Báo cáo khoa học: A novel phosphorylated glycoprotein in the shell matrix of the oyster Crassostrea nippona pptx

By contrast to the widespread occurrence of aragonite, calcite is limited to several taxa with species-dependent microstructures composed of Keywords domain structure; foliated layer; oy

A novel phosphorylated glycoprotein in the shell matrix of the oyster Crassostrea nippona

Tetsuro Samata, Daisuke Ikeda, Aya Kajikawa, Hideyoshi Sato, Chihiro Nogawa, Daishi Yamada, Ryo Yamazaki and Takahiro Akiyama

Laboratory of Cell Biology, Faculty of Environmental Health, Azabu University, Sagamihara, Japan

Subsequent to the pioneering work of Miyamoto et al

[1], Sudo et al [2] and Shen et al [3], more than 20

genes encoding the organic matrix (OM) components

of molluscan shells have been determined and their

deduced amino acid sequences clarified [4–12]

How-ever, the information available to date has been

restricted to the nacreous and prismatic layers of pearl

oysters, leaving the other shell layers poorly

investi-gated at the molecular level One exception is the

find-ing of acidic glycoprotein MSP-1 in the foliated layer

of Patinopecten yessoensis [4]

Through their control of nucleation, growth,

mor-phology and polymorphism of CaCO3 crystals, these

OMs are commonly assumed to be intimately

associ-ated with every phase of molluscan biomineralization, and thus with the overall regulation of the shell micro-structure More recent investigations have primarily involved in vitro measurement of OM activities related

to crystal formation [13–18] Although these studies have clearly shown that OM modulates molluscan bio-mineralization, the results nevertheless demonstrate marked methodology-dependent variation The func-tion of OM thus remains unclear, even in vitro, and is

a topic of future research

Molluscan shells are composed of either aragonite

or calcite By contrast to the widespread occurrence

of aragonite, calcite is limited to several taxa with species-dependent microstructures composed of

Keywords

domain structure; foliated layer; oyster shell;

phosphorylated matrix protein; poly-Asp

sequences

Correspondence

T Samata, Laboratory of Cell Biology,

Faculty of Environmental Health, Azabu

University, 1-17-71 Fuchinobe, Sagamihara,

Kanagawa 229-0006, Japan

Fax: +81 42 769 2560

Tel: +81 42 769 2560

E-mail: samata@azabu-u.ac.jp

Database

The nucleotide sequences have been

sub-mitted to DDBJ with the accession number

AB207821–AB207826

(Received 11 January 2008, revised 31

March 2008, accepted 7 April 2008)

doi:10.1111/j.1742-4658.2008.06453.x

We found a novel 52 kDa matrix glycoprotein MPP1 in the shell of Cras-sostrea nippona that was unusually acidic and heavily phosphorylated Deduced from the nucleotide sequence of 1.9 kb cDNA, which is likely to encode MPP1 with high probability, the primary structure of this protein shows a modular structure characterized by repeat sequences rich in Asp, Ser and Gly The most remarkable of these is the DE-rich sequence, in which continuous repeats of Asp are interrupted by a single Cys residue Disulfide-dependent MPP1 polymers occurring in the form of multimeric insoluble gels are estimated to contain repetitive locations of the anionic molecules of phosphates and acidic amino acids, particularly Asp Thus, MPP1 and its polymers possess characteristic features of a charged mole-cule for oyster biomineralization, namely accumulation and trapping of

Ca2+ In addition, MPP1 is the first organic matrix component considered

to be expressed in both the foliated and prismatic layers of the molluscan shell microstructure In vitro crystallization assays demonstrate the induc-tion of tabular crystals with a completely different morphology from those formed spontaneously, indicating that MPP1 and its polymers are poten-tially the agent that controls crystal growth and shell microstructure

Abbreviations

CBB, Coomassie brilliant blue; GISM, translucent gelatinous insoluble organic matrix; ISM, insoluble organic matrix; MPP1, molluscan phosphorylated protein 1; ntp, nucleotide position; OM, organic matrix; SM, soluble organic matrix.

prismatic, foliated, chalky and granular structures In

particular, the shells of oyster species are composed of

a highly complex microstructure consisting of the

chalky layer in addition to the foliated and prismatic

layers The foliated layer is formed by the aggregation

of units termed lath, each with a width of 2 lm and

length of 10 lm [19], whereas the chalky layer has a

homogeneous morphology composed of tiny calcite

granules [19] A variety of studies, mostly based on

amino acid analysis of bulk soluble matrix (SM) and

insoluble matrix (ISM) [20–24], have shown the

pres-ence of OM in oyster species with particularly highly

acidic properties This high acidity is due to Asp and

phosphoserin (p-Ser) [25] Much of the accumulating

data on oyster shell biomineralization were obtained by

Wheeler et al., who have provided summaries of their

extensive studies [26,27] Their investigation of the

frac-tionation and functional analysis of the OM

compo-nents highlighted the inhibitory activity of the OM

against crystal formation in vitro Immunocytochemical

studies of the OM in the prismatic layer of C virginica,

as reported by Kawaguchi and Watabe [28], revealed

that the ISM constituted the framework of the OM

and SM, which comprised several phosphorylated

pro-teins and might be distributed on the surface of the

ISM and surrounded calcite crystals Atomic force

microscope and scanning electron microscope

observa-tions of foliar chips after pyrolysis and their

subse-quent crystallization revealed that crystal formation

occurred on the surface of the laths under the

regula-tion of the OM, which showed pulsed secreregula-tion [19]

As noted above, the primary structure of oyster OM

has yet to be precisely determined In the present

study, we aimed to elucidate the overall picture of the

OM components of Crassostrea nippona by a

combina-tion of biochemical and genetical analyses For gene

analysis, given the close similarity of the shell structure

and amino acid composition of the OM of the oyster

and scallop, we started with the isolation of cDNA

clones homologous with MSP-1 gene Additional

in vitro crystallization assays were then performed to

investigate the function of the OM components

Results

Biochemical characterization of the OM

components extracted from oyster shell

Fractionation of the bulk OM separated two fractions,

namely the SM at approximately 20 mg per 50 g of

shell and the ISM, which was further sub-divided into

two components: a predominant translucent gelatinous

insoluble organic matrix (GISM) pellet at

approxi-mately 120 mg per 50 g of shell and a small quantity

of fibrous precipitate at approximately 5 mg per 50 g

of shell

After SDS⁄ PAGE of GISM, which was largely-solubilized in a sample buffer containing 2-mercaptoeth-anol after boiling, and subsequent staining procedures with negative staining, Stains-all and Methyl green visu-alized an exclusive band of approximately 52 kDa, which showed a negative reaction with Coomassie brilliant blue (CBB) (Fig 1)

SDS⁄ PAGE of the 52 kDa component after enzy-matic deglycosylation and dephosphorylation showed apparent downward shifts in molecular masses of 2.5 and 3.5 kDa, respectively (Fig 2)

Table 1 shows that the 52 kDa component in GISM exhibits an amino acid composition, strikingly domi-nated by Asx (aspartic acid plus asparagine), which, together with Ser and Gly, accounted for more than 80% of the total residue By contrast, the bulk SM showed a different amino acid composition, which comprised large amounts of Asx, Glx (glutamic acid plus glutamine) and Gly, and a much smaller amount

of Ser than that of GISM

Amino acid sequence analysis using a peptide sequencer failed to determine the N-terminal sequence

of the 52 kDa component Likewise, LC⁄ MS ⁄ MS anal-ysis of the V8 protease digests of the 52 kDa compo-nent did not reveal any peptide with sequences corresponding to those of the 44 kDa deduced protein

66.2 45 (kDa)

Fig 1 SDS ⁄ PAGE electrophoretogram of GISM in the OM of

C nippona The same amount of sample was applied to each lane Lane M, molecular mass standards; lane A, CBB staining; lane B, Stains-all staining; lane C, negative staining; lane D, Methyl green staining Arrows on the right side of the lanes indicate the position

of the 52 kDa component A weakly stained band in lane A does not correspond to the 52 kDa component but a minor component with a molecular mass of 45 kDa.

encoded by the 1.9 kb cDNA and those reported so

far On the other hand, the deduced 44 kDa protein

was identified as a top protein score of 55 (probability

based mowse score) using the Mascot search engine

for the fragments digested with endoproteinase Asp-N

of the 52 kDa component, whereas scores of the other

proteins in the database were lower than 20 Among each peptide sequence with high peptide scores, a short but specific sequence of DCGVDCGYYEPV (score of 19) at the N-terminal region of the deduced 44 kDa protein and an additional sequence of DNNGDGNG (score of 16) in the NG repeat sequence at the C-ter-minal region were characteristic The same result was obtained using the Sequest search engine The most appropriate condition for Asp-N digestion was the addition of 75 ng of enzyme to 15 lg of protein FTIR analysis of GISM showed the most intensive absorption peaks at 1654 cm)1 and 1561 cm)1, corre-sponding to amides I and II, respectively, characteristic

in protein moiety (Fig 3) [29] The small peak at

1243 cm)1 may represent amide III, sulfates or phos-phates and that at 1408 cm)1 may be associated with carboxylate [29,30] An additional large absorption peak occurred at around 1097 cm)1, which was consid-ered to be associated with carbohydrates [29,30]

Cloning and sequencing of cDNA encoding the

OM component in the foliated layer

A nucleotide fragment of approximately 320 bp was amplified using the primer pairs of F1 and R1 Nucle-otide sequences of the primer positions in this frag-ment (fragfrag-ment A) completely matched that of MSP-1 gene corresponding to F1 and mismatched at five nucleotide positions corresponding to R1, and the deduced amino acid sequences at the N-terminal and C-terminal regions were SGSSSSS and GGDGGDG 3¢-Rapid amplification of cDNA ends (3¢-RACE) using the set of primers of the adaptor primer and the

66.2

45

(kDa)

66.2

45 (kDa)

Fig 2 SDS ⁄ PAGE electrophoretogram of (A) dephosphorylated

GISM and (B) deglycosylated GISM Lane M, molecular mass

stan-dards; lane 1, dephosphorylated GISM (A) and deglycosylated

GISM (B); lane 2, native GISM The same amount of the sample

was applied to each lane Arrows on the right side of the lanes

indi-cate the position of the native and the (A) dephosphorylated and

(B) deglycosylated 52 kDa components.

Fig 3 FTIR spectrum of the GISM fraction The vertical scale shows the intensity exhibited by %T.

Table 1 Amino acid compositions of the 52 kDa component and

the SM of C nippona together with that of the deduced 44 kDa

protein Values were calculated by mole percentage Asx,

Asp + Asn; Glx, Glu + Gln; Ser, Ser + p-Ser Any amount of amino

acids lower than approximately 1% in the 52 kDa component and

the SM may not be accurate because of contamination from the

poly(vinylidene difluoride) membrane.

44 kDa

deduced

protein

52 kDa

gene-specific primer F2 based on the nucleotide

sequence of fragment A amplified a fragment of

approximately 1040 bp (fragment B), in which the F1

primer annealed with the same sequence, located

345 bp upstream of the primer position The 5¢-region

of the nucleotide sequence completely matched that of

fragment A

Next, 5¢-rapid amplification of cDNA ends

(5¢-RACE) revealed the presence of one positive clone

(fragment C) with a length of approximately 1050 bp

The 3¢-region of the nucleotide sequence completely

matched that of fragment B

Using PCR employing two gene-specific primers of

F3 and R3 to obtain the full-length cDNA, a fragment

of approximately 1.7 kb was amplified, which included

sequences consistent with those of the

above-men-tioned fragments, A, B and C After addition of the

remaining sequences, namely approximately 100 bp of the 5¢-region and 110 bp of the 3¢-region, the full length of the obtained clone was determined to be approximately 1.9 kb An additional two clones that lacked nucleotide sequences between nucleotide posi-tion (ntp) 913–1011 and ntp 754–1083 of the 1.9 kb clone were amplified The full lengths of these two clones were approximately 1.8 and 1.56 kb, respec-tively The nucleotide sequences reported here have been submitted to the GenBank TM⁄ EBI Data Bank with accession numbers AB207821–AB207826

The cDNA preserved the fundamental structure necessary for an ORF such as the start and stop codons, poly A signal and polyA tail An in-frame stop codon TAG was located at ntp 1696–1698 with

a putative polyadenylation signal (AATAAA) located

at ntp 1866–1871 of the 1.9 kb cDNA The relevant

Fig 4 Nucleotide sequence of the 1.9 kb cDNA and deduced amino acid sequence Numbers on the left indicate the nucleotide positions in the 1.9 kb cDNA sequence (upper) and positions of the amino acid resi-dues in the deduced protein (lower) The putative signal peptide is underlined The start codon (ATG), stop codon (TAG) and putative polyadenylation signal (AATAAA) are boxed.

nucleotide and deduced amino acid sequences are

shown in Fig 4

Deduced protein structure encoded by the 1.9 kb

cDNA

The deduced protein encoded by the 1.9 kb cDNA

fragment encompassed 516 amino acid residues and

had a calculated molecular mass before

post-transla-tional modification of 46561.41 Da Following the

typ-ical sequence for signal peptide, comprising 19 amino

acids, the N-terminal amino acid of the mature protein

was expected to be Ala based on the prediction using

neutral networks and hidden Markov models

Eventu-ally, the molecular mass of the mature protein was

estimated to be 44490.85 Da, containing 497 amino

acid residues

The amino acid composition of the deduced protein

was characterized by a high proportions of Ser

(33.80%), Gly (28.97%) and Asp (26.77%), which

together accounted for more than 80% of the total

amino acid residues (Table 1) By contrast, the

occur-rence of basic amino acids was markedly low, with

only two Lys residues, resulting in a much higher

pro-portion of acidic to basic amino acids than in MSP-1

The deduced 44 kDa protein revealed a modular

structure with a domain characterized by repeat

sequences rich in Ser and Gly, named the SG domain

This was segmented eight times by comparatively short

repeats of a DE-rich sequence (Fig 5) The sequence

of N-terminal region was followed by an NGD

domain rich in Asn, Gly and Asp, which formed nine segments of NGD Another NGD domain, containing seven segments of NGD, was characterized by five sets

of GDYNGN⁄ A occurring at the C-terminal region Similar short sequences of GGDGGDGDN occurred twice at the C-terminal side The NGD domain at the N-terminal region was connected by an SDG-rich sequence comprised mainly of an irregular arrange-ment of Ser, Gly and Asp A similar sequence repeated twice at the C-terminal region with nine repeats of SD The subsequent SG domain was dominated by sequences of (Ser)n–(Gly), where n = 1–4 The DE-rich sequence predominantly contained the acidic amino acids, which appeared in a characteristic manner as (DEDCED), (DDGDEDCEDE),

(DDDDDCD-DDD) In the sequence, Asp was contained preferably over Glu, and a single Cys residue was located at its center

A search of the nonredundant GenBank CDS data-base using blast (protein–protein blast and Search for short, nearly exact matches) showed a similarity of 34.4% between the sequence throughout the molecules

of the deduced 44 kDa protein and MSP-1, with only exceptional high similarity between the SG domain of them (Fig 6) Partially high correspondence with phos-phophorin, a dentin Ca-binding phosphoprotein [31], and Lustrin A [3], a molluscan OM protein from a gastropod Haliotis rufescens, was observed over the 50 amino acids comprising the SG domain of this protein

No clear homology with any other protein occurring

in the database

Motif analyses by scanprosite (provided by Swiss Institute of Bioinformatics, SIB, Geneva, Switzerland) and netphosk (provided by Center for Biological Sequence Analysis BioCentrum-DTU Technical Uni-versity of Denmark, Lyngby, Denmark) suggested that

35 and 45 casein kinase II phosphorylation sites were present, respectively A motif of an N-glycosylation site was detected at two positions of the molecule An additional motif of GAGs (glucose aminoglycans)-binding indicated as DGSD was confirmed at two positions of the C-terminal region

With consideration of the phosphorylation sites and excluding the putative signal peptide, use of the scansite tools of the ExPASy server showed that the deduced 44 kDa protein had a very low theoretical pI

of 1.21 considering the 35 casein kinase II phosphory-lation sites

The additional two proteins encoded by the 1.8 and 1.56 kb cDNAs lacked amino acid residues between

256 and 288 corresponding to the SG domain in the second unit of the deduced 44 kDa protein and

Fig 5 Schematic representation of the domain structures of

MPP1 and MSP-1 The SG domain, DE-rich sequence and NGD

domain of MPP1 are arranged to constitute the unit structure

twice, named unit-1 and unit-2 The sequence between these two

units was completely conserved.

residues 203 to 316 corresponding to the whole second

unit of the protein, respectively

Tissue specific expression of a transcript of the

1.9 kb cDNA

As shown in Fig 7, northern blot hybridization

showed that a transcript of approximately 1.5–2.0 kb

was detected solely in the RNA from mantle pallial,

where it contributed to the formation of the foliated

layer A band slightly smaller in size, and which had

a much weaker intensity of the chemiluminescence

reaction than the former band, was detected in the

mRNA from the mantle edge, where it contributed to

the formation of the prismatic layer By contrast,

they were not expressed in gill or adductor muscle

In vitro assay of OM activity

In the systems used for the ‘CaCO3 crystal growth assay’, characteristic inhibitory efficiency against crystal formation was recognized after addition of the SM, GISM and the 52 kDa component to the crystallizing solution Inhibition was observed as a change in crystal morphology, from a characteristic rhombohedral shape

to a poor crystalline habit with rounded edges for calcite crystals, and from a spherical shape with needle-like structure to a spherulite shape with smooth surfaces for aragonite crystals, and the complete loss of crystal shape for both in an additive volume-dependent manner One interesting result obtained by contrast interference microscopy was the induction of tabular crystals of oval

to quadrangular shape with rough edges and very fine parallel stria along the bottom face when the three above mentioned components were added to the arago-nitic crystallizing solution with the underlying GISM-derived membrane These crystals were observed to be tightly adhered to the membrane in a manner com-pletely different from those inorganically formed or those formed without fixative (Fig 8A-1, 2) Scanning electron microscopy of the edge of the crystals revealed the presence of rod-like rectangular structures with

a striking morphological appearance and dimensions closely comparable to those of the folia (Fig 8B) Consistent with the findings of Wheeler et al [15], an instantaneous decrease in pH was seen in the ‘CaCO3 precipitation assay’ when CaCl2was added to the bicar-bonate solution, followed by an additional downward trend intercalated by relatively stable periods The dura-tion of the stable periods was increased and the rate of

pH decrease was attenuated in a volume-dependent

Fig 6 Alignment of the amino acid sequences of MPP1 and MSP-1 Asterisks show identical amino acids, and dashes correspond to deletions Numbers on the right and left indicate the number of the amino acid residues in the MPP1 (upper) and MSP-1 (lower) sequences.

Fig 7 Electrophoretogram of a transcript of the 1.9 kb cDNA by

northern hybridization Samples of total RNA were isolated from

different oyster tissues: lane A, mantle edge, responsible for

pris-matic layer formation; lane B, mantle pallial, responsible for foliated

layer formation; lane C, adductor muscle; lane D, gill; lane M,

molecular weight standard of RNA The arrow indicates the 2.0 kb

RNA marker.

manner with respect to the additive (Fig 9) Notably,

this tendency toward the inhibition of crystal nucleation

was more intensive with the 52 kDa component than

with the same amount of phosphovitin used for

refer-ence (Fig 9)

Discussion

A common feature of the oyster OM as reported in a

number of studies is the overall similarity of amino

acid composition among the bulk SM, ISM and even

several purified components that comprise the SM, as

described above [20–24] Because no other component

exhibits the same composition or is stained with both

negative staining and Methyl green, we assume that the 52 kDa component, which accounts for a consider-able part of the gelatinous material in the foliated layer, is the main phosphorylated glycoprotein A sec-ond key component in oyster biomineralization might

be the polyanionic components contained in the SM, although their primary structures are still unclear The predicted amino acid composition of the deduced 44 kDa protein agrees well with that of the

52 kDa component in the foliated layer of C nippona (Table 1) and the 54 kDa phospholylated component (RP-1) in the same layer of C virginica [26], as well as those of the bulk OMs reported from several oyster species described to date [20–24] In addition,

LC⁄ MS ⁄ MS analysis of the endoproteinase Asp-N digest of the 52 kDa component revealed the presence

of several peptides with amino acid sequences corre-sponding to those in the sequence of the genetically determined 44 kDa protein, although amino acid sequence analyses using the peptide sequencer failed to determine the N-terminal sequence of the 52 kDa component, strongly suggestive of the presence of N-terminal block As noted in the present study, FTIR, amino acid composition and motif analyses all suggest that the size discrepancy between the deduced

A1

B

A2

Fig 8 Surface views of crystals induced by ‘CaCO 3 crystal

growth assay’ (A1) Spontaneously formed aragonite crystals,

Scale bar = 100 lm (A2) Tabular crystals of oval to quadrangular

shape with rough edges induced on the GISM-derived membrane

after addition of the 52 kDa component at 5 lg Scale

bar = 100 lm (B) Scanning electron microscopy of the edge of

the tabular crystals Scale bar = 100 lm The presence of residual

undissolved CaCO3 crystals was carefully checked by scanning

electron microscopy, an energy dispersive X-ray spectrometer,

FTIR and an X-ray diffractometer Experiments were repeated at

least 10 times for each batch.

A B

C D E

0:00 2:00 4:00 6:00 8:00 10:00 12:00 14:00

(min)

(pH) 8.8

8.6

8.4

8.2

8.0

7.8

7.6

7.4

7.2

7.0

Fig 9 Recordings of CaCO 3 precipitation by ‘CaCO 3 precipitation assay’ (A) Reference experiment performed by addition of distilled water (DW) to the crystallizing solution (B, D, E) Addition of the

52 kDa component to the crystallizing solution at 2.5 lg (B), 10 lg (D) and 50 lg (E) (C) Addition of phosphovitin to the crystallizing solution at 50 lg.

44 kDa protein and the 52 kDa component may be

attributed to post-translational phosphorylation and

glycosylation This assumption was supported by the

results obtained for the enzymatic dephosphorylation

and deglycosylation experiments of the 52 kDa

com-ponent These data indicate with high probability that

the 1.9 kb cDNA is the gene encoding the 52 kDa

protein Finally, we conclude that the 52 kDa

compo-nent is a main novel phosphorylated glycoprotein that

is intimately involved in shell formation of C nippona

and thus can be designated: MPP1 (molluscan

phosph-orylated protein 1) Although MPP1 shares high

homology with MSP-1 as a whole, the differences

between them are obvious with respect to the presence

of a DE-rich sequence and the lack of a K domain,

together with the relatively high amount of Cys in

MPP1 (Fig.5), their respective molecular masses

(52 kDa for MPP1 versus 74.5 kDa for MSP-1), the

number of potential phosphorylation sites (35–45 sites

in MPP1 versus 9–10 sites in MSP-1) and their

respec-tive pI (1.21 for MPP1 versus 3.15 for MSP-1,

consid-ering ten casein kinase II phosphorylation sites)

The complete primary structures of two highly acidic

OM proteins from the prismatic layer and one from

the foliated layer have been reported, namely Aspein,

with a GS(D)5 repeat [9]; Asprich, whose D block has

a maximum 10 Asp repeat [11]; and MSP-1 in the

foli-ated layer, which lacks the poly-D sequences [4] In

addition, a 17 kDa protein, caspartin, isolated from

the prismatic layer of Pinna nobilis [32], had Asp as

the first of 75 N-terminal amino acid residues;

how-ever, its complete primary structure has not been

revealed Among these three genetically determined

proteins, only MSP-1 has been confirmed as being

dis-tributed in the shell, as demonstrated by the

N-termi-nal amino acid sequence of the OM component

matching that deduced from the nucleotide sequence

of the MSP-1 gene, although a band with a

compara-ble molecular size as that of MSP-1 could not be

vali-dated by SDS⁄ PAGE

Regarding the modular structure of MPP1, the

remarkable DE-rich sequence appears to be

anoma-lous, in that the continuous repeats of Asp are

inter-rupted by a single Cys residue, which is conserved in

all DE-rich sequences except one This sequence

con-servation of Cys hints at its functional significance,

namely that it is incorporated in the formation of

intra- or inter-molecular disulfide bonds In the latter

case, MPP1 monomer may be self-assembled to a

poly-mer, converting them to an insoluble form, although

the mechanism of this insolubility is unknown

The secondary structure of MPP1 estimated by the

method of Chau and Fasman [33] consists

predomi-nantly of a loop structure, which mainly corresponds

to the repeated arrangement of the SG domain with densely distributed phosphorylation sites inserted by the DE-rich sequence In turn, this gives rise to the regular arrangement of the anionic molecules of phosphates and acidic amino acids Given this assumption, disulfide-dependent MPP1 polymers occurring in the form of multimeric insoluble gels can be estimated to contain a massively repeating acidic region MPP1 polymers may thus participate in oyster shell formation by accumulating Ca2+ through

an ionotropic effect of phosphates, analogous to that with sulfates [34], which extend from the peptide chain Further binding of Ca2+ to carboxyl groups

of Asp or Glu arranged in the DE-rich sequence occurs, followed by the subsequent reaction of the

Ca2+ with CO3 ), which may be concentrated by the specific function of nacrein whose presence in oyster shells has been genetically determined [35] In this way, subsequent sequential reaction of the anionic and cationic ions may result in the nucleation of CaCO3 crystals With regard to the biochemistry of the reactions between the OM and Ca2+, Weiner and Hood [22] and Weiner and Traub [36] proposed that the regular spacing of the carboxyl side chains of Asp is a close reflection of that of Ca2+ in CaCO3 crystal lattices, and thus controls crystal polymor-phism However, it should be noted that highly acidic proteins have been associated with calcitic shell lay-ers, indicating the potential involvement of the Asp-and⁄ or p-Ser rich components in calcite formation not only in the prismatic layers, but also in the foli-ated layers This notion is supported by the results of the present study

By contrast to this notion, however, our in vitro crystallization assay showed that the OM compo-nents had an inhibitory effect against CaCO3 crystal formation This does not necessarily imply a negative role for the OM components in oyster shell biomin-eralization because, although the soluble and the additive components inhibited crystal formation when present in the isolated state, the same molecules induced tabular crystals with a completely different morphology from spontaneously formed crystals when pre-mixed with underlying GISM-derived mem-brane Unfortunately, X-ray diffractional analysis of the tabular crystals failed to determine their mineral-ogy due to their small quantities, which were far less than the minimum detectable quantity The basement membrane is an artificial material, which is prepared from the gelatinous pellet by clumping together on drying The surface area of the membrane may

be hydrated again and returned to the form of a

concentrated gel in the crystallizing solution,

imply-ing that oyster shell formation may occur in a

gelati-nous environment containing a multimeric complex

of the MPP1 molecule A similar environment was

envisaged in the case of the formation of the

nacre-ous layer, to which jelly component comprising

MSI60 might be related [37,38] For formation of

the multimeric complex, GAGs that were estimated

to be in close contact with GISM [28] might be

responsible because the potential binding sites of

GAG were found in the deduced 44 kDa protein

As an additional but decisive contributor to calcite

induction, we emphasize the role of phosphate, which

has been specifically identified as the accessory

mole-cule of p-Ser in the OM of the foliated layer This

notion is supported by the fact that phosphate content

in the foliated layer far exceeds that in the aragonitic

shell layers [20] One study identified phosphate as

favorably controlling calcite formation when added to

the calcium carbonate solution in trace amounts [39]

The precise effect of phosphate in polymorphism

con-trol awaits future study

Additional identification of the MPP1-related

com-ponent in the prismatic layer of C nippona, as well

as in vitro crystallization assays using recombinant

proteins or synthesized peptides, will initiate a new

phase in the elucidation of oyster shell formation,

and highlight the control of CaCO3 polymorphism

and shell microstructure in molluscs In further trials

to obtain a whole figure of molluscan shell

biominer-alization, several additional factors must be taken

into consideration; namely, the behaviour of cells, the

composition of extrapallial fluids, functions of the

signal molecules regulating expression of the OM

component, as well as environmental factors, as

described by Kuboki et al [40] Genetical research

combined with an analyses of these factors may

com-prise a potential tool for the elucidation of molluscan

biomineralization in the future

Experimental procedures

Molluscan materials

We used live individuals of C nippona cultured at the

hatch-ery of Shimane Technology Center for Fisheries, Japan

Extraction and purification of the organic matrix

proteins

Shell surfaces were cleaned with an electric rotary grinder

(JOY-ROBO, Cannock, UK) to roughly remove

perios-tracum and adherent hard tissues Pieces of folia were

carefully separated from the powder of chalky material and then immersed in 5% NaClO for 30 min to remove organic contaminants After rinsing with distilled water (DW) and air-drying, folia were ground into powder with

a ball mill (ITO Manufacturing, Nagano, Japan) The powdered folia was decalcified with 5% acetic acid for

3 days at 4C under constant stirring and with pH regu-lated at over 4.5, followed by dialysis against DW The dialyzed solution was centrifuged at 15 000 g for 30 min

to obtain separation of the supernatant SM and precipi-tated GISM These two fractions were boiled in a sample buffer containing 5% 2-mercaptoethanol for 1 min and then subjected to SDS⁄ PAGE using Pagel (gradient gel

of 5–20%; ATTO, Tokyo, Japan) under reducing condi-tions in a Dual Mini Slab Chamber (ATTO) After elec-trophoresis, bands were stained with CBB (Sigma-Aldrich Chemie, Steinheim, Germany), Stains-all (BDH, Dorset, UK) [41], Methyl green (CHROMA, Rockingham, VT, USA) [42] and negative staining [43], all as previously described

Amino acid composition and N-terminal sequence analysis

Following separation with SDS⁄ PAGE, OM components were electro-blotted onto a poly(vinylidene difluoride) membrane (Immobilon Transfer Membranes; Millipore, Bedford, MA, USA) by a semi-dry blotting system (Nihon Eidou, Tokyo, Japan) and then stained with CBB To determine the amino terminal sequence, the target protein bands were cut from the membrane and subjected directly

to an automated amino acid sequence analyzer LF3000 (Beckman Coulter, Fullerton, CA, USA) To determine amino acid composition, membrane pieces corresponding

to the protein bands were hydrolyzed in 5.7 m HCl at

110C for 24 h Hydrolyzed samples were analyzed with

an L-8500 automated amino acid analyzer (Hitachi, Tokyo, Japan) using ion-exchange, post-column Ninhydrin detection

Enzymatic digestion and LC⁄ MS ⁄ MS analysis V8 protease (Pierce, Rockford, IL, USA) and endoprotein-ase Asp-N proteendoprotein-ase (Roche, Bendoprotein-asel, Switzerland) were added

to the gel pieces, which contained the 52 kDa component dissolved in 50 mm sodium phosphate buffer (pH 7.8) The amounts of the enzymes and proteins were changed at a ratio between 1 : 50 and 1 : 200 After incubation at 37C for

18 h, the protease digests were dried and dissolved in 10 lL

of trifluoroacetic acid, and then cleaned up by Zip-tip (Milli-pore) Purified digests were subjected to LC⁄ MS ⁄ MS anal-ysis on a Paradigm MS4 LC System coupled to a model LCQ ion trap mass spectrometer (Thermo Fisher Scientific, Waltham, MA, USA) equipped with an electrospray

inter-face utilizing a C18 column (Michrom Bioresources, Auburn,

CA, USA)

Deglycosylation and dephosphorylation

experiments

PNgase F (Roche) digestion of GISM was carried out as

described below After addition of 100 lL of incubation

buffer [50 mm sodium phosphate buffer (pH 7.8), 10 mm

EDTA (pH 8.0), 0.5% (v⁄ v) Nonidet P40, 0.2% (w ⁄ v)

SDS, 1% (v⁄ v) 2-mercaptoethanol] to an equivalent volume

of GISM, the mixture was incubated for 18 h at 37C with

2 units of PNgase F

Alkaline phosphatase (Roche) digestion of GISM was

carried out according to the manufacturer’s instructions

After addition of 5 lL of 10· phosphatase buffer to 45 lL

of GISM, the reaction mixture was incubated for 1.5 h at

37C with 4 units of alkaline phosphatase

FTIR analysis

Samples were mixed with KBR and analyzed by FTIR

(Magna-IR 750, Thermo Fisher Scientific)

cDNA cloning

Tissue collection for RNA extraction

The outer mantle epithelial tissue responsible for secretion

of the foliated layer was carefully separated from that part

of the mantle edge responsible for secretion of the prismatic

layer and immediately frozen in liquid nitrogen

Total RNA extraction

Total RNA was extracted from 300 mg of mantle epithelial

tissue using Isogen (Nippongene, Tokyo, Japan) and purified

with a SV RNA Isolation System (Promega, Madison, WI,

USA) The total amount of RNA was calculated with a

spectrophotometer (GeneQuant; GE Healthcare Bioscience,

Quebec, Canada)

PCR amplification

Single-stranded cDNA was synthesized with SuperScript III

RNase H) Reverse Transcriptase (Invitrogen, Carlsbad,

CA, USA), and purified after transcription using a Wizard

SV Gel and PCR Clean-Up System (Promega) A cDNA

fragment encoding the oyster OM protein was amplified

using a set of gene-specific primers of F1 (forward 953,

3¢-end corresponding to ntp 953 of the MSP-1 gene)

(5¢-TCC GGC TCA AGC TCT AGC TCT-3¢) and R1 (reverse

1369 of the MSP-1 gene) (5¢-TCC ATC ACC TCC ATT

GCC TCC-3¢), corresponding to the amino acid sequences

of the SGSSSSS and GGNGGDG of the MSP-1 gene,

respectively Primers were supplied by Texas Genomics Japan (Tokyo, Japan) PCR amplification was performed using KOD-Plus as an enzyme for extensive reaction with a thermal cycler (Bio-Rad Laboratories, Hercules, CA, USA) 3¢-RACE was carried out using a set of primers of an adaptor primer (TCG AAT TCG GAT CCG AGC TCT) and the gene-specific primer of F2 (forward 918) (5¢-TGC GAT GAT GAT GAC AGC GGA-3¢), based on the nucle-otide sequence of the cDNA fragment obtained from the first PCR

5¢-RACE was primed using a Smart Race Kit (Clontech, Mountain View, CA, USA) using a set of an adaptor UPM and the gene-specific primer of R2 (reverse 1056) (5¢-TGC GAG GAT GGT GGT GAT GGA-3¢), designed from the nucleotide sequence of the cDNA fragment amplified by 3¢-RACE

The full length of the cDNA encoding the oyster OM protein was amplified using a set of the gene-specific prim-ers of F3 (forward 136) (5¢-CCT AGA AGA ATA CAT CGG GGT-3¢), and R3 (reverse 1827) (5¢-TCT GGC ATG AAA CAC GAC AAC-3¢), based on the nucleotide sequences of the 5¢ and 3¢ terminal regions, respectively

TA cloning After purification and A-tailing, the PCR products were used for ligation with pGEM-T Easy Vectors (Promega), and catalyzed with T4 DNA ligase at 4C for 16 h The ligation products were supplied for transformation of JM109 high-efficiency competent cells (Promega) Positive clones were selected by blue⁄ white colour screening and standard ampicillin selection, followed by purification using

a Qiaprep Spin Miniprep Kit (Qiagen, Tokyo, Japan)

Sequencing The purified clones were labelled with a Thermo Sequence Primer Cycle Sequencing Kit (GE Healthcare Bioscience) and sequenced with an automated DNA sequence analyzer DSQ-1000L (Shimadzu, Kyoto, Japan)

Northern blot hybridization Total RNA was extracted with Isogen (Nippongene) from each tissue (mantle edge, mantle pallial, gill and adductor muscle) of C nippona and purified using a SV RNA Isola-tion System (Promega) RNA samples were segregated by electrophoresis on a 1% (w⁄ v) formaldehyde agarose gel and transferred to a positively-charged nylon membrane (GE Healthcare Bioscience) Hybridization was performed

at 58C using an Alkali Phos Direct Labelling and Detec-tion Kit (GE Healthcare Bioscience) Probes for analysis were designed in correspondence to ntp 4–124 of the 1.9 kb cDNA CDP-star was used for detection and