Elena V. Lukashina

Tritium planigraphy study of structural alterations in the coat protein of Potato virus X induced by binding of its triple gene block 1 protein to virions

Alterations in Potato virus X (PVX) coat protein structure after binding of the protein, encoded by the first gene of PVX triple gene block (triple gene block 1 protein, TGBp1), to the virions were studied using tritium planigraphy. Previously, it has been shown that TGBp1 molecules interact with the PVX particle end, containing the 5′‐terminus of PVX RNA, and that this interaction results in a strong decrease in virion stability and its transformation to a translationally active state. In this work, it has been shown that the interaction of TGBp1 with PVX virions leads to an increase of ∼ 50% in tritium label incorporation into the 176–198 segment of the 236‐residue‐long PVX coat protein subunit, with some decrease in label incorporation into the N‐terminal coat protein region. According to the new ‘sandwich’ variant of our recently proposed model of the three‐dimensional structure of the intravirus PVX coat protein, the 176–198 segment is assigned to the β‐sheet region located at the subunit surface, presumably participating in coat protein interactions with the intravirus RNA and/or in protein–protein interactions, whereas the N‐terminal coat protein region corresponds to the other part of the same β‐sheet. For the remaining segments of the PVX coat protein subunit, no significant difference between tritium incorporation into untreated and TGBp1‐treated PVX was observed. A detailed description of the ‘sandwich’ version of the intravirus PVX coat protein model is presented.

Spatial structure peculiarities of influenza A virus matrix M1 protein in an acidic solution that simulates the internal lysosomal medium

The structure of the C‐terminal domain of the influenza virus A matrix M1 protein, for which X‐ray diffraction data were still missing, was studied in acidic solution. Matrix M1 protein was bombarded with thermally‐activated tritium atoms, and the resulting intramolecular distribution of the tritium label was analyzed to assess the steric accessibility of the amino acid residues in this protein. This technique revealed that interdomain loops and the C‐terminal domain of the protein are the most accessible to labeling with tritium atoms. A model of the spatial arrangement of the C‐terminal domain of matrix M1 protein was generated using rosetta software adjusted to the data obtained by tritium planigraphy experiments. This model suggests that the C‐terminal domain is an almost flat layer with a three‐α‐helical structure. To explain the high level of tritium label incorporation into the C‐terminal domain of the M1 protein in an acidic solution, we also used independent experimental approaches (CD spectroscopy, limited proteolysis and MALDI‐TOF MS analysis of the proteolysis products, dynamic light scattering and analytical ultracentrifugation), as well as multiple computational algorithms, to analyse the intrinsic protein disorder. Taken together, the results obtained in the present study indicate that the C‐terminal domain is weakly structured. We hypothesize that the specific 3D structural peculiarities of the M1 protein revealed in acidic pH solution allow the protein greater structural flexibility and enable it to interact effectively with the components of the host cell.

The In Situ Structural Characterization of the Influenza A Virus Matrix M1 Protein within a Virion

The first attempt has been made to suggest a model of influenza A virus matrix M1 protein spatial structure and molecule orientation within a virion on the basis of tritium planigraphy data and theoretical prediction results. Limited in situ proteolysis of the intact virions with bromelain and surface plasmon resonance spectroscopy study of the M1 protein interaction with lipid coated surfaces were used for independent confirmation of the proposed model.

Analysis of the role of the coat protein N-terminal segment in Potato virus X virion stability and functional activity

Previously, we have reported that intact Potato virus X (PVX) virions cannot be translated in cell-free systems, but acquire this capacity by the binding of PVX-specific triple gene block protein 1 (TGBp1) or after phosphorylation of the exposed N-terminal segment of intravirus coat protein (CP) by protein kinases. With the help of in vitro mutagenesis, a nonphosphorylatable PVX mutant (denoted ST PVX) was prepared in which all 12 S and T residues in the 20-residue-long N-terminal CP segment were substituted by A or G. Contrary to expectations, ST PVX was infectious, produced normal progeny and was translated in vitro in the absence of any additional factors. We suggest that the N-terminal PVX CP segment somehow participates in virion assembly in vivo and that CP subunits in ST virions may differ in structure from those in the wild-type (UK3 strain). In the present work, to test this suggestion, we performed a comparative tritium planigraphy study of CP structure in UK3 and ST virions. It was found that the profile of tritium incorporation into ST mutant virions in some CP segments differed from that of normal UK3 virions and from UK3 complexed with the PVX movement protein TGBp1. It is proposed that amino acid substitutions in ST CP and the TGBp1-driven remodelling of UK3 virions induce structural alterations in intravirus CPs. These alterations affect the predicted RNA recognition motif of PVX CP, but in different ways: for ST PVX, labelling is increased in α-helices 6 and 7, whereas, in remodelled UK3, labelling is increased in the β-sheet strands β3, β4 and β5.

Kinetic Features of Labeled Product Formation under the Action of Atomic Tritium on Frozen Solutions and Lyophilically Dried Mixtures of Amino Acids

Formation of labeled amino acids in reactions of their lyophilically dried mixtures and frozen solutions with atomic tritium generated by thermal activation was studied in relation to the reaction time and pressure of molecular tritium. The molar radioactivity of the amino acids is a complex function of the reaction time. At short reaction times, the radioactivity of the amino acid depends primarily on its concentration in the near-surface layer. At long labeling times, in the case of surfactants, the yield of labeled products can decrease owing to side reactions. The influence of water on the rate of formation of labeled products and its role in thermalization of “hot” tritium atoms in the target is discussed. An increase in the tritium pressure in the system increases the initial radioactivity of the target but affects the yield of the labeled amino acids insignificantly. Recommendations are formulated on optimizing the conditions for labeling of biological macromolecules in their structural studies by tritium planigraphy.

Modified model of the structure of the potato virus X coat protein

A modified model was proposed for the tertiary structure of the coat protein (CP) molecules in potato virus X (PVX) virions, similar to the original model of 2001 describing the structure of CP of potato virus A, a member of another group of filamentous viruses. According to the new model, CP comprises two main structural domains, namely, a bundle of α-helices, located near the long axis of the virion, and the socalled RNP fold (or abCd fold), located in the vicinity of its surface. The model made it possible to suggest a possible mechanism of the PVX virion structural rearrangement (remodeling) resulting from translational activation of virions by the TGB1 movement protein according to Atabekov and colleagues.

Determination of Low Activity of Tritium-Labeled Amino Acids Using Simultaneously Flow Scintillation and Amino Acid Analyzers

The possibility of measuring a low activity of tritium-labeled amino acids in the eluate from Amino Acid Analyzer 835 (Hitachi, Japan) using a Radiomatic 150TR Flow Scintillation Analyzer (Packard Instrument Co., USA) was studied. Due to stepped variations of pH, ionic strength, and salt concentration in eluting solutions during amino acid separation and utilization of ninhydrin reagent in spectrophotometric measurements of amino acids, special selection of scintillation liquids was necessary. Six scintillation cocktails were tested: ZhS-8 (Reakhim, Ukraine), OptiPhase “HiSafe” 3 (Wallac Oy, EGGgr; Co., Finland), Hionic-Fluor, Ultima-Flo AP, Ultima-Flo M, and Ultima Gold (Packard Instrument Co., USA). It was found that Hionic-Fluor and Ultima-Flo AP cocktails are the most appropriate for flow measurements of tritium activity. Under optimal conditions the detection limit with Hionic-Fluor and Ultima-Flo AP was 150 and 100 decays min-1 in the peak of amino acid, respectively. Such a high sensitivity allows utilization of the above analytical system for measurements of amino acid radioactivity to study the structure of proteins and protein complexes by tritium planigraphy.

Isolation of Influenza Virus A Hemagglutinin C-Terminal Domain by Hemagglutinin Proteolysis in Octylglucoside Micelles

A method of isolation of hydrophobic membrane-bound C-terminal domain of influenza virus A hemagglutinin (HA) is suggested. The method is based on the insertion of HA into octylglucoside micelles followed by pepsin or thermolysin hydrolysis. Subsequent treatment of proteolytic digests with chloroform-hexafluoroisopropanol mixture resulted in the extraction of a few hydrophobic peptides into organic phase. Mass-spectrometry (MALDI-TOF) analysis revealed that the peptides with ion masses corresponding to the anchoring C-terminal domain with or without modifications predominated in the organic solution. The data obtained confirmed our speculation on the possibility of the suggested isolation scheme following from the strong interactions of anchoring domains in compact trimeric structure of HA spikes combined with micelle protection effect. Several appropriate peptides presence in the organic phase apparently arises from the presence of a few accessible proteolytic sites in HA transmembrane region.