1. Spatial structure and oligomerization of viscotoxin A3 in detergent micelles: Implication for mechanisms of ion channel formation and membrane lysis
Alexander S Paramonov, Ekaterina N Lyukmanova, Alexander G Tonevitsky, Alexander S Arseniev, Zakhar O Shenkarev Biochem Biophys Res Commun. 2021 Dec 31;585:22-28. doi: 10.1016/j.bbrc.2021.11.022. Epub 2021 Nov 9.
Thionins are the family of small (~5 kDa) cationic cysteine-rich peptides involved in the immune response in plants. Viscotoxin A3 (VtA3) is the thionin from mistletoe (Viscum album) demonstrating antimicrobial and cytotoxic activity against cancer cells in vitro. VtA3 (charge +6) interacts with the membranes containing anionic lipids and forms cation-selective ion channels. Here we studied the VtA3 structure in membrane-mimicking media by NMR spectroscopy. Spatial structure of VtA3, consisting of a helical hairpin and a short β-sheet, was stable and did not undergo significant changes during micelle binding. VtA3 molecule bound with high affinity to the surface of zwitterionic dodecylphosphocholine (DPC) micelle by hydrophobic patch in the helical hairpin. Oligomerization of VtA3 was observed in the anionic micelles of sodium dodecylsulphate (SDS). No direct contacts between the peptide molecules were observed and the possible interfaces of detergent-assisted oligomerization were revealed. The data obtained suggest that the VtA3 membrane activity, depending on the concentration, obeys the 'toroidal' pore model or the 'carpet' mechanism. The model of the membrane disrupting complex, which explains the ion channel formation in the partially anionic membranes, was proposed.
2. Viscotoxin and lectin content in foliage and fruit of Viscum album L. on the main host trees of Hyrcanian forests
Sanaz Yousefvand, Farnoosh Fattahi, Seyed Mohsen Hosseini, Konrad Urech, Gerhard Schaller Sci Rep. 2022 Jun 20;12(1):10383. doi: 10.1038/s41598-022-14504-3.
Mistletoe (Viscum album L.) is a hemiparasitic plant that absorbs water and nutrients from the host tree. Mistletoe contains two groups of cytotoxic, immunomodulatory and antitumor proteins, viscotoxins and lectins. This study evaluated the quantity and quality of viscotoxins and total lectins in the stems with leaves (foliage) and fruit of mistletoe on Parrotia persica and Carpinus betulus in September with immature green berries and in December with mature white berries. Viscum album L. plants were harvested from host species located in the Hyrcanian forests of Iran in 2019. The highest level of viscotoxins was detected in the December foliage of V. album settled on C. betulus (9.25 mg/g dry weight [DW]), and the highest content of lectins was found in the December foliage of V. album settled on P. persica (0.79 mg/g DW) and C. betulus (0.73 mg/g DW) respectively. The immature green berries of V. album from both host species contained much higher concentrations of viscotoxins and lectins than the mature white berries. Four isoforms of viscotoxins, viscotoxin A1, A2, A3 and B could be identified in all samples of both host species. Viscotoxin A3 was the predominant viscotoxin isoform followed by viscotoxin A1.
3. NMR structural determination of viscotoxin A3 from Viscum album L
S Romagnoli, R Ugolini, F Fogolari, G Schaller, K Urech, M Giannattasio, L Ragona, H Molinari Biochem J. 2000 Sep 1;350 Pt 2(Pt 2):569-77.
The high-resolution three-dimensional structure of the plant toxin viscotoxin A3, from Viscum album L., has been determined in solution by (1)H NMR spectroscopy at pH 3.6 and 12 degrees C (the structure has been deposited in the Protein Data Bank under the id. code 1ED0). Experimentally derived restraints including 734 interproton distances from nuclear Overhauser effect measurements, 22 hydrogen bonds, 32 φ angle restraints from J coupling measurements, together with three disulphide bridge constraints were used as input in restrained molecular dynamics, followed by minimization, using DYANA and Discover. Backbone and heavy atom root-mean-square deviations were 0.47+/-0.11 A (1 A=10(-10) m) and 0.85+/-0.13 A respectively. Viscotoxin A3 consists of two alpha-helices connected by a turn and a short stretch of antiparallel beta-sheet. This fold is similar to that found in other thionins, such as crambin, hordothionin-alpha and -beta, phoratoxin A and purothionin-alpha and -beta. The difference in the observed biological activity for thionins of known structure is discussed in terms of the differences in the calculated surface potential distribution, playing an important role in their function through disruption of cell membranes. In addition, the possible role in DNA binding of the helix-turn-helix motif of viscotoxin A3 is discussed.