Báo cáo Y học: Chimeric receptor analyses of the interactions of the ectodomains of ErbB-1 with epidermal growth factor and of those of ErbB-4 with neuregulin potx

Chimeric receptor analyses of the interactions of the ectodomainsof ErbB-1 with epidermal growth factor and of those of ErbB-4 with neuregulin Jae-Hoon Kim1,*, Kazuki Saito1,2and Shigeyu

Chimeric receptor analyses of the interactions of the ectodomains

of ErbB-1 with epidermal growth factor and of those of ErbB-4

with neuregulin

Jae-Hoon Kim1,*, Kazuki Saito1,2and Shigeyuki Yokoyama1,2,3

1

Yokoyama CytoLogic Project, ERATO, Japan Science and Technology Corporation, c/o Tsukuba Research Consortium,

Tokodai, Tsukuba, Japan; 2 RIKEN Genomic Sciences Center, Suehiro-cho, Tsurumi, Yokohama, Japan;

3 Department of Biophysics and Biochemistry, Graduate School of Science, University of Tokyo, Hongo, Bunkyo-ku, Tokyo, Japan

A series of chimeric receptors was generated between the

epidermal growth factor (EGF) receptor, ErbB-1, and its

homologue, ErbB-4, to investigate the roles of the

extracel-lular domains (I–IV) in the ligand specificities As compared

with ErbB-1 and the chimeras with both domains I and III of

ErbB-1, the chimeras with only one of these domains

exhibited reduced binding of125I-labeled EGF Particularly,

the contribution of domain III was appreciably larger than

that of domain I of ErbB-1 in125I-labeled EGF binding

Nevertheless, the chimeras with domain III of ErbB-1 and

domain I of ErbB-4were prevented from binding to

125I-labeled EGF competitively by the ErbB-4ligand,

neu-regulin (NRG) On the other hand, NRG did not compete

with125I-labeled EGF for binding to the chimeras with the

ErbB-1 domain I and the ErbB-4domain III Therefore, NRG binding to ErbB-4depends much more on domain I than on domain III With respect to autophosphorylation and subsequent ERK activation, EGF activated the chi-meras with either domain I or III of ErbB-1 In contrast, NRG activated the chimeras with the ErbB-4domain I and the ErbB-1 domain III, but not those with the ErbB-1 domain I and the ErbB-4domain III Therefore, the relative contributions between domains I and III of ErbB-4in the NRG signaling are different from those of ErbB-1 in the EGF signaling

Keywords: chimeric receptors; epidermal growth factor; ErbB family; ligand recognition; neuregulin

The ErbB-family tyrosine kinases play central roles in the

proliferation, differentiation, and development of cells [1]

The family is composed of four members, including the

1/epidermal growth factor (EGF) receptor [2],

ErbB-2/neu [3], ErbB-3 [4], and ErbB-4 [5] Each of these receptors

has an extracellular region, a single transmembrane region,

and a cytoplasmic sequence containing a tyrosine kinase

domain and a C-terminal tail The extracellular region has

about 40% homology among the four family members and

can be further divided into four domains (I–IV); the

N-terminal domain I has sequence similarity to domain

III, which is flanked by two cysteine-rich domains, II and IV

More than a dozen ligands have been found to interact

with the ErbB-family receptors [6] These ligands have a

characteristic structure called the EGF-like motif, which is

defined by three disulfide bridges [7–9], and can be classified into three major groups according to their receptor-binding specificities The first group consists of EGF, transforming growth factor a, and amphiregulin, all of which bind directly to ErbB-1 The isoforms of neuregulin (NRG, also known as heregulin and neu differentiation factor) are members of the second group, and have specific affinity for ErbB-3 and ErbB-4 The third group is composed of the ligands that bind to both ErbB-1 and ErbB-4, such as betacellulin, heparin-binding EGF, and epiregulin The binding of ligands to the extracellular region of receptors causes receptor dimerization and autophosphory-lation of the C-terminal tail [10] The phosphorylated tyrosine residues in the tail serve as docking sites for the proteins that possess a src homology 2 (SH2) domain [11] or

a phosphotyrosine-binding (PTB) domain [12] All members

of the ErbB family have docking sites for growth factor receptor-bound protein 2 (Grb2) and/or SH2-containing polypeptide (Shc), both of which have SH2 and/or PTB domains Recruitment of adapter proteins by the phos-phorylated receptors can stimulate the Ras signaling pathway, leading to the activation of extracellular signal-regulated protein kinases (ERKs) [13] The Ras/ERK pathway is one of the most important and well-studied pathways that transduce extracellular signals into the intranuclear activation of gene expression [14]

A number of studies have described the ligand interac-tions of the ErbB family, but most of them have dealt with only the EGF receptor (ErbB-1) Among the four extracel-lular domains of ErbB-1, domain III is considered to be the major binding site for EGF First, cross-linking of

Correspondence to K Saito or S Yokoyama, RIKEN Genomic

Sciences Center, Suehiro-cho, Tsurumi, Yokohama 230-0045, Japan.

E-mail: saito@gsc.riken.go.jp or

E-mail: yokoyama@biochem.s.u-tokyo.ac.jp

Abbreviations: CHO, Chinese hamster ovary; DMEM/F-12,

Dulbecco’s modified Eagle’s medium/nutrient mixture F-12; EGF,

epidermal growth factor; ERK, extracellular signal-regulated protein

kinase; NRG, neuregulin; PTB domain, phosphotyrosine-binding

domain; SH2 domain, src homology 2 domain.

*Present address: Center for Cellular Switch Protein Structure,

Korea Research Institute of Bioscience and Biotechnology, Yusong,

Taejon, South Korea.

(Received 26 November 2001, revised 7 March 2002,

accepted 12 March 2002)

125I-labeled EGF to ErbB-1 in A431 cells resulted in a

single-labeled CNBr fragment (residues 294–543), which involves

domain III [15] In addition, some monoclonal antibodies

that recognize epitopes in domain III competitively inhibited

the EGF binding [16] By replacing domain III with that of

the human EGF receptor, the chicken EGF receptor gained

higher affinity for mammalian EGF, similar to that of the

entire human receptor [17,18] The C-terminal part of EGF

was found to be located near Lys456 of domain III in the

ligand–receptor complex by a cross-linking experiment [19]

Among the ectodomain fragments, the one corresponding to

domain III showed the highest affinity for EGF [20]

Nevertheless, it has been reported that domain I as well as

domain III is involved in EGF binding, suggesting bivalent

binding of EGF to the EGF receptor A deletion in the

N-terminal region of domain I impaired the EGF binding of

ErbB-1 [21] The N-terminus of EGF was linked to Tyr101

in domain I by using a covalent cross-linking reagent [22]

Chimeras between the chicken and human EGF receptors

revealed that domain I contributes somewhat to the binding

of EGF, in addition to the major contribution of domain III

[18] At present, the bivalent manner of EGF binding to the

receptor, in which both domains I and III are utilized, is

accepted within the mechanism of receptor dimerization [23]

Considering that the extracellular domains share high

sequence homology among the four ErbB members, it is

possible that the ligand binding by the ectodomains of other

family members is similar to that of ErbB-1 However, with

respect to the EGF-like motif of the ErbB-3/4ligand, NRG,

the determinant residues for the specific binding to ErbB-3/4

are somewhat different from those of EGF [24] The

determinants of NRG are clustered in a part that

corres-ponds to the N-terminal part of EGF, while those of EGF are

in two different parts: the central antiparallel b sheet and the

surface including Tyr13, Leu15, Arg41, and Leu47 [25–28]

In the present study, we constructed a series of chimeric

receptors between ErbB-1 and ErbB-4(Fig 1) These two

members of the ErbB family have different specificities for

the ligands, EGF and NRG, respectively, but are very

similar in their other properties Actually, both ErbB-1 and

ErbB-4have a ligand-promoted tyrosine kinase activity,

whereas ErbB-2 does not have any authentic ligands and

ErbB-3 is deficient in the kinase activity Thus, we found

that the relative contributions among the extracellular

domains to the cognate-ligand binding are different between

ErbB-1 and ErbB-4

E X P E R I M E N T A L P R O C E D U R E S

Materials

Human EGF (recombinant) and NRG1-b1 (the EGF-like

motif of neuregulin 1-b1, amino-acid residues 176–246,

recombinant) were purchased from R&D Systems Inc

(Minneapolis, MN, USA) Murine125I-labeled EGF was

from NEN Life Science Products, Inc (Boston, MA, USA)

Anti-(ErbB-1) Ig (sc-03), (ErbB-4) Ig (sc-283), and

anti-ERK2 Ig (sc-153), and a monoclonal antibody to

phosphotyrosine (sc-508), were purchased from Santa Cruz

Biotechnology Inc (Santa Cruz, CA, USA) The

anti-[phospho-p44/42 MAP kinase (Thr202/Tyr204)] Ig was

obtained from New England Biolabs, Inc (Beverly, MA,

USA)

Construction of expression plasmids for ErbB-1, ErbB-4, and chimeric receptors

The mammalian expression plasmid for ErbB-1 was con-structed as described previously [29] The full-length cDNA molecule encoding ErbB-4was obtained from human brain Quick-Clone cDNA (Clontech) by the PCR, and was inserted into the AflII–Xba I sites of the mammalian expression plasmid pcDNA3.1/Zeo(+) (Invitrogen) A schematic diagram of the constructed chimeric receptors is shown in Fig 1A The constructs were carefully designed to maintain the disulfide bond connections within the domains [30] The chimeric receptor 1111-4was generated by replacing the full-length extracellular region of ErbB-4(1– 639) with that of ErbB-1 ()24to 614) The chimeric receptors 1114-4, 1144-4, and 1444-4 were engineered to

Fig 1 Schematic representation and expression of ErbB-1, ErbB-4, and chimeric receptors (A) EC represents the extracellular region, which consists of domains I, II, III, and IV; TM, the transmembrane region;

TK, the tyrosine kinase domain; and CT, the C-terminal tail Con-structs 1111-1 and 4444-4 correspond to the human wild-type ErbB-1 and ErbB-4, respectively (B) Whole-cell lysates of CHO cell clones were resolved by 7.5% SDS/PAGE and were transferred to a nitro-cellulose membrane To confirm the expression of the receptors, the membrane was immunoblotted with an appropriate antibody that recognizes a region of the C-terminal tail of ErbB-1 or ErbB-4 The positions of the molecular mass markers (kDa) are shown on the left.

contain N-terminal portions of the extracellular region of

ErbB-1 ()24to 479, )24to 311, and )24to 163) and

C-terminal portions of ErbB-4(500–1308, 333–1308, and

187–1308), respectively To create chimeric receptors that

have the ErbB-1 cytoplasmic region in common (4444-1,

4441-1, 4411-1, and 4111-1), the entire extracellular region

of ErbB-1 or portions thereof ()24to 615, )24to 477, )24

to 311, and)24to 163) were replaced by the corresponding

regions of ErbB-4(1–639, 1–498, 1–332, and 1–186,

respectively) All of the chimeric receptors mentioned above

were constructed by the PCR with appropriate primers, and

were confirmed by DNA sequence analysis

Cell lines and cell culture

Chinese hamster ovary (CHO) cells, which lack endogenous

ErbB-1 and ErbB-4, were grown in Dulbecco’s modified

Eagle’s medium/nutrient mixture F-12 (DMEM/F-12)

medium (Life Technologies, Inc) supplemented with 10%

fetal bovine serum and antibiotics The mammalian

expression vectors, which were constructed to express

the wild-type or chimeric receptors, were introduced into

CHO cells by the LipofectAMINE method (Life

Technologies Inc) Several transfectants were selected in

complete medium containing Zeocin (0.2 mgÆmL)1)

Comparable expression of the receptors was confirmed by

immunoblotting of the cell lysates (Fig 1B) As often

observed for membrane proteins, the bands were rather

broad in the blots, due to the heterogeneity of the attached

carbohydrate chains

EGF binding assay

Confluent cells in 12-well plates were incubated in duplicate

with 10 ngÆmL)1 125I-labeled EGF in DMEM/F-12 medium

containing 1 mgÆmL)1BSA at 4°C for 2 h The free125

I-labeled EGF was removed by washing three times with

ice-cold NaCl/Picontaining 1 mgÆmL)1 BSA The cells were

lysed in 0.5 mL of 0.5MNaOH, and the radioactivity was

measured by a gamma counter The extent of nonspecific

binding was determined in the presence of a 200-fold excess

of unlabeled EGF

Stimulation, lysate preparation, immunoprecipitation,

and immunoblotting

The transfected CHO cells were starved in serum-free

medium containing 1 mgÆmL)1 BSA for 24h, and then

human EGF or NRG1-b1 was added to stimulate the cells

for 5 min The cells were washed with ice-cold NaCl/Piand

lysed in a buffer containing 30 mM Tris/HCl, pH 7.4,

150 mM NaCl, 5 mMEDTA, 40 mM 2-glycerophosphate,

10% glycerol, 1% Triton X-100, 1 mM

phenyl-methanesulfonyl fluoride, 1 mM sodium orthovanadate,

10 lgÆmL)1 aprotinin, and 10 lgÆmL)1 leupeptin Cell

debris was removed by microcentrifugation at 4°C for

10 min, and the protein concentrations of the cell lysates

were measured with a Protein Assay Kit (Bio-Rad) The

lysates were resolved by SDS/PAGE, and then were

transferred to a nitrocellulose membrane for

immunoblot-ting with an appropriate antibody Protein bands were

visualized by the ECL system (Amersham Pharmacia

Biotech) The ERK activation was determined by

immunoblotting with an antibody that recognizes activated ERK specifically

R E S U L T S

Ligand-binding abilities of the chimeric receptors The ligand-binding abilities of the chimeric receptors were measured (Fig 2) After the incubation with 125I-labeled EGF, the cells expressing ErbB-1 retained strong radioac-tivity as compared to the control cells, while those expres-sing ErbB-4did not show any EGF binding (closed bars) First, by elucidating the relative contributions of the four extracellular domains of ErbB-1 to the specific binding of the cognate ligand, EGF, we verified the assays using the chimeras, because the contributions of the ErbB-1 ectodo-mains to the EGF binding had already been established by the study with the chicken and human chimeric EGF receptors [18] Chimera 1111-4, in which the transmembrane and cytoplasmic regions of ErbB-1 (1111-1) were replaced

by those of ErbB-4 (4444-4), showed an adequate affinity for 125I-labeled EGF As the difference in the affinity between 1111-1 and 1111-4may arise from the expression level of each transfectant, 1111-4has a similar affinity for

125I-labeled EGF to that of 1111-1, as reported for a similar chimera between ErbB-1 and ErbB-2 [31] The transmem-brane and cytoplasmic regions of ErbB-1 are not involved in the specific EGF binding Similarly, 1114-4 showed nearly the same125I-labeled EGF binding as those of 1111-1 and 1111-4, indicating that the extracellular domain IV is not important for the EGF binding Furthermore, the 125 I-labeled EGF bindings of 1111-1, 1111-4, and 1114-4 were reduced to the background level by the addition of an excess amount of unlabeled EGF (open bars), but not by NRG1-b1 (gray bars) Consequently, the three N-terminal do-mains, I–III, of ErbB-1 possess the binding sites specific for EGF In contrast, the replacement of domain III and of domains III and II, resulting in 1144-4 and 1444-4, respectively, greatly decreased the125I-labeled EGF binding, indicating that domain III of ErbB-1 is primarily important

Fig 2 Binding of125I-labeled EGF to the wild-type ErbB-1, ErbB-4, and the chimeric receptors Monolayers of CHO cell clones expressing the wild-type ErbB-1, ErbB-4, or the indicated chimeric receptor were incubated with 125 I-labeled EGF at 4 °C for 2 h After the incubation, the cells were washed three times with ice-cold NaCl/P i containing

1 mgÆmL)1BSA and were solubilized with 0.5 M NaOH Radioactivity retained on the cells was then measured by a gamma counter (closed bars) For competition assays, the cells were incubated with 125 I-labeled EGF in the presence of a 200-fold excess amount of unI-labeled EGF (open bars) or NRG1-b1(grey bars).

for the EGF binding This agrees with previous reports that

domain III of ErbB-1 is the major binding site for EGF,

even in the bivalent manner of EGF binding On the other

hand, chimeras 4111-1 and 4411-1, generated by the

replacement of domain I and of domains I and II,

respectively, of ErbB-1 by the corresponding domain(s) of

ErbB-4, retained significant 125I-labeled EGF binding

However, the replacement of domain III and of domains

III and IV, which resulted in 4441-1 and 4444-1,

respect-ively, completely abolished the125I-labeled EGF binding

These results confirm that domain III of ErbB-1 plays an

important role in the cognate–ligand interaction of ErbB-1

Nevertheless, the 125I-labeled EGF bindings of 4111-1

and 4411-1 were appreciably smaller than those of 1111-1,

1111-4, and 1114-4, indicating that domain I of ErbB-1

participates somewhat in the EGF binding, in addition to

domain III Chimeras 1144-4 and 1444-4, which contain

domain I but lack domain III of ErbB-1, showed weak, but

detectable,125I-labeled EGF binding, because the bindings

were obviously reduced by unlabeled EGF in the assays

using the same transfectant cells This also indicates that the

ErbB-1 domain I is involved in EGF binding, but the

contribution of domain I is smaller than that of domain III

This agrees with the previously reported conclusions, that

EGF binding to the receptor depends mainly on domain III

and less on domain I in the bivalent binding [18] Therefore,

binding assays using the chimeras between ErbB-1 and

ErbB-4properly evaluate the relative contributions of the

extracellular domains to the cognate-ligand bindings

Thus, the relative contributions of the four extracellular

domains of ErbB-4to the specific binding for the cognate

ligand, NRG1-b1, were then examined on the basis of the

competition of unlabeled NRG1-b1 with125I-labeled EGF

for the chimera binding (grey bars in Fig 2) Even though

4111-1 has the ErbB-1 domain III, which binds EGF most

strongly among the ectodomains of ErbB-1, the125I-labeled

EGF binding to 4111-1 was competitively reduced to the

background level by the addition of unlabeled NRG1-b1,

whereas those of 1114-4, 1111-4, and 1111-1 were not

affected This suggests that domain I of ErbB-4greatly

contributes to the cognate-NRG binding of the receptor Similarly, the125I-labeled EGF binding to 4411-1, which also has the ErbB-4domain I and the ErbB-1 domain III, was reduced by the addition of unlabeled NRG1-b1 In addition, unlabeled NRG1-b1 hardly reduced the 125 I-labeled EGF binding of either 1444-4 or 1144-4, even though these chimeras lack the ErbB-1 domain III, and therefore exhibit only weak125I-labeled EGF binding These results confirm the conclusion that domain I contributes the most to the cognate-NRG binding of ErbB-4

Autophosphorylation of the chimeric receptors ErbB-1, ErbB-4, and the chimeric receptors were tested for autophosphorylation (Fig 3) In response to the ligand binding to the ectodomains, the dimerized receptors phos-phorylate their own cytoplasmic C-terminal tails After the cells expressing ErbB-1 were stimulated with EGF or NRG1-b1, ErbB-1 was immunoprecipitated with an anti-(ErbB-1) Ig, and the phosphorylation of the receptor was visualized by immunoblotting with an anti-phosphotyrosine

Ig ErbB-1 was phosphorylated in response to EGF, but not

to NRG1-b1 Among the chimeric receptors constructed here, 1111-4, 1114-4, 1144-4, 1444-4, 4111-1, and 4411-1 were phosphorylated by stimulation with EGF The extents

of the autophosphorylation of 1111-1, 1111-4, 1114-4,

4111-1, and 4411-4111-1, which all have the ErbB-1 domain III, were stronger than those of 1144-4 and 1444-4 without the

ErbB-1 domain III In the125I-labeled EGF binding assay (closed bars in Fig 2), the former five receptors bound larger amounts of 125I-labeled EGF than the latter two The receptors with neither domain III nor domain I of ErbB-1, 4444-4, 4444-1, and 4441-1, showed negligible autophosph-orylation (Fig 3) and no125I-labeled EGF binding (Fig 2) Therefore, the contributions of domains III and I in the EGF-induced autophosphorylation of ErbB-1 were fully consistent with those in the EGF binding

Furthermore, the extent of the EGF-induced auto-phosphorylation of 1444-4 was slightly lower than that of 1144-4, while that of 4111-1 was higher than that of 4411-1

Fig 3 Ligand-induced tyrosine autophosphorylation of ErbB-1, ErbB-4, and the chimeric receptors CHO cell clones expressing ErbB-1, ErbB-4, or each of the chimeric receptors were serum-starved for 24h in serum-free medium containing 1 mgÆmL)1BSA After the starvation, the cells were treated with the indicated ligands (20 ngÆmL)1) for 5 min or left untreated (–) Lysates were subjected to immunoprecipitation with anti-(ErbB-1) Ig

or anti-(ErbB-4) Ig Immunoprecipitates were resolved by 7.5% SDS/PAGE, transferred to a nitrocellulose membrane, and visualized by immunoblotting with an anti-phosphotyrosine Ig Membranes were stripped and reprobed with the corresponding anti-ErbB Ig to control for protein loading.

(Fig 3) This indicates that domain II may also contribute

to the ligand interaction In this context, 4411-1 bound less

125I-labeled EGF than 4111-1 (closed bars in Fig 2) In the

case of transforming growth factor a, which belongs to the

same ligand group for the ErbB members as EGF, domain

II of ErbB-1 was found to be involved in the ligand

interaction by insertion mutagenesis [32] Although

three-dimensional structures are not yet available for the ErbB

members, a comparative model of ErbB-1, based on the

structure of the type-1 insulin-like growth factor receptor

[33], shows that the N-terminal part of domain II is involved

in a lobe of domain I [34] Domain II of ErbB-1 might

participate in the ligand interaction as a part of structural

domain I, or it may support the relative positions between

the ligand-binding domains, I and III Cells transfected with

either 4414-4 or 1414-4 did not show any response to the

ligands (data not shown) In chimeras with such

complica-ted constructions, misfolding of the receptors might prevent

domains I and III from assuming their correct positions

On the other hand, ErbB-4was phosphorylated only by

NRG1-b1, but hardly by EGF The chimeras with domain I

of ErbB-4, such as 4444-1, 4441-1, 4411-1, and 4111-1,

showed sufficient autophosphorylation in response to

NRG1-b1, while those without domain I of ErbB-4did

not exhibit any NRG1-b1-induced autophosphorylation In

contrast, domain III contributes much less than domain I to

NRG binding by ErbB-4, considering the loaded amounts

of the chimeras, shown in a control strip of Fig 3, and thus

the NRG1-b1-induced autophosphorylations of 4444-1 and

4441-1 were just slightly stronger than those of 4411-1 and

4111–1 Even if the binding of NRG1-b1 to ErbB-4 is

bivalent, like that of EGF to ErbB-1, domain I is

predominant in the specific interaction of ErbB-4with the

cognate ligand, NRG1-b1

Activation of downstream ERK by the chimeric receptors

To determine whether the receptor phosphorylation triggers

the activation of downstream cellular pathways, the

chimeric receptors were tested for ligand-induced ERK

activation (Fig 4) In control cells, the ERK activity was

not affected by either EGF or NRG1-b1 The cells

expressing ErbB-1 activated ERK when treated with EGF, but not with NRG1-b1 Chimeras 1111-4, 1114-4, 1144-4, 1444-4, 4111-1 and 4411-1, which were all auto-phosphorylated in response to EGF, induced obvious ERK activation upon stimulation with EGF Although transient overexpression of the receptors in cells may cause non-physiological autophosphorylation, these observations show that the phosphorylation of the receptors certainly transmits the external EGF signal to the downstream enzymes However, as compared with the125I-labeled EGF binding and autophosphorylation assays, it is more difficult

to see the contribution of domain III of ErbB-1 to the ERK activation, for example, from the difference between 1114-4 and 1144-4 This may be due to the saturation of ERK activation resulting from the amplifying effect of the signaling cascade

D I S C U S S I O N

In the present study, by using chimeric receptors, the contributions of the extracellular domains of ErbB-1 and ErbB-4to ligand-specific signaling were examined In the case of EGF signaling by ErbB-1, the receptor has two major functional binding sites, domains I and III, as suggested by the bivalent binding of EGF From many studies using individual mutations of ligand residues, two contact sites have been mapped on EGF for the interaction with the receptor: the central antiparallel b sheet and the surface including Tyr13, Leu15, Arg41, and Leu47 [25–28] Affinity labeling between ErbB-1 and EGF, using a heterobifunctional reagent, showed that the N- and C-terminal parts of the ligand are cross-linked to domains

I and III, respectively, of the receptor [19,22] The b sheet of EGF may bind to domain I of ErbB-1, and the other surface

of the ligand binds to domain III of the receptor Recently, Gly441 of the ErbB-1 domain III was proposed to be involved in the binding site that recognizes Arg45 of human EGF [35]

In contrast, domain I is predominant in the NRG signaling by ErbB-4 In the case of NRG, although cross-linking experiments have not been applied to the complex with ErbB-4, several residues in the N- and C-terminal parts

Fig 4 Ligand-induced ERK phosphorylation in the cell clones expressing ErbB-1, ErbB-4, or the chimeric receptors CHO cell clones expressing ErbB-1, ErbB-4, or each of the chimeric receptors were serum-starved for 24 h in serum-free medium containing 1 mgÆmL)1BSA After the starvation, the cells were treated with the indicated ligands (20 ngÆmL)1) for 5 min or left untreated (–) Whole-cell lysates were resolved by 10% SDS/PAGE and were immunoblotted with an antibody specific to the active, doubly phosphorylated form of ERK Membranes were stripped and reprobed with an anti-ERK Ig to control for protein loading.

of the EGF-like motif of the ligand have already been

characterized as high and low affinity sites for the receptor,

respectively [36] Considering the results of this study, the

N-terminal high affinity site of NRG1-b1 binds to the

dominant ligand-binding site, domain I, of ErbB-4

Recently, domain I of ErbB-3 was also found to have a

binding site for NRG1-b1 [37]

Thus, our results suggest that both EGF and NRG1-b1

have a similar orientation in the complex with the cognate

receptors, which suggests a common mechanism for both

homodimerization and heterodimerization of the

ErbB-family receptors Nevertheless, the interaction of the

ligand with the receptor domain I may be somewhat

different between EGF and NRG1-b1 Domain I of

ErbB-1 binds the central b sheet of EGF, while that of

ErbB-4recognizes several N-terminal residues of

NRG1-b1 Although the b sheet of the ligands is located adjacent

to the N-terminus in the deduced three dimensional

structures, domain I of the receptors may bind a different

part of the cognate ligands, because an artificial ligand,

biregulin, which was made by the substitution of a

partial NRG sequence for the N-terminus of EGF, bound

with high affinity to both ErbB-1 and ErbB-4[24] When

bound to the receptors, this artificial molecule uses the

N-terminal and b sheet parts to bind with domains I of

ErbB-4and ErbB-1, respectively

In conclusion, we have demonstrated differences in the

relative contributions of the domains of ErbB-1 to the EGF

signaling and those of ErbB-4to the NRG signaling

Analyses using chimeric receptors are very useful to

elucidate the relative contributions among the domains of

the receptors in living cells

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