Positively charged amino acid residues located similarly in sea anemone and scorpion toxins

E.P Loret,R.M Del Valle,P Mansuelle,F Sampieri,H Rochat

doi:10.1016/s0021-9258(19)89460-7

E.P Loret, R.M Del Valle + Show 3 more

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https://doi.org/10.1016/s0021-9258(19)89460-7

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Abstract

Specific groups of sea anemone and scorpion toxins compete on the same pharmacological site, on the voltage-gated sodium channel of mammal excitable membranes. However, these scorpion and sea anemone toxins are two distinct protein families. Here we purified and sequenced a new sea anemone toxin, Bg II, highly toxic to mammals and also a less toxic mutant, Bg III. Two Bg II models were determined from sequence homologies with two sea anemone toxin two-dimensional NMR structures. Only one model conformed to circular dichroism data obtained from Bg II and was compared with an x-ray structure of a scorpion toxin. The comparison of the two structures shows that 5 amino acid residues are located similarly in the sea anemone toxin and the scorpion toxin. From these 5 residues, 4 are basic residues, constituting two distinct positively charged poles on the surface of these toxins. In the sea anemone mutant isolated, a negative charge beside one of the positive poles decreases the toxicity. These results show that positively charged amino acid residues could be essential for the activity of these toxins and outline the role of electrostatic bonds in the interaction of sea anemone and scorpion toxins with their receptor.

Highlights

From the Waboratoire de Biochimie, CNRS URA 1455,Faculte de Medecine, Secteur Nord, 13916 Marseille Cedex 20, France a n d the YCentro Nacional de Inuestigaciones Cientificas, 6880-6990 La Habana, Cuba
T w o Bg I1 models were determined from sequence ho- homologies with two sea anemones having their three-dimenwNdm dsoiuiMcontehhlRsoorgofasaiitnertsrhsmeuexwcl-otdtriuwctaahratyoaettesswsd.ottOrbrouustnasicclmetiytnuauierorlaadeennrseafleioysrnmmfhostomcoohowdnereBseplsgittecIoho1oanxanatia5nfntonodartexwmmmwinoeiano.-dsdnoTitecmoahocm teecoidnixprcsrciaoinueormslenaiadp-arnladrosnBsi-iinegmoltnyiIica1loalranrenssetsdoricunzAoceanat.nufhcW oreeIrm.1hEdeseenahdtctoehhtwroemsstctirtwinhureoccaduttupltabrrhroeyetdpettirwiwconhovosr-ioddapiiresrmesmoetoendvisaaenirtosBalna.hgaiCdalIivon1nemuamfcpusloanuedrcraieftrsalio,ocmnnebauooogtfffthe scorpion toxin
Mutant isolated, a negative charge beside one of the positive poles decreases the toxicity. These results show that positively charged amino acid residues could be Purification-Sea anemone were collectedin theGulf of Mexico area

Summary

IonexchangeHPLCwasmade with an analytical sulfopropyl TSK

Sea anemone toxinsare short proteins(4000-5000Da) crosslinked by three disulfidebridges ( 1 4 ) Their binding is potential-dependent and induces openingof the channelfollowed by a slow closing phase [5,6,7,8]. CD spectra were measured in 50-pm path length cells from 260 to 180 nm with a Jobin-Yvon UV CD specmammalian sodium channel are proteins of 60-65 residues trophotometer.Measurements were performedat 20 "C.CD spectra are long cross-linked by four disulfide bridges. They are divided reported as A€ per amide. The abbreviations used are: BgI1 and Bg 111, toxins purified from the seaanemoneB. granulifera; ATX Ia and BDS I, toxins purified from the sea anemone Anemoniasulcata; Bg IIa, model made from ATX Ia; Bg IIb, model made from BDS I, Aah 11, toxin purified from the scorpion venom Androctonus australis hector; HPLC, high performance liquid chromatography

RESULTS AND DISCUSSION

TABLEI Energies for the BgII models

ATX Ia Bg IIa BDS Bg IIb withBg ub

Similarities in Sea Anemone and Scorpion Toxin Structures