Báo cáo khoa học: Molecular cloning and functional expression of a gene encoding an antiarrhythmia peptide derived from the scorpion toxin pptx

Molecular cloning and functional expression of a gene encoding an antiarrhythmia peptide derived from the scorpion toxin Fang Peng1, Xian-Chun Zeng1, Xiao-Hua He1, Jun Pu2, Wen-Xin Li1,

Molecular cloning and functional expression of a gene encoding an antiarrhythmia peptide derived from the scorpion toxin

Fang Peng1, Xian-Chun Zeng1, Xiao-Hua He1, Jun Pu2, Wen-Xin Li1, Zhi-Hui Zhu2and Hui Liu1

1

Department of Biotechnology, College of Life Sciences, Wuhan University, China;2Department of Cardiology, Tongji Hospital, Huazhong University of Science and Technology, Wuhan, China

From a cDNA library of Chinese scorpion Buthus martensii

Karsch, full-length cDNAs of 351 nucleotides encoding

precursors (named BmKIM) that contain signal peptides of

21 amino acid residues, a mature toxin of 61 residues with

four disulfide bridges, and an extra Gly-Lys-Lys tail, were

isolated The genomic sequence of BmKIM was cloned and

sequenced; it consisted of two exons disrupted by an intron

of 1622 bp, the largest known in scorpion toxin genomes,

inserted in the region encoding the signal peptide The

cDNA was expressed in Escherichia coli The recombinant

BmKIM was toxic to both mammal and insects This is the

first report that a toxin with such high sequence homology with an insect-specific depressant toxin group exhibits toxi-city to mammals Using whole cell patch-clamp recording, it was discovered that the recombinant BmKIM inhibited the sodium current in rat dorsal root ganglion neurons and ventricular myocytes and protected against aconitine-induced cardiac arrhythmia

Keywords: sodium current; ventricular myocyte; rat dorsal root ganglion; BmKIM; patch-clamp

Scorpion venom is a rich resource for various bioactive

peptides Accumulated data have demonstrated that

scor-pion neurotoxins affect the ion permeability of excitable

cells by specific interaction with Na+, K+, Ca2+or Cl–

channels [1–3] Scorpion toxins that interact with sodium

channels are composed of 60–70 amino acid residues, which

can be divided into a or b mammal neurotoxins and

classified as excitatory or depressant insect-selective

neuro-toxins according to biological specificity in vivo,

pharmaco-logical and electrophysiopharmaco-logical activity [4,5] The a-toxins

bind to mammalian Na+channels on site 3 in a

voltage-dependent manner and slow their inactivation by

modula-ting their voltage dependence Unlike scorpion a-toxins,

b-toxins bind in a voltage-independent manner to site 4 on

the mammalian Na+ channels and shift the activation

voltage to more negative potentials [6,7] Scorpion insect

toxins are selectively active on lepidopterous and dipterous

insects [8] The excitatory toxins cause a fast excitatory

paralysis in animals and induce repetitive firing in insect

nerves; in contrast, the depressant toxins cause a slow

depressor flaccidity due to depolarization of the nerve

membrane and blockage of the sodium conductance in axons [9,10] Although some toxins act specifically on mammals and insects, others additionally affect both groups and crustaceans [11–13]

Thus far, hundreds of distinct peptides specific for Na+ channels have been purified from 20 to 30 different species

of scorpions; at least 120 complete primary structures have been identified [14,15] Most of the effects of these peptides have been demonstrated in nerve and skeletal muscle and with lower frequency in cardiac muscle even though the incidence of cardio-pulmonary abnormalities induced by the scorpion sting is well documented [16,17] In fact, the concept of toxicity should include not only neurotoxins but also other toxins The Asian scorpion Buthus martensi Karsch (BmK) is not dangerously venomous for mammals;

in fact, its components have demonstrated antihyperalgesic and antiepileptic effect [18,19] In traditional Chinese medicine, BmK has been used for its reversal effects on circulation failure However, the cardiovascular effects of BmK venom have not been systematically studied and the mechanism underlying the alterations in cardiovascular function remains unclear [20] In our present work, we describe the cloning of the gene sequence of BmKIM, the functional expression of the recombinant toxin in Escheri-chia coliand its effect on the sodium channels of neurons and ventricular myocytes

E X P E R I M E N T A L P R O C E D U R E S

Materials Buthus martensiKarsch scorpion were collected from farm areas in Hubei province in China Sarcophaga falculata blowfly larvae, Sprague–Dawley (SD) rats, and albino Kunmingmice were bred in the laboratory E coli strains BL21 and vector pGEX-5x-1 were used for expression

Corrspondence to W.-X Li, Department of Biotechnology,

College of Life Sciences, Wuhan University, Wuhan 430072, China.

Fax: + 86 27 87883833, Tel.: + 86 27 87682831,

E-mail: wxli@whu.edu.cn, zhrpeng@whu.edu.cn

Abbreviations: IPTG, isopropyl thio-b- D -galactoside; GSH,

glutathi-one; GST, glutathione S-transferase; DRG, dorsal root ganglia;

PVC, premature ventricular complex; VT, ventricular tachycardia;

VF, ventricular fibrillation.

Note: The nucleotide sequences reported in this paper have been

submitted to the GenBank with accession numbers AF459791 and

AF459792.

(Received 6 May 2002, revised 16 July 2002, accepted 25 July 2002)

Synthesis of oligonucleotide probe

The oligonucleotide probe used to screen the venom

gland cDNA library, constructed as described previously

[21], was designed according to the conserved region of

the amino acid sequence of insect-specific depressant

toxins (G39–D49) The sequence of the probe was

5¢-GGACTTGCATGCTGGTGTGAAGGCCTTCCTG

AT-3¢ The probe was32P-end-labelled using T4

polynucleo-tide kinase

Screening of the venom gland cDNA library

Ten thousand clones from the venom gland cDNA library

were analyzed by the 32P-end-labelled oligonucleotide

probe High and low density screenings of bacterial colonies

for recombinant plasmids were performed on nylon filters

as described previously [22]

Amplification of genomic DNA of BmKIM

The oligonucleotides used for PCR were the following:

forward primer A1, 5¢-GCCGGATCCTGATTGCCTA

GAAGATGA-3¢; reverse primer A2, 5¢-GCCCTCGAG

TCAACCGCATGTATTACTTTCAG-3¢ The forward

and reverse primers were preceded by BamHI and XhoI

sites (underlined), respectively, to allow ligation into

pBluescript PCR was used to amplify the genomic

DNA encoding the conserved region of BmKIM

precur-sors The scorpion BmK genomic DNA was purified

from the muscle tissue of scorpions as previously

des-cribed [23] and used as the template for PCR The

product was reamplified by a second PCR reaction with a

nested gene-specific primer, 5¢-GCCCTCGAGCACCG

AAGCCTTTGCATTC-3¢ corresponding to the amino acid

sequence K25–Y32 and the same forward primer as the first

PCR

DNA sequence analysis

Nucleotide sequence was determined using PE Biosystem

Model 377 DNA sequence with universal T7 promoter

primers according to the method of Sanger

Construction of expression vector pGEX-5x-1-BmKIM

The template used for PCR was the double strand cDNA of

BmKIM inserted into pSPORT I The primers A3 were as

follows: 5¢-GCCGGATCCCCGATGACGATGACAAG

GATGGATATATAAGA-3¢ as forward primer containing

a BamHI restriction enzyme site (underlined) and

corres-ponding to five codons encoding an enterokinase cleavage

site and positions 64–79 of the BmKIM cDNA, i.e

NH2-terminal residues 1–5 of BmKIM The reverse primer

A2, that carried a XhoI restriction enzyme site and stop

codon, corresponded to positions 227–246 of BmKIM

cDNA PCR was performed and the PCR product was

cloned into pGEX-5X-1 after digestion with BamHI and

XhoI and purification The in-frame fusion was confirmed

by the dideoxynucleotide sequencing method with

univer-sal pGEX primers E coli BL21 was used for plasmid

propagation

Cleavage of fusion protein and purification

by affinity chromatography

E colistrain BL21 carrying the pGEX-BmKIM was grown

at 37C in Luria–Bertani broth containing 50 lgÆmL)1 ampicillin When the cell density had reached D600¼ 0.6, induction was initiated by the addition of 1.0 mMisopropyl thio-b-D-galactoside (IPTG) Cells were harvested 4 h after addition of IPTG by centrifugation and resuspension in 1.0 mL water per 50 mL of culture The supernatant from the bacterial cell lysate obtained by sonication was added to prepacked glutathione (GSH) Sepharose 4B and washed in

50 mM Tris/HCl and 10 mM EDTA buffer, adjusted to

pH 8.0 After elution of the unbound proteins, the bound GSH binding protein termed fusion protein glutathione S-transferase-BmKIM (GST-BmKIM) was eluted from the GSH agarose in the same buffer containing 20 mMGSH or cleaved directly by enterokinase The buffer 50 mM Tris/ HCl, 5 mM CaCl2, 40 mM dithiothreitol, and 14 mM EDTA, adjusted to pH 8.0 containing enterokinase was added to the column which bind the fusion protein GST-BmKIM at 26C The eluate containing enterokinase was added again to the column The operation was repeated three times which took about 10 min The cleavage yield was eluted from the GSH gel in the water The recombinant toxin was then purified and desalted using Sephadex G-50 column (100 mL) Fractions were collected and analyzed by SDS/PAGE; the fractions containing the recombinant BmKIM protein were then lyophilized

Amino acid composition analysis and N-terminal sequencing

Amino acid analysis was carried out essentially as described

by Liu & Chang [24] The sample was hydrolyzed by 2% (v/v) tryptamine/4M-toluene-p-sulfonic acid at 110C for

24 h Analysis of this preparation was completed using a 121-MB Beckman amino acid analyzer An Applied Bio-systems 476A sequencer was used for automated Edman degradation The phenylthiohydantoin derivatives of the amino acids were identified using an Applied Biosystems Model 120A PTH-Analyzer

Circular dichroism spectroscopy

CD spectra were obtained between 250 and 180 nm on a Jasco-715 spectropolarimeter using a quartz cell of 2 mm path length with a sample concentration of 0.24 mgÆmL)1 Spectra were measured at 2 nm intervals with a time constant of 1 s at 25C Data were collected from 10 separate recordings and averaged by using a microcompu-ter Data were expressed as the variation of molar amino acid residue absorption coefficient (De) The secondary structure content was determined according to the method

of Hennessey and Johnson [25]

Toxicity tests Toxicity was tested by ventral injection of 2 lL aqueous samples into 100 ± 2 mg, 5–6 day old Sarcophaga falculata blowfly larvae and by tail vein injection of 200 lL, subcutaneous injection of 2 mL, or intracerebroventricular

injection of 2 lL aqueous samples into 20 ± 2 g albino

Kunmingmice Each sample was tested in six larvae or three

mice The development of toxic effects was then monitored

over the next 2 days Similar buffers or saline were used as

negative controls The FPU50(flaccid paralysis unit), LD50

(lethal dose) values were calculated according to the

methodology of Behrens & Karber [26]

Preparation of adult rabbit ventricular myocyte

The rabbit ventricular myocyte were prepared by an

improved enzymatic dissociation method [27] The heart

were perfused through the aorta with Ca2+-free Tyrode’s

solution at 37C, followed by the Ca2+-free Tyrode’s

solution with added amounts of 0.2 mMCa2+and 0.04%

collagenase I over an 8-min period After perfusion, the

resected ventricles were minced into small pieces, incubated

in fresh Tyrode’s solution for 5–10 min The isolated cells

were resuspended in the Tyrode’s solution containing 0.05%

BSA, and the Ca2+concentration was gradually increased

to 1.0 mM The Ca2+-free Tyrode’s solution contained

(mM): NaCl 135, KCl 5.4, MgCl21.0, NaH2PO40.33, Hepes

10, glucose 10, adjusted to pH 7.25 with 1.0MNaOH

Preparation of albino rats dorsal root ganglia neurons

Dorsal root ganglia (DRG) neurons were obtained from the

lumbar region of albino rats, and neurons were isolated by

the method described previously [28] Ganglia were digested

with 0.2% collagenase II in a Hanks’ solution for 90 min

and then 0.1% trypsin for 10 min After the treatment with

enzymes, the digested DRGs were triturated and washed

with Hanks’ solution three times After resuspension in

Dulbecco’s minimum essential medium/F12 solution

sup-plemented with 10% fetal bovine serum, neurons were

plated on to polyornithine-coated coverslips Isolated

neu-rons were incubated in 95% air plus 5% CO2for 2–7 h prior

to the experiment

Whole-cell patch-clamp recording

The sodium current (INa) of single cells was recorded using

the whole cell voltage clamp technique The chamber was

continuously perfused at a temperature of 15C in external

solution (mM): (NaCl 30, choline chloride 110, KCl 5.4,

CaCl20.1, MgCl21.0, NaH2PO40.33, and Hepes 10 titrated

to pH of 7.3 with 1MNaOH) The solution inside the suction

pipette contained (mM): CsCl 120, CaCl21.0, MgCl2 5.0,

Na2ATP 5.0, EGTA 11, Hepes 10, and glucose 11, titrated to

pH of 7.3 with 1 mMCsOH Using this solution allowed an

effective isolation of INafrom other ionic currents A holding

potential of )80 mV was chosen The pipette had a tip

resistance of less than 1.0MW, while the input resistance of

the cells was about 1.0 GW Membrane currents were

measured with pipettes pulled from glass capillary tubes

and connected to an EPC-9 amplifier operating PULSE/

PULSEFITSoftware (HEKA Elektronik, Germany)

Aconitine-induced arrythmia model

Sprague–Dawley (SD) rats, weighing 230 ± 20 g, were

anesthetized with sodium pentobarbital (50 mgÆkg)1, i.p)

The experiments were carried out in accordance with the

guidelines laid down by the National Institutes of Health in the USA regarding the care and use of experimental animals and committee giving approval for the experiments The right jugular vein was cannulated for drug administration The lead II ECG maintained continuous readings using a polygraph system One hour after the intravenous admini-stration of BmKIM (dissolved in distilled water and administered in a volume of 0.5 mL per 250 g body wt), aconitine was infused intravenously at a dose of 4 lgÆmin)1 The times at which PVC (premature ventricular com-plex), VT (ventricular tachycardia), and VF (ventricular fibrillation) appeared were noted and recoded; the cumu-lative aconitine dosage to induce PVC, VT, VF was calculated Data are expressed as mean ± SEM Differences between control and treatment groups were analyzed by Dunnett’s test, paired t-test Difference at a P-value < 0.05 was considered to be statistically significant

R E S U L T S

Isolation and sequencing of BmKIM cDNA The yield from the initial screening of the cDNA library with the32P-labeled cDNA probe was about 260 positive clones On the final screening, 25 clones were selected on the basis of the strength of the autoradiographic signal Restriction analysis revealed size variation of the insert between 380 and 530 bp The seven longest inserts were subjected to sequence analysis The nucleotide sequence obtained was displayed an ORF of 258 bp encoding a polypeptide of 85 amino acids and termed BmKIM The 5¢ and 3¢ UTRs of BmKIM cDNA are 17 bp and 76 bp, respectively A single AATAAA polyadenylation signal was found 11 nt upstream of the poly (A) tail There was only one stop codon (TAA) at the 3¢ terminus of the ORF The cDNA sequence has been submitted to GenBank under accession number AF45972

A search for deduced amino acid sequence homology revealed that the precursor of BmKIM showed 89, 82, 82,

79, 75, and 69% sequence identity with that of BmKAEP [29], BaIT2[30], LqqIT2[31], LqhIT2[32], BmKIT2[33], and BjIT2[34], respectively (BmKAEP and BmKIT2are derived from Buthus martensii Karsch; BaIT2 from Buthacus arenicola;LqqIT2from Leiurus quinquestriatus quinquestri-atus; LqhIT2from Leiurus quinquestriatus hebraeus; BjIT2 from Buthotus judaicus) This suggested that the signal peptide cleavage occurred at the nucleotide 1702 Moreover, the mature toxin should be composed of 61 amino acid residues, which would be expected to lose three carboxy-terminal amino acids (Gly-Lys-Lys) during post-transla-tional processing according to a variety of rules applicable

to processing of neuroactive peptides [35] BmKIM dis-played high sequence homology with depressant insect-selective toxins (BmKAEP, BaIT2, LqqIT2, LqhIT2, BmKIT2and BjIT2) However, in comparison with these toxins, BmKIM was not homologous at several positions: Ile12, Trp16, Gly27, Phe28, and Tyr31; all other group toxins contain Ser at position 31 Both this group and most sodium-channel-binding scorpion toxin peptides have a conserved Ser (or Ala or Asp) residue before the fifth Cys residue, i.e a small molecular residue rather than an aromatic residue, such as Tyr Also interesting is the fact that Gly6 and Ser57 are highly conserved in depressant

insect-select toxins from BmK (BmKIM, BmKAEP and

BmKIT2), but Arg6 or Lys6 and Thr57 are conserved in

other scorpion species

Cloning and analysis of genomic sequence of BmKIM

We have isolated, cloned and sequenced the genomic

regions encoding BmKIM toxin The genomic amplification

of BmKIM by nested PCR yielded a major band of about

1900 bp The sequence has been submitted to GenBank

under accession number AF45971 Sequence analysis of this

fragment confirmed that the genomic gene of BmKIM

consisted of two exons disrupted by an intron of 1622 bp

This intron is in the sequence encoding the signal peptide,

after the first base (G) of an Asp codon at position 63,

beginning with GT and ending with AG, consistent with

previously reported intron junctions The sequence of the 5¢

splice donor was 5¢-G/gtaag and that of the 3¢ splice

acceptor was 5¢-ag/C; these sequences are consistent with

the consensus found in other scorpion toxins [14] Using A3

and A2 corresponding to the mature toxin region as

primers, and the BmKIM genomic DNA as template for

PCR, the nucleotide sequence obtained was the same as the

cDNA Therefore, there is only one intron in the sequence

encoding the signal peptide The position and structure of

BmKIM intron are quite similar to that of other scorpion

sodium toxins, but so far it is the longest among known

scorpion toxin introns

Construction of expression vectors and expression

of the fusion proteins

The cDNA encoding BmKIM was amplified by PCR with

forward and reverse primers The noncoding regions, the

signal peptide and the three carboxy-terminal residues

(Gly-Lys-Lys) of the toxin were removed from the cDNA and

specific restriction enzyme sites were added to facilitate

insertion into the pGEX-5X-1 expression vector, such that a

gene fusion (GST-BmKIM) could be constructed In the

construction, five codons encoding an enterokinase cleavage

site (encoding DDDDK) were added at the BmKIM

restriction site 5¢ to the factor Xa sequence such that the

linkage between GST and BmKIM in the fusion was

IEGRGIPDDDDK These constructs were used to

trans-form E.coli and were expressed upon IPTG induction

Optimal expression was achieved after 3 h of induction with

1.0 mM IPTG at 28C, adjusted to pH 8.0 with 10M

NaOH, which formed the GST derivatives as a soluble

protein but not inclusion bodies Periplasmic extracts

(before and after induction) of the transformants were

subjected to SDS/PAGE (Fig 1) GST-BmKIM was then

purified from these extracts on an GSH affinity column as

exhibited in Fig 1; intense bands corresponding to the

molecular masses of the expected proteins were obtained:

26 kDa for GST and 33 kDa for GST-BmKIM The yields

of affinity-purified proteins were 10 mgÆL)1 of culture,

estimated by Bradford means [36]

Enzymatic cleavage of fusion protein and purification

of the recombinant BmKIM

The fusion protein was cleaved completely with an

entero-kinase/substrate ratio of 50% at 26C for 10 min on the

GSH gel (Fig 1) The recombinant BmKIM (rBmKIM) was eluted from the GSH gel, purified and desalted using Sephadex G-50 column (100 mL) The purified rBmKIM migrated as a 6.7 kDa protein in a SDS/PAGE (Fig 1) The final yield of recombinant BmKIM was approximately 1–2 mgÆL)1 of culture The amino acid composition of rBmKIM and the N-terminal sequence obtained from sequencing DGYIRGSNGC were identical with the pre-dicted protein This clearly indicated that the expressed rBmKIM fused with GST protein was processed correctly

by the enterokinase

Circular dichroism spectrum The CD spectrum of rBmKIM between 180 and 250 nm was similar to those of other scorpion toxins (AaHIT2 [37], CssII [38]; AaHIT2 is anti-insect toxin purified from the venom of the Scorpion Androctonus australis Hector; CssII, b-type antimammal toxin from Centruroides suffuses suffu-ses) They were characterized by minima at 207 nm and by a maximum at 190 nm The negative band at 207 nm had a lower intensity in the case of rBmKIM in comparison with that in the spectra of AaHIT2 (a-toxin) and CssII (b-toxin) Moreover, a weak negative band at 227 nm, present in the

CD spectrum of rBmKIM, was not observed in the CD spectra of AaHIT2 or CssII; this could be related to n p* transition characteristic of b-turn structures(Fig 2) By use

of CD data, the secondary structure content of rBmKIM (Table 1) was calculated according to the method of Hennessey & Johnson [25] The sum of all the secondary structures obtained by CD analysis fell between 0.90 and 1.10, and the values for contents in secondary structures were either positive or never below )0.05 (Table 1) As shown in Table 1, the CD data analysis of BmKIM was

Fig 1 Expression and cleavage of gene GST-BmKIM fusion protein GST-BmKIM was expressed in E.coli BL21 by IPTG induction The fusion protein was purified with GSH agarose system and G-50 col-umn chromatography BmKIM was liberated from the fusion protein

by enterokinase Coomassie-strained gel of Laemmli 15% poly-acrylamide gel of uninduced cell-free extract of E.coli carrying pGEX-5x-1-BmKIM (lane 1); total cell-free extract induced with IPTG for 3 h (lane 2); molecular mass markers indicated at 31, 20, 16, 14, 6.3 and 3.5 kDa (lane 3); purified fusion protein by GSH agarose system (lane 4); purified GST (26 kDa) by GSH agarose system (lane 5); cleavaged fusion protein by enterokinase (lane 6); and purified recombinant BmKIM (lane 7).

compared to the CD data analyses of other scorpion toxins and displayed the similar secondary structure Therefore, the rBmKIM was a correctly refolded recombinant toxin

Effect of rBmKIM on sodium currents in DRG neurons and ventricular myocytes

The membrane potential of DRG neurons and ventricular myocytes was held at )80 mV, close to the resting membrane potential Whole cell path-clamp recording revealed that rBmKIM could inhibit the total sodium currents both in DRG neurons and ventricular myocyte (Fig 3A) The effect of BmKIM on current–voltage (I–V) relationship was examined between)70 and +30 mV in

10 mV steps As shown in Fig 3B, there was no shift of either the threshold, peak or equilibrium potential of INa under control conditions, in the presence of rBmKIM This was identical with the predicted function (a depressant toxins, which inhibited the sodium current) based on its high sequence homology with depressant toxins Moreover, the effect on DRG neurons and ventricular myocyte were both dose-dependent At higher concentration, rBmKIM inhi-bited the sodium currents completely, at low concentration, just half or less The relative changes in the peak INawere plotted as a function of toxin concentration (Fig 4) The continuous line was drawn according to the equation: the percentage decrease in INa¼ (IC50/[C] + 1))1where [C] is the toxin concentration, and IC50is the dose for 50% block

As shown in Fig 4, there was difference in the effect of rBmKIM on the DRG neurons and ventricular myocyte The response of DRG neurons to rBmKIM (IC¼ 0.498 lM) was shifted to a substantially lower concentration than the response of ventricular myocytes to rBmKIM

Table 1 Secondary structure analyses H, a-helix; A, antiparallel

b-sheet; P, parallel b-sheet; T, b-turn; O, other structures tot, total.

The secondary structures from analysis by the method of Hennessey

and Johnson [25].

Protein H A P T O tot

AaHIT2 0.24 0.34 )0.02 0.25 0.29 1.10

CssII 0.16 0.35 )0.01 0.26 0.24 1.01

BmKIM 0.18 0.30 0 0.28 0.22 0.98

Fig 2 Circular dichroism spectra of AaHIT2, CssII and BmKIM from

180 to 250 nm De corresponds to the variation of molar amino acid

residue absorption coefficient expressed in M )1 Æcm)1.

Fig 3 The inhibitory effects of BmKIM on cardiac peak sodium currents (I Na ) (A) Effect

of BmKIM under whole cell patch-clamp recording Control of sodium currents recor-ded by stepping up the membrane from )80 to +30 mv in 10 mV increments from the hold-ing potential of )80 mv on ventricular myo-cyte and DRG neuron A decrease in the peak sodium currents is caused by BmKIM (B) Relationship of voltage and sodium cur-rents in the presence and absence of BmKIM.

(IC¼ 3.662 lM) This suggested rBmKIM interacts with

DRG neuron sodium channels with higher affinity than the

ventricular myocyte sodium channels Unlike Ts c and

CnII-10 (Ts c is from Brazilian scorpion Tityus

serrula-tus; CnII-10 is from Mexican scorpion Centruroides noxius),

they are equally potent for cardiac and neuronal Na+

channels [39]

Pharmacological activity of recombinant BmKIM

Injected into larvae, rBmKIM caused a slow, progressive

depressant flaccid paralysis The FPU50 was 2.4 lg per

100 mg The toxic effect on mice was not achieved by

subcutaneous or intracerebroventricular injection, but only

by intravenous injection of purified rBmKIM The LD50

was about 0.8 mgÆkg)1 These data indicated that rBmKIM

had toxicity to both mammals and insects, though the

toxicity was at a lower level

Assay of antiarrhythmia activity

Table 2 illustrates the effects of rBmKIM on

aconitine-induced arrhythmias Using the model of aconitine-aconitine-induced

arrhymia in rats and compared with distilled water,

pretreatment of rBmKIM at 50 lgÆkg)1 significantly

increased the dosage of aconitine required to induced

PVC, VT, and VF To some extent, these results indicated

that rBmKIM produced antiarrhythmia activity in rat

D I S C U S S I O N

Toxicity tests in vivo showed that the recombinant toxin had toxic effect not only on insects but also on mammals, though the gene of the toxin displayed high sequence homology with that of insect-specific depressant toxins This

is first report of such insect-specific toxin had toxic effect on mammals Because the toxic effect on the mice was not found for subcutaneous and intracerebroventricular injec-tion but only for intravenous injecinjec-tion, it is possible that the toxic effect of rBmKIM on mammals is relation to the cardio toxicity

In fact, various scorpion venoms have been known to have direct myocardial action and manifest with cardio-pulmonary abnormalities including cardiac arrhythmias, arteria hypertension, pulmonary edema and circulatory failure [16] BmK scorpion venom has been used in traditional Chinese medicine for its reversal effect on circulation failure However, the cardiovascular effects of BmK venom have not been systematically studied and a regimen for effective treatments has not been established The mechanisms underlying these alterations in cardiovas-cular function remain unclear It has been suggested that the cardiovascular effects of scorpion venom are dependent upon the venom stimulation of the sympathetic and parasympathetic nervous system [40] Recently, an increas-ing number of studies suggest that several scorpion venoms and some of their purified toxins could directly affect the functional status of cardiac myocytes [41,42] Using whole cell patch-clamp recording, it was determined that BmKIM inhibited total sodium currents of ventricular myocyte and protected against aconitine-induced cardiac arrhythmias Although the rBmKIM also produced effects on DRG neurons, the BmKIT2 (75% sequence identity with BmKIM) has the same effects on DRG neurons [43] but has no toxicity to mammals It suggested that the effect on DRG neurons wasn’t sufficient to kill mice, and the ventricular myocyte may be the direct target of the rBmKIM by intravenous injection

Knowing that rBmKIM can affect sodium channels of DRG neurons and that ventricular myocytes possess different affinity and induce different functions provides valuable information for the study of nerve and cardiac

Na+channels No doubt, functional expression of BmKIM would make it possible to further study the biological mechanisms of cardiovascular effects and its structure BmKIM displayed high sequence homology with that of depressant insect-selective group It would be of interest to determine the rationale for the toxicity of BmKIM in mammals, when other members of the depressant insect-selective group do not possess this trait Comparing amino acid sequences, Tyr31 may be important because it was Ser is usually found at this position in most of the sequences of the depressant insect-selective group In fact, Ser31 was very conserved in most Na+ channel-specific scorpion toxin peptides It was located at the third or fourth position before the fifth Cys Sometimes, Ser31 is substituted by small residues such as A (Ala) or D (Asp) Only AaHIT4 and BmKAS, a specific anti-insect toxin, also contained a Tyr residue at this position AaHIT4, the unique anti-insect toxin also has a toxic effect on mammals and can acts on the a- and b-sites of the mammalian sodium channel [44] Therefore, whether Tyr31 is related

Table 2 The amounts of aconitine required to induce arrhythmia in

untreated rats and rats given 50 lgÆkg)1of BmKIM *P < 0.05 vs.

control.

Dose of aconitine to produce l)1g kg)1

Control 38 ± 4 67 ± 5 90 ± 10

BmKIM 75 ± 5* 100 ± 8* 148 ± 14*

Fig 4 Concentration–response curve of BmKIM for peak Na current

(I Na ) at a holding potential of )80mv The line is a fit of the function

(IC 50 /[C] + 1))1, with IC 50 ¼ 4.25 · 10)6M Points represent mean

value for six cells.

to the recognition of different sodium channel needs to be

determined

Scorpion toxic peptides have a highly conserved, dense

core formed by an a-helix and two to three strands of

b-sheet structural motifs, maintained by disulfide bridges

[11] Therefore, their species specificity is probably mediated

by rather subtle changes in amino acid residues in selected

positions of the primary structure It has been suggested that

the net charge of the toxins is important to define the degree

of toxicity of the peptides Apparently, the positively

charged toxins have lower LD50 values, in other words,

are more toxic [45] The aromatic residues may play a major

role in toxin-channel recognition because they not only

affect the binding to Na+ channels but also alter the

conformation of the receptor by the p electron cloud So,

aromatic resides might be related to affecting different Na+

channel, and the residues with positive charged might be

related to the efficiency This was supported by modification

of the LqhaIT, whose mutations at three sites, Tyr49-Ile,

Ala50-Lys and Asn54-Lys, resulted in a marked decrease in

antimammalian toxicity (6.4-fold) but little change in its

biological activity against insects [46] We assume that

Tyr31 may determine whether BmKIM acts specifically

towards mammals or arthropods Additionally, BmKIM

does not have a strong positive potential, which accounts

for its low toxicity to both mammals and insects Further

modifications of residues that belong to the aromatic cluster

and positive charges may be useful for final determination

of the toxic site and for clarification of the molecular basis

for the wide toxic range of BmKIM

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

We thank Wang Teng and Dr Wang Xi for providing the coordinates

for the electrophysiology of BmKIM; Prof Ma Hui-wen for his

kindness in offering us the plasmid pGEX and GST Gel Professor Yi

Qing-min for uses his lyophile apparatus and his helpful discussions.

This work was sponsored by the National Natural Science Foundation

of China (No 39970897).

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