Tài liệu Báo cáo khoa học: A zymogen form of masquerade-like serine proteinase homologue is cleaved during pro-phenoloxidase activation by Ca2+ in coleopteran and Tenebrio molitor larvae docx

A zymogen form of masquerade-like serine proteinase homologueKum Young Lee1, Rong Zhang1, Moon Suk Kim1, Ji Won Park1, Ho Young Park2, Shun-ichiro Kawabata3 and Bok Luel Lee1 1 College o

A zymogen form of masquerade-like serine proteinase homologue

Kum Young Lee1, Rong Zhang1, Moon Suk Kim1, Ji Won Park1, Ho Young Park2, Shun-ichiro Kawabata3 and Bok Luel Lee1

1

College of Pharmacy, Pusan National University, Jangjeon Dong, Korea;2Insect Resources Laboratory, Korea Research Institute

of Bioscience and Biotechnology, Taejeon, Korea;3Department of Biology, Kyushu University, Fukuoka, Japan

To elucidate the biochemical activation mechanism of the

insect pro-phenoloxidase (pro-PO) system, we purified a

45-kDa protein to homogeneity from the hemolymph of

Tenebrio molitor(mealworm) larvae, and cloned its cDNA

The overall structure of the 45-kDa protein is similar to

Drosophilamasquerade serine proteinase homologue, which

is an essential component in Drosophila muscle development

This Tenebrio masquerade-like serine proteinase homologue

(Tm-mas) contains a trypsin-like serine proteinase domain in

the C-terminal region, except for the substitution of Ser to Gly

at the active site triad, and a disulfide-knotted domain at the

amino-terminal region When the purified 45-kDa Tm-mas

was incubated with CM-Toyopearl eluate solution

contain-ing pro-PO and other pro-PO activatcontain-ing factors, the resultcontain-ing

phenoloxidase (PO) activity was shown to be independent of

Ca2+ This suggests that the purified 45-kDa Tm-mas is an

activated form of pro-PO activating factor The55-kDa zymogen form of Tm-mas was detected in the hemolymph when PO activity was not evident However, when Tenebrio hemolymph was incubated with Ca2+, a 79-kDa Tenebrio pro-PO and the 55-kDa zymogen Tm-mas converted to 76-kDa PO and 45-kDa Tm-mas, respectively, with detect-able PO activity Furthermore, when Tenebrio hemolymph was incubated with Ca2+and b-1,3-glucan, the conversion of pro-PO to PO and the 55-kDa zymogen Tm-mas to the 45-kDa protein, was faster than in the presence of Ca2+only These results suggest that the cleavage of the 55-kDa zymogen

of Tm-mas by a limited proteolysis is necessary for PO activity, and the Tm-mas is a pro-PO activating cofactor Keywords: innate immunity; insect; Masquerade; pro-phe-noloxidase; serine proteinase homologue

The pro-phenoloxidase (pro-PO) activation system in

arthropods is an important part of the host immune

defence, where it functions to detect and kill invading

pathogens It is also a good model system to elucidate the

pattern recognition mechanism of nonself pattern

recogni-tion proteins, such as peptidoglycan recognirecogni-tion protein or

b-1,3-glucan binding protein, which are part of the innate

immune reaction [1,2] However, the molecular mechanism

of pro-PO activation remains poorly understood Previously,

we reported the structures and functions of two pro-PO

activating factors (PPAF-I and PPAF-II) from the

coleopt-eran insect, Holotrichia diomphalia larvae [3–5] PPAF-I is

an easter-type serine proteinase and PPAF-II is a

masqu-erade-like serine proteinase homologue We have

demon-strated that they are necessary for activating the phenoloxidase (PO) cascade, by in vitro reconstitution experiments However, we did not determine the biological functions of PPAF-II during Holotrichia pro-PO activation Two questions remain to be answered: why is a masquer-ade-like serine proteinase homologue a requirement for PO activity, and how and why is there cross-talk between a masquerade-like serine proteinase homologue and an eas-ter-type serine proteinase during the pro-PO activation reaction? Another key question that remains is how these pro-PO activating factors can be activated in response to microbial infection One hypothesis is that pattern recogni-tion proteins make a complex with pro-PO activating enzyme(s) and microbial cell wall components, and then activation of pro-PO activating enzyme(s) zymogen con-verts pro-PO to active PO by limited proteolysis [6–8] Recently we reported that in larvae of the coleopteran insect, Tenebrio molitor, pro-PO was activated by b-1,3-glucan and Ca2+, and the activated PO was involved in the cell/clump/cell adhesion reaction as well as in the synthesis

of melanin [9] This insect has one kind of pro-PO; however, two kinds of pro-PO were found in H diomphalia larvae [9,10] If it is possible to purify pro-PO activating factors from T molitor larvae, we can explain the difference between pro-PO activation reactions in the one-pro-PO and two-pro-PO systems in T molitor and H diomphalia larvae, respectively Also, we have reported the presence of early staged encapsulation-relating proteins in T molitor larvae [11,12] Given the crucial nature of the melanotic

Correspondence to B L Lee, College of Pharmacy, Pusan National

University, Jangjeon Dong, Kumjeong Ku, Busan, 609-735, Korea.

Fax: +82 51 581 1508, E-mail: brlee@pusan.ac.kr

Abbreviations: PO, phenoloxidase; pro-PO, pro-phenoloxidase;

Tm-mas, Tenebrio masquerade-like serine proteinase homologue;

TCA, trichloroacetic acid; PVDF, polyvinylidene difluoride; PPAF,

pro-phenoloxidase activating factors; P-NPGB,

p-nitrophenyl-p¢-guanidinobenzoate; p-APMSF, p-amidinophenyl-methanesulfonyl

fluoride.

Note: The nucleotide sequence data reported in this paper will appear

in the DDBJ, EMBL and GenBank Nucleotide Sequence Database

with the accession number AB084067.

(Received 29 April 2002, revised 9 July 2002, accepted 29 July 2002)

encapsulation response in insect immunity, it is of great

importance to purify pro-PO activating factors and to

determine the Tenebrio pro-PO activation mechanism at the

molecular level

This paper describes the purification and cDNA cloning

of a 45-kDa protein that acts as a pro-PO activating

cofactor in T molitor larvae The deduced amino acid

sequence of the 45-kDa protein derived from the cDNA

revealed that this protein exhibits high sequence similarity

with Drosophila masquerade serine proteinase homologue

[13] The biological function of the purified 45-kDa protein

was examined during pro-PO activation reaction

M A T E R I A L S A N D M E T H O D S

Animals, collection of hemolymph and hemocytes

T molitorlarvae (mealworm) were maintained on a

labo-ratory bench in terraria containing wheat bran Vegetables

were placed on top of the bran to provide water

Hemo-lymph and hemocytes were collected as described previously

[9] Briefly, to harvest the hemolymph, larvae were injected

with 50 lL of modified anticoagulation buffer (30 mM

trisodium citrate, 26 mM citric acid, 20 mM EDTA,

15 mMNaCl, pH 5.5) using a 25-G needle The tail of each

larva was cut off using fine scissors and the extruding

hemolymph was placed in a test tube on ice The collected

crude hemolymph was centrifuged at 203 000 g for 4 h at

4C The supernatant then stored at)80 C until use

Assay of PO activity

PO activity was determined according to our previously

published method [3] Briefly, 30 lL crude hemolymph

(50 lg protein) or fractionated solution from column

chro-matography were preincubated in 85 lL 20 mMTris/HCl

pH 8.0 containing 1 lg b-1,3-glucan for 10 min at 30C,

and then 400 lL substrate solution (1 mM4-methylcatechol,

2 mM4-hydroxyproline ethylester in 20 mMTris/HCl buffer

pH 8.0, containing 5 mMCaCl2) was added to the reaction

mixture After incubation at 30C for 10 min, the increase

in absorbance at 520 nm was measured using a Shimadzu

spectrophotometer PO activity was expressed as the change

in absorbance at 520 nm per 10 min incubation (A520per

10 min per 30 lL) To examine the effects of the 45-kDa

protein on PO activity, a mixture of CM-Toyopearl eluate

solution (15 lg) and the purified 45-kDa protein (1 lg) were

added to 400 lL substrate solution in the presence or

absence of 5 mM CaCl2 After incubation at 30C for

10 min, the increase in absorbance at 520 nm was measured

as described above

Purification of 45-kDaTenebrio masquerade protein

(Tm-mas)

To purify 45-kDa Tm-mas from Tenebrio larvae, 50 mL

hemolymph supernatant solution were collected following

ultracentrifugation, and then concentrated by ultrafiltration

through a membrane filter (Amicon, YM-10) About 3 mL

of the concentrated solution was applied to a Toyopearl

HW-55S size exclusion column (1.5· 50 cm) equilibrated

with buffer A (50 mMTris/HCl pH 6.5, containing 5 mM

EDTA), and eluted with buffer A at a flow rate of

12 mLÆh)1 Fractions specifically showing PO activity in the presence of b-1,3-glucan and Ca2+were pooled The pooled solution was named HW-55S solution and was used to purify 45-kDa protein Fifty mL HW-55S solution (300 mg) were loaded onto a Toyopearl CM-650M cation exchange column (1· 11 cm) equilibrated with buffer A, and washed with buffer A until no absorbance could be detected at

280 nm The flow-through fraction and washing solution were combined, and concentrated by ultrafiltration The resulting ultrafiltered concentrated solution (3 mL) was diluted 10 times with buffer A and loaded onto a Blue-Sepharose (1.0· 5.2 cm) hydrophobic column equilibrated with buffer A The column was washed with the same buffer

at a flow rate of 0.2 mLÆmin)1, until there was no absorbance at 280 nm, and then it was eluted with buffer

A containing 0.2MNaCl The eluted solution was concen-trated by repeated ultrafiltration to exclude NaCl To confirm the presence of the 45-kDa protein, PO activity was examined by incubating together the concentrated 0.2M

NaCl elution solutions from the Blue-Sepharose and Toyopearl CM-650M columns For further purification of the 45-kDa protein, the concentrated elution solution (7 mg) from Blue-Sepharose was loaded onto a Butyl-Toyopearl FPLC column equilibrated with buffer B [50 mM

phosphate pH 7.0, containing 1.7M (NH4)2SO4] The column was eluted with a linear gradient of ammonium sulfate (from 1.7 to 0M) at a flow rate of 0.3 mLÆmin)1 The fractions containing an approximately 45-kDa protein as determined by SDS/PAGE (reducing conditions) were pooled and concentrated by ultrafiltration kit (YM-10 membrane) Fractions containing 45-kDa protein from the Butyl-Toyopearl FPLC column were pooled and applied to

a Mono-Q FPLC anion exchange column equilibrated with buffer C (20 mMTris/HCl pH 7.4) The absorbed proteins were eluted with a linear gradient of 0–1MNaCl containing buffer C Fractions exhibiting PO activity when incubated with 0.2M NaCl eluate from the Toyopearl CM-650M column, were pooled and concentrated by ultrafiltration The purified Tm-mas was reduced and S-pyridylated according to a previously published method [14] The S-pyridylated 45-kDa Tm-mas was digested with trypsin, and the resulting peptides were separated by HPLC on a C18

reverse-phase column (Gilson) To determine the N-termi-nal sequence of the Tm-mas, it was subjected to SDS/PAGE under reducing conditions The band of Tm-mas was blotted onto a poly(vinylidene difluoride) (PVDF) mem-brane (Millipore), cut out, and subjected to automated amino acid sequence analysis [15] The protein concentra-tions were determined by the method of Lowry et al [16] using BSA as a standard

Molecular cloning of 45-kDa Tm-mas

A cDNA library from T molitor larvae was constructed by using a ZAP-cDNA synthesis kit (Stratagene) To screen the Tm-mas clones, we performed immunoscreening by using the affinity-purified 45-kDa Tm-mas antibody Following isopropyl-b-D-thiogalactoside induction, 5· 104 plaques were screened with an affinity-purified antibody raised against the purified 45-kDa Tm-mas A secondary antibody (alkaline phosphatase-conjugated anti-rabbit IgG, Bio-Rad) was used at a dilution of 1 : 1000 Phage DNA was isolated from phage lysates by using a lambda DNA preparation kit

(Biometra) according to the manufacturer’s instructions.

We analysed all of the plaques showing positive signals on

immunoscreening We sequenced the clones according to

the dideoxy chain-termination method of Sanger et al [17]

The amino acid sequence of the 45-kDa Tm-mas was

compared with the protein sequence database of the

National Center for Biotechnology Information using

GENETYX(Software Development Co., Ltd, Tokyo)

Antibody and immunoblotting

Antibody against the Tm-mas was raised by injecting 10 lg

of the purified protein into a male albino rabbit with

complete Freund’s adjuvant and giving a booster injection

of the same amount of protein 14 days later [18] The

resulting antibody was affinity-purified as described

previ-ously [11] For immunoblotting, the proteins separated by

SDS/PAGE were transferred electrophoretically to a PVDF

membrane which was then blocked by immersion in 5%

skimmed milk solution containing 1% horse serum for 12 h

The membrane was then transferred to rinse solution I

(20 mMTris/HCl pH 7.5, containing 150 mMNaCl, 0.1%

Tween-20, 2.5% skimmed milk) containing the

affinity-purified antibody against the 45-kDa protein (50 ngÆmL)1)

and incubated at 4C for 2 h The bound antibody was

identified using the Western Blot Chemiluminescence

Reagent kit (NENTMLife Sciences)

The gel mobility changes of 45-kDa Tm-mas

and pro-PO during pro-PO activation

To examine the biological functions of the 45-kDa Tm-mas

during pro-PO activation, the PO activity was measured by

using HW-55S solution in the presence of b-1,3-glucan and

Ca2+ To examine the cleavage of 55-kDa Tm-mas at

different times, reaction mixture showing PO activity was

precipitated by trichloroacetic acid (TCA) and 45-kDa

Tm-mas was identified by Western blotting To examine the

effects of serine proteinase inhibitors on the proteolysis of

55-kDa Tm-mas and PO activity, HW-55S solution was

preincubated for 30 min with 200 lM

p-nitrophenyl-p¢-guanidinobenzoate (p-NPGB) and 200 lM

p-amidino-phenyl-methanesulfonyl fluoride (p-APMSF), and then

reaction mixture was further incubated in the presence of

b-1,3-glucan and Ca2+ As a control, HW-55S solution was

preincubated without inhibitors After 60 min incubation,

PO activity was measured and the cleaved 45-kDa Tm-mas

was identified by Western blotting

R E S U L T S

Purification of 45-kDa Tm-mas

The purification procedures of Tm-mas are shown in

Fig 1A To isolate the pro-PO activating factors (PPAFs)

from Tenebrio larval hemolymph, we first prepared

HW-55S solution showing PO activity in the presence of

b-1,3-glucan and Ca2+, by using a Toyopearl HW-55S column

As shown in Fig 1B, HW-55S solution exhibited the most

rapid increase in PO activity in the presence of b-1,3-glucan

and Ca2+ Under the same conditions, PO activity was not

observed with b-1,3-glucan only However, Ca2+ in the

absence of b-1,3-glucan activated pro-PO, but more slowly

than a combination of b-1,3-glucan and Ca2+ This result suggests that HW-55S solution contained all the necessary PPAFs, pro-PO and b-1,3-glucan recognition protein(s) To purify PPAF, HW-55S solution was first subjected to a Toyopearl CM-650 column chromatography and the flow-through fraction was purified by hydrophobic chro-matography on Blue-Sepharose CL-6B followed on Butyl-Sepharose The active fractions showing PO activity were further purified by Mono-Q FPLC column (indicated as a bar in Fig 2A) The purified protein migrated as a single band of 45-kDa on SDS/PAGE (12% acrylamide) under reducing conditions (Fig 2B) Two-hundred mL hemo-lymph from 4000 larvae with a protein content of 2000 mg yielded 30 lg of the purified 45-kDa Tm-mas The purified Tm-mas was used for raising polyclonal antibody The Tenebrio 79-kDa pro-PO was purified according to our previously published methods [9]

Fig 1.

1 (A) Procedures used to purify 45-kDa Tm-mas from the hemolymph of T molitor larvae and (B) the PO activity of HW-55S solution PO activity was measured by incubation with 30 lL HW-55S solution with Ca2+and b-1,3-glucan (d), Ca2+only (m), b-1,3-glucan only (j) and with neither Ca2+nor b-1,3-glucan (s).

In vitro reconstitution experiments

To confirm the possibility of the purified 45-kDa Tm-mas as

Tenebrio PPAF, we performed in vitro reconstitution

experiments by using collected fractions or the purified

proteins from column chromatography As shown in

Fig 3A, when Toyopearl CM-flow-through and Toyopearl

CM-eluate were incubated in the presence of b-1,3-glucan

and Ca2+, PO activity was clearly shown to be dependent

on b-1,3-glucan and Ca2+(column 5) Tenebrio pro-PO was

localized in Toyopearl CM-eluate solution by Western

blotting analysis (data not shown) Toyopearl

CM-flow-through solution was further purified by Blue-Sepahrose

and Mono-Q FPLC column When the purified Tenebrio

pro-PO from Toyopearl CM-eluate and the purified

Tm-mas from Toyopearl CM-flow-through were incubated,

PO activity was not observed (Fig 3B, column 4) However,

when Toyopearl CM-eluate and the purified Tm-mas were

incubated, PO activity was shown to be independent of

Ca2+(column 5 and 6) These results suggested two things: first, that another protein(s) in Toyopearl CM-eluate might

be necessary for PO activity; second, that the 45-kDa Tm-mas already seemed to be activated from its zymogen form, during the process of column chromatography We examined this latter possibility by Western blotting analysis

As shown in Fig 3C, the affinity-purified antibody raised against the 45-kDa Tm-mas recognized a 45-kDa single band in the Mono-Q fraction (lane 4) However, a 55-kDa protein was recognized in crude hemolymph (lane 1) and Toyopearl CM-flow-through (lane 2) Both the 55-kDa and 45-kDa proteins were recognized in the Blue-Sepharose fraction (lane 3) This result suggests that the purified 45-kDa protein is activated from a precursor 55-kDa zymogen form by limited proteolysis during Blue-Sepharose column and Mono-Q FPLC column chromatography Isolation of cDNA clone for Tm-mas

To determine the whole amino acid sequence of the purified Tm-mas, we first determined three partial amino acid sequences by trypsin digestion as follows: NSQGIDFNLI, GNLYNDIALL and NPNRYLQVGIVA However, an N-terminal sequence could not be obtained due to blockage

To isolate a cDNA clone for the 45-kDa Tm-mas, we immunoscreened the cDNA library of T molitor larvae

Fig 2 (A) Elution pattern of Mono-Q FPLC column and (B) SDS/

PAGE pattern of eachcolumn step during 45-kDa Tm-mas purification.

(A) The Mono-Q column fractions indicated by bars were collected

and used for subsequent experiments (see Materials and methods) (B)

Lane 1, HW-55S solution; lane 2, the eluate solution of Toyopearl

CM-650; lane 3, flow-through fractions of Toyopearl CM-650; lane 4,

eluate solution of Blue-Sepharose CL-6B column, lane 5, active

frac-tion of Mono-Q FPLC column The proteins were analysed by SDS/

PAGE (10% acrylamide) under reducing conditions.

Fig 3 (A) PO activities of HW-55S and fractions of Toyopearl CM-650 column, (B) PO activities between the purified pro-PO and the eluate solution of Toyopearl CM-650, and (C) Western blotting of products during 45-kDa Tm-mas purification (C) Proteins were pre-cipitated with TCA and subjected to SDS/PAGE and then immu-noblotting with affinity-purified antibodies raised against 45-kDa Tm-mas Lane 1, 10 lg hemolymph protein; lane 2, 10 lg flow-through solution of Toyopearl CM-650 column; lane 3, 5 lg eluate solution of Blue-Sepharose column; lane 4, 1 lg of the active fractions

of Mono-Q FPLC column The molecular size markers are indicated

to the right in kDa.

with an affinity-purified antibody against the 45-kDa

Tm-mas, and obtained 10 positive clones The nucleotide

sequence and the deduced amino acid sequence of one of

these clones, named Tm-mas, are shown in Fig 4 This

cDNA contained an open reading frame of 1332 nucleotides

corresponding to 444 amino acid residues with a precise

mass of 48 814 Da The apparent mass of 55-kDa for

Tm-mas on SDS/PAGE is slightly larger than that of the

deduced sequence This mobility pattern is similar to several

other masquerade proteinase homlogue’s [5,19] where the

mass of the purified masquerade-like proteins is higher

under nonreducing than reducing conditions suggesting that

disulfide bonding is responsible for the higher mass The

three chemically determined partial amino acid sequences of

the 45-kDa Tm-mas coincided with the deduced amino acid

sequences in this open reading frame (dotted lines)

There-fore, we concluded that this is a cDNA for the Tm-mas The

Tm-mas has two domains, an N-terminal domain and a

serine proteinase-like domain The hydrophobic first 22

amino acids of the N-terminal end of the protein probably

constitute a signal peptide sequence with a putative signal

peptidase cleavage site between Ala22 and Ile23

(arrow-head) [20] One putative disulfide-knotted motif is present in

the N-terminal domain of the protein The putative catalytic

domain, from Asn176 (arrow) to Glu444, is characteristic of

that found in serine proteinase homologues, as is the

presence of a Gly residue instead of a Ser residue in the

catalytic site The residues of a serine proteinase substrate

binding pocket (open diamond in Fig 5), which determine

the substrate specificity of active serine proteinases, were present in the 45-kDa Tm-mas The six cysteine residues (closed circles in Fig 5), which form three disulfide bridges

in most serine proteinases, were conserved in this 45-kDa Tm-mas There were two potential N-glycosylation sites (Asn-Xaa-Set/Thr, indicated by closed-diamonds in Fig 4)

A homology between the Tm-mas and those in the NCBI database showed that the deduced amino acid sequence of the Tm-mas was similar to Holotrichia 45-kDa protein (Hd-PPAF-II, 59.1%) [5], Tachyplus factor D (Td-D, 38.9%) [21], masquerade of Drosophila melanogaster (Dm-mas, 35.2%) [13], masquerade-like protein of crayfish Pacifasta-cus leniusculus (Pl-mas, 41.2%) [22], mosquito infection-response serine proteinase-like protein (Ag-ispl5, 34.1%) [23], Tenebrio 45-kDa (Tm-45, 46.6%) [5], as well as HolotrichiaPPAF-I (Hd-PPAF-I, 33.3%) [4] and Tachyplus proclotting enzyme (Td-PCE, 31.8%) [24] as shown in Fig 5 The proteins Ag-ispl5, Td-D, Pl-mas, and Dm-mas showed amino acid substitutions of Ser with Gly (or Ala) in the active site triad (arrow) In conclusion, a schematic comparison of the main structural features of Tm-mas with Hd-PPAF-II, AP-ispl5, Tm-45, Td-D and Dm-mas showed

a modified serine proteinase domain at the C terminus, and

a disulfide-knotted motif present in the N terminus Previously we found that a disulfide-knotted motif of Hd-PPAF-I was present in big defensin [25], an antimicro-bial peptide purified from Tachyleus hemocytes Six cysteine residues of the disulfide-knotted motif of Tm-PPAF-I are also conserved with those of other disulfide-knotted motifs

Fig 4 Nucleotide and deduced amino acid

sequences of cloned cDNA encoding the 45-kDa

Tm-mas Numbers of nucleotides starting

from the first base at the 5¢ end are shown on

the left of each line; the deduced amino acid

sequence is numbered from the initiating Met

residue on the right of each line The

chemi-cally determined three partial amino acid

sequences of the 45-kDa Tm-mas are

under-lined by dots The potential attachment sites

for N-linked carbohydrate chains are

indicat-ed by r sites of the catalytic triad of serine

proteinases are shown by s; the arrowhead

indicates the putative cleavage site for the

signal peptide; the arrow indicates the putative

start residue of catalytic domain.

However, the biological function of this motif has not yet

been determined Finally, the purified Tm-mas exhibited no

amidase activity against a variety of commercially available

peptidyl-NH-Mec substrates tested (data not shown)

Determination of Tm-mas localization

To examine the localization of Tm-mas, we firstly prepared

fat body, plasma, hemocyte lysate and hemolymph from

T molitor larvae As shown in Fig 6, no appreciable

amount of 55-kDa zymogen Tm-mas was detected in the

hemocyte lysate or fat body (lanes 2 and 3) A significant

amount of protein, however, was detected in the plasma and

hemolymph (lanes 4 and 5), indicating that Tm-mas was

localized in the plasma

Biochemical characteristics of Tm-mas during pro-PO

activation

To determine the biological function of the purified 45-kDa

Tm-mas in the Tenebrio pro-PO system, we used SDS/

PAGE and Western blotting to assess whether changes in

PO activity were reflected in changes in the gel mobility of

Tenebrio pro-PO and the 55-kDa zymogen Tm-mas As

shown in Fig 7A, 25% of Tenebrio pro-PO from

HW-55S was activated to PO in the presence of Ca2+ after

45 min incubation (lane 6); however, when HW-55S

solution was incubated with b-1,3-glucan and Ca2+,

 50% of pro-PO was activated after 45 min (lane 11)

Under the same conditions, all of the 55-kDa zymogen form

of Tm-mas had converted to 45-kDa Tm-mas by 45 min, in

the presence of b-1,3-glucan and Ca2+(lane 11 in Fig 7B)

The activation ratio of the 55-kDa zymogen form in the

presence of b-1,3-glucan and Ca2+was faster than in the

presence of Ca2+only (compare lane 6 with lane 11 in

Fig 7B) This result suggests that the activation of the 55-kDa zymogen form to the 45-kDa Tm-mas is a requirement for PO activity in the Tenebrio Pro-PO activation system Furthermore, we examined the effects

of serine proteinase inhibitors against proteolysis of the 55-kDa Tm-mas and PO activity by using two kinds of serine proteinase inhibitors, such as p-NPGB and p-APMSF As shown in Fig 7C and D, when HW-55S

Fig 6 Localization of the 55-kDa Tm-mas determined by immuno-blotting Hemolymph was obtained from 150 larvae and centrifuged at

700 g

2 at 4 C for 10 min Precipitated hemocytes were washed with

500 lL anticoagulation buffer (pH 5.5) and suspended again with

500 lL anticoagulation buffer One hundred lL of this suspension provided the total haemocyte component The remaining solution (400 lL) was sonicated for 15 s at 4 C and centrifuged at

15 000 r.p.m (22 000 g) at 4 C for 10 min The supernatant was used

as haemocyte lysate The soluble proteins were precipitated with TCA and subjected to SDS/PAGE and then immunoblotting with affinity-purified antibody raised against the 45-kDa Tm-mas Lane 1, 10 lg protein of flow-through solution from Toyopearl CM-650 column; lane 2, 10 lg of soluble fat body protein; lane 3, 10 lg of soluble haemocyte lysate protein; lane 4, 10 lg of plasma protein; lane 5, 10 lg

of haemolymph protein.

Fig 5 Alignment of the catalytic domains of Tm-mas and Holotrichia 45-kDa protein (Hd-PPAF-II) withcatalytic domains of known serine proteinase homologues Tachyplus factor-D (Tt-D), Drosophila masquerade (Dm-mas), crayfish masquerade (Pl-mas), Anopheles immune response serine proteinase-like protein (Ap-ispl5) and known serine proteinase, such as Holotrichia PPAF-I (Hd-PPAF-I) and Tachyplus proclotting enzyme (Tt-PCE) Numbers refer to the predicted protein sequence Stars indicate the residues of the catalytic triad of serine proteinase The conserved cysteine residues are indicated by d; residues conserved in all sequences are shown within boxes; e indicate the positions of residues known to occupy the substrate binding pockets of trypsin; the arrow indicates the substitution residue of the catalytic triad of serine proteinase Gaps were introduced to obtain maximal sequence similarity.

solution was preincubated with p-NPGB and p-APMSF,

and then calcium and b-1,3-glucan were added to HW-55S

solution, PO activity and proteolysis of the 55-kDa Tm-mas

were not observed (Fig 7C, column 3 and Fig 7D, lane 3)

However, PO activity and the cleavage of the 55-kDa

Tm-mas were clearly shown when calcium and b-1,3-glucan

were added to HW-55S solution in the absence of inhibitors

(Fig 7C, column 2 and Fig 7D, lane 2) These results

suggest that the cleavage of the 55-kDa Tm-mas might be

induced by unidentified serine proteinase Also, it was

confirmed that PO activity is shown when the 55-kDa

Tm-mas is cleaved to the 45 kDa Tm-mas

D I S C U S S I O N

In this study, we isolated a novel 45-kDa protein from the

hemolymph of T molitor larvae, which showed high

homology (35% sequence identity) with Drosophila

mas-querade serine proteinase homologue We have called this

protein Tenebrio masquerade-like proteinase homologue

(Tm-mas) This is also the first report to demonstrate that a

novel masquerade-like serine proteinase homologue

zymo-gen (55-kDa Tm-mas) is cleaved to 45-kDa Tm-mas as a

prerequisite for PO activity Several kinds of serine

proteinase homologue have been purified already from

vertebrates and invertebrates, and they have been suggested

to perform different biological functions, including

antim-icrobial activities (e.g horseshoecrab factor D [21] and

human azurocidin [26]), or by acting as adhesion molecules

(e.g Drosophila masquerade [13], Pacifastacus

masquerade-like protein [22], glutacin [27] and neurotactin [28]), immune

molecules (e.g mosquito ispl5 [23], Holotrichia PPAF-II

[5]), growth factors (e.g human hepatocyte growth factor

[29]) or as pattern recognition proteins in crayfish [19] As

their name indicates, all known serine proteinase

homo-logues are very similar to serine proteinases, differing only in the substitution of their catalytic residues

It is suggested that the pro-PO activating system, which functions in nonself recognition and defence responses in invertebrates, is composed of an enzyme cascade consisting

of pattern recognition proteins, several serine proteinases and pro-PO [1,2] Recently our group and three other groups have reported that Drosophila easter-type serine proteinases with disulfide-knotted domain(s) are involved in the pro-PO activation system [4,30–32] Recently we have reported that Holotrichia masquerade-like PPAF-II (Hd-PPAF-II) is also engaged in Holotrichia pro-PO activation and is cleaved at Arg99–Glu100 by an easter-type serine

Fig 8 Amino acid sequence comparison of the cleavage sites for Tm-mas and Hd-PPAF-II The arrow indicates the cleavage site of Hd-PPAF-II by Hd-PPAF-I.

Fig 7 Western blotting of (A) Tenebrio 79-kDa pro-PO, and (B)

55-kDa Tm-mas in HW-55S solution by incubation withCa2+ and

b-1,3-glucan and the effects of serine proteinase inhibitors on (C) PO

activity and (D) proteolysis of 55-kDa Tm-mas PO activity of HW-55S

solution was measured as described in Fig 1 The reaction mixtures at

different times were precipitated with TCA and subjected to SDS/

PAGE and then immunoblotting with the affinity-purified antibody

raised against the Tenebrio 79-kDa pro-PO and 45-kDa Tm-mas (A)

The 79-kDa and 76-kDa bars indicate Tenebrio pro-PO and PO,

respectively (B) The 55-kDa and 45-kDa bars indicate the zymogen

form and cleaved protein of 45-kDa Tm-mas, respectively Lane 1,

30 lL HW-55S solution was incubated with neither Ca2+nor

b-1,3-glucan for 60 min; lane 2, incubation with b-1,3-b-1,3-glucan only for

60 min; lane 3, 4, 5, 6 and 7, incubation with Ca2+only for 10, 20, 30,

45, 60 min, respectively; lane 8, 9, 10, 11 and 12, incubation with Ca2+

and b-1,3-glucan for 10, 20, 30, 45, 60 min, respectively (C)

Incuba-tion condiIncuba-tions with serine proteinase inhibitors were described in

Materials and methods PO activity of HW-55S solution with or

without inhibitors was measured as described in Fig 1 Column 1,

after 0 min incubation without inhibitors; column 2, after 60 min

incubation without inhibitors; column 3, after 60 min incubation with

inhibitors D, The reaction mixtures of Fig 7C at different times were

precipitated with TCA and subjected to SDS/PAGE and then

immunoblotting with the affinity-purified antibody raised against the

45-kDa Tm-mas.

proteinase [5] To address the possibility that Tm-mas also

has a similar cleavage site to Holotrichia masquerade-like

PPAF-II, we have compared the Tm-mas amino acid

sequence with the sequence in the vicinity of the

Hd-PPAF-II cleavage site As shown in Fig 8, the tentative cleavage

site of Lys98-Glu99 in Tm-mas is perfectly conserved in

Holotrichia masquerade-like PPAF-II, suggesting that a

serine proteinase cleaves the Lys98–Glu99 site of Tm-mas

However, in this study, the identity of the serine proteinase

that cleaves the 55-kDa zymogen form, has not been

elucidated Further studies focusing on this unidentified

serine proteinase will provide clues to understanding the

biological function of serine proteinase homologues in the

pro-PO activation system

Previously, we reported the cDNA sequence of another

masquerade-like serine proteinase homologue (Tm-45

protein), obtained from a Tenebrio cDNA library that

had been cloned following screening with Holotrichia

PPAF-II antibody [5] The deduced amino acid sequence

of Tm-45 protein has 46.6% similarity with the purified

45-kDa Tm-mas described in the present report (data not

shown) Although the Tm-45 protein has not yet been

purified, any differences we may be able to detect between

the biological functions of Tm-45 and Tm-mas will be

important for understanding the details of the Tenebrio

pro-PO system

One interesting point regarding masquerade-like serine

proteinase homologues, is that horseshoecrab factor D

copurified with a serpin during purification procedures [21],

which suggests that masquerade-like serine proteinases

might make a complex with serpin During insect pro-PO

activation in response to invasion by a microbial pathogen,

there is a possibility that zymogen Tm-mas could be released

from a serpin, and that the released zymogen form of

Tm-mas could be cleaved at the Arg/Lys–Glu site by an

easter-type serine proteinase The cleaved Tm-mas would

then be able to cause pro-PO activation by acting as a

cofactor Further studies will be required to test this

hypothesis

A C K N O W L E D G E M E N T S

This work was supported mainly by research grants No

R01-1999-00118 from the KOSEF to B L Lee This work was also supported by

KOSEF grant (No 20005-209-02-2) to B L Lee.

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