cell Guanylyl Cyclase Stimulation--
Confluent cells
(NPR-A, NPR-AC423S, and Neo clones) on 24-well cluster
plates were washed twice with serum-free DMEM and were incubated in a
final volume of 1 ml of the same medium containing 0.5 mM 3-isobutyl-1-methylxanthine (IBMX), 0.5% bovine serum albumin, and
varying concentrations (1012 to 10
7
M) of rANP. After 1 h incubation, the extracellular
cyclic GMP was determined by radioimmunoassay as already described
(23).
Guanylyl Cyclase Assays-- Membranes obtained from NPR-A, NPR-AC423S, and Neo clones were used for guanylyl cyclase assays as described in other studies (9, 24). The membranes (5 µg) were incubated for 10 min at 37 °C in 50 mM Tris-HCl, pH 7.6, with 10 mM theophylline, 2 mM IBMX, 10 mM creatine phosphate, 10 units of creatine kinase, 1 mM GTP, and 4 mM MgCl2. Different conditions were tested by including 1 µM rANP, 1 mM ATP, rANP with ATP, or 1% Triton X-100 with 4 mM MnCl2 instead of MgCl2. Cyclic GMP was separated from GTP by chromatography on alumina and evaluated by radioimmunoassay as previously reported (23).
Western Blotting and Immunodetection--
Membrane proteins
(50-100 µg) were separated on 5% SDS-PAGE in the presence or in
absence of 5% -mercaptoethanol in the loading buffer. The proteins
were transferred to a nitrocellulose membrane (Hybond C, Amersham
Pharmacia Biotech) using the Novablot semi-dry transfer system
(Amersham Pharmacia Biotech). Detection of NPR-A was achieved using a
rabbit polyclonal antiserum raised against the sequence YGERGSSTRG
corresponding to human NPR-A carboxyl terminus and purified by affinity
chromatography. The rat NPR-A differs from this epitope at a single
position; however, both receptors have been shown to be equally
recognized. Specific signal was probed with a horseradish
peroxidase-coupled anti-rabbit polyclonal antibody according to the ECL
Western blotting Analysis System (Amersham Pharmacia Biotech).
His-tagged HT-ECD and HT-ECDC423S were run on 7.5%
SDS-PAGE in the presence or in absence of 5%
-mercaptoethanol in
the loading buffer. The proteins were transferred to a nitrocellulose
membrane as described above. These ectodomains were detected using a
commercial mouse anti-tetra-histidine antibody (Qiagen) according to
the technique provided by the manufacturer. Specific signal was probed
with an horseradish peroxidase-coupled anti-mouse polyclonal antibody
using the ECL Western blotting Analysis System.
Data Analysis--
Dose-response curves were analyzed with the
program AllFit for Windows based on the four-parameter logistic
equation (25). Radioligand binding data were analyzed with the same
program based on a model for the law of mass action (26).
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RESULTS |
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NPR-AC423S Is a Disulfide-bridged Covalent
Dimer--
We investigated the possibility that mutation of
Cys423 to Ser would allow intermolecular linkage between
two receptor subunits. Membrane preparations from HEK 293 cells
expressing wild type rat NPR-A and NPR-AC423S were analyzed
on SDS-PAGE under reducing and non-reducing conditions. As shown in
Fig. 2 the migration of the C423S mutant
under non-reducing conditions indicates that its state of
oligomerization is mainly higher than monomeric. The estimated
molecular mass is about 260 kDa, compatible with NPR-A dimer. A
residual monomeric band is visible and accounts for approximately 15%
of the total signal as estimated by densitometry. However, in other
experiments this signal was barely detectable indicating that the
proportion of residual monomers may vary (not shown). In repeat
experiments, no higher molecular weight oligomer above the dimer could
be seen neither for the wild type nor in the mutant NPR-A.
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Thus, our results demonstrate that disulfide-linkage of rNPR-A can be specifically induced by the C423S mutation and that the wild type receptor does not spontaneously form intermolecular covalent linkage. Inherent to these results is the capacity of rNPR-A to dimerize non-covalently in absence of ligand.
Interchain Disulfide Bridge Involves Extracellular Domain--
We
also assessed the capacity of the C423S mutation to produce disulfide
linkage of a soluble NPR-A extracellular domain. His-tagged wild type
(HT-ECD) and C423S mutated (HT-ECDC423S) receptors were
produced, purified on Ni-NTA agarose gel, and analyzed for their level
of dimerization. As seen in Fig. 3, wild type HT-ECD shows a single band on non-reducing SDS-PAGE corresponding to ECD monomers of ~67 kDa. Interestingly, HT-ECDC423S
migrates as two bands corresponding to monomers (~67 kDa) and dimers
(~127 kDa). This ~127-kDa band mainly accounts for ~60% of the
total signal as evaluated by densitometry. It can be concluded from
these results that the ECDC423S can spontaneously form
disulfide-linkage in the absence of ligand but with significantly less
efficiency than the full-length rNPR-AC423S.
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Receptor Dimer Covalent Linkage Increases High Affinity Binding for Natriuretic Peptides-- In order to investigate the effect of covalent dimerization of rNPR-AC423S on natriuretic peptide affinity, we characterized binding of rANP and pBNP through competition curves against 125I-rANP. These two peptides were chosen because our recent work demonstrated that rANP displays only high affinity binding on membranes prepared from COS-P-expressing rNPR-A, whereas pBNP shows two classes of binding components corresponding to high and low affinities (27). As shown in Fig. 4, using receptor expressed in HEK 293, competition studies on membranes using rANP are still showing a unique high affinity binding component with rNPR-A (pK 10.7 ± 0.06) as well as with rNPR-AC423S (pK 10.37 ± 0.17) (Table I). pBNP competition curve on wild type rNPR-A yields two components corresponding to high (pK 9.56 ± 0.06) and low (pK 7.91 ± 0.05) affinities, which is similar to the values obtained in our previous work for intact rNPR-A (27). Interestingly, competition binding of pBNP on rNPR-AC423S yields a curve that is globally shifted to the left (Fig. 4). Analysis of this curve still discriminates two binding components with pK values of 10.11 ± 0.16 and 8.2 ± 0.19. In fact, analysis of the curve indicates that the curve shift mainly is due to a difference in the proportion of high affinity sites that are twice more abundant in rNPR-AC423S (67.4 ± 5.9%) than in wild type rNPR-A (35.5 ± 4.5%) (Table I).
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From these results, we conclude that the increase in high affinity component observed with pBNP reflects a conformational state of the receptor that is, at least partially, stabilized by the disulfide linkage. A possible explanation for the low affinity component still observed with rNPR-AC423S may reside in the residual non-linked receptor seen on non-reducing SDS-PAGE.
Competitive binding studies with rANP and pBNP were performed on
soluble HT-ECD and HT-ECDC423S (Fig.
5). Binding studies on HT-ECD are
yielding very low affinity constants with a pK of 8.82 ± 0.22 for rANP and of 7.35 ± 0.06 for pBNP (Table
II). Noteworthy, a one-component binding
model is sufficient to define each curve. Strikingly, HT-ECD
C423S demonstrates a high affinity binding with rANP
(pK of 10.17 ± 0.01), a value highly similar to its
membranous counterpart. pBNP binding on HT-ECDC423S also
shows a significant improvement of affinity with a pK of 8.7 ± 0.05; however, this improved affinity is not reaching the value of the high affinity component observed with the membrane receptor.
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From these results it can be hypothesized that the dimerization of the soluble ECD by disulfide linkage fulfills one of the steps leading to a high affinity binding. It can also be reasoned that rANP would induce sufficient further stabilization or conformational change. On the contrary pBNP might not be as efficient to induce by itself further stabilization. Finally, considering that pBNP can induce a high affinity component in the full-length receptor, it is reasonable to think that the intracellular and/or the transmembrane domain participates in pBNP high affinity binding.
Dimerization Leads to Constitutive Activation of
rNPR-A--
Taking into account that disulfide linkage stabilizes a
high affinity state of rNPR-A, we investigated if this affects the catalytic properties of the receptor. We performed cGMP production assays on cells stably expressing rNPR-A or rNPR-AC423S,
which were chosen to have about the same level of expression. Only
negligible extracellular cGMP level is detected through all range of
ANP stimulation of the Neo cells (Fig.6).
The rNPR-A clone displays a typical dose-response curve with an
ED50 of 152 ± 15 pM and a maximal cGMP
production of 192 pmol/(105 cell/60 min). An
ED50 of 70 ± 2 pM is found for the
rNPR-AC423S mutant, but strikingly, the level of basal cGMP
production is considerably elevated corresponding to ~20-fold of the
wild type basal level (Fig. 6). Another feature of the mutant resides
in its reduced maximal stimulation level by rANP as compared with rNPR-A. The effect of these two characteristics is a dramatic leveling
in the stimulation amplitude of the mutant (1.4-fold) as compared with
the wild type receptor (52-fold).
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At this point, it was important to assess the capacity of the mutant to reach the cell surface since its very low level of stimulation in response to ANP might be caused by an alteration of maturation, resulting in intracellular trapping. We have checked this hypothesis by comparing the cellular localization of the wild type and mutant NPR-A. Receptor localization was measured through quantitative study of 125I-rANP binding on intact cells as compared with total binding on solubilized cell membrane preparation (data not shown). The results indicate that wild type NPR-A is almost entirely localized to the cell surface, whereas almost (80%) of NPR-AC423S mutant is at the cell surface. Therefore, the C423S mutation does not lead to major maturation defects and intracellular trapping.
In conclusion, the C423S mutation induces a constitutive activation of the receptor in cells and also alters directly or indirectly its maximal response to ANP.
Constitutively Active Dimeric Mutant Is Desensitized--
In view
of the latter characteristics of rNPR-AC423S, it was of
interest to biochemically test the guanylyl cyclase activity of the
mutant. Maximal guanylyl cyclase activity is traditionally determined
with a Triton X-100/Mn2+ treatment that is assumed to
artificially stimulate guanylyl cyclases to their maximal level (28).
Membrane preparations were tested through different conditions using
GTP alone (basal), ATP, ANP, ANP + ATP, and Triton/Mn2+
(maximal stimulation). Surprisingly, with Triton/Mn2+
treatment, the maximal activation of the C423S mutant is altered showing a 50% reduction as compared with the wild type rNPR-A. We thus
expressed the results as percentage of maximal activation (Triton/Mn2+) (Fig. 7).
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Based on these results, several observations can be made. First, the C423S mutant displays a basal constitutive activity that accounts for 5.6 times the wild type value. Also, ATP alone induces a 3-fold activation on rNPR-AC423S catalytic activity, whereas ATP activation is barely detectable for the wild type receptor. On the other hand, ANP treatment produces a 10.4-fold stimulation for rNPR-A but only of 1.7-fold for the mutant. Moreover, the stimulation of the mutant with ANP alone is about twice less than with ATP. Finally, ANP + ATP treatment gives a strong synergistic effect (35% of maximal level) for wild type NPR-A but only a cumulative effect for the mutant resulting in 2-fold reduction in relative stimulation level.
In summary, the mutant displays singular characteristics in being
desensitized, abnormally responsive to ATP alone and by not responding
synergistically to an ANP + ATP treatment.
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DISCUSSION |
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In this work, we have shown that the C423S mutation of rat rNPR-A yields a disulfide-bridged receptor dimer, conceivably through the juxtamembranous Cys432. This receptor dimer displays an improved binding for pBNP and is constitutively activated. We also studied the properties of rNPR-A soluble ECD. As previously reported (8), this soluble receptor exhibits low affinity binding for rANP. However, the same C423S mutation applied on ECD yields disulfide-bridged dimers upon which rANP displays a binding affinity comparable to that for the full-length receptor. This indicates that receptor dimers represent basic units involved in high affinity ligand-receptor recognition.
A study from Lowe (17) has described the occurrence of disulfide-bridged human NPR-A. In this case, spontaneous forms of tetramers, dimers, and monomers were detected. In another work, Iwata et al. (16) detected disulfide-bridged NPR-A tetramers from bovine membranes preparations (16). However, since they used 1 mM dithiothreitol throughout membrane preparation, artifactual disulfide bridge shuffling may have been favored in this latter case. Also, the number of cysteines in the extracellular domain of the bovine receptor is not known making difficult any further interpretation. Noteworthy, this group also suggested that in all probability the two juxtamembrane cysteine residues in NPR-A may be involved in inter-chain tetrameric linkage (4). This hypothesis may be theoretically conceivable, but direct proof of such organization has not been provided. Also, some of our results are not compatible with that concept. For instance, as we are showing here, the disulfide linkage probably through the juxtamembrane cysteine 432 of rNPR-AC423S leads to constitutive activation. Thus, hypothetical disulfide-linked tetramers involving this same cysteine would be susceptible to cause constitutive activation of NPR-A, which is obviously not what is found naturally. Different explanations might be possible, for example that covalent tetramerization, unlike disulfide-linked dimerization, may not favor constitutive activation. Hence, alternate pairing of the two juxtamembranous cysteines involved in a hypothetical tetramerization might prevent the constitutive activation. Finally, disulfide-linked tetramers may arise from some kind of artifact and are not relevant in NPR-A normal function. These questions are opened.
In the present work, by inducing disulfide-bridged dimerization with the C423S mutation, we are confirming that covalent oligomer would be easily detectable if they were present. Furthermore, since no covalent oligomers are observed for wild type rNPR-A, we could analyze the biochemical effects of the rNPR-AC423S mutation or covalent dimerization. The substantial increase of the pBNP high affinity binding observed with rNPR-AC423S indicates that the disulfide linkage favors high affinity ligand-receptor interaction. Furthermore, the constitutive activation of rNPR-AC423S demonstrates that the disulfide linkage also mimics the agonistic effect. However, it is difficult to evaluate the activation induced by the mutation in reason of the desensitization of the receptor. Nevertheless, the constitutive activity indicates that a stabilized dimer represents a basic functional unit for rNPR-A cyclase activity. This goes along with the results obtained by Rondeau et al. (29) who demonstrated that the ligand/receptor stoichiometry of bovine NPR-A (L:1/R:2) is in agreement with ligand-stabilized dimer. That further non-covalent oligomerization events could follow (i.e. leading to tetramers) cannot be excluded. However, such putative large aggregates might not be required for receptor activation.
Several studies have demonstrated that hNPR-A spontaneously forms non-covalent dimers (15, 18). Thus, the disulfide bridge in rNPR-AC423S is probably not inducing dimerization but may rather modify the interactions between already assembled dimers. From this, a model based on "loose" and "tight" conformations can be imagined, the tight state corresponding to high ligand binding affinity and guanylyl cyclase activation. Thus, rANP might efficiently contact both receptor subunits and tighten their interaction. This effect might be less efficiently induced by pBNP, and this would be reflected by the high (tight?) and low (loose?) affinity components. Finally, covalent dimerization of the C423S mutant would trap a state closely related to the tight conformation.
According to our results, it is likely that a dimeric interaction of the domain surrounding the disulfide bridge is important for the activation process. This can be discussed in the perspective of other single transmembrane domain receptors. For instance, in the case of the growth hormone receptor (GHR), it has been shown that the growth hormone (GH) is stabilizing receptor dimer through simultaneous contact of the ligand with two receptor subunits. Interestingly, the crystal structure of the GHR·GH complex indicates that, in addition to these hormone-stabilized receptor interfaces, there is also an important dimeric contact of the extracytoplasmic domain close to the transmembrane spanning domain (30). Furthermore, it has been shown that the mutation D152H underlying the Laron syndrome (familial GH resistance) acts by disturbing the folding of this contact region, hence abolishing the GHR response to GH (31). Thus, dimeric contact involving this juxtamembrane region is important in the activation process of GHR.
On the contrary, the crystal structure of the EpoR complexed with a synthetic agonist shows no direct interaction of the corresponding juxtamembranous region (32). Interestingly, however, mutagenesis studies have shown that the introduction of a cysteine residue through the R129C mutation yields a disulfide-bridged, constitutively activated receptor (33). As judged from the crystal structure, this mutated residue is located at the bottom of the juxtamembranous domain (32). Thus, in order to allow the bridge formation, this specific region of Epo-R must transiently dimerize in the absence of ligand.
This approach of introducing cysteine residues has been used to study the oligomerization of other membrane receptors. In particular, it has been used for an exhaustive study on the interactions between the protomers of the bacterial aspartate receptor (34). Since no cysteine is naturally found in this receptor, introduction of cysteines at specific points of the molecule allowed the study of spatial proximity between the subunits. However, in this case, the use of oxidative reagents was necessary to catalyze formation of the intermolecular bridges. Once again, productive covalent dimerization was found to arise from the juxtamembranous region.
In another study, the introduction of a cysteine residue in the juxtamembranous region of the EGF-R resulted in a disulfide-bridged receptor dimerization that was ligand-dependent (35). On the other hand, some mutations producing disulfide-bridged dimer and constitutive activation are naturally occurring and are underlying genetic diseases. For example, several mutations associated with Cruzon syndrome are causing spontaneous dimerization and activation of the fibroblast growth factor receptor (36, 37). These mutations, all involving the change of a wild type residue to Cys, are occurring either in the juxtamembranous domain or in the linker region between the Ig2 and Ig3 immunoglobulin-like domains. It is noteworthy that the Ig3 domain plays an important role in ligand binding and is, thus, probably part of a natural interface between the receptor subunits. Finally, a series of mutations (MEN 2A) occurring in the juxtamembranous domain of the RET proto-oncogene are leading to covalent dimerization and constitutive activation (38). They all involve the loss of one cysteine residue. It is assumed that the intermolecular disulfide bound is due to another cysteine that is left unpaired and reactive.
Considering our results and these observations, it is likely that the region surrounding the inter-molecular disulfide bridge of rNPR-AC423S is a natural interface involved in activation. Supporting this idea, this region is well conserved among the various guanylyl cyclases, indicating its functional importance (Fig. 1). As we proposed above, it is likely that upon agonist binding this juxtamembranous region establishes a dimeric contact. This tightening, which is likely mimicked by the disulfide linkage of the mutant, might induce some conformational changes in the intracellular domain. However it should be mentioned that, even if the constitutive activation of the C423S mutant can be easily attributed to the interchain bridge, we cannot definitively exclude the contribution of an eventual conformational change induced by the mutation independently of the linkage.
An important player in the regulation of particulate guanylyl cyclase activity is the kinase homology domain (KHD). Hypothetically, a contact of the juxtamembranous domain might modify the intracellular interactions between the subunits, with the initial consequence of removing the repressor effect of KHD. Also, according to the current model of sequential activation of NPRs (8), ATP binding to the KHD precedes and/or is concomitant with guanylyl cyclase derepression. These events must be associated with some modifications in the KHD molecular interactions within the monomer and/or the dimer. Strikingly, our results are showing a dramatic increase of the ATP effect on GC activity of rNPR-AC423S as compared with the wild type. This may further indicate that the KHD is affected by the mutation and is "trapped" in a conformation corresponding to the activated state. However, such increased sensitivity to ATP has also been observed with rNPR-A when desensitized through ANP pretreatment (9). Thus, this ATP effect on rNPR-AC423S may also be caused by a desensitization arising from the constitutively activated state.
In order to be catalytically active, the GC subunits must establish reciprocal adequate positioning (13). In this respect, the KHD-GC hinge might play an important function as judged from the work of Wilson and Chinkers (18). Furthermore, KHD deletion mutagenesis studies have demonstrated the constitutive activation of rNPR-A (39). Thus, in the absence of KHD the productive positioning of the GC subunits seems to be spontaneous. The intracellular portion of the receptor probably possesses a certain level of autonomous dimerization potential, but the accessibility of the interfaces may be transitory. The net result might depend on the mutual influence of the ECD, the KHD, the hinge, and the GC domains. Such contribution of the intracellular domains may explain the difference on the level of dimerization that we observed between the full length and the ECDC423S.
Finally, another constitutively active rNPR-A mutant has been described. Garbers and colleagues (40) generated a constitutively activated rNPR-A via a mutation within the guanylyl cyclase catalytic domain. Guanylyl cyclase activity of this mutant was 7 times higher than the wild type but was unresponsive to any treatment, including ATP stimulation. Indeed, the guanylyl cyclase of this mutant behaved as autonomously activated without any influence of the receptor context. Noteworthy, this mutant seems not to be desensitized via dephosphorylation.
On the contrary, the constitutive activation of rNPR-AC423S
basically stems from the receptor context. Furthermore, it is likely to
be closely related to a step corresponding to the normal
agonist-induced activation. Finally, it has been shown that
ligand-induced desensitization of NPR-A is not due to feedback
phenomena arising from cGMP accumulation in the cell but probably
through dephosphorylation of the KHD during the activation process
(41). Hence, the KHD of the C423S mutant might show the same
dephosphorylation, an aspect we are currently investigating.
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FOOTNOTES |
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* This work was supported by a grant from the Medical Research Council of Canada.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.
Recipient of a postdoctoral fellowship from the Pharmacology
Research Chair.
§ Recipient of a studentship from FCAR.
¶ Recipient of a Research Chair in Pharmacology jointly founded by Merck Frosst Canada and PMAC/MRC. To whom reprint requests should be addressed: Dépt. de Pharmacologie, Faculté de Médecine, Université de Montréal, C. P. 6128, Centre-Ville, Montréal H3C 3J7, Canada. Tel.: 514-343-6334; Fax: 514-343-2359; E-mail: DELEAN{at}pharmco.UMontreal.ca.
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ABBREVIATIONS |
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The abbreviations used are: NPR, natriuretic peptide receptor; rANP, rat atrial natriuretic peptide-(1-28) or natriuretic peptide A; pBNP, porcine brain natriuretic peptide-(1-32); CNP, C-type natriuretic peptide; PAGE, polyacrylamide gel electrophoresis; GC, guanylyl cyclase; h, human; KHD, kinase homology domain; NTA, nitrilotriacetic acid; IBMX, 3-isobutyl-1-methylxanthine; ECD, extracellular domain; GH, growth hormone; GHR, growth hormone receptor; HT, hexahistidine-tagged.
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