Identification of a cathepsin D potentially involved in H2Acleavage from scallop Chlamys farreri

Chenghua Li Æ Huan Zhang Æ Ling Li ÆLinsheng Song

Received: 18 December 2008 / Accepted: 2 April 2009 / Published online: 19 April 2009

� Springer Science+Business Media B.V. 2009

Abstract We report here a cDNA and its deduced amino

acid sequence encoding a cathepsin D-like, aspartic prote-

ase from Chlamys farreri (denoted as CfCD) by expressed

sequence tag and rapid amplification of cDNA ends tech-

niques. The cDNA of CfCD consisted of 1,810 nucleotides

with a canonical polyadenylation signal sequence

AATAAA and a polyA tail, encoding a short signal peptide

of 18 amino acids, a pro-enzyme peptide of 29 amino acid

residues, and a mature enzyme of 349 residues. The

deduced amino acid sequence of CfCD was significant

homology to CDs from human, fish and invertebrates. Two

conserved catalytic motifs (VFDTGSSNLWV and AI-

ADTGTSLLVG) and two potential N-glycosylation sites

were also identified in the deduced amino acid sequence of

CfCD. All this characteristics indicated CfCD should be a

member of CDs family. The mRNA spatial expression of

CfCD in mantle, gonad, gill, hemocytes, hepatopancreas

and adductor muscle was examined by quantitative real-

time PCR. mRNA transcripts of CfCD could be detected in

all tissues with the highest expression level in hepatopan-

creas. After 8 h Vibrio anguillarum challenge, the expres-

sion level of CfCD changed significantly in all examined

tissues except mantle (P = 0.183) and hemocytes (P =

0.069). The information generated in the present study

would be helpful for future studies aiming at investigating

the detailed functions of cathepsin D from marine

invertebrates.

Keywords Chlamys farrei � Cathepsin D �Tissue expression � Innate immunity

Introduction

Cathepsin D (EC 3.4.23.5) (CD), the best well-known

cathepsins, was a glycoprotein with mannose-containing

oligosaccharides attached at active positions Asn67 and

Asn183 [1]. It was reported that CD was firstly synthesized

in rough endoplasmic reticulum as preprocathepsin D

(pCD). After removal of signal peptide, the 52 kDa pro-

cathepsin D is targeted to intracellular vesicular structures

in mammals [1]. The enzyme exists in their processed form

as disulfide-linked heavy and light chain subunits with

molecular weights ranging from 20 to 35 kDa in mammals.

While, fish CDs appear to lack the sequences necessary to

generate a two-chain form [2]. Herring [3] and Antarctic

icefish CDs have a single chain form, which is *40 kDa in

molecular mass [4].

Cathepsin D has broad peptide bond specificity similar

to pepsin and has been shown to be involved in various

physiological pathways, such as intracellular catabolic

proteolysis [5, 6], extracellular proteolysis [7] and pro-

cessing, secretion and activation of enzymes and hormones

[7, 8]. In recent years, the association of CD with host

innate immunity has received increased attention. Numer-

ous studies also found that pCD/CD level represents an

independent prognostic factor in a variety of cancers and is

therefore considered to be a potential target of anti-cancer

therapy [1]. CD could process antigens for presentation to

C. Li (&)

Yantai Institute of Coastal Zone Research for Sustainable

Development, Chinese Academy of Sciences, 26 Yinhai Road,

Laishan District, 264003 Yantai, China

e-mail: chli@yic.ac.cn

H. Zhang � L. Li � L. Song (&)

Key Laboratory of Experimental Marine Biology, Institute of

Oceanology, Chinese Academy of Sciences, 7 Nanhai Rd.,

266071 Qingdao, China

e-mail: lshsong@ms.qdio.ac.cn

123

Mol Biol Rep (2010) 37:1451–1460

DOI 10.1007/s11033-009-9534-2

immune system [2]. CD was demonstrated to be the main

enzyme involved in the degradation of alpha-synuclein and

generation of its carboxy-terminally truncated species,

which play a key role in control of Parkinson’s disease

development in human [9]. In catfish Parasilur asotus,

AMP named Parasin I derived from H2A, was yielded by

CD through specific cleaving the Ser19_Arg20 bond of

histone H2A [10]. We had demonstrated that the N-ter-

minus of scallop H2A was a potential AMP with significant

antibacterial activity [11]. However, the protease respon-

sible for the generation of the AMP has not yet been

identified to our knowledge. The main objectives of this

study are: (1) to clone the full-length cDNA of CD from

Chlamys farreri (denoted as CfCD); (2) to characterize its

tissue expression profile; (3) to clarify its similarity to CD

involved in H2A cleavage.

Materials and methods

Scallops

The scallops C. farreri (shell length 5–10 cm) were pur-

chased from Qingdao, Shandong Province, China, and

cultured in the aerated seawater at 20–23�C for a week

before processing. For the Vibrio anguillarum challenge

experiment, the scallops were cultured in seawater with

high density of V. anguillarum (109 CFU ml-1), and a

group of uninfected scallops were used as control. The

infected scallops were randomly sampled at 8 h and cen-

trifuged at 1,000g, 4�C for 10 min to harvest the hemo-

cytes. There were five replicates for tissue RNA extraction.

cDNA library construction and EST analysis

A cDNA library was constructed from the whole body of a

scallop challenged by V. anguillarum, using the ZAP-cDNA

synthesis kit and ZAP-cDNA GigapackIII Gold cloning kit

(Stratagene). Random sequencing of the library using T3

primer yielded 6,935 successful sequencing reactions. An

EST of 502 bp (clone no. c1333ct348cn367) was highly

similar to previously identified CD from Bombyx mori

(AAY43135) and Penaeus monodon (ABQ10738). There-

fore, this EST sequence was selected for further cloning of

the full length cDNA of cathepsin D in C. farreri.

RNA isolation and cDNA synthesis

Total RNA was isolated from scallop hemocytes using the

TRIzol reagent (Invitrogen). First cDNA synthesis was

carried out with the DNase I (Promega)-treated total RNA

(1 lg) as template and oligo (dT) primer or gene specific

primer (Table 1). The reactions were incubated at 42�C for

1 h, terminated by heating at 95�C for 5 min, and subse-

quently stored at -80�C. For 50 RACE, Terminal deoxy-

nucleotidyl transferase (TdT) (Takara) was used to add

homopolymer dCTP tails to the 50 end of the purified first-

strand cDNA.

Cloning of the full-length CfCD

Two specific primers, sense primer P1 (50-GACAAGATTT

CAAGTCTCCCACC-30) and reverse primer P2 (50-CGTA

GGAGAAGTTGCCAGAATAG-30), were designed based

on the sequence of EST to clone the full sequence of CfCD.

Table 1 Sequence data

used in phylogenetic

and multiple alignment

analysis

Species Common name Accession number Properity

Aedes aegypti Egypt mosquito Q03168 Cathepsin D

Bombyx mori Domestic silkworm AAY43135 Cathepsin D

Penaeus monodon Black tiger shrimp ABQ10738 Cathepsin D

Apriona germari Mulberry longicorn beetle AAL51056 Cathepsin D

Drosophila melanogaster Fruit fly NP_652013 Cathepsin D

Takifugu rubripes Fugu rubripes BAD69801 Cathepsin D

Gallus gallus Chicken NP_990508 Cathepsin D

Danio rerio Zebrafish CAK05390 Cathepsin D

Oncorhynchus mykiss Rainbow trout AAC60301 Cathepsin D

Xenopus tropicalis Silurana tropicalis AAH61433 Cathepsin D

Schistosoma mansoni Blood fluke AAB63442 Cathepsin D

Homo sapiens Human AAV38957 Cathepsin D

Mus musculus House mouse NP_034113 Cathepsin D

Hynobius leechii Gensan salamander AAD33219 Cathepsin D

Silurus asotus Amur catfish AAM62283 Cathepsin D

Homo sapiens Human P14091 Cathepsin E

Takifugu rubripes Fugu rubripes BAD69802 Cathepsin D2

1452 Mol Biol Rep (2010) 37:1451–1460

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PCR reactions to get the 50 and 30 end cDNA of CfCD were

performed in a PTC-100 Programmable Thermal Control-

ler Cycler (MJ Research) using sense primer T3 and

reverse primer P2 or P1 and T7 in a 25 ll reaction volume

containing 2.5 ll of 109 PCR buffer, 1.5 ll of MgCl2(25 mmol l-1), 2.0 ll of dNTP (2.5 mmol l-1), 1.0 ll of

each primer (10 lmol l-1), 15.8 ll of PCR-grade water,

0.2 ll of Taq polymerase (Takara) (5 U ll-1) and 1 ll of

cDNA mix. The PCR temperature profile was 94�C for

5 min followed by 34 cycles of 94�C for 40 s, 58�C for

40 s, 72�C for 1 min and the final extension step at 72�C

for 10 min. The PCR products were gel-purified and cloned

into pMD18-T simple vector (Takara, Japan). After trans-

formed into the competent cells of Escherichia coli

Top10F0, the positive recombinants were identified through

anti-Amp selection and PCR screening with M13-47

(50-CGCCAGGGTTTTCCCAGTCACGAC-30) and RV-M

(50-GAGCGGATAACAATTTCACACAGG-30) primers. Three

of the positive clones were sequenced on an ABI3730

Automated Sequencer (Applied Biosystem).

Sequence analysis of CfCD

The CfCD gene sequence was analyzed using the BLAST

algorithm at NCBI web site (http://www.ncbi.nlm.nih.gov/

blast), and the deduced amino acid sequence was analyzed

with the Expert Protein Analysis System (http://www.

expasy.org/). The percentages of similarity and identity of

full-length amino acid sequences between CfCD and CD

proteins from other organisms were calculated by the

Identity and Similarity Analysis program (http://www.

biosoft.net/sms/index.html). The potential glycosylation

sites was forecasted by NetNGlyc 1.0 Server (http://www.

cbs.dtu.dk/services/NetNGlyc/). The molecular weight was

assessed by SMS software (http://www.bio-soft.net/sms/).

SignalIP 3.0 program was utilized to predict the presence

and location of signal peptide, and the cleavage site

in amino acid sequences (http://www.cbs.dtu.dk/services/

SignalP/).

Quantification analysis of CfCD expression

by quantitative real time RT-PCR

The expression of CfCD transcript in hemocytes after

Vibrio challenge was measured by quantitative real time

RT-PCR. Total RNA was extracted according to the pro-

tocol of TRIzol (Invitrogen). Single-strand cDNA was

synthesized as mentioned above with the DNase I-treated

total RNA as template and oligo (dT) primer.

The quantitative real time RT-PCR was carried out in an

ABI PRISM 7300 Sequence Detection System (Applied

Biosystems), and performed in a total volume of 25 ll,

containing the 12.5 ll of 29 SYBR Green Master Mix

(Applied Biosystems), 5 ll of the diluted cDNA mix, l ll

of each of primers (0.4 lmol l-1), 5.5 ll of DEPC-treated

water. A Gene-specific primers pairs (P3: 50-TCAAGTA

GGCGGAAAGGCATCAG-30, P4: 50-GGCACATCAATA

CCAGCAAACCC-30) were used to amplify a product of

300 bp. A constitutive expression gene, the beta-actin

gene, was used as an internal control to verify the quality of

RNA and adjust the cDNA templates (P5:50-TATGCCCT

CCCTCACGCTAT-30, P6: 50-GCCAGACTCGTCGTAT

TCCT-30). The thermal profile for real time PCR was 50�C

for 2 min and 95�C for 10 min followed by 40 cycles of

95�C for 15 s and 59�C for 1 min. Dissociation curve

analysis of amplification products was performed at the end

of each PCR reaction to confirm that only one PCR product

was amplified and detected. After the PCR program, data

were analyzed with the ABI 7300 SDS software (Applied

Biosystems). To maintain consistency, the baseline was set

automatically by the software. The comparative Ct method

was used to analyze the relative expression levels of CfCD

as reported by Li et al. [12]. All data were given in terms of

relative mRNA expression as means ± SE. The results

were subjected to analysis of t test, and the P values \0.05

were considered statistically significant.

Results and discussion

Cloning and sequencing analysis of CfCD cDNA

An 1,810 bp nucleotide sequence representing the complete

cDNA sequence of CfCD was obtained by overlapping EST

and the fragments amplified by RACE. The sequence was

deposited in GenBank under accession no. EU935468. The

deduced amino acid sequence of CfCD was shown in Fig. 1.

The complete sequence of CfCD cDNA contained a 50

untranslated region (UTR) of 15 bp, a 30 UTR of 604 bp

with a canonical polyadenylation signal-sequence AATA

AA and a polyA tail, and an open reading frame (ORF) of

1,191 bp encoding a polypeptide of 396 amino acids with

the predicted molecular weight of 42.78 kDa and the the-

oretical isoelectric point of 6.98. The N-terminus had the

features consistent with a signal peptide with a putative

cleavage site located after position 18 (SSA-LH). The pro-

peptide domain started at position 19 and ended at position

47 (double lined in Fig. 1). The deduced mature peptide

was 37.48 kDa in molecular mass, consistent with fish CDs

[3, 4], indicating CfCD might exist as a single chain form

not as disulfide-linked heavy and light chain subunits in

mammals. The speculation should be further confirmed by

PAGE analysis of native scallop CD. The active enzyme

was highly anionic with a theoretical pI of 4.99, which was

in line with CDs characteristics as an acid protein and dis-

tribution in lysome [13].

Mol Biol Rep (2010) 37:1451–1460 1453

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As a kind of aspartyl proteases, the two con-

served aspartyl proteases active sites were also identified

in CfCD (underlined in Fig. 1). Two catalytic motifs

(VFDTGSSNLWV and AIADTGTSLLVG) were located

from 90 to 100 amino acid residue and 277 to 288

amino acid residue. Two N-glycosylation sites (NGT and

NFS) were also identified from CfCD located at 129

and 242 amino acid residue, respectively (shadowed in

Fig. 1).

Phylogenetic and alignment analysis

Two conserved phylogenetic trees were constructed based

on the amino acid sequences of known CDs from different

Fig. 1 Nucleotide and amino

acid sequences of cathepsin D

from the Chlamys farreri with

flanking 50 and 30 untranslated

regions. Translated amino acids

are placed below the

corresponding codons. In the

30UTR, polyadenylation signals

are in italics and boldface.

Concerning the translated amino

acid sequence, signal peptide

was italics; N-glycosylated sites

at Asparagines were shadowed,

eukaryotic and viral aspartyl

proteases active sites were

underlined, and A1 Propeptide

were double lined

1454 Mol Biol Rep (2010) 37:1451–1460

123

organism (Fig. 2). The overall topology of the two trees

constructed with NJ and UPGMA methods was totally

identical supporting that scallop CD was a member of the

conserved CD family. All the vertebrates CDs were firstly

clustered together and formed a sister group to all the

invertebrates CDs. These two types CDs then clustered

together to separate with outgroups cathepsin D2 and

cathepsin E. In each sister group, the orders of cluster was

in line with the generally accepted phylogenetic relation-

ship, indicating that CD was a potentially candidate

molecular marker for systematic analysis.

ClustalW analysis indicated that the deduced amino acid

sequence of CfCD shared significant homology with other

reported CDs (Fig. 3), such as 81% with CD from Penaeus

monodon; 74% with Drosophila melanogaster; 72% with

Takifugu rubripes; 70% with Mus musculu and Homo

sapiens.

Catalytic motifs, glycosylation site and cysteine residue

were also showed conserved characteristics from alignment

analysis. The first catalytic motif was completely identical in

all organisms. There are only several synonymous mutation

occurred in the second motif. The glycosylation site closest

to the N-terminal was highly conserved in all organisms,

while the second site was replaced by D (shrimp, mosquito

and fish), E (mouse and fruit fly), N (beetle), S (hman) in

some species. Alignment of amino acid residues also indi-

cated the presence and position of disulfide bridges were also

conserved in CfCD, which was consistent with the common

characteristic for aspartic peptidases.

Alignment CfCD with CD involved in H2A cleavage

Significant similarity was also found between CfCD and

catfish CD involved in specific cleavage H2A (Fig. 4). The

corresponding identities or positives are 55 and 71%

respectively, indicating the CfCD was a candidate gene

participated in H2A cleavage in scallop. RNAi strategy

should be employed to further elucidate the real function of

CfCD, emphasizing the H2A N-terminal peptide’s dynamic

change before and after CfCD knock-out.

Fig. 1 continued

Mol Biol Rep (2010) 37:1451–1460 1455

123

Spatial-course expression of CfCD

after Vibrio challenge

To examine the tissues distribution profile of CfCD, total

RNA from the tissues of mantle, gonad, gill, hemocytes,

hepatopancreas and adductor muscle was extracted from an

unchallenged or challenged (8 h after challenge) adult

zhikong scallop. The result was showed in Fig. 5. The

CfCD transcript could be detectable in all the examined

tissues, which was highly consistent with CD expression

profile in other animals. The highest CfCD expression level

was found in hepatopancreas, the counterpart organ to

S.asotus

D.rerio

O.mykiss

T.rubripes

H.leechii

X.tropicalis

G.gallus

H.sapiens

M.musculus

S.mansoni

C.farreri

B.mori

P.monodon

A.germari

A.aegypti

D.melanogaster

CathepsinD2

CathepsinE

100

99

92

57

99

53

89

78

78

94

73 85

99

52

64

0.05

Vertebrates

CDs

Invertebrates

CDs

A

S.asotus

D.rerio

T.rubripes

O.mykiss

H.leechii

X.tropicalis

G.gallus

H.sapiens

M.musculus

S.mansoni

C.farreri

B.mori

A.germari

P.monodon

A.aegypti

D.melanogaster

CathepsinD2

CathepsinE

99

100

86

100

82

97

85

69

100

42

92

86

95

55

98

0.000.050.100.150.200.250.300.35

Vertebrates

CDs

Invertebrates

CDs

B

Fig. 2 Phylogenetic trees

based on amino acid sequences

of CDs with NJ

(a) and UPGMA (b) methods

1456 Mol Biol Rep (2010) 37:1451–1460

123

Fig. 3 Multiple alignment of CfCD with other known CDs. Amino acid residues that are conserved in at least 80% of sequences are shaded in

dark, and similar amino acids are shaded in grey

Mol Biol Rep (2010) 37:1451–1460 1457

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Fig. 3 continued

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vertebrates’ liver. In turbot, the highest expression level

of the CD was also found in liver [14]. After scallop

pathogenic microorganism V. anguillarum challenge, the

expression level of CfCD changed significantly in all

examined tissues except mantle (P = 0.183) and hemo-

cytes (P = 0.069). Based on the fold changes relative to

challenged gonad, the expression of CfCD was most

abundant in unchallenged hepatopancreas by 123.8-fold.

After 8 h Vibrio infection, the scallop CD mRNA in

hepatopancreas decreased to 59.8-fold. The expression

level of CfCD in muscle was 2.4- and 5.1-fold before and

after microbial challenge. The change of expression level

of CD might because of abundant generation of some stress

protein after Vibrio challenge. The different expression

profile in different tissue might be related to the complex

and specific function of CD depending on different species

and cell types, just like cathepsin B did [15].

In conclusion, we reported a pathogen-induced scallop

cathepsin D which has common features to those of other

organisms so far examined and expression analysis sug-

gested that scallop cathepsin D might play a certain role in

scallop immune system. This research established the bases

for further study the detailed functions of cathepsin D from

marine invertebrates.

Fig. 3 continued

Fig. 4 Alignment of CfCD with catfish CD involving in specific cleavage of H2A

Mol Biol Rep (2010) 37:1451–1460 1459

123

Acknowledgments We thank the editor and reviewers for their

valuable comments on earlier versions of our manuscript. This

research was supported by Chinese Academy of Sciences Innovation

Program (AK0911DB-097-3) and Open Grant from Key Laboratory

of Applied Marine Biology to Dr. Li.

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07.018

0

20

40

60

80

100

120

140

160

HA GO MU MA GI HEE

xpre

ssio

n le

vel o

f C

fCD

Untreared tissues

Challenged tissues

** **

*

*

Fig. 5 Tissue expression level

of CfCD before and after

bacterial challenge. HAhemocytes, GO gonad, MUadductor muscle, MA mantle,

GI gill, HE hepatopancreas.

*P \ 0.05, **P \ 0.01

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