Functional characterization of sticholysin I and W111C mutant reveals the sequence of the actinoporin's pore assembly.

Valeria Antonini,Diana Martínez,Victor Pérez-Barzaga,David Pentón,Mauro Dalla Serra,Silvia Bampi,Mayra Tejuca,Daniel Gillet

doi:10.1371/journal.pone.0110824

Valeria Antonini, Diana Martínez + Show 6 more

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https://doi.org/10.1371/journal.pone.0110824

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Abstract

The use of pore-forming toxins in the construction of immunotoxins against tumour cells is an alternative for cancer therapy. In this protein family one of the most potent toxins are the actinoporins, cytolysins from sea anemones. We work on the construction of tumour proteinase-activated immunotoxins using sticholysin I (StI), an actinoporin isolated from the sea anemone Stichodactyla helianthus. To accomplish this objective, recombinant StI (StIr) with a mutation in the membrane binding region has been employed. In this work, it was evaluated the impact of mutating tryptophan 111 to cysteine on the toxin pore forming capability. StI W111C is still able to permeabilize erythrocytes and liposomes, but at ten-fold higher concentration than StI. This is due to its lower affinity for the membrane, which corroborates the importance of residue 111 for the binding of actinoporins to the lipid bilayer. In agreement, other functional characteristics not directly associated to the binding, are essentially the same for both variants, that is, pores have oligomeric structures with similar radii, conductance, cation-selectivity, and instantaneous current-voltage behavior. In addition, this work provides experimental evidence sustaining the toroidal protein-lipid actinoporins lytic structures, since the toxins provoke the trans-bilayer movement (flip–flop) of a pyrene-labeled analogue of phosphatidylcholine in liposomes, indicating the existence of continuity between the outer and the inner membrane leaflet. Finally, our planar lipid membranes results have also contributed to a better understanding of the actinoporin’s pore assembly mechanism. After the toxin binding and the N-terminal insertion in the lipid membrane, the pore assembly occurs by passing through different transient sub-conductance states. These states, usually 3 or 4, are due to the successive incorporation of N-terminal α-helices and lipid heads to the growing pores until a stable toroidal oligomeric structure is formed, which is mainly tetrameric.

Highlights

Sticholysins (Sts) I and II (StI/II) are two very similar poreforming toxins (PFT) isolated from the sea anemone Stichodactyla helianthus
The method used to estimate the radii of the pores formed by StIr or sticholysin I (StI) W111C takes advantage on the ability of the PFT to induce colloid–osmotic hemolysis
Considering that StIr and StI W111C conductances are 442 and 471 pS, respectively, and that 12 mS/ cm is the solution conductivity, the radii estimated for StIr and StI W111C were 0.960.1 and 1.060.1 nm, respectively. These values are in agreement both with the pore sizes estimated by RBC assay, e.g. 1.060.1 and 1.160.1 nm for StIr and StI W111C, respectively, and with the values previously estimated for native StI by planar lipid membranes (PLM) of 1.060.1 nm [24]

Summary

Introduction

Sticholysins (Sts) I and II (StI/II) are two very similar poreforming toxins (PFT) isolated from the sea anemone Stichodactyla helianthus. They belong to actinoporins, a family of extremely potent PFT expressed by anemones. Actinoporins are 20 kDa cysteineless proteins with preference for sphingomyelincontaining membranes. They are composed of a tightly folded bsandwich flanked by two a-helices [5,6,7,8,9]; the N-terminal helix being involved in the transmembrane pore formation [10,11,12,13]

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