Báo cáo khoa học: Amino acid residues on the surface of soybean 4-kDa peptide involved in the interaction with its binding protein potx

Amino acid residues on the surface of soybean 4-kDa peptideinvolved in the interaction with its binding protein Kazuki Hanada1, Yuji Nishiuchi2and Hisashi Hirano1 1 Yokohama City Univers

Amino acid residues on the surface of soybean 4-kDa peptide

involved in the interaction with its binding protein

Kazuki Hanada1, Yuji Nishiuchi2and Hisashi Hirano1

1

Yokohama City University, Kihara Institute for Biological Research/Graduate School of Integrated Science, Yokohama, Japan;

2

Peptide Institute, Inc., Protein Research Foundation, Osaka, Japan

Soybean 4-kDa peptide, a hormone-like peptide, is a ligand

for the 43-kDa protein in legumes that functions as a protein

kinase and controls cell proliferation and differentiation As

this peptide stimulates protein kinase activity, the interaction

between the 4-kDa peptide (leginsulin) and the 43-kDa

protein is considered important for signal transduction

However, the mechanism of interaction between the 4-kDa

peptide and the 43-kDa protein is not clearly understood

We therefore investigated the binding mechanism between

the 4-kDa peptide and the 43-kDa protein, by using

gel-filtration chromatography and dot-blot immunoanalysis,

and found that the 4-kDa peptide bound to the dimer form

of the 43-kDa protein Surface plasmon resonance analysis

was then used to explore the interaction between the 4-kDa

peptide and the 43-kDa protein To identify the residues of

the 4-kDa peptide involved in the interaction with the 43-kDa protein, alanine-scanning mutagenesis of the 4-kDa peptide was performed The 4-kDa peptide-expression system in Escherichia coli, which has the ability to install disulfide bonds into the target protein in the cytoplasm, was employed to produce the 4-kDa peptide and its variants Using mass spectrometry, the expressed peptides were con-firmed as the oxidized forms of the native peptide Surface plasmon resonance analysis showed that the C-terminal hydrophobic area of the 4-kDa peptide plays an important role in binding to the 43-kDa protein

Keywords: hormone-like peptide; receptor-like protein; protein–protein interaction; alanine-scanning mutagenesis; surface plasmon resonance

A 43-kDa protein in legume seeds has been shown to bind

to animal insulin [1] This 43-kDa protein consists of

a (27 kDa) and b (16 kDa) subunits linked together with

disulfide bridge(s) The a-subunit has a cysteine-rich region

considered to be the interface for the interaction with its

ligand, and the b-subunit has protein kinase activity about

two-thirds that of the tyrosine kinase activity of rat insulin

receptor Although proteins homologous to the 43-kDa

protein exist in different plant species [2–5], the biological

function of these proteins has not been completely clarified However, the 43-kDa protein from cotton has weak antifungal activity against Alternaria brassicicola and Bot-rytis cinerea[4] As the 43-kDa protein is localized in plasma membranes and cell walls [6], the 43-kDa protein is thought

to have receptor-like function

This function, as a receptor-like protein, has allowed us

to assume the presence of a physiologically active ligand which is capable of binding to the 43-kDa protein A 4-kDa peptide was isolated from germinating soybean seed radicles by affinity chromatography on a 43-kDa protein-immobilized column [7] The 4-kDa peptide is able

to stimulate protein kinase activity of the 43-kDa protein [7] The maximum stimulatory effect was observed at a low concentration (1 nM) of the 4-kDa peptide, suggesting that it is involved in signal transduction of the 43-kDa protein [7] The 4-kDa peptide is localized, in small amounts, around the plasma membranes and cell walls [7] This subcellular localization is similar to that of the 43-kDa protein, suggesting that the 4-kDa peptide is located at a site suitable for interaction with the 43-kDa protein

In a previous study we provided some evidence to show that the 4-kDa peptide is physiologically active The 4-kDa peptide was found to stimulate cell proliferation and cell redifferentiation when added to the culture medium of carrot callus tissue [8] Furthermore, when cDNA from the 4-kDa peptide was introduced into the carrot callus, the transgenic callus grew rapidly compared with the non-transgenic callus during the early stages of development [8] These results suggest that this peptide is

Correspondence to H Hirano, Yokohama City University, Kihara

Institute for Biological Research/Graduate School of Integrated

Science, Maioka-cho 641-12, Totsuka, Yokohama, 244-8013 Japan.

Fax: + 81 45 820 1901; Tel.: + 81 45 820 1904;

E-mail: hirano@yokohama-cu.ac.jp

Abbreviations: E coli, Escherichia coli; IPTG, isopropyl

thio-b-D -galactoside; PVDF, poly(vinylidene difluoride); SPR, surface

plasmon resonance; Trx, thioredoxin.

Enzymes: alkaline phosphatase (EC 3.1.3.1); lysylendopeptidase

(EC 3.4.21.50); restriction endonucleases EcoRI (EC 3.1.21.4)

and NcoI (EC 3.1.31.4); thioredoxin reductase (EC 1.8.1.9);

tyrosine kinase (EC 2.7.1.112).

Note: As the binding capabilities of insulin and the 4-kDa peptide to

the 43 kDa protein were similar, Watanabe et al named the 4-kDa

peptide as leginsulin in their early publication There are many

con-troversies related to the naming of this peptide as leginsulin To avoid

confusion, in the present article we referred to the peptide as
4-kDa

peptide instead of leginsulin.

(Received 28 February 2003, revised 16 April 2003,

accepted 22 April 2003)

involved in the signal transduction mediated by the

43-kDa protein in carrot [8] However, the molecular

mechanism of the interaction between the 4-kDa peptide

and 43-kDa protein is unknown In previous work, we

determined the tertiary structure of the 4-kDa peptide by

NMR spectroscopy and found that this peptide belongs

to the T-knot superfamily [8] The structure of the 4-kDa

peptide is similar to those of many growth factors in

animals, protease inhibitors and antimicrobial peptides in

plants, and toxins in insects [9] As the function of these

molecules is to bind to their target proteins to regulate or

inhibit their activities, it is assumed that the function

of the 4-kDa peptide also relates to the regulation of the

43-kDa protein kinase activity

In this work, we performed gel-filtration chromatography

to study the interaction between the 4-kDa peptide and the

43-kDa protein We also investigated the binding

mechan-ism of the 4-kDa peptide, by alanine-scanning mutagenesis

The results indicate that the hydrophobic region of this

peptide is important for binding to the 43-kDa protein We

also describe the topological similarity of active residues

between the 4-kDa peptide and animal insulin

Materials and methods

Materials

All oligonucleotides were obtained from Invitrogen Life

Technologies The expression vector for Escherichia coli,

pET-32a[+], the expression host cell, BL21trxB (DE3),

and the BugBuster protein extraction reagent were

obtained from Novagen (Madison, WI, USA) A

nickel-chelating affinity chromatography column, HiTrap

chelat-ing HP (1 mL), and the gel-filtration chromatography

column for the SMART system, Superose 12 PC3.2/30,

were obtained from Amersham Bioscience (Uppsala,

Sweden) The size-standard proteins kit for gel-filtration

chromatography was purchased from Bio-Rad

Laborat-ories (Hercules, CA, USA) Biacore sensor chip CM5, was

obtained from Biacore (Uppsala, Sweden) The restriction

enzymes, EcoRI and NcoI, were from Nippon Gene

(Tokyo, Japan) All other inorganic and organic

com-pounds were purchased from WAKO Chemicals (Osaka,

Japan)

Gel-filtration chromatography

Gel-filtration chromatography was performed using the

SMART system in PC3.2/30 columns containing Superose

12 resin in 100 mMsodium phosphate/0.5MNaCl, pH 7.6

The samples were eluted using the same buffer Eighty

microlitres of fraction was collected in each tube

subse-quently, after discarding the exclusion volume All gel

filtrations were carried out at room temperature For gel

filtration using the Superose 12 resin, two sample solutions

were prepared The first was the gel-filtration elution buffer

containing the 43-kDa protein incubated for 30 min at

room temperature; and the second was the gel-filtration

elution buffer containing a mixture of the 4-kDa peptide

and the 43-kDa protein [molecular concentration ratio:

2 : 1 (43-kDa protein : 4-kDa peptide)] incubated for

30 min at room temperature

Dot-blot analysis The eluted fractions of the gel filtration were spotted onto a poly(vinylidene difluoride) (PVDF) membrane (10 lL per spot) The membrane was blocked with 1% nonfat dry milk

in NaCl/Tris buffer (20 mMTris/HCl, pH 7.4, containing 0.5MNaCl) for 1 h at room temperature Polyclonal rabbit anti-(4-kDa peptide) was dissolved in NaCl/Tris and incubated with the membrane overnight at 4C The membrane was washed twice (10 min each wash) in NaCl/ Tris buffer at room temperature and incubated with goat anti-(rabbit IgG) labeled with alkaline phosphatase The signal was detected with BCIP/NBT membrane phospha-tase substrate (KPL, Gaithersburg, MD, USA)

Construction of the bacterial expression vector and site-directed mutagenesis

The DNA sequence of the wild-type 4-kDa peptide was amplified from the soybean 4-kDa peptide cDNA by PCR using the following oligonucleotide primers: N-terminal primer: 5¢-AAC CAT GGC TAA AGC AGA TTG TAA TGG TGC ATG T-3¢; C-terminal primer: 5¢-AAG AAT TCT TAT TAT CCA GTT GGA TGT ATG CAG AA-3¢ The amplified sequence was cloned into plasmid pET-32a(+), via the NcoI and EcoRI restriction sites, into a multicloning site located downstream of the S-Tag sequence This plasmid was termed pTrx-LEG The validity

of the 4-kDa peptide DNA sequence was verified by dideoxy sequencing Site-directed mutagenesis was per-formed, using pTrx-LEG as a template, according to the methods of Higuchi et al [10] and Ho et al [11] All residues of the 4-kDa peptide, with the exception of alanines, cysteines, glycines and prolines, were singly replaced by alanine The resulting constructs were verified

by DNA sequencing All of the mutational 4-kDa peptide DNA sequences were recloned into the same restriction site

of the wild-type 4-kDa peptide DNA sequence

Expression and purification of the 4-kDa peptide variants

E coliBL21trxB(DE3) [F–ompT hsdSB(rB–mB–) gal dcm trxB15::kan (DE3)], transformed with pTrx-LEG or the corresponding variants, was grown at 37C in 1 L of Luria–Bertani (LB) medium, containing 50 lg/mL carbeni-cillin, until a D600value of 0.6 was reached After addition of isopropyl thio-b-D-galactoside (IPTG) to a final concentra-tion of 1.0 mM, cells were grown for a further 4 h and harvested by centrifugation at 6000 g for 10 min at 4C The cells were suspended in 40 mL of BugBuster protein-extraction reagent The cell suspension was incubated on

an orbital shaker, at a slow setting, for 10 min at room temperature In the soluble fraction, cell debris was removed

by centrifugation at 48 000 g for 15 min at 4C The supernatant was used as a crude extract The Trx-tagged 4-kDa peptide, or its variants in the crude extract, were purified according to immobilized metal affinity chroma-tography The crude extract was applied to HiTrap chelating HP that immobilized Ni2+ equilibrated with

20 mMsodium phosphate buffer (pH 7.4) containing 0.5M NaCl The target protein was eluted with a 10–500 mM linear gradient of imidazole in 20 m sodium phosphate

buffer (pH 7.4) containing 0.5M NaCl The fractions

containing the target protein were combined

Peptide mass fingerprinting

The Trx-tagged 4-kDa peptide, or its variants, were digested

with lysylendopeptidase (WAKO Chemicals) The digests

were desalted with ZipTipl-C18 (Millipore, Boston, MA,

USA) and subjected to analysis by MALDI-TOF MS

(Tofspec 2E; Micromass, Manchester, UK) In

MALDI-TOF MS, ionization was accomplished with a 337-nm

pulsed nitrogen laser Spectra were acquired in reflectron

using a 20-kV acceleration voltage Samples were prepared

by mixing equal volumes of a 1–10 lMsolution of the digests

and a saturated solution of a-cyano-4-hydroxycinnamic

acid as a matrix in 50% CH3CN with 0.1% trifluoroacetic

acid Four microlitres of this mixture was spotted onto

the sample plate and allowed to desiccate to dryness

TheMASSLYNXsoftware (Micromass) was used to analyze the spectra

Biacore

To confirm the mechanism of complex formation between the 4-kDa peptide and the 43 kDa-protein, we employed surface plasmon resonance (SPR) analysis using Biacore X (Biacore) The purified wild-type 4-kDa peptide was immobilized onto sensorchip CM5 according to the supplier’s instructions Different amounts of 43-kDa pro-tein, dissolved in running buffer (20 mMsodium phosphate,

pH 7.4, containing 0.5MNaCl), were injected as analytes for binding analysis at 25C using a flow rate of

20 lLÆmin)1 The binding affinities of the Trx-tagged wild-type 4-kDa peptide and its variants were determined using Biacore X, to measure the association rate constant (ka)

Fig 1 Gel-filtration chromatography of the

43-kDa protein and the 4-kDa peptide/43-kDa

protein complex (A) Chromatogram of the

43-kDa protein (B) Chromatogram of the

4-kDa peptide and the 43-kDa protein

com-plex The elution points of the size-standard

proteins are shown with arrows: BGG, bovine

gamma globulin (158 kDa); OA, ovalbumin

(44 kDa); MG, equine-myoglobin (17 kDa);

VB12, vitamin B 12 (1.35 kDa) Lines have

been used in each chromatogram to separate

the fractions (C) Dot-blot analysis of the

fraction shown in panel B Fractions, as given

in B were spotted onto a poly(vinylidene

difluoride) membrane The fractions

contain-ing the 4-kDa peptide were detected uscontain-ing

anti-(4-kDa peptide) Numbers refer to the

fractions shown in panel B Underlined

numbers indicate the presence of the 4-kDa

peptide See the Materials and methods for

further details.

and the dissociation rate constant (kd) The 43-kDa

protein was immobilized onto sensorchip CM5, according

to the supplier’s instructions, to yield approximately 5560

response units of covalently coupled protein Kinetic

analysis was carried out by injecting three serial dilutions

(400 nM, 800 nM and 1.6 lM) of Trx-tagged 4-kDa

peptide or variants in running buffer (20 mM sodium

phosphate, pH 7.4, containing 0.5MNaCl) at 25C using

a flow rate of 20 lLÆmin)1

Fitting sensorgram data was carried out according to

global fitting, and the kaand kdvalues were calculated with

a 1 : 1 Langmuir model using theBIAEVALUATIONsoftware,

version 3.2 RC2 (Biacore) The dissociation constant (KD)

was calculated as KD¼ kd/ka

Results and discussion

Identification of a complex of 4-kDa peptide and 43-kDa protein

We first sought to determine the potential association of the 43-kDa protein, as the receptor of the physiologically active peptide usually forms an oligomer to activate the function of the receptor [12] When the 43-kDa protein was subjected

to gel-filtration chromatography, we observed only one peak for a complex of 80-kDa, suggesting that the 43-kDa protein is present as a dimer (Fig 1A) Subsequently, we applied the solution containing the 43-kDa protein and 4-kDa peptide to the gel filtration column, and observed a peak with almost the same retention time as that of the 80-kDa complex We studied proteins containing these fractions by dot-blot analysis using anti-(4-kDa peptide) The result revealed that both the 4-kDa peptide and 43 kDa protein were present in the same fractions, suggesting that the 4-kDa peptide interacts with the dimer of 43-kDa protein

To determine the Kdof the 4-kDa peptide and 43-kDa protein, the wild-type 4-kDa peptide was immobilized onto sensorchip CM5 by amine coupling The 43-kDa protein solution was passed through the flow cells as an analyte Interaction of ligand and analyte was detected in real time as

a change in the SPR signal The association and dissociation sensorgrams obtained are shown in Fig 2 The Kdof the 4-kDa peptide for binding to the 43-kDa protein was calculated as 1.86· 10)8M

Interaction of Trx-tagged 4-kDa peptide with the 43-kDa protein

The Trx-tagged 4-kDa peptide was expressed in a thioredoxin-reductase gene (TrxB) null mutant, BL21trxB(DE3), and purified according to immobilized metal affinity chromatography (Fig 3) The binding activity

of the 4-kDa peptide to the 43-kDa protein is dependent on the maintenance of its tertiary structure by three intra-molecular disulfide bonds The reduced 4-kDa peptide has significantly less activity than the oxidized form of the

Fig 2 Representative surface plasmon resonance sensorgrams of

binding between the 43-kDa protein and the 4-kDa peptide were

dependent on concentration Details of the procedure are described in

the Materials and methods Phases before the asterisk (*) represent the

association sensorgrams; phases after the asterisk represent the

disso-ciation sensorgrams The kinetic parameters, assodisso-ciation rate constant

(k a ) and dissociation rate constant (k d ), were calculated using

B IAEVALUATION software; k a ¼ 5.28 · 10 4

M )1 Æs)1 and k d ¼ 9.85 ·

10)4Æs)1 The dissociation constant, K D , was calculated as K D ¼ k a /k d ;

K D ¼ 1.86 · 10)8M

Fig 3 Coomassie blue-stained SDS/PAGE gels showing the Trx-tagged 4-kDa peptide variants The number of each lane corresponds

to the position which introduced variation: panel A D2A–D19A; and panel B R21A– T36A Lanes M, the molecular marker; lane T, Trx-tag; and lane W, Trx-tagged wild-type 4-kDa peptide Arrows show Trx-tag and Trx-tagged 4-kDa peptide variants (C) Sites

of mutations induced in the 4-kDa peptide The sites are shown by open boxes Ser17 was not substituted to alanine because the side-chain was buried inside the 4-kDa peptide.

peptide [7] To introduce the intramolecular disulfide bonds

in the expressed 4-kDa peptide, we used BL21trxB(DE3)

host cell, TrxB null mutant and pET-32a[+] vector

Bessette et al [13] described that this strain can form

Fig 4 MALDI-TOF MS analysis of

wild-type 4-kDa peptide (A) Mass spectrum of the

wild-type 4-kDa peptide Trx-tagged wild-type

4-kDa peptide was digested with

lysylendop-eptidase and subjected to MALDI-TOF MS.

The 4-kDa peptide was observed as 3S–S

form, 3916.70 m/z ([M+H] + ), marked by

circling (B) Theoretical mass of each oxidized

form of the 4-kDa peptide The column of

oxidized form shows the number of

intra-molecular disulfide bonds (S–S).

Table 1 Identification of the oxdized form of 4-kDa peptide variants by

MALDI-TOF MS 3S–S denotes the formation of three

intramolec-ular disulfide bonds.

Trx-tagged variant

Theoretical mass [M+H]+(m/z)

Observed mass [M+H]+(m/z)

Fig 5 Representative sensorgrams of binding between analytes (Trx-tagged wild-type 4-kDa peptide and Trx-tag) and ligand (43-kDa pro-tein) (A) Binding of Trx-tagged wild-type 4-kDa peptide (B) Binding

of Trx-tag Phases before the asterisk (*) represent the association sensorgrams; phases after the asterisk represent the dissociation sensorgrams.

disulfide bonds more efficiently in the cytoplasm than in the

oxidizing environment of the periplasmic space Stewart

et al [14] showed that Trx, which serves as an oxidant

instead of a reductant, mediates disulfide bond formation in

the thioredoxin-reductase null mutant because the reduction

system in the cytoplasm does not work By peptide mass

fingerprinting, we confirmed that the expressed 4-kDa

peptide has three intramolecular disulfide bonds (Fig 4,

Table 1) This result indicates that we can construct various

alanine substitution-variants crosslinked with disulfide

bonds using this expression system

The purified 43-kDa protein was immobilized onto

sensorchip CM5 and confirmed to bind to the Trx-tagged

4-kDa peptide by SPR analysis The Kdof the Trx-tagged

4-kDa peptide for the 43-kDa protein was determined as

8.56· 10)8M (Fig 5A, Table 2) It should be noted that

the Kdvalue reported here is higher than that previously

described for the wild-type 4-kDa peptide, probably because

of changes in the source of the 4-kDa peptide (see the

Materials and methods for further details) To investigate

whether Trx-tag impedes binding of the 4-kDa peptide to

the 43-kDa protein, Trx-tag expressed in E coli transformed

with pET-32a[+] was injected to the 43-kDa

protein-coupling sensorchip In this experiment, we did not observe

any sensorgrams showing that Trx-tag bound to the 43-kDa

protein (Fig 5B) This result shows that the 4-kDa peptide

and 43-kDa protein, but not Trx-tag, are involved in

binding of the Trx-tagged 4-kDa peptide to the 43-kDa

protein

The 4-kDa peptide in the expressed Trx-tagged 4-kDa peptide has three intramolecular disulfide bonds As it had a binding activity similar to that of the wild-type 4-kDa peptide, we concluded that the intramolecular disulfide bonds were correctly formed in the Trx-tagged 4-kDa peptide

Dissociation constants of the 4-kDa peptide variants

To investigate the residues of the 4-kDa peptide involved in binding to the 43-kDa protein, we generated 4-kDa peptide variants, in which 19 residues were substituted with alanine using pTrx-LEG as a template To avoid potential struc-tural perturbation, alanine, cysteine, glycine and proline residues were not substituted All variants were generated as Trx-tagged proteins and purified according to the methods used for the wild-type 4-kDa peptide The purity of the fused proteins was confirmed on a Coomassie blue-stained SDS/PAGE gel All purified proteins were detected as major bands with the expected molecular weights (Fig 3) The number of disulfide bonds in the variants was investigated

by peptide mass fingerprinting, and all variants were found

to have three disulfide bonds (Table 1) The Kdvalues for binding to the 43-kDa protein were investigated by SPR analysis, as employed for the wild-type 4-kDa peptide The results of our analyses of the 4-kDa peptide alanine variants are shown in Table 2 and Fig 6 Figure 6 shows the ratio of the Kdvalue of the 4-kDa peptide variant to the

Kdvalue of the wild-type 4-kDa peptide Of the 19 alanine

Table 2 Association rate constants (k a ), dissociation rate constants (k d ) and dissociation constants (K D ) for binding alanine variants of Trx-tagged 4-kDa peptide to 43-kDa protein Dissociation constants were calculated as follows: K D ¼ k d /k a Relativ e K D values were calculated as: K d variants/

K d wild type.

Trx-tagged variant k a (10 3

M )1 Æs)1) k d (10)4M )1 Æs)1) K D (10)8M ) Relative K D

A Charged to alanine variants

B Aromatic to alanine variants

C Polar to alanine variants

D Fatty to alanine variants

variants, 13 caused a significant impairment in binding of

the 43-kDa protein, i.e greater than a fourfold increase in

the Kdvalue Three of the 13 variants (Asp2, Asn4 and Ser8)

are located in the N-terminus of the 4-kDa peptide and their

Kd values for the 43-kDa protein increase from five- to

12-fold Two variants, Val12 and Arg18, which showed a

six- and 11-fold increase in Kd, respectively, are located in

the loop between the first and the second strand in the

4-kDa peptide His34 and Thr36 variants, located in the

C-terminus of the 4-kDa peptide, result in a seven- and

ninefold increase in Kd, respectively The other variants

(Ile25, Leu27, Phe28, Val29, Phe31, Ile33), whose residues

constitute the hairpin-b motif, caused a remarkable decrease

in affinity for the 43-kDa protein, ranging from fourfold

(Leu27) to 116-fold (Val29) These variants were classified

into several groups, and it was found that hydrophobic and

aromatic residues contributed remarkably to the increase

of Kdfor the 43-kDa protein (Table 2); in particular, five

residues (Ile25, Phe28, Val29, Phe31 and Ile33) play a

critical role in binding to the 43-kDa protein

Role of amino acids in the 4-kDa peptide

By alanine-scanning mutagenesis of the 4-kDa peptide, we identified that 13 amino acids play an important role in the interaction between this peptide and the 43-kDa protein Eleven amino acids among the 13 mutants were organized into two discontinuous fragments (fragment 1 and fragment 2) Fragment 1 comprised the N-terminal region (Asp2– Ser8), while fragment 2 constituted the C-terminal region (Ile25–Thr36) (Fig 6C) As the mutations of fragment 2 result in a higher increase in Kdthan those of fragment 1, fragment 2 was considered to play a more important role in affinity for the 43-kDa protein Of the 11 amino acids, one is charged, four are polar, four are hydrophobic and two are aromatic The higher number obtained of aromatic and hydrophobic residues emphasized the importance of these amino acids in the interaction between the 4-kDa peptide and the 43-kDa protein The secondary structures of these two fragments, as revealed from NMR spectroscopy of the 4-kDa peptide, indicate that fragment 1 contains the loop

Fig 6 Structure of the functional epitopes of the 4-kDa peptide The Ca backbone of the 4-kDa peptide is shown as a tube representation (A, B and C) The mutated amino acids are shown in space-filling representation Alanine variants of amino acids, shown in white, had no effect on affinity Those in yellow produced a two- to 10-fold reduction in affinity, and those in orange had a 10- to 100-fold reduction in affinity Alanine variants of amino acids, shown in red, had a >100-fold decrease in affinity (D) Summary of alanine scanning of the 4-kDa peptide The results are expressed as the ratio of dissociation of the variant to that of the wild-type The amino acids mutated to alanine are designated by a single-letter code.

and b-strand, and fragment 2 contains hairpin-b [14] These

structures form the sheet of the putative binding area

(Fig 7A,B) Of the two fragments, fragment 2 appears to be

the most important in binding to the 43-kDa protein

Mutation of Val29 and Phe31 to alanine resulted in the

43-kDa protein with the lowest affinity, and substitution of

Ile25 and Ile33 with alanine produced a 20-fold higher Kd

than found in the wild-type protein (Table 2) Interestingly,

all of the residues in fragment 2 were located at the same

region, forming a hydrophobic patch (Figs 6 and 7A,B,C)

The other residues, charged or polar, of fragment 2

surrounded this hydrophobic patch The residues of

frag-ment 1 were also found in the surrounding hydrophobic

patch (Figs 6 and 7A,B,C) These topological alignments

suggest that the hydrophobic residues, Val29 and Phe31,

play a central role in binding to the 43-kDa protein and that

the wall consisting of fragment 1 and part of fragment 2

contributes to binding of the 4-kDa peptide to the 43-kDa

protein (Fig 7A,B,C)

In Fig 6C, we identified that two amino acids (Val12 and

Arg18), in addition to the 11 residues described above, were

involved in binding to the 43-kDa protein The substitution

of Val12 and Arg18 to alanine affected binding to the 43-kDa protein Unexpectedly, the side-chains of these two residues were oriented in a different direction from those of fragment 1 and fragment 2, which indicates that Val12 and Arg18 do not belong to fragment 1 and fragment 2 and indicates that Val12 and Arg18 might play a different role from those residues of fragment 1 and fragment 2 Further analysis of the interaction between the 4-kDa peptide and 43-kDa protein is required

Several reports suggest that the decreases in affinity observed in these types of mutations directly effect receptor–ligand interaction, rather than misfolding, of variant proteins [15] Alanine substitution is reported to

be nondisruptive for globular protein structure [16] In the 4-kDa peptide, three intramolecular disulfide bonds are important for maintaining the tertiary structure In the present study, peptide mass fingerprinting showed that, similarly to the wild-type 4-kDa peptide, all alanine variants possessed three disulfide bonds (Fig 4, Table 1) Furthermore, all variants have a ka value which is similar to that of wild-type peptide, suggesting that substitution with alanine has no effect on the tertiary

Fig 7 The location of fragment 1 and fragment 2 in the 4-kDa peptide tertiary structure, and comparison of the tertiary structure of insulin and the 4-kDa peptide (A and B) Fragment 1 and fragment 2 are shown in orange and red, respectively (C) Hydrophobic potential surfaces of the 4-kDa peptide According to hydrophobicity, the molecular surface is colored on a gradient from red (negative hydrophobicity) to blue, passing through white at a hydrophobicity of zero (D) Inactive state of insulin (1ai0) (E) Active state of insulin (1hit) (F) The 4-kDa peptide (1ju8) The residues that constitute the insulin receptor-binding area are shown in red, and the residues important for the direction to insulin receptor are shown in orange (D and E) In (F), four residues in red are most influenced by alanine substitution, and two residues in orange are located in a similar space as the residues in orange of (E) The opened yellow squares showed a similar topology of side-chains of putative active residues in both insulin and the 4-kDa peptide (E and F).

structure of the 4-kDa peptide (Table 2) Exceptionally,

mutation of Phe28 to alanine caused a decrease in ka

(Table 2), as it is located in the loop of the hairpin-b

motif and this area is also exposed to the solvent This

suggests that the aromatic residue, Phe28, plays a vital

role in maintaining the hairpin-b during interaction with

solvent

Interaction of insulin with the 43-kDa protein

Similarly to the 4-kDa peptide, insulin is able to interact

with the 43-kDa protein [1] If the 4-kDa peptide and

insulin share the same manner of binding to the 43-kDa

protein, topological similarity of critical residues should

exist in the two peptides, as the two peptides do not share

the same fold We have hypothesized previously that the

area consisting of Val23, Val29, Phe31 and Ile33 in the

4-kDa peptide [8] is involved in binding to the 43-kDa

protein because of topochemical similarity to the active

area of insulin consisting of ValA3, TyrA19, ValB12 and

TyrB16 (Fig 7D,E,F) In the active state, insulin exposes

the active area (ValA3, TyrA19, ValB12 and TyrB16) for

entry into the insulin receptor (Fig 7E) [17] Among the

mutations of these four residues in the 4-kDa peptide

(Val23, Val29, Phe31 and Ile33), three (Val29, Phe31 and

Ile33) were involved in affinity for the 43-kDa protein

Instead of Val23, Ile25 was found to be important for

binding to the 43-kDa protein The topology of the

side-chains of Ile25, Val29, Phe31 and Ile33 in the 4-kDa

peptide was similar to that of the active area in insulin

(Fig 7F) If the mechanism of the interaction between the

4-kDa peptide and 43-kDa protein has the minimum

components of insulin–insulin receptor interaction, the area

consisting of Ile25, Val29, Phe31 and Ile33 in the 4-kDa

peptide should play a critical role in the interaction with

the 43-kDa protein These results suggest that there might

exist, on the surface of the 43-kDa protein, an area that

consists of hydrophobic residues facing the hydrophobic

patch in the 4-kDa peptide

On the other hand, the C-terminal b-strand area, PheB25

and TyrB26, in insulin is required to direct the insulin

receptor [18–22] When the 4-kDa peptide was compared to

the active state of insulin, Leu27 and Phe28 of the 4-kDa

peptide could occupy a similar place as PheB25 and TyrB26

of insulin (Fig 7E,F) Therefore, it is suggested that Leu27

and Phe28 share the same role as PheB25 and TyrB26 in

insulin

The area consisting of Ile25, Val29, Phe31 and Ile33 in the

4-kDa peptide is important for interaction with the 43-kDa

protein (Figs 6 and 7D,E,F) Although Leu27 and Phe28

are also involved in the interaction with 43-kDa protein, the

role of these residues is probably different from that of the

four residues (Ile25, Val29, Phe31 and Ile33) Generally,

the hydrophobic triplet of PheB24, PheB25 and TyrB26 of

the C-terminal B-chain domain of insulin is important for

directing the affinity of insulin receptor interaction [18–22]

As Leu27 and Phe28 of the 4-kDa peptide are located in the

same region against the aromatic triplet, Leu27 and Phe28

in the 4-kDa peptide probably regulate the orientation of

interaction with the 43-kDa protein

Although the 43-kDa protein is not identical to the insulin

receptor, they show a resemblance in some structural

architecture For example, both proteins form a dimer, while their protomers consist of two disulfide-linked a and b subunits, contain a cysteine-rich region in their a subunits, and show protein kinase activity in their b subunits As mentioned above, the interaction system between 4-kDa peptide and 43-kDa protein may be similar to the insulin– insulin receptor interaction system

Acknowledgements

We thank Prof F X Avile´s and Dr N Islam for their invaluable suggestions during this work We also thank Dr M Takaoka for her help in producing the recombinant 4-kDa peptide This work was supported in parts by grants for the National Project on Protein Structural and Functional Analysis to H.H.

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