Evidence for the presence of a hole in the capsid of turnip yellow mosaic virus after RNA release by freezing and thawing. Decapsidation of turnip yellow mosaic virus in vitro

Evolutionary Adaptation of an RNA Bacteriophage to Repeated Freezing and Thawing Cycles

Bacteriophage fitness is determined by factors influencing both their replication within bacteria and their ability to maintain infectivity between infections. The latter becomes particularly crucial under adverse environmental conditions or when host density is low. In such scenarios, the damage experienced by viral particles could lead to the loss of infectivity, which might be mitigated if the virus undergoes evolutionary optimization through replication. In this study, we conducted an evolution experiment involving bacteriophage Qβ, wherein it underwent 30 serial transfers, each involving a cycle of freezing and thawing followed by replication of the surviving viruses. Our findings show that Qβ was capable of enhancing its resistance to this selective pressure through various adaptive pathways that did not impair the virus replicative capacity. Notably, these adaptations predominantly involved mutations located within genes encoding capsid proteins. The adapted populations exhibited higher resistance levels than individual viruses isolated from them, and the latter surpassed those observed in single mutants generated via site-directed mutagenesis. This suggests potential interactions among mutants and mutations. In conclusion, our study highlights the significant role of extracellular selective pressures in driving the evolution of phages, influencing both the genetic composition of their populations and their phenotypic properties.

The generation of empty Turnip yellow mosaic virus capsids through depletion of virion-associated divalent cations

Turnip yellow mosaic virus (TYMV) is a well-studied icosahedral plant virus that has attractive properties for nanoscience applications. Stable empty particles devoid of viral genomic RNA have historically been generated from virions by: 1. high pressure; 2. extreme alkaline pH; and 3. freeze-thaw using liquid nitrogen. Herein we report a fourth and more convenient avenue for empty particle formation through EDTA treatment, implicating chelation of virion-associated cations. We present findings that confirm TYMV virions purified in an EDTA-based buffer are converted to 94 % empty on average during purification. Additional experimentation revealed TYMV virions purified through CsCl vs. sucrose gradients are more readily converted to empty particles after freeze thaw. These studies are novel as they show a purification method through EDTA-treatment that can generate stable empty particles devoid of viral genome. The convenience of this method should prove suitable for scientists seeking to use TYMV capsids in nanoscience-inspired applications. Importantly, these findings provide insight into historical discrepancies in creating empty particles after freeze-thaw, as the method in which TYMV virions are purified influences the downstream virion-to-empty conversion process.

Recombinant turnip yellow mosaic virus coat protein as a potential nanocarrier

AIMS

To display a short peptide (GSRSHHHHHH) at the C-terminal end of turnip yellow mosaic virus coat protein (TYMVc) and to study its assembly into virus-like particles (TYMVcHis₆ VLPs).

METHODS AND RESULTS

In this study, recombinant TYMVcHis₆ expressed in Escherichia coli self-assembled into VLPs of approximately 30-32 nm. SDS-PAGE and Western blot analysis of protein fractions from the immobilized metal affinity chromatography (IMAC) showed that TYMVcHis₆ VLPs interacted strongly with nickel ligands in IMAC column, suggesting that the fusion peptide is protruding out from the surface of VLPs. These VLPs are highly stable over a wide pH range from 3·0 to 11·0 at different temperatures. At pH 11·0, specifically, the VLPs remained intact up to 75°C. Additionally, the disassembly and reassembly of TYMVcHis₆ VLPs were studied in vitro. Dynamic light scattering and transmission electron microscopy analysis revealed that TYMVcHis₆ VLPs were dissociated by 7 mol l^-1 urea and 2 mol l^-1 guanidine hydrochloride (GdnHCl) without impairing their reassembly property.

CONCLUSIONS

A 10-residue peptide was successfully displayed on the surface of TYMVcHis₆ VLPs. This chimera demonstrated high stability under extreme thermal conditions with varying pH and was able to dissociate and reassociate into VLPs by chemical denaturants.

SIGNIFICANCE AND IMPACT OF THE STUDY

This is the first C-terminally modified TYMVc produced in E.  coli. The C-terminal tail which is exposed on the surface can be exploited as a useful site to display multiple copies of functional ligands. The ability of the chimeric VLPs to self-assemble after undergo chemical denaturation indicates its potential role to serve as a nanocarrier for use in targeted drug delivery.

Superchiral near fields detect virus structure

Optical spectroscopy can be used to quickly characterise the structural properties of individual molecules. However, it cannot be applied to biological assemblies because light is generally blind to the spatial distribution of the component molecules. This insensitivity arises from the mismatch in length scales between the assemblies (a few tens of nm) and the wavelength of light required to excite chromophores (≥150 nm). Consequently, with conventional spectroscopy, ordered assemblies, such as the icosahedral capsids of viruses, appear to be indistinguishable isotropic spherical objects. This limits potential routes to rapid high-throughput portable detection appropriate for point-of-care diagnostics. Here, we demonstrate that chiral electromagnetic (EM) near fields, which have both enhanced chiral asymmetry (referred to as superchirality) and subwavelength spatial localisation (∼10 nm), can detect the icosahedral structure of virus capsids. Thus, they can detect both the presence and relative orientation of a bound virus capsid. To illustrate the potential uses of the exquisite structural sensitivity of subwavelength superchiral fields, we have used them to successfully detect virus particles in the complex milieu of blood serum.

Encapsidation of genomic but not subgenomic Turnip yellow mosaic virus RNA by coat protein provided in trans

We have studied the encapsidation requirements of Turnip yellow mosaic virus (TYMV) genomic and subgenomic RNA using an "agroinfiltration" procedure involving transient expression of RNAs and coat protein (CP) in Nicotiana benthamiana leaves. Although N. benthamiana is a nonhost, expression of TYMV RNA in its leaves by agroinfiltration resulted in efficient local infection and production of the expected virions containing genomic and subgenomic RNAs together with empty capsids. A nonreplicating genomic RNA with a mutation in the polymerase domain was efficiently encapsidated by CP provided in trans, even though RNA levels were a thousand-fold lower than in normal infections. In contrast, encapsidation of CP mRNA was not observed under these conditions, even when the CP mRNA had authentic 5'- and 3'-termini. Deletion of the 3'-tRNA-like structure from the genomic RNA did not alter the encapsidation behavior, suggesting that this feature does not play a role in the encapsidation of TYMV RNA. Our results indicate differences in the encapsidation process between genomic and subgenomic RNAs, and suggest an interaction between RNA replication and the packaging of subgenomic RNA.

Atomic force microscopy investigation of Turnip Yellow Mosaic Virus capsid disruption and RNA extrusion

Turnip Yellow Mosaic Virus (TYMV) was subjected to a variety of procedures which disrupted the protein capsids and produced exposure of the ssRNA genome. The results of the treatments were visualized by atomic force microscopy (AFM). Both in situ and ex situ freeze-thawing produced RNA emission, though at low efficiency. The RNA lost from such particles was evident, in some cases in the process of exiting the virions. More severe disruption of TYMV and extrusion of intact RNA onto the substrate were produced by drying the virus and rehydrating with neutral buffer. Similar products were also obtained by heating TYMV to 70 -75 degrees C and by exposure to alkaline pH. Experiments showed the nucleic acid to have an elaborate secondary structure distributed linearly along its length.

Crystal Structure of an Empty Capsid of Turnip Yellow Mosaic Virus

Empty capsids (artificial top component) of turnip yellow mosaic virus were co-crystallized with an encapsidation initiator RNA hairpin. No clear density was observed for the RNA, but there were clear differences in the conformation of a loop of the coat protein at the opening of the pentameric capsomer (formed by five A-subunits) protruding from the capsid, compared to the corresponding loop in the intact virus. Further differences were found at the N terminus of the A-subunit. These differences have implications for the mechanism of decapsidation of the virus, required for infection.

Mutation of interfacial residues disrupts subunit folding and particle assembly of Physalis mottle tymovirus

Virus-like particles (VLPs) serve as excellent model systems to identify the pathways of virus assembly. To gain insights into the assembly mechanisms of the Physalis mottle tymovirus (PhMV), six interfacial residues, identified based on the crystal structure of the native and recombinant capsids, were targeted for mutagenesis. The Q37E, Y67A, R68Q, D83A, I123A, and S145A mutants of the PhMV recombinant coat protein (rCP) expressed in Escherichia coli were soluble. However, except for the S145A mutant, which assembled into VLPs similar to that of wild type rCP capsids, all the other mutants failed to assemble into VLPs. Furthermore, the purified Q37E, Y67A, R68Q, D83A, and I123A rCP mutants existed essentially as partially folded monomers as revealed by sucrose density gradient analysis, circular dichroism, fluorescence, thermal, and urea denaturation studies. The rCP mutants locked into such conformations probably lack the structural signals/features that would allow them to assemble into capsids. Thus, the mutation of residues involved in inter-subunit interactions in PhMV disrupts both subunit folding and particle assembly.

Structural studies on the empty capsids of Physalis mottle virus

The three-dimensional crystal structure of the empty capsid of Physalis mottle tymovirus has been determined to 3.2 A resolution. The empty capsids crystallized in the space group P1, leading to 60-fold non-crystallographic redundancy. The known structure of Physalis mottle virus was used as a phasing model to initiate the structure determination by real-space electron-density averaging. The main differences between the structures of the native and the empty capsids were in residues 10 to 28 of the A-subunit, residues 1 to 9 of the B-subunit and residues 1 to 5 of the C-subunit, which are ordered only in the native virus particles. An analysis of the subunit disposition reveals that the virus has expanded radially outward by approximately 1.8 A in the empty particles. The A-subunits move in a direction that makes 10 degrees to the icosahedral 5-fold axes of symmetry. The B and C-subunits move along vectors making 12 degrees and 15 degrees to the quasi 6-fold axes. The quaternary organization of the pentameric and hexameric capsomeres are not altered significantly. However, the pentamer-hexamer contacts are reduced. Therefore, encapsidation of RNA appears to cause a reduction in the particle radius concomittant with the ordering of the N-terminal arm in the three subunits. These structural changes in Physalis mottle virus appear to be larger than the corresponding changes observed in viruses for which both the empty and full particle structures have been determined.

Refined structure of desmodium yellow mottle tymovirus at 2.7 A resolution

Desmodium yellow mottle virus is a 28 nm diameter, T=3 icosahedral plant virus of the tymovirus group. Its structure has been solved to a resolution of 2.7 A using X-ray diffraction analysis based on molecular replacement and phase extension methods. The final R value was 0.151 (R(free)=0.159) for 134,454 independent reflections. The folding of the polypeptide backbone is nearly identical with that of turnip yellow mosaic virus, as is the arrangement of subunits in the virus capsid. However, a major difference in the disposition of the amino-terminal ends of the subunits was observed. In turnip yellow mosaic virus, those from the B and C subunits comprising the hexameric capsomeres formed an annulus about the interior of the capsomere, while the corresponding N termini of the pentameric capsomere A subunits were not visible at all in electron density maps. In Desmodium yellow mottle tymovirus, amino termini from the A and B subunits combine to form the annuli, thereby resulting in a much strengthened association between the two types of capsomeres and an, apparently, more stable capsid. The first 13 residues of the C subunit were invisible in electron density maps. Two ordered fragments of single-stranded RNA, seven and two nucleotides in length, were observed. The ordered water structure of the virus particle was delineated and required 95 solvent molecules per protein subunit.

Polymorphism of turnip yellow mosaic virus empty shells and evidence for conformational changes occurring after release of the viral RNA. A differential scanning calorimetric study

Turnip yellow mosaic virus (TYMV) is a small isometric plant virus which decapsidates by releasing its RNA through a hole in the capsid, leaving behind an empty shell [R. E. F. Matthews and J. Witz, (1985) Virology 144, 318-327]. Similar empty shells (artificial top component, ATC) can be obtained by submitting the virions to various treatments in vitro. We have used differential scanning calorimetry, analytical sedimentation, and electron microscopy to investigate the thermodenaturation of natural empty shells (NTC, natural top component) present in purified virus suspensions, and of several types of ATCs. ATCs divided in two major classes. Those obtained by alkaline titration, by the action of urea or butanol behaved as NTC: their thermograms contained only one peak corresponding to the irreversible dissociation of the shells and the denaturation of the coat protein. The temperature of this unique transition varied significantly with pH, from 71 degrees C at pH 4.5 to 84 degrees C at pH 8.5. The thermograms of ATCs obtained by freezing and thawing, or by the action of high pressure, contained two peaks: shells dissociated first into smaller protein aggregates at 57 degrees C (at pH 5.0) to 61 degrees C (at pH 8.5), which denatured at the temperature of the unique transition of NTC. Shells obtained by heating virions to 55 degrees C at pH 7.6, changed conformation after the release of the viral RNA, as upon continuous heating to 95 degrees C, their thermograms were similar to those of the shells obtained by freezing and thawing, whereas after purification they behaved like NTC. Structural implications of these observations are discussed.

Three-dimensional structure of physalis mottle virus: implications for the viral assembly

The structure of the T=3 single stranded RNA tymovirus, physalis mottle virus (PhMV), has been determined to 3.8 A resolution. PhMV crystals belong to the rhombohedral space group R 3, with one icosahedral particle in the unit cell leading to 20-fold non-crystallographic redundancy. Polyalanine coordinates of the related turnip yellow mosaic virus (TYMV) with which PhMV coat protein shares 32 % amino acid sequence identity were used for obtaining the initial phases. Extensive phase refinement by real space molecular replacement density averaging resulted in an electron density map that revealed density for most of the side-chains and for the 17 residues ordered in PhMV, but not seen in TYMV, at the N terminus of the A subunits. The core secondary and tertiary structures of the subunits have a topology consistent with the capsid proteins of other T=3 plant viruses. The N-terminal arms of the A subunits, which constitute 12 pentamers at the icosahedral 5-fold axes, have a conformation very different from the conformations observed in B and C subunits that constitute hexameric capsomers with near 6-fold symmetry at the icosahedral 3-fold axes. An analysis of the interfacial contacts between protein subunits indicates that the hexamers are held more strongly than pentamers and hexamer-hexamer contacts are more extensive than pentamer-hexamer contacts. These observations suggest a plausible mechanism for the formation of empty capsids, which might be initiated by a change in the conformation of the N-terminal arm of the A subunits. The structure also provides insights into immunological and mutagenesis results. Comparison of PhMV with the sobemovirus, sesbania mosaic virus reveals striking similarities in the overall tertiary fold of the coat protein although the capsid morphologies of these two viruses are very different.

Crystal structure of turnip yellow mosaic virus

The structure of turnip yellow mosaic virus (TYMV) has been solved to 3.2 A resolution and an R-value of 18.7%. The structure is consistent with models based on low resolution X-ray and electron microscopy studies, with pentameric and hexameric protein aggregates protruding from the surface and forming deep valleys at the quasi three-fold axes. The N-terminal 26 residues of the A-subunit are disordered, while those of the B- and C-subunits are seen to interact around the interior of the quasi six-fold cluster where they form an annulus. The three histidine residues of each protein subunit are located in the interior and accessible for interaction with the RNA genome. The appearance of the interior surface of the virus capsid, along with buried surface area calculations, suggest that a pentameric unit is lost during decapsidation.

Difference imaging reveals ordered regions of RNA in turnip yellow mosaic virus

BACKGROUND

Turnip yellow mosaic virus (TYMV) is a small icosahedral plant virus with a capsid containing 180 subunits arranged with hexamer-pentamer clustering. Cross-linking studies have indicated extensive contacts between RNA and coat protein, suggesting that substantial parts of the RNA might be icosahedrally ordered.

RESULTS

Comparison of maps computed to a Fourier cut-off of 1.5 nm from electron micrographs of ice-embedded specimens of TYMV and of empty capsids produced by freeze-thawing reveals strong inner features around the threefold axes in the virus but not in the empty capsid. Internal features of subunit packing indicate that interhexamer contacts are closer than those between pentamers and hexamers and that pentamer density in the empty capsid is reduced relative to that in the virus.

CONCLUSIONS

The differences between virus and empty capsid indicate that substantial parts of the RNA are icosahedrally ordered and that the exit of RNA on freeze-thawing is accompanied by the loss of at least one pentamer unit.

Organization of turnip yellow mosaic virus investigated by neutron small angle scattering at 80 K: an intermediate state preceding decapsidation of the virion?

The organization of turnip yellow mosaic virus has been investigated by neutron small angle scattering at 300 K and 80 K in buffers containing various amounts of D2O. We confirm that in native virions, no substantial part of the RNA is located at a radius larger than ca. 100-110 A, i.e., that there is very little interpretation of the RNA into the capsid. At 80 K, scattering curves do not depend much upon contrast, from 40% D2O to 100% D2O buffers, but are strongly affected by interparticle interference. We could, however, show that it is not the case for the subsidiary intensity maximum at q approximately 0.06 A-1. From the position of this maximum, we conclude that upon freezing, the radius of the capsid expands by c.a. 3.5% and the RNA penetrates deeply into the protein shell. Biological implications of this conformational change immediately preceding decapsidation are discussed.

The thermal stability and decapsidation mechanism of tymoviruses: a differential calorimetric study

The thermal stability of virions present in purified suspensions of three tymoviruses, turnip yellow mosaic virus (TYMV), belladonna mottle virus (BelMV) and eggplant mosaic virus (EMV) was investigated by microcalorimetry. Virions are less stable than natural empty shells at 4.5 < or = pH < or = 8.5. Polyvalent cations present in TYMV stabilize the virions at pH < or = 5.0 only. Virions decapsidate in three steps: i) the release of the viral RNA, probably through a hole in the capsid; ii) the dissociation of the artificial empty shells thus formed; and iii) the denaturation of the dissociated components. An exothermic process accompanies the first step. Structural implications are discussed.

Universal calibration of gel permeation chromatography and determination of molecular shape in solution

Gel permeation chromatography (GPC) has become a routine technique for both biology and polymer chemistry. By comparison our theoretical perception of the separation principle of GPC is still immature and conflicting and so is the assessment of the analytical informational content of this method. In order to discriminate between the various parameters that might influence GPC and thus to decide among the numerous propositions of calibration, several odd biopolymers (tropomyosin, spectrin, DNA, tobacco mosaic virus, alpha-actinin, ovomucoid) were selected. They were characterized by analytical ultracentrifugation as well as quasielastic light scattering, and they were compared to globular proteins including icosahedral viruses (tomato bushy stunt virus, turnip yellow mosaic virus, Q beta, MS2) on several different HPLC column matrices. The results demonstrate that the universal calibration principle of GPC is the viscosity radius, i.e., the molecular volume times a shape function which is defined by the intrinsic viscosity. Alternate propositions such as molecular weight, second virial coefficient, diffusion coefficient (Stokes radius), radius of gyration, mean linear projected length, contour length, and related measures seem to be excluded on the basis of the evidence presented. These results help to focus the physical picture which seems to govern GPC. Finally it is demonstrated that GPC is a versatile and unique tool with which to characterize molecular shape and dynamics in solution.

A circular dichroism study of the Turnip yellow mosaic virus-RNA

We examined the circular dichroism spectra of intact Turnip yellow mosaic virus, freezed/thawed virus, empty capsid particles, and phenol extracted RNA. The circular dichroism signal of the empty capsid was found to contribute for less than 1% to the circular dichroism of the virus. Differences in the circular dichroism spectra indicate that TYMV-RNA exhibits different conformations when it is in situ in the virus, when it has been ejected by freezing/thawing and when it has been phenol extracted. Increase of the ionic strength up to 0.1 M NaCl led to conformational change of the RNA either freezed/thawed ejected or phenol extracted but not in situ in the capsid. Addition of spermidine (3 mM) induced a conformational change only for the phenol extracted RNA. These results are discussed with respect to the origin of the various conformational states of viral RNA.

1H, 13C, and 31P nuclear magnetic resonance studies of cowpea mosaic virus: detection and exchange of polyamines and dynamics of the RNA

1H and 13C NMR studies on cowpea mosaic virus (CpMV) revealed that polyamines are present in the middle (M) and upper bottom (BU) components obtained by CsCl density gradient centrifugation but not in the top (T) component; the lower bottom (BL) component contains trace amounts of polyamine. Dialysis of the BL component against spermidine led to incorporation of spermidine which gave rise to NMR peaks very similar to those observed with the natural M and BU components. NMR results conclusively demonstrate that polyamines in the M and BU components of CpMV are exchangeable with cesium ions and the exchange process is pH dependent. They also provide experimental support for the hypothesis that the BU to BL conversion results from the displacement of polyamines and possibly other natural counter ions of the RNA by cesium ions [G. Bruening, (1977), In "Comprehensive Virology" (H. Fraenkel-Conrat and R. R. Wagner, eds.), Vol. 11, pp. 55-141. Plenum, New York]. No sharp peaks, attributable to mobile amino acid side chains, were seen in spectra of an intact CpMV particle or its empty protein shell (T component). 31P NMR spin-lattice relaxation time and nuclear Overhauser effect parameters, which are sensitive to high-frequency motions, suggest that the RNA and, when present, the bound polyamine undergo internal motions with correlation times in the nanosecond range.