Tài liệu Báo cáo khoa học: Co-operative effect of the isoforms of type III antifreeze protein expressed in Notched-fin eelpout, Zoarces elongatus Kner ppt

For RD1 and RD2, the amino acid replacements of the hydrophobic residues 20th and 41st have been identified for the ice-binding surface.. Overall, the type III AFP isoforms differ in thei

protein expressed in Notched-fin eelpout, Zoarces

elongatus Kner

Yoshiyuki Nishimiya1, Ryoko Sato1, Manabu Takamichi2, Ai Miura1and Sakae Tsuda1,2

1 Functional Protein Research Group, Research Institute of Genome-based Biofactory (RIGB), National Institute of Advanced Industrial Science and Technology (AIST), Sapporo, Japan

2 Division of Biological Sciences, Graduate School of Science, Hokkaido University, Sapporo, Japan

Antifreeze protein (AFP) possesses the unique ability

to bind to the surface of ice crystals, which permits

growth of ice at limited open spaces on the surface,

leading to the formation of numerous convex ice

surfa-ces between the bound AFPs [1] The growing ice

sur-face becomes energetically unfavorable for further

absorption of water molecules proportionately with the

surface curvature, leading to termination of ice growth

(Kelvin effect) [2] This AFP-induced inhibition of ice

crystal growth can be detected macroscopically as a

depression in the freezing temperature (Tf) of the

solution without alteration of the melting temperature (Tm) (|Tf) Tm|) This is generally termed thermal hys-teresis (TH)

AFPs categorized as type III (
7 kDa) have been identified in blood serum of fish living in polar sea-water with a year-round temperature of
)1.8
C: Arctic and Antarctic eelpouts (Austrolycicthys brachy-cephalus, Lycodes polaris, and Lycodichthys dearborni), Atlantic ocean pout (Macrozoarces americanus), and Atlantic wolffish (Anarhichas lupus) [3–6] Type III AFP forms a globular shape characterized by internal

Keywords

co-operative effect; Notched-fin eelpout;

type III antifreeze protein

Correspondence

S Tsuda, Functional Protein Research

Group, Research Institute of Genome-based

Biofactory (RIGB), National Institute of

Advanced Industrial Science and Technology

(AIST), 2-17-2-1 Tsukisamu-Higashi,

Toyohira, Sapporo 062-8517, Japan

Fax: +81 11 857 8983

Tel: +81 11 857 8912

E-mail: sakae.tsuda@aist.go.jp

Note

The nucleotide and protein sequences

reported here have been deposited in the

DDBJ database under the accession

numbers AB188389–AB188401.

(Received 27 August 2004, revised 9

November 2004, accepted 17 November

2004)

doi:10.1111/j.1742-4658.2004.04490.x

We found that Notched-fin eelpout, which lives off the north east coast

of Japan, expresses an antifreeze protein (AFP) The liver of this fish contains DNAs that encode at least 13 type III AFP isoforms (denoted nfeAFPs) The primary sequences of the nfeAFP isoforms were categor-ized into SP- and QAE-sephadex binding groups, and the latter were fur-ther divided into two subgroups, QAE1 and QAE2 groups Ice crystals observed in HPLC-pure nfeAFP fractions are bipyramidal in shape with different ratios of c and a axes, suggesting that all the isoforms are able

to bind ice We expressed five recombinant isoforms of nfeAFP and ana-lyzed the thermal hysteresis (TH) activity of each as a function of pro-tein concentration We also examined the change in activity on mixing the isoforms TH was estimated to be 0.60
C for the QAE1 isoform, 0.11
C for QAE2, and almost zero for the SP isoforms when the con-centrations of these isoforms was standardized to 1.0 mm Significantly, the TH activity of the SP isoforms showed concentration dependence in the presence of 0.2 mm QAE1, indicating that the less active SP isoform becomes ‘active’ when a small amount of QAE1 is added In contrast, it does not become active on the addition of another SP isoform These results suggest that the SP and QAE isoforms of type III AFP have dif-ferent levels of TH activity, and they accomplish the antifreeze function

in a co-operative manner

Abbreviations

AFGP, antifreeze glycoprotein; AFP, antifreeze protein; nfeAFP, type III AFP from Notched-fin eelpout; TH, thermal hysteresis.

twofold symmetry of the ‘pretzel’ fold [7–14], which

provides a markedly flat amphipathic ice-binding

surface contributed by residues 9–10, 13–16, 18–21, 41,

42, 44 and 61 [15–18] A large database of amino acid

sequences is available for the various isoforms of type

III AFP The sequences of at least 12 isoforms

(denoted HPLC1–12) have been determined for

Macrozoarces americanus, which were originally

categ-orized into QAE-Sephadex-binding and

SP-Sephadex-binding groups [19] The best-characterized AFP,

HPLC12, is the only a member of the QAE group, all

others (HPLC1–11) belonging to the SP group The

QAE and SP isoforms share only 55% identity among

their primary sequences, although there is 90% identity

among the SP isoforms [20] Immunological

cross-reac-tivity is also different between the QAE and SP

iso-forms [5] Post-translational modification has been

reported only for the SP isoforms [19] Of the residues

that form the ice-binding surface, the hydrophilic ones

are almost uniformly conserved in the QAE and SP

isoforms, whereas the hydrophobic residues tend to be

changeable The same has been found for the AB1 and

AB2 isoforms from Austrolycicthys brachycephalus [3]

They share 83% sequential identity with the same

hydrophilic residues at the ice-binding surface, whereas

the hydrophobic residues Pro19 and Ala20 located on

the surface of AB1 are replaced with Ile19 and Val20

in AB2, respectively At a concentration of

20 mgÆmL)1, TH activity of AB1 is 1.27
C, which is

slightly higher than 1.17
C of AB2 Lycodichthys

dearborni also has three major AFPs (RD1, RD2, and

RD3) [21] RD3 is an exceptional isoform which

com-prises two type III AFP domains connected in tandem

through a nine-residue linker The sequential identity

between RD1 and RD2 is 94%, and the former shares

98% and 85% identities with the N-terminal and

C-terminal domains of RD3, respectively (for RD2,

the corresponding identities are 94% and 77%,

respectively) For RD1 and RD2, the amino acid

replacements of the hydrophobic residues (20th and

41st) have been identified for the ice-binding surface

At a concentration of 10 mgÆmL)1, the TH activities of

RD1 and RD2 are almost identical (0.95
C and

0.90
C, respectively), whereas RD3 has a slightly

lower activity of 0.81
C Overall, the type III AFP

isoforms differ in their hydrophobic residues but not

significantly in their hydrophilic residues with regard

to the ice-binding surface One may speculate that

these differences may differentiate the antifreeze

func-tions of the isoforms However, not much is known

about the relationship between TH activity and the

isoforms, especially the existence of a co-operative

effect of the isoforms in the QAE and SP groups

We recently found that a significant amount of type III AFP can be purified from the minced muscles of Notched-fin eelpout (Zoarces elongatus Kner), which lives off the north east coast of Japan (
40
of lati-tude) where the temperature of the seawater is)1.7
C

in mid-winter This fish naturally expresses at least 13 AFP isoforms (nfeAFPs) The primary sequences of two major species were examined using a protein se-quencer, and 13 sequences were independently deter-mined by analysis of cDNA sequences using the mRNA library constructed for the fresh liver of this fish By comparing all of the identified sequences of nfeAFPs with those of ordinary type III AFP hetero-geneity [19], 13 isoforms, denoted nfeAFP1–13, were categorized into SP and QAE groups The latter were further divided into QAE1 and QAE2 groups which are mainly distinguished by 10 characteristic residues The QAE1 isoforms exhibit high sequence similarity to

a well-known QAE isoform, HPLC12, from ocean pout Here we expressed five recombinant isoforms, nfeAFP2 and nfeAFP6 (SP group), nfeAFP8 (QAE1 group), nfeAFP11 and nfeAFP13 (QAE2 group) so as

to compare the TH activity between the groups TH activity was also measured for a mixture of the SP and QAE isoforms to examine their co-operative effect on antifreeze activity

Results

Preparation and sequence analysis of nfeAFPs Figure 1 shows the elution profile of the soluble pro-teins in the muscle homogenate of Notched-fin eelpout

on the cation-exchange column The mixture of

Fig 1 Elution profile obtained for the muscle homogenate of Notched-fin eelpout by cation-exchange chromatography (High-S column) A linear gradient (dotted line) from 0 to 500 m M NaCl at a flow rate of 1 mLÆmin)1was used to elute the fractions containing the isoforms of nfeAFP.

nfeAFP isoforms was eluted by application of a

con-centration gradient of NaCl (
50–250 mm) Their

activity was confirmed by photomicroscopic

observa-tion of the bipyramidal ice crystal The mixture of

nfeAFPs migrated as a
4.5-kDa band on SDS ⁄

PAGE, which is smaller than the actual molecular

mass (
7 kDa), as previously observed [5,22] The

mixture of the two fractionated nfeAFPs was resolved

into six major and eight minor peaks labeled 1–14 in

Fig 2A by RP-HPLC using a C18 reverse-phase

col-umn The molecular mass of
6600 was estimated to

the peaks 1–10, and
7000 to the peaks 11–14 by

MALDI-TOF MS An elongated bipyramidal ice

crys-tal in the c-axis direction was observed (Fig 2B) for

peaks 1–10 eluted in the 41–54% concentration range

of acetonitrile (the hexagonal shape observed for peak

1 is attributable to the low protein concentration) In

contrast, a thick bipyramidal ice crystal was detected

for peaks 11–14 eluted in the range above 54%

aceto-nitrile We analysed the amino acid sequence for peak

2 in Fig 2A (later assigned to nfeAFP6) and its cleaved

fragments using a conventional sequence analyzer As

shown in Fig 3, the amino acid sequence of residues

1–56 was determined (denoted A1) for a nondigested

component of the peak Figure 3 also shows the

sequence determinations of five fragments of peak 2

(denoted N1–N5) cleaved by asparaginyl endopeptidase

and five fragments of the peak cleaved by TPCK tryp-sin (T1–T5) By comparing the cleaved sequences with each other, the N1 and T1 fragments were assigned to the N-terminal sequence, and N5 and T5 to the C-ter-minal sequence The C-terminus was assigned to Ala

as it would not be cleaved by the proteases used The other sequential overlaps between A1, N2, N3, N4, T2, T3, and T4 allowed us to identify that A1 consists

of 56 of the 64 residues of this isoform, in which the unknown 35th and 48th residues were assigned to Glu and Val, respectively The information on the com-plete sequence analyzed for peak 2 allowed us to iden-tify that the isoform belongs to the type III AFP the N-terminus of which is unblocked, probably the SP group isoform identified from ocean pout [19] An incomplete 62-residue sequence determined for a non-digested component of peak 8 in Fig 2A is also shown in Fig 3 (labeled A2) It should be noted that both A1 and A2 have Gly at the N-terminus, which is similarly identified in the SP isoforms from ocean pout

cDNA cloning and sequence alignment

of nfeAFPs The complete amino acid sequences of the 13 isoforms

of nfeAFP were determined based on the cDNA

A

B

Fig 2 (A) HPLC purification of the isoforms

of type III AFP from Notched-fin eelpout The peaks containing the HPLC-pure isoforms are labeled 1–14 The amino acid sequence was analysed for peaks 2 and 8 (Figs 3 and 4) (B) Photomicrographs of the single ice crystal observed for each HPLC-pure isoform dissolved in 0.1 M NH 4 HCO 3 (pH 7.9).

library as described in Experimental procedures The

N-terminal residue of the 13 intact AFPs was

determined by reference to the ordinary type III AFP

sequences and the identified signal sequences of

A1 and A2: i.e MKSVILTGLFFVLLCVDHMSSA

for nfeAFP11 and 12 and MKSVILTGLLFVLLCVD

HMSSA for nfeAFP1–10, 13 The signal sequence of

nfeAFP2 was only partially identified from cDNA

The sequence A1 is identical with the 1st 65 residues

of nfeAFP6 with the 66th lysine residue at the

C-ter-minus, which is presumably removed by the

post-translational processing [19] Although such processing

can be assumed for nfeAFP1–5 and nfeAFP10 which

have Lys at their C-termini, we assumed a

Lys-con-taining sequence as the complete amino acid sequence

of the isoforms, as no direct evidence has been

obtained so far to indicate their deletion For

nfeAFP6, the effect of a C-terminal lysine on activity

was examined, as described later Interestingly, the

sequence A2 is not identical with any of the nfeAFP

sequences listed in Fig 4, although it shows maximum

similarity to nfeAFP2: Ala23, Ala35, and Met37 of A2

are substituted by Glu, Val, and Ala of nfeAFP2,

respectively Most of the isoforms are about 65

resi-dues in length; only nfeAFP13 consists of 70 resiresi-dues

nfeAFP13 exceptionally contains two cysteines (Cys64

and Cys66), the sequence of which shows high

similar-ity to an isoform denoted ‘genomic k3’ identified from

ocean pout [20] The presently identified 13 isoforms

of nfeAFP do not exhibit 100% identity with any

other reported sequences of type III AFP

Based on the sequence similarity to the known type

III AFP isoforms from Atlantic ocean pout [20], the

13 isoforms of nfeAFP were categorized into SP and

QAE groups as listed in Fig 4, for which there is a

typical difference in the 34th to 37th residues; therefore

sequence gaps (–) were introduced into positions 37

and 34 for the SP and QAE groups, respectively A1, A2, and nfeAFP1–6 were categorized into the SP group and nfeAFP7–13 into the QAE group For clar-ity, Gly1 of the SP group is defined as the 2nd residue

in the present study We further divided the QAE iso-forms into two subgroups, QAE1 (nfeAFP7–10) and QAE2 (nfeAFP11–13), which are distinguished by 10 characteristic residues colored blue and green in Fig 4

The sequence identity within the 13 isoforms is
48%

The identity is 77% when compared within the SP iso-forms, 76% within the QAE1 isoiso-forms, and 91%

within the QAE2 isoforms, respectively With regard

to the putative ice-binding residues indicated with asterisks (*) in Fig 4, the 42nd residue is different between the SP and QAE groups In addition, Gln9, Leu19, Val20 and Val41 in the QAE1 group are replaced by Val9, Val19, Gly20 and Ile41, respectively,

in the QAE2 group It is worth noting that Gln9 is conserved in all known isoforms of type III AFP, except HPLC7 which contains Arg9 [20] Overall, the hydrophilic residues are mostly conserved among the nfeAFP isoforms for the ice-binding residues (for example, Gln9, Asn14, Thr15, Thr18, and Gln44)

However, significant amino acid replacements are iden-tified for the hydrophobic residues located at the 13th, 19th, 20th, and 41st positions

Antifreeze activity of recombinant nfeAFPs

To examine the relationship between TH activity and sequence diversity of type III AFPs, the following five isoforms, listed in Fig 4, were expressed and purified:

nfeAFP2 (SP group); nfeAFP6, a major isoform of the muscle homogenate (SP group); nfeAFP8, the sequence of which is similar to HPLC12 (QAE1 group); nfeAFP11, a Val9-containing isoform (QAE2 group); nfeAFP13, the largest isoform containing

Peak 2

A1 GESVVATQLIPINTALTPAMMEGKVTNPSGIPFAxMSQIVGKQVNTPxAKGQTLMP -N1 GESVVATQLIPIN

N2 TALTPAMMEGKVTNPSGIPFAxMSQIVGxQVN N3 TALTPAMMEGKVTN

N4 PSGIPFAEMSQIVGxQVNTPVAxGQTL -N5 MVKTYVPA T1 GESVVATQLIPINTALTPAMMEGK

T2 VTNPSGIPFAEMSQ T3 QVNTPVAK T4 GQTLMPGMVK T5 TYVPA

Peak 8

A2 GQSVVATQLIPMNTALTPAMMAGKVTNPSGIPFAEMSQIVGKQVNVIVAKGQTLMPDMVKTY -

Fig 3 Amino acid sequences of the cleaved

peptides obtained from the HPLC peaks.

A1, 56 amino acid residues of peak 2

deter-mined by the sequencer; N1–N5, fragments

of peak 2 cleaved by asparaginyl

endopepti-dase; T1–T5, fragments of peak 2 cleaved

by TPCK trypsin; A2, 62 amino acid residues

of peak 8 determined by sequencer.

Val9 and two cysteines (Cys64 and Cys66) (QAE2

group) NfeAFP6 and nfeAFP8 exhibit the highest

sequence identity with the isoforms HPLC6 and

HPLC12 from M americanus, respectively (the amino

acid sequences of HPLC6 and HPLC12 are listed in

Fig 4) Again both nfeAFP2 and nfeAFP6 were

expressed with C-terminal lysines We also expressed

nfeAFP6minusLys66 (nfeAFP6DLys; SP group) to

examine the effect of the C-terminal lysine on

activ-ity For nfeAFP13, TH activity was determined in the

presence and absence of reductant (dithiothreitol), as

it can form multimers via intermolecular disulfide

bridges (Fig 5)

Figure 6 shows the molar concentration dependence

of TH activity for the six genetically produced

iso-forms of nfeAFP examined using the Vogel

osmo-meter A nonlinear profile of TH activity typical of

ordinary AFPs was identified for nfeAFP8 (QAE1

group), although its maximum activity (
0.7
C) was

slightly lower than that reported for HPLC12, which

was determined using the Clifton nanoliter

osomome-ter [7] A similar profile was detected for nfeAFP13

(QAE2 group) in the absence of reductant The

addi-tion of reductant significantly lowered the activity of

nfeAFP13, indicating that the monomer is less active

than when a small amount of multimers is present

(Fig 5) An extremely low level of TH activity was

detected for another QAE2 isoform, nfeAFP11 We

detected no appreciable TH activity for nfeAFP2,

nfeAFP6, and nfeAFP6DLys (SP group) The lack of a

significant difference between nfeAFP6 and

nfeAFP6DLys suggests that a lysine at the C-terminus

does not affect the ice-binding function, which is con-sistent with previous indications for ocean pout AFPs [19] It is worth noting that nfeAFP2 and nfeAFP6 both form a folded structure, which was evidenced by

a number of secondary shifts observed throughout the range of their 1H-NMR spectra TH activity at a con-centration of 1.0 mm was 0.60
C for nfeAFP8 (QAE1 isoform), 0.44
C (multimers) and 0.11
C (monomer) for nfeAFP13 (QAE2 isoform), 0.02
C for nfeAFP11 (QAE2 isoform), and almost zero for nfeAFPs 2 and 6 (SP isoforms) Formation of an elongated bipyramidal ice crystal was observed for the solutions of nfeAFP2 (0.3 mm) and nfeAFP6 (3.75 mm) at a cooling rate of

Fig 4 Alignment of amino acid of sequence

of type III AFP identified from Notched-fin eelpout (nfeAFP) Spaces are introduced to optimize the alignment The yellow color indicates the conserved residues of the nfeAFP isoforms Ten characteristic residues colored blue and green distinguish the QAE1 and QAE2 groups The putative ice-binding residues are indicated with asterisks The sequences of HPLC6 and HPLC12 isoforms from M americanus are also shown for comparison.

Fig 5 SDS ⁄ PAGE (16% gel) of a purified cysteine-containing QAE2 isoform of type III AFP from Notched-fin eelpout (nfeAFP13) Lane A, 0.3 m M nfeAFP13 in the presence of 10 m M of dithiothrei-tol (DTT); lane B, 0.3 m M nfeAFP13 in the absence of dithiothreitol The protein standards (MW) are indicated on the left The mono-mer of nfeAFP13 is the dominant species irrespective of the addi-tion of reductant.

0.01–0.05
CÆmin)1, suggesting that these species have

the ability to inhibit ice growth

We further examined whether the addition of a

small amount (0.2 mm) of ‘active’ nfeAFP8 influences

the TH activity of ‘less active’ nfeAFP6

Approxi-mately 0.10
C of TH activity was detected (Fig 6)

As shown in Fig 7, the TH activity of the less active

nfeAFP6 shows clear concentration dependence in the

presence of 0.2 mm nfeAFP8 (maximum TH¼

0.60
C) A similar TH profile was obtained for

nfeAFP6DLys in the presence of 0.2 mm of nfeAFP8

These data indicate that ‘less active’ AFP isoforms can

exert a substantial level of antifreeze activity after the

addition of a small amount of ‘active’ isoform The

less active nfeAFP6 does not, however, become active

after the addition of another less active isoform,

nfeAFP2 (Fig 7) No significant difference was

detec-ted between nfeAFP6 and nfeAFP6DLys, which

con-firms that the C-terminal lysine does not directly

participate in the antifreeze function

Discussion

We have identified new isoforms of type III AFP from

Notched-fin eelpout living off the Japanese coast at

40
of latitude The isoforms were categorized into

SP and QAE groups according to the known difference

in residues 34–37 The QAE group was further divided

into two subgroups distinguished by 10 characteristic residues (Fig 4) A QAE1 isoform, nfeAFP8, exhibits the highest sequence identity with HPLC12, which was previously identified from Atlantic ocean pout (Ala24, Met30, Val35, Glu58, and Thr64 in nfeAFP8 are replaced by Ser24, Val30, Glu35, Asp58, and Pro64

in HPLC12) Therefore we categorized HPLC12 into the QAE1 group It has been shown that HPLC12 is eluted last during HPLC [19], implying that the QAE isoform is more hydrophobic than the SP isoform Although we did not complete the assignment of the HPLC peaks (Fig 2) to the present isoforms, we detec-ted a difference in molecular mass between HPLC peaks 1–10 (
6600 Da) and peaks 11–13 (
7000 Da) (Fig 2) Hence, it is highly likely that QAE isoforms

of nfeAFP are eluted later in HPLC (Fig 2), which agrees with the earlier elution of the SP isoforms (for example, peak 2, nfeAFP6) In addition, the bipyrami-dal ice crystals observed for the HPLC-pure samples labeled 11–14 have a low c⁄ a axial ratio (i.e they are thick in shape) compared with samples 2–10 of Fig 2

A low c⁄ a axial ratio has been suggested to be a sign

of higher TH activity [8,18,23] Hence, one can specu-late that samples 11–14 correspond to QAE isoforms

of nfeAFP, whereas the others correspond to SP iso-forms, and the TH activity of the QAE isoform is higher than that of the SP isoform

Fig 6 TH activity measured using an osmometer (model OM 802;

Vogel) as a function of concentration (m M ) of type III AFP

iso-forms, nfeAFP2 (h), nfeAFP6 (r), nfeAFP6DLys (e), nfeAFP8

(·), nfeAFP11 (s), nfeAFP13 in the absence of dithiothreitol (n),

and nfeAFP13 in the presence of dithiothreitol (m) The

measure-ment was repeated three times using fresh samples, and mean

values were plotted with error bars.

Fig 7 TH activity measured as a function of concentration (mM) of type III AFP isoforms: nfeAFP6 (m) and nfeAFP6DLys (s) in the presence of 0.2 m M nfeAFP8; nfeAFP6 (r) and nfeAFP6DLys (h) in the presence of 0.2 m M nfeAFP2 The measurements were repea-ted three times using fresh samples and mean values were plotrepea-ted with error bars.

Although we identified ice-shaping activity for the

SP isoforms of nfeAFP (Fig 2), their TH activities

were below the level of detection of the instrument

used (Vogel osmometer) (Fig 6) TH activity could

also not be detected for 15Eklac, a 15-residue

syn-thetic peptide corresponding to the 11-residue

repeat-ing unit of a 36-residue type I AFP, usrepeat-ing the Clifton

nanoliter osmometer [24] This minimized peptide

forms a vertex-flat bipyramid of ice crystal, for which

it was assumed imperfect inhibition of the crystal

growth of f2021g plane, a target ice surface of an

intact type I AFP Such an unsatisfactory level of ice

growth inhibition leading to nondetection of TH

activity is also assumed for the present SP isoform

Obviously, there are many candidates among the

resi-dues that could offer such character to the SP

iso-form However, the residues located in the functional

site (i.e ice-binding region) are thought to be the

prime candidates, as variants of type III AFP form a

mostly identical 3D structure irrespective of the

amino acid replacements [7–10,13,14] As shown in

Fig 4 (*), replacements between the three isoforms

are identified for the hydrophobic residues located at

positions 9, 13, 19, 20, 41, and 42 of the putative

ice-binding sequence A clear difference between the SP

and QAE isoforms is identified for the 42nd residue;

Ser42 in QAE isoforms is replaced by Gly42 in SP

isoforms However, a mutant of HPLC12 (QAE1),

S42G, has been reported to exhibit full TH activity

[11], therefore the character of the SP isoform cannot

be ascribed to Gly42 alone

It has also been reported for HPLC12 that

replace-ment of a hydrophobic residue with a smaller aliphatic

residue results in loss of TH activity; 23–28% loss was

reported for the mutants L19A, V20A, and V41A

Furthermore, 55% loss of activity has been reported

for the double mutant L10A⁄ I13A, and 75% loss for

L19A⁄ V41A [18] Leu19 and Val20 of the QAE1

iso-form are replaced by Pro19 and Ala20 in the presently

examined SP isoforms, nfeAFP2 and nfeAFP6 The

replacement of these residues presumably alters

the ice-binding character of the AFP isoform A

‘semi-reversible’ ice-binding model for the kinetics of

AFP-induced ice growth inhibition has been proposed

[25,26], which includes the following adsorption steps

of AFP: (a) attachment to the ice–water interface;

(b) rearrangement of adsorbed molecules by

diffu-sion, reorientation, and⁄ or conformational change; (c)

detachment from the interface

Again ice-shaping ability is suggested to be a

charac-teristic of all isoforms of nfeAFP (Fig 2) The

hydro-phobic residues located at positions 9, 13, 19, 20, 41,

and 42 are structured so as to surround the ice-binding

surface in the 3D structure of type III AFP (PDB Code

¼ 1MSI) Hence, it can be speculated that a set of hydrophobic residues in an isoform differentiates the surface complementarity with the target plane of the ice crystal, which affects adsorption steps (b) and (c) espe-cially, resulting in a different level of TH activity

A clear concentration dependence of TH activity was observed for a QAE1 isoform (nfeAFP8) simi-larly to HPLC12, whereas it was below detectable level for the QAE2 isoforms (nfeAFP11 and nfeAFP13) (Fig 6) It should be mentioned that Gln9, a highly conserved residue in the known type III AFPs, is replaced with Val9 in the QAE2 iso-forms The Cys-containing QAE2 isoform, nfeAFP13, has the ability to form trimers and tetramers in the absence of reductant (dithiothreitol), although mono-mers are predominantly formed irrespective of the presence of reductant (Fig 5) The difference in TH activity of nfeAFP13 in the presence and absence of dithiothreitol (Fig 6) implies that the TH activity of the monomer (+ dithiothreitol) is enhanced approxi-mately threefold by the presence of a small amount

of trimers and tetramers (– dithiothreitol) We previ-ously reported that an artificial multimer of type III AFP has considerably increased TH activity com-pared with the monomer [27] In addition, for type I AFP isoforms from winter flounder consisting of 11 amino acid repeats, a longer isoform consisting of four repeats showed almost twice the activity of the ordinary three-repeat isoforms [28] For b-helical AFP isoforms from spruce budworm, the activity of CfAFP-501 (
12 kDa) with two additional loops is twofold higher than that of CfAFP-337 (
9 kDa) [29] Baardsnes et al [30] recently reported that the increase in activity of the type III AFP multimer results from an increase in the size of the ice-binding surface These results suggest that, although the monomer of nfeAFP13 does not exert substantial TH activity by itself, it is enhanced with the help of a small amount of multimers A similar observation was reported for antifreeze glycoprotein (AFGP) from Antarctic cod, Pagothenia borchgrevinki, the molecular mass of which is in the range 2.6–33 kDa: the low

TH activity of smaller sized AFGP (
3 kDa) is markedly enhanced by the addition of the larger spe-cies (
10.5 kDa) [31]

We found that TH activity of a SP isoform, nfeAFP6, is greatly enhanced by, and showed clear concentration dependence on, the addition of a small amount of a QAE1 isoform, nfeAFP8 (Fig 7) This is similar to the case of the QAE2 isoform, nfeAFP13; the activity of its monomer was enhanced by the pres-ence of a small amount of the multimer Although

there is no direct experimental evidence to explain the

mechanism, one can assume the following co-operative

ice-binding mechanism: (a) the ‘active’ AFP isoform

(QAE1) firstly adsorbs to the ice crystal, which

decrea-ses its growing speed and lowers the energy barrier to

allow adsorption of the ‘less active’ isoform; (b) the

less active isoform (SP or QAE2) can then adsorb to

the ‘open space’ between the prebound AFPs of the ice

crystal surface; (c) most of the nfeAFP isoforms

adsorb to the growth-terminated ice crystal in the final

state This hypothesis is comparable to that of

Bur-cham et al [31] They assumed that stabilization of the

antifreeze action of small (weak) species of AFGP

(AFGP6-8) by large (strong) species (AFGP1-5)

pro-duces co-operative coverage of a seed ice crystal,

thereby preventing further crystal growth When we

added a less active SP isoform (nfeAFP2) to another

less active SP isoform (nfeAFP6) (Fig 7), the

co-operative ice binding did not occur, resulting in no

substantial TH activity for the less active isoform

It is interesting to note that the less active SP

iso-form (nfeAFP6) is the major AFP species produced in

Notched-fin eelpout (Fig 2) A similar observation

was reported for AFGP; the concentration of the

smal-ler sized AFGP in the serum of Antarctic cod is more

than eightfold that of the larger AFGP components

[32] Ocean pout also produces many SP isoforms (11

species) compared with one QAE isoform [20] Why is

the less active SP isoform of type III AFP dominant in

the fish serum? In winter, the level of expression of

AFPs is maximized to
20–30 mgÆmL)1 in the serum

[33] The SP isoform is less hydrophobic, as evidenced

by the present HPLC experiment (Fig 2), and indeed

is more soluble than the QAE isoform (data not

shown) Hence, a plausible explanation for the

sub-stantial content of the SP isoform is as follows: (a) the

SP isoform is generated to reduce the hydrophobicity

and improve the solubility of type III AFP isoforms as

a whole at the expense of surface complementarity; (b)

accordingly, the SP isoform is the species that cannot

exert substantial TH activity by itself; (c) although the

antifreeze activity of the SP isoform is low, it can exert

TH activity with the help of the QAE isoform The

production of a number of AFP isoforms may be a

strategy to retain AFPs in the serum at a sufficiently

high concentration to prevent the serum from freezing

To summarize, we have succeeded in identifying 13

new isoforms of type III AFP from Notched-fin

eel-pout, which were categorized into three groups: SP,

QAE1, and QAE2 We detected a clear difference in

TH activity between the isoforms, although ice-binding

ability was detected for all of them This was ascribed

to differences in hydrophobic residues located in the

ice-binding region The less active SP isoform becomes active on addition of a small amount of the active QAE1 isoform, whereas it does not become active on addition of another less active SP isoform These results suggest that isoforms of type III AFP co-opera-tively exert the antifreeze function

Experimental procedures

Purification and sequence analysis of nfeAFPs Type III AFP was purified from the muscle of Notched-fin eelpout After removal of the head and gut, the meat of the fish was homogenized with water using an electric mixer [tissue⁄ water ratio (g) ¼ 1 : 1] The homogenate was

centri-fuged at 3000 g for 30 min, and the supernatant obtained

dialyzed against 50 mm sodium acetate (pH 3.7) overnight

at 4
C After removal of the precipitate formed during dialysis, the AFP-containing solution was loaded on to a high-S column (1.0· 5.0 cm; Bio-Rad, Hercules, CA, USA), and the column-bound AFPs were eluted with a lin-ear NaCl gradient (0–0.5 m) in 50 mm sodium acetate buf-fer (pH 3.7) The fractions containing the isolated AFP were collected and further chromatographed by RP-HPLC using a C18reverse-phase column (TOSOH, Tokyo, Japan; TSKgel ODS-80Ts) with a linear gradient of 0–100% aceto-nitrile in 0.1% trifluoroacetic acid For observation of ice-crystal morphology, the lyophilized powder of the AFP collected was dissolved in 0.1 m NH4HCO3 For amino acid sequence analysis, the AFP was digested with asparaginyl endopeptidase (TaKaRa, Shiga, Japan) at 37
C for 24 h in

50 mm sodium acetate (pH 5.0) containing 10 mm dithio-threitol and 1 mm EDTA Another digested fragment was obtained by incubation with TPCK trypsin (Pierce, Rock-ford, IL, USA) for 24 h at 37
C in 0.1 m NH4HCO3 (pH 7.9) These digested fragments were separated by RP-HPLC Sequence analysis of the fragments and native AFP was carried out with an Applied Biosystem (Foster City, CA, USA) 491 protein sequencer

PCR amplification and cDNA sequencing

of nfeAFP Fresh liver from a Notched-fin eelpout caught in the middle

of the winter of 2001 was cut into 0.5-cm-thick slices, and soaked in RNA stabilization reagent (Qiagen, Hilden, Germany) overnight at )4
C After being frozen at )80
C, 25 mg frozen liver was completely ground with liquid nitrogen using a mortar and pestle, and homogenized using a shredder spin column (Qiagen) Total RNA was then isolated from the liver using an RNeasy Protect kit (Qiagen) mRNA was purified from total RNA using the Oligotex-dT30 mRNA Purification kit (TaKaRa) A cDNA library was generated from 1.6 lg mRNA with the

ZAP-cDNA Synthesis kit (Stratagene, La Jolla, CA, USA).

PCR was performed for a major cDNA consisting of

500 bp purified from the cDNA library using the templates

of Ex-Taq DNA polymerase (TaKaRa), oligo-dT linker

primer (5¢-GAGAGAACTAGTCTCGAGTTT-3¢), and the

synthetic primer of the adapter sequence (5¢-TCGGG

AATTCGGCACGAGG-3¢) The annealing sites of these

primers were connected to 3¢-terminus and 5¢-terminus of

cDNA The PCR conditions are as follows: denaturing at

94
C for 1 min, 2 cycles pre-extending at 94
C for 1 min,

extending at 56
C and 72
C for 1 min each, and 28 cycles

extending at 94
C, 50
C, and 72
C for 1 min each The

PCR products obtained were purified and ligated into

pGEM-T Easy (Promega, Madison, WI, USA) The cloned

DNAs encoding nfeAFP isoforms were sequenced using the

ABI Prism Big dye terminator cycle sequencing kit and

ABI 3100 genetic analyzer (Applied Biosystems)

Expressions and purification of the five

recombinant nfeAFPs

The five DNA fragments encoding nfeAFP2, 6, 8, 11, and

13, from which the signal sequence was removed, were

amplified by PCR using cloning plasmid vectors, and

ligated into pET20b (Novagen) with the restriction

enzymes, NdeI and XhoI The plasmid-DNAs obtained were

transformed into Esherichia coli strain BL21 (DE3), and

the transformants were grown at 28
C in Luria–Bertani

medium supplemented with 100 lgÆmL)1 ampicillin, until

cell growth reached the early stationary phase To induce

expression of the recombinant nfeAFPs, 0.5 mm isopropyl

thio-b-d-galactoside was added to the medium, and the

cul-tures were grown at 28
C overnight Most of the nfeAFPs

were expressed as the soluble form, but nfeAFP13, which

contains two cysteines (Cys64 and Cys66), was only

expressed as the inclusion body Hence, the nfeAFP13

sam-ple was prepared by the methods described in [15] with the

following modifications: (a) the inclusion body was

dis-solved in 100 mm Tris⁄ HCl (pH 8.5) containing 6 m

guani-dine hydrochloride and 10 mm 2-mercaptoethanol; (b)

nfeAFP13 was then refolded with 50 mm K2HPO4⁄ 100 mm

NaCl⁄ 10 mm 2-mercaptoethanol (pH 10.7) The nfeAFP

isoforms obtained were dialyzed against 50 mm sodium

acetate buffer (pH 3.7) and then purified by

cation-exchange chromatography with a linear NaCl gradient

(0–0.5 m) in 50 mm sodium acetate buffer (pH 3.7) (50 mm

sodium citrate buffer, pH 2.9, was used for the purification

of nfeAFP11) The fractions containing the purified

nfeAFPs were stored and dialyzed against 0.1 m NH4HCO3

(pH 7.9) The purity was checked by SDS⁄ PAGE (16% gel)

[34] It should be noted that the purified nfeAFP13

appeared to form multimers via intermolecular disulfide

bridges; nfeAFP forms a monomer in the presence of

reductant (+ dithiothreitol), while its trimer and tetramer

were also generated in the absence of reductant as shown in

Fig 5 Therefore, for the measurement of TH activity, nfeAFP13 was reduced for 12 h at 4
C with 0.1 m

NH4HCO3 (pH 7.9) containing 10 mm dithiothreitol, and activity was measured on fresh samples

Measurement of ice crystal morphology and TH activity

Ice-crystal morphology was observed using an in-house photomicroscope system consisting of a Leica DMLB 100 photomicroscope equipped with a Linkam LK600 (liquid nitrogen-type) temperature controller and a CCD camera

A droplet (
0.5 lL) of the sample solution was frozen and then heated until a single ice crystal was observed sepa-rately in the solution by manipulation of the temperature controller The change in morphology of a single ice crystal into a hexagonal bipyramid caused by the accumulation of AFP on the ice surfaces was then observed at a cooling rate

of 0.05
C per minute

The Clifton nanoliter osmometer (Clifton Technical Phys-ics, Hartford, NY, USA) is usually used to determine the ice-growth-initiation temperature, which is defined as the freezing point (Tf) of the AFP solution However, this instru-ment is no longer available commercially, so we used the fol-lowing method with an alternative osmometer (model OM 802; Vogel): (a) 50 lL sample solution was placed in the cooling pot ()7
C) of the instrument; (b) the frosty probe was put manually into the supercooled sample to initiate water freezing; (c) the increase in solution temperature caused by latent heat emission was monitored; (d) the plat-eau temperature was determined to be the Tf point of the sample All the nfeAFP samples were dissolved in 0.1 m

NH4HCO3 (pH 7.9) for the Tf measurement The melting temperature (Tm) of the AFP solutions was carefully deter-mined by monitoring the melting of an ice crystal on the photomicroscope stage, which was manipulated by the LK600 temperature controller The measurement of Tfand

Tmwas repeated three times using fresh samples, and mean values were used for determination of TH activity (TH¼|Tm – Tf|) It has been documented that the TH value determined using this osmometer is slightly lower than that determined using the Clifton nanoliter osmometer [13,27,30]

Acknowledgements

We thank Dr Tamotsu Hoshino, Michiko Kiriaki, and Mineko Fjiwara for analysis of amino acid sequences, and Yumika Miura for analysis of DNA sequences

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