O.V. Karpova

Thermal transition of native tobacco mosaic virus and RNA-free viral proteins into spherical nanoparticles.

Spherical nanoparticles (SNPs) were generated by two-step thermal remodelling of native tobacco mosaic virus (TMV) at 94 °C. Particles of irregular shape and varying size were generated by TMV at 90 °C. They could be converted into SNPs by heating at 94 °C and were considered to be intermediate precursors of SNPs. In addition to SNP monomers (53 nm diameter), generated by individual TMV virions, large SNPs (100-800 nm diameter) were assembled. The size of the SNPs depended on the TMV concentration. The SNPs could be generated by distinct forms of RNA-free TMV coat protein (CP) aggregates and individual CP subunits. A one-step SNP assembly appeared to occur in these cases. These results show that SNPs represent a new type of particle nanoplatform for producing compositions of SNPs with foreign protein molecules bound to their surface.

Mutagenic analysis of Potato Virus X movement protein (TGBp1) and the coat protein (CP): in vitro TGBp1–CP binding and viral RNA translation activation

Previously, we have shown that encapsidated Potato virus X (PVX) RNA was non-translatable in vitro, but could be converted into a translatable form by binding of the PVX movement protein TGBp1 to one end of the virion or by coat protein (CP) phosphorylation. Here, a mutagenic analysis of PVX CP and TGBp1 was used to identify the regions involved in TGBp1-CP binding and translational activation of PVX RNA by TGBp1. It was found that the C-terminal (C-ter) 10/18 amino acids region was not essential for virus-like particle (VP) assembly from CP and RNA. However, the VPs assembled from the CP lacking C-ter 10/18 amino acids were incapable of TGBp1 binding and being translationally activated. It was suggested that the 10-amino-acid C-ter regions of protein subunits located at one end of a polar helical PVX particle contain a domain accessible to TGBp1 binding and PVX remodelling. The non-translatable particles assembled from the C-ter mutant CP could be converted into a translatable form by CP phosphorylation. The TGBp1-CP binding activity was preserved unless a conservative motif IV was removed from TGBp1. By contrast, TGBp1-dependent activation of PVX RNA translation was abolished by deletions of various NTPase/helicase conservative motifs and their combinations. The motif IV might be essential for TGBp1-CP binding, but insufficient for PVX RNA translation activation. The evidence to discriminate between these two events, i.e. TGBp1 binding to the CP-helix and TGBp1-dependent RNA translation activation, is discussed.

Effects of sequence elements in the potato virus X RNA 5' non-translated αβ-leader on its translation enhancing activity

The 5′ non-translated αβ-leader sequence of potato virus X RNA consists of two regions: the α sequence (41 nucleotides with no G) and the β sequence (42 nucleotides upstream from AUG). The αβ-leader has been shown to enhance strongly the expression of adjacent genes in chimeric mRNAs. This phenomenon has been postulated to be due to the unpaired conformation of the 5′-terminal 30 nucleotides and/or to the presence within the α region of the CCACC pentanucleotide complementary to the 3′-terminal conserved structure of 18S rRNA. Different derivatives of αβ-leader have been constructed for use in determining the contribution of separate elements of the αβ sequence to translational enhancement. It was found that deletion of the α sequence large fragment which was supposed to be unfolded did not reduce the Δαβ-leader enhancement activity. Moreover, translational enhancement was greater for this derivative. Deletion of the β sequence resulted in a considerable increase in activity of the α-leader showing that the β region was dispensable for translation. Disruption or ‘masking’ of CCACC led to inactivation of the αβ-leader as a translational enhancer. Thus, we identified the CCACC pentanucleotide as the primary motif responsible for the translation enhancing ability of αβ-leader.

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.

Translation arrest of potato virus X RNA in Krebs-2 cell-free system: RNase H cleavage promoted by complementary oligodeoxynucleotides

Translation arrest of genomic potato virus X (PVX) RNA promoted by complementary oligodeoxynucleotides in Krebs‐2 cell‐free system is described. 14–15 mer oligodeoxynucleotides complementary to the 5′‐proximal cistron of PVX RNA were shown to induce specific truncation of the major non‐structural polypeptide coded by PVX RNA. Evidence is presented that effective translational arrest of PVX RNA in the presence of complementary oligonucleotides restults from the site‐specific cleavage of RNA by endogenous RNase H intrinsic to the Krebs‐2 extract. No similar translational arrest was found in the rabbit reticulocyte lysate cell‐free system.

Examination of Biologically Active Nanocomplexes by Nanoparticle Tracking Analysis

Nanoparticle tracking analysis (NTA) was first applied to biologically active nanocomplexes to obtain concurrent information on their size, state of aggregation, concentration, and antigenic specificity in liquid. The subject of the NTA was an immunogenic complex (a candidate nanovaccine) comprised of spherical particles (SPs) generated by thermal remodeling of the tobacco mosaic virus and Rubella virus tetraepitopes exposed on the surface of SP.

Regulation of RNA Translation in Potato Virus X RNA-Coat Protein Complexes: The Key Role of the N-Terminal Segment of the Protein

The efficiency of in vitro translation of the potato virus X (PVX) RNA was studied for viral ribonucleoprotein complexes (vRNP) assembled from the genomic RNA and the viral coat protein (CP). In vRNP particles the 5′-proximal RNA segments were encapsidated into the CP, which formed helical headlike structures differing in length. Translation of the PVX RNA was completely suppressed upon incubation with PVX CP and was activated within vRNPs assembled in vitro with two CP forms, differing in the modification of the N-terminal peptide containing the main phosphorylation site(s) for Thr/Ser protein kinases. It was shown that CP phosphorylation activates RNA translation within vRNPs and that the removal of the N-terminal peptide of CP suppresses activation, but CP still acts as a translational suppressor. This fact made it possible to suppose that the replacement of Ser/Thr by amino acid residues that are not subject to phosphorylation in the N-terminal peptide of CP of the mutant PVX (PVX-ST) completely inhibits RNA translation within vRNP. However, experiments disproved this assumption: PVX-ST RNA was efficiently translated within native virions, RNA of the wild-type (wt) PVX was efficiently translated in heterogeneous vRNP (wtRNA + PVX-ST CP), and the opposite result (repression of translation) was obtained for another heterogeneous vRNP (PVX-ST RNA + wtCP). Therefore, the N-terminal CP peptide located on the surface of the PVX virion or vRNP particles plays a key role in the activation of viral RNA translation.

β-structure of the coat protein subunits in spherical particles generated by tobacco mosaic virus thermal denaturation

Conversion of the rod-like tobacco mosaic virus (TMV) virions into “ball-like particles” by thermal denaturation at 90–98 °C had been described by R.G. Hart in 1956. We have reported recently that spherical particles (SPs) generated by thermal denaturation of TMV at 94–98 °C were highly stable, RNA-free, and water-insoluble. The SPs were uniform in shape but varied widely in size (53–800 nm), which depended on the virus concentration. Here, we describe some structural characteristics of SPs using circular dichroism, fluorescence spectroscopy, and Raman spectroscopy. It was found that the structure of SPs protein differs strongly from that of the native TMV and is characterized by coat protein subunits transition from mainly (about 50%) α-helical structure to a structure with low content of α-helices and a significant fraction of β-sheets. The SPs demonstrate strong reaction with thioflavin T suggesting the formation of amyloid-like structures.

Deletion of the Intercistronic Poly(A) Tract from Brome Mosaic Virus RNA 3 by Ribonuclease H and Its Restoration in Progeny of the Religated RNA 3

Summary The dicistronic genomic RNA 3 of brome mosaic virus (BMV) was used in experiments on site-specific cleavage by RNase H and subsequent religation of large BMV RNA 3 fragments with T4 RNA ligase. BMV RNA 3 was cleaved at the intercistronic poly(A) tract into two fragments: a long (L-BMV 3) 5′-terminal fragment (M r 0.40 × 106) containing the 3a gene, and a short (Sh-BMV 3) fragment (M r 0.28 × 106) containing the coat protein gene and the 3′-terminal tRNA-like tyrosine-accepting structure. Two or three adenylate residues were present at the 5′ end of Sh-BMV 3 and one adenylate at the 3′ end of L-BMV 3. After religation of these RNA fragments BMV RNA 3 was constructed with a deletion including the entire intercistronic poly(A) tract but not the flanking sequences. The religated RNA 3 replicated in wheat plants co-inoculated with BMV RNA 1 and RNA 2. The normal poly(A) tract was restored in progeny BMV RNA 3 during the course of replication.

Use of a polycation spacer for noncovalent immobilization of albumin on thermally modified virus particles

The noncovalent immobilization of the protein bovine serum albumin on the surface of spherical nanoparticles 330 ± 60 nm in diameter is described. These nanoparticles are prepared by the thermal treatment of tobacco mosaic virus and are preliminarily covered with a layer of the cationic polymer poly(N-ethyl-4-vinylpyridinium bromide). The electrostatic adsorption of the polycation on the surface of negatively charged spherical nanoparticles (on average 1.2 × 104 macromolecules per particle) is accompanied by recharging of the surface; as a result, the negatively charged protein bovine serum albumin can be adsorbed on it in an amount of 1.7 × 104 molecules per particle. The modification of spherical nanoparticles with the polycation and protein does not cause the aggregation of particles. The spherical-nanoparticle-polycation-protein ternary complex demonstrates increased stability in salt solutions relative to the spherical-nanoparticle-polycation binary complex. Because of the simplicity of the method used to modify the surface of spherical nanoparticles, it shows promise for preparation of functionally active complexes.