Role of metal ion-mediated interactions in the assembly and stability of Sesbania mosaic virus T=3 and T=1 capsids

Sesbania mosaic virus (SeMV) capsids are stabilized by RNA-protein, protein-protein and calcium-mediated protein-protein interactions. The removal of calcium has been proposed to be a prerequisite for the disassembly of the virus. The crystal structure of native T=3 SeMV capsid revealed that residues D146 and D149 from one subunit and Y205, N267 and N268 of the neighboring subunit form the calcium-binding site (CBS). The CBS environment is found to be identical even in the recombinant CP-NDelta65 T=1 capsids. Here, we have addressed the role of calcium and the residues involved in calcium co-ordination in the assembly and stability of T=3 and T=1 capsids by mutational analysis. Deletion of N267 and N268 did not affect T=3 or T=1 assembly, although the capsids were devoid of calcium, suggesting that assembly does not require calcium ions. However, the stability of the capsids was reduced drastically. Site-directed mutagenesis revealed that either a single mutation (D149N) or a double mutation (D146N-D149N) of SeMV coat protein affected drastically both the assembly and stability of T=3 capsids. On the other hand, the D146N-D149N mutation in CP-NDelta65 did not affect the assembly of T=1 capsid, although their stability was reduced considerably. Since the major difference between the T=3 and T=1 capsids is the absence of the N-terminal arginine-rich motif (N-ARM) and the beta-annulus from the subunits forming the T=1 capsids, it is possible that D149 initiates the N-ARM-RNA interactions that lead to the formation of the beta-annulus, which is essential for T=3 capsid assembly.     

The role of arginine-rich motif and beta-annulus in the assembly and stability of Sesbania mosaic virus capsids

Sesbania mosaic virus (SeMV) capsids are stabilized by protein-protein, protein-RNA and calcium-mediated protein-protein interactions. The N-terminal random domain of SeMV coat protein (CP) controls RNA encapsidation and size of the capsids and has two important motifs, the arginine-rich motif (ARM) and the beta-annulus structure. Here, mutational analysis of the arginine residues present in the ARM to glutamic acid was carried out. Mutation of all the arginine residues in the ARM almost completely abolished RNA encapsidation, although the assembly of T=3 capsids was not affected. A minimum of three arginine residues was found to be essential for RNA encapsidation. The mutant capsids devoid of RNA were less stable to thermal denaturation when compared to wild-type capsids. The results suggest that capsid assembly is entirely mediated by CP-dependent protein-protein inter-subunit interactions and encapsidation of genomic RNA enhances the stability of the capsids. Because of the unique structural ordering of beta-annulus segment at the icosahedral 3-folds, it has been suggested as the switch that determines the pentameric and hexameric clustering of CP subunits essential for T=3 capsid assembly. Surprisingly, mutation of a conserved proline within the segment that forms the beta-annulus to alanine, or deletion of residues 48-53 involved in hydrogen bonding interactions with residues 54-58 of the 3-fold related subunit or deletion of all the residues (48-59) involved in the formation of beta-annulus did not affect capsid assembly. These results suggest that the switch for assembly into T=3 capsids is not the beta-annulus. The ordered beta-annulus observed in the structures of many viruses could be a consequence of assembly to optimize intersubunit interactions.     

Kinetics of thermal aggregation of tobacco mosaic virus coat protein

The kinetics of thermal aggregation of coat protein (CP) of tobacco mosaic virus (TMV) have been studied at 42 and 52°C in a wide range of protein concentrations, [P]₀. The kinetics of aggregation were followed by monitoring the increase in the apparent absorbance (A) at 320 nm. At 52°C the kinetic curves may be approximated by the exponential law in the range of TMV CP concentrations from 0.02 to 0.30 mg/ml, the first order rate constant being linearly proportional to [P]₀ (50 mM phosphate buffer, pH 8.0). The analogous picture was observed at 42°C in the range of TMV CP concentrations from 0.01 to 0.04 mg/ml (100 mM phosphate buffer, pH 8.0). At higher TMV CP concentrations the time of half-conversion approaches a limiting value with increasing [P]₀ and at sufficiently high protein concentrations the kinetic curves fall on a common curve in the coordinates {A/A _lim; t} (t is time and A _lim is the limiting value of A at t ). According to a mechanism of aggregation of TMV CP proposed by the authors at rather low protein concentrations the rate of aggregation is limited by the stage of growth of aggregate, which proceeds as a reaction of the pseudo-first order, whereas at rather high protein concentrations the rate-limiting stage is the stage of protein molecule unfolding.     

Characterization of cymbidium mosaic virus coat protein gene and its expression in transgenic tobacco plants

Cymbidium mosaic virus (CyMV) is the most prevalent virus infecting orchids. Here, we report the isolation of partial cDNA clones encoding the genomic RNA of CyMV. Like most of the polyadenylated monopartite positive-strand RNA viruses, the open reading frame (ORF) coding for the viral coat protein (CP) is located at the 3 end. The ORF predicts a polypeptide chain of 220 amino acids with a molecular weight of 23 600. Sequence comparison of this ORF to the CP sequences of potato virus X(PVX) and white clover mosaic virus (WCIMV) revealed a strong amino acid homology in the mid-portion of the CP, but the overall homology was low. The CyMV CP gene was placed downstream of a cauliflower mosaic virus 35S promoter and the chimaeric gene was transferred into Nicotiana benthamiana. Transgenic plants expressing the CyMV CP were protected against CyMV infection.     

Low sodium dodecyl sulfate concentrations inhibit tobacco mosaic virus coat protein amorphous aggregation and change the protein stability

Effects of low SDS concentrations on amorphous aggregation of tobacco mosaic virus (TMV) coat protein (CP) at 52 degrees C and on the protein structure were studied. It was found that SDS completely inhibits the TMV CP (11.5 microM) unordered aggregation at the detergent/CP molar ratio of 15 : 1 (0.005% SDS). As judged by fluorescence spectroscopy, these SDS concentrations did not prevent heating-induced disordering of the large-distance part of the TMV CP subunit, including the so-called "hydrophobic girdle". At somewhat higher SDS/protein ratio (40 : 1) the detergent completely disrupted the TMV CP hydrophobic girdle structure even at room temperature. At the same time, these low SDS concentrations (15 : 1, 40 : 1) strongly stabilized the structure of the small-distance part of the TMV CP molecule (the four alpha-helix bundle) against thermal disordering as judged by the far-UV (200-250 nm) CD spectra. Possible mechanisms of TMV CP heating-induced unordered aggregation initiation are discussed.     

The potential use of a viral coat protein gene as a transgene screening marker and multiple virus resistance of pepper plants coexpressing coat proteins of cucumber mosaic virus and tomato mosaic virus

Transgenic pepper plants coexpressing coat proteins (CPs) of cucumber mosaic virus (CMV-Kor) and tomato mosaic virus (ToMV) were produced by Agrobacterium-mediated transformation. To facilitate selection for positive transformants in transgenic peppers carrying an L gene, we developed a simple and effective screening procedure using hypersensitive response upon ToMV challenge inoculation. In this procedure, positive transformants could be clearly differentiated from the nontransformed plants. Transgenic pepper plants expressing the CP genes of both viruses were tested for resistance against CMV-Kor and pepper mild mottle virus (PMMV). In most transgenic plants, viral propagation was substantially retarded when compared to the nontransgenic plants. These experiments demonstrate that our transgenic pepper plants might be a useful marker system for the transgene screening and useful for classical breeding programs of developing virus resistant hot pepper plants.     

Expression of coat protein gene of Cucumber mosaic virus (CMV-subgroup IA) Gladiolus isolate in Nicotiana tabacum

The coat protein (CP)-mediated resistance against Cucumber mosaic virus (CMV) subgroup IA was developed in transgenic lines of Nicotiana tabacum cv. Petit Havana using Agrobacterium tumefaciens-mediated transformation. Ten independently transformed lines have developed, four of which were tested for resistance against CMV using virus challenge inoculations. The transgenic lines exhibiting complete resistance remained healthy and symptomless in their life span and showed reduced or no virus accumulation in their systemic leaves after virus challenge inoculation. These transgenic lines also showed resistance against CMV strains which are not closely related to CMV-Gladiolus strains. This is the first report of CP-mediated transgenic resistance against a CMV subgroup IA member isolated from India showing resistance to all CMV strains occurring in the same vicinity.     

Interaction with capsid protein alters RNA structure and the pathway for in vitro assembly of cowpea chlorotic mottle virus

Viruses use sophisticated mechanisms to allow the specific packaging of their genome over that of host nucleic acids. We examined the in vitro assembly of the Cowpea chlorotic mottle virus (CCMV) and observed that assembly with viral RNA follows two different mechanisms. Initially, CCMV capsid protein (CP) dimers bind RNA with low cooperativity and form virus-like particles of 90 CP dimers and one copy of RNA. Longer incubation reveals a different assembly path. At a stoichiometry of about ten CP dimers per RNA, the CP slowly folds the RNA into a compact structure that can be bound with high cooperativity by additional CP dimers. This folding process is exclusively a function of CP quaternary structure and is independent of RNA sequence. CP-induced folding is distinct from RNA folding that depends on base-pairing to stabilize tertiary structure. We hypothesize that specific encapsidation of viral RNA is a three-step process: specific binding by a few copies of CP, RNA folding, and then cooperative binding of CP to the "labeled" nucleoprotein complex. This mechanism, observed in a plant virus, may be applicable to other viruses that do not halt synthesis of host nucleic acid, including HIV.     

登革病毒衣壳蛋白在大肠杆菌中的表达及其自组装活性的研究

采用高保真RT-PCR自登革2型病毒43株基因组RNA中扩增全长C基因及缺失羧基端Cv片段,分别构建可表达C及Cv的重组质粒pLEX—C和pLEX—Cv,转化E．coliGI724后用色氨酸诱导表达。经SDS—PAGE分析,表达的C及Cv蛋白相对分子质量分别约为12000和10000,分别约占菌体蛋白总量的19％和13％。Western印迹检测表明重组表达的C蛋白均可被特异识别登革病毒衣壳蛋白的单克隆抗体特异识别。表达的蛋白经过硫酸铵沉淀和蔗糖密度梯度离心后,通过琼脂糖凝胶电泳和负染电镜均未能检测到衣壳样颗粒的存在,说明登革病毒衣壳蛋白可能不具体外自组装活性。     

Structure of hibiscus latent singapore virus by fiber diffraction: a nonconserved his122 contributes to coat protein stability

Hibiscus latent Singapore virus (HLSV) is a rigid rod-shaped plant virus and a new member of the Tobamovirus family. Unlike all other Tobamoviruses, the HLSV genome contains a unique poly(A) tract in its 3′ untranslated region. The virion is composed of a monomeric coat protein (CP) unit of 18 kDa, arranged as a right-handed helix around the virus axis. We have determined the structure of HLSV at 3.5 Å by X-ray fiber diffraction and refined it to an R-factor of 0.096. While the overall structure of the HLSV CP resembles that of other Tobamoviruses, there are a few unique differences. There is a kink in the LR helix due to the presence of His122. Also, the adjacent Lys123 may further destabilize the helix by positive charge repulsion, making the kink more pronounced. The His122-Asp88 salt bridge provides significant stability to the loop adjacent to the RR helix. Carboxyl-carboxylate interactions that drive viral disassembly are also different in HLSV. The nucleotide recognition mechanisms for virus assembly between HLSV and ribgrass mosaic virus are similar, but different between tobacco mosaic virus and cucumber green mottle mosaic virus.     

Transgenic tobacco plants expressing the coat protein of cucumber mosaic virus show different virus resistance

Transgenic tobacco (Nicotiana tabacum cv. Xanthi-nc) plants were regenerated after cocultivation of leaf explants withAgrobacterium tumefaciens strain LBA4404 harboring a plasmid that contained the coat protein (CP) gene of cucumber mosaic virus (CMV-As). PCR and Southern blot analyses revealed that the CMV CP gene was successfully introduced into the genomic DNA of the transgenic tobacco plants. Transgenic plants (CP⁺) expressing CP were obtained and used for screening the virus resistance. They could be categorized into three types after inoculation with the virus: virus-resistant, delay of symptom development, and susceptible type. Most of the CP⁺ transgenic tobacco plants failed to develop symptoms or showed systemic symptom development delayed for 5 to 42 days as compared to those of nontransgenic control plants after challenged with the same virus. However, some CP⁺ transgenic plants were highly susceptible after inoculation with the virus. Our results suggest that the CP-mediated viral resistance is readily applicable to CMV disease in other crops.     

Alterations of the conformation of the RNAs of alfalfa mosaic virus upon binding of a few coat protein molecules

Structural changes in the single-stranded genome RNAs (RNAs 1, 2 and 3) and the subgenomic coat protein messenger (RNA 4) of alfalfa mosaic virus upon addition of a few coat protein molecules of the virus were investigated by measuring the fluorescent intensity of bound ethidium bromide and by circular dichroism. No effect could be observed in the case of the genome RNAs. However, in RNA 4, which is of much less complexity than the genome RNAs, a reduction of the ethidium bromide binding by 30% was found, whereas the positive molar ellipticity at 265 nm was reduced by 9% upon binding of the coat protein. Both changes point to a reduction of the ordered structure of the RNA. Since the protein is known to bind first at the 3′-terminus of RNA 4 and probably also of the genome RNAs, the conformational changes observed could be those thought to be necessary for replicase recognition in this positive-stranded RNA virus which needs the coat protein for starting an infection cycle.     

Isolation of mutants of Arabidopsis thaliana in which accumulation of tobacco mosaic virus coat protein is reduced to low levels.

Summary We have found that Arahidopsis thaliana is susceptible to infection with a crucifer strain of tobacco mosaic virus (TMV-Cg); the coat protein of TMV-Cg accumulated to a high level in uninoculated rosette leaves several days after inoculation. As a first step in the search for host-coded factors that are involved in virus multiplication, we isolated mutants of A. thaliana in which the accumulation of TMV-Cg coat protein was reduced to low levels. Of 6000 M₂ plants descended from ethyl methanesulfonate-treated seeds, two such lines (PD 114 and PD378) were isolated. Genetic analyses suggested that the PD 114 phenotype was caused by a single nuclear recessive mutation, and that PD114 and PD378 belonged to the same complementation group. The coat protein accumulation of a tomato strain of TMV (TMVL) was also reduced in PD 114 plants compared to that in the wild-type plants. In contrast, PD114 plants infected with turnip crinkle or turnip yellow mosaic viruses, which belong to taxonomic groups other than Tobamovirus, expressed similar levels of these coat proteins as did infected wild-type plants.In this paper, we use the term multiplication (of a virus in a plant) to mean a substantial increase in virus concentration in the uninoculated leaves of the infected plant. Therefore, the efficiency of each process of invasion of the plant by the virus, uncoating, replication and degradation of the virus genome, formation and degradation of the virus particles, and spreading of the virus in the plant will affect the degree of multiplication     

Properties of a host range and coat protein variant of broad bean true mosaic comovirus from Vicia faba

Unlike other described isolates of broad bean true mosaic comovirus (BBTMV), a variant, code name SB, infected some non-leguminous plant species and, in N. benthamiana, induced systemic mottling and puckering of the leaves. However, like other described BBTMV isolates, purified SB particle preparations contained isometric particles c. 28 nm in diameter that sedimented as two nucleoprotein components with S_{20, w} values of 90S and 109S; some preparations occasionally contained a component of c. 50S. Virus particles contained two ssRNA species which, when denatured in glyoxal, had estimated M_T values of 2.1 × 10⁶ and 1.3 × 10⁶ and co-electrophoresed with cowpea mosaic virus RNA-1 and RNA-2 respectively. Isolate SB was serologically indistinguishable from British and German isolates of BBTMV. However, SB virus particles contained a major polypeptide (L) of M_r between c. 31 000 and up to three minor ones (S) or M_r between c. 20 000 and 24 000. This contrasts with protein preparations from other BBTMV isolates that typically contain only two polypeptides of M_r c. 37 000 (L) and 21 000 (S). Following isopycnic centrifugation in CsCl, SB particles purified from pea separated into two major components with densities of 1.39 and 1.44 g cm^-3 and a minor component of estimated density 1.43 g cm^-3. In Cs₂SO₄, virus preparations separated into three major components with densities of 1.30, 1.32 and 1.36 g cm^-3 and a minor one of density 1.27 g cm^-3. In CsCl isopycnic gradients, SB particles purified from TV. benthamiana separated into two components with densities of 1.38 and 1.43 g cm^-3. During immuno-electrophoresis in agarose gels, freshly prepared virus and preparations stored for up to 4 days at 4°C contained a single component that migrated rapidly to the anode, whereas similar preparations of an English isolate of BBTMV migrated as a single component that moved only slowly toward the anode but which, within 48 h, contained an additional component with a migration rate similar to that of isolate SB. Isolate SB is therefore a host range variant of BBTMV which, in comparison with previously described isolates of BBTMV, has an increased negative charge of its particles prior to any appreciable degradation of its S protein, and S protein that is degraded less rapidly. These features probably account for the anomalies observed in isopycnic centrifugation.     

A pathogenicity determinant maps to the N‐terminal coat protein region of the Pepino mosaic virus genome

Pepino mosaic virus (PepMV) poses a worldwide threat to the tomato industry. Considerable differences at the genetic level allow for the distinction of four main genotypic clusters; however, the basis of the phenotypic outcome is difficult to elucidate. This work reports the generation of wild‐type PepMV infectious clones of both EU (mild) and CH2 (aggressive) genotypes, from which chimeric infectious clones were created. Phenotypic analysis in three solanaceous hosts, Nicotiana benthamiana, Datura stramonium and Solanum lycopersicum, indicated that a PepMV pathogenicity determinant mapped to the 3′‐terminal region of the genome. Increased aggression was only observed in N. benthamiana, showing that this factor is host specific. The determinant was localized to amino acids 11–26 of the N‐terminal coat protein (CP) region; this is the first report of this region functioning as a virulence factor in PepMV.     

Novel enzymatic activity derived from the Semliki Forest virus capsid protein

The N-terminal segment of the Semliki Forest virus polyprotein is an intramolecular serine protease that cleaves itself off after the invariant Trp267 from a viral polyprotein and generates the mature capsid protein. After this autoproteolytic cleavage, the free carboxylic group of Trp267 interacts with the catalytic triad (His145, Asp167 and Ser219) and inactivates the enzyme. We have deleted the last 1-7 C-terminal residues of the mature capsid protease to investigate whether removal of Trp267 regenerates enzymatic activity. Although the C-terminally truncated polypeptides do not adopt a defined three-dimensional structure and show biophysical properties observed in natively unfolded proteins, they efficiently catalyse the hydrolysis of aromatic amino acid esters, with higher catalytic efficiency for tryptophan compared to tyrosine esters and k_cat/K_M values up to 5 × 10⁵ s⁻¹ M⁻¹. The enzymatic mechanism of these deletion variants is typical of serine proteases. The pH enzyme activity profile shows a pK_a1 = 6.9, and the Ser219Ala substitution destroys the enzymatic activity. In addition, the fast release of the first product of the enzymatic reaction is followed by a steady-state second phase, indicative of formation and breakdown of a covalent acyl-enzyme intermediate. The rates of acylation and deacylation are k₂ = 4.4±0.6 s⁻¹ and k₃ = 1.6±0.5 s⁻¹, respectively, for a tyrosine derivative ester substrate, and the amplitude of the burst phase indicates that 95% of the enzyme molecules are active. In summary, our data provide further evidence for the potential catalytic activity of natively unfolded proteins, and provide the basis for engineering of alphavirus capsid proteins towards hydrolytic enzymes with novel specificities.     

Dissecting the multifunctional role of the N‐terminal domain of the Melon necrotic spot virus coat protein in RNA packaging,viral movement and interference with antiviral plant defence

The coat protein (CP) of Melon necrotic spot virus (MNSV) is structurally composed of three major domains. The middle S‐domain builds a robust protein shell around the viral genome, whereas the C‐terminal protruding domain, or P‐domain, is involved in the attachment of virions to the transmission vector. Here, we have shown that the N‐terminal domain, or R‐domain, and the arm region, which connects the R‐domain and S‐domain, are involved in different key steps of the viral cycle, such as cell‐to‐cell movement and the suppression of RNA silencing and pathogenesis through their RNA‐binding capabilities. Deletion mutants revealed that the CP RNA‐binding ability was abolished only after complete, but not partial, deletion of the R‐domain and the arm region. However, a comparison of the apparent dissociation constants for the CP RNA‐binding reaction of several partial deletion mutants showed that the arm region played a more relevant role than the R‐domain in in vitro RNA binding. Similar results were obtained in in vivo assays, although, in this case, full‐length CPs were required to encapsidate full‐length genomes. We also found that the R‐domain carboxyl portion and the arm region were essential for efficient cell‐to‐cell movement, for enhancement of Potato virus X pathogenicity, for suppression of systemic RNA silencing and for binding of small RNAs. Therefore, unlike other carmovirus CPs, the R‐domain and the arm region of MNSV CP have acquired, in addition to other essential functions such as genome binding and encapsidation functions, the ability to suppress RNA silencing by preventing systemic small RNA transport.     

Molecular analysis of the capsid protein gene of a german isolate of barley mild mosaic virus

Summary Barley mild mosaic virus (BaMMV) is one of the agents causing the barley yellow mosaic disease. The sequence corresponding to the 3end of the BaMMV RNA1 of a German isolate was sequenced and the coding sequence for the 251 amino acid containing capsid protein was determined. Comparison of this sequence to other potyviral sequences and to the corresponding sequence of two Japanese isolates of BaMMV was done. The three different isolates of BaMMV show a high degree of similarity.Abbrevations BaMMV barley mild mosaic virus - BaYMV barley yellow mosaic virus; bp: base pair - IPTG isopropyl -D thiogalactopyranoside - kb kilo base - NTR nontranslated region - ORF open reading frame - PVDF polyvinylidene difluoride