Cys mutants as tools to study the oligomerization of the pore-forming toxin sticholysin I
Autor(en): | Hervis, Yadira P. Valle, Aisel Canet, Liem Rodriguez, Azalia Lanio, Maria E. Alvarez, Carlos Steinhoff, Heinz J. Pazos, Isabel F. |
Stichwörter: | ACTINOPORINS; Cys mutants; disulfide bond formation; DISULFIDE BONDS; EQUINATOXIN-II; FRAGACEATOXIN C; FUNCTIONAL-CHARACTERIZATION; MECHANISM; MEMBRANE PERMEABILIZATION; MULTIGENE FAMILIES; Oligomerization; Pharmacology & Pharmacy; Pore-forming protein; SEA-ANEMONE STICHODACTYLA; ST-II; Sticholysins; Toxicology | Erscheinungsdatum: | 2023 | Herausgeber: | PERGAMON-ELSEVIER SCIENCE LTD | Journal: | TOXICON | Volumen: | 222 | Zusammenfassung: | Sticholysin I (StI) is a water-soluble protein with the ability to bind membranes where it oligomerizes and forms pores leading to cell death. Understanding the assembly property of this protein may be valuable for designing potential biotechnological tools, such as stable or structurally defined nanopores. In order to get insights into the stabilization of StI oligomers by disulfide bonds, we designed and characterized single and double cysteine mutants at the oligomerization interface. The oligomer formation was induced in the presence of lipid membranes and visualized by SDS-PAGE. The contribution of the oligomeric structures to the membrane binding and pore-forming capacities of StI was assessed. Single and double cysteine introduction at the protein-protein oligomerization interface does not considerably affect the conformation and function of the monomeric protein. In the presence of membranes, a cysteine double mutation at positions 15 and 59 favored formation of different size oligomers stabilized by disulfide bonds. The results of this work highlight the relevance of these positions (15 and 59) to be considered for developing biosensors based on nanopores from StI. |
ISSN: | 0041-0101 | DOI: | 10.1016/j.toxicon.2022.106994 |
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