Tobacco mosaic virus: model for structure and function of a simple virus

From stars to stripes: RNA-directed shaping of plant viral protein templates-structural synthetic virology for smart biohybrid nanostructures

The self-assembly of viral building blocks bears exciting prospects for fabricating new types of bionanoparticles with multivalent protein shells. These enable a spatially controlled immobilization of functionalities at highest surface densities-an increasing demand worldwide for applications from vaccination to tissue engineering, biocatalysis, and sensing. Certain plant viruses hold particular promise because they are sustainably available, biodegradable, nonpathogenic for mammals, and amenable to in vitro self-organization of virus-like particles. This offers great opportunities for their redesign into novel "green" carrier systems by spatial and structural synthetic biology approaches, as worked out here for the robust nanotubular tobacco mosaic virus (TMV) as prime example. Natural TMV of 300 x 18 nm is built from more than 2,100 identical coat proteins (CPs) helically arranged around a 6,395 nucleotides ssRNA. In vitro, TMV-like particles (TLPs) may self-assemble also from modified CPs and RNAs if the latter contain an Origin of Assembly structure, which initiates a bidirectional encapsidation. By way of tailored RNA, the process can be reprogrammed to yield uncommon shapes such as branched nanoobjects. The nonsymmetric mechanism also proceeds on 3'-terminally immobilized RNA and can integrate distinct CP types in blends or serially. Other emerging plant virus-deduced systems include the usually isometric cowpea chlorotic mottle virus (CCMV) with further strikingly altered structures up to "cherrybombs" with protruding nucleic acids. Cartoon strips and pictorial descriptions of major RNA-based strategies induct the reader into a rare field of nanoconstruction that can give rise to utile soft-matter architectures for complex tasks. This article is categorized under: Biology-Inspired Nanomaterials > Protein and Virus-Based Structures Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Biology-Inspired Nanomaterials > Nucleic Acid-Based Structures.

In vitro transcription of infectious RNAs from full-length cDNAs of tobacco mosaic virus

We have cloned full-length double-stranded cDNAs of tobacco mosaic virus (TMV) (tomato strain L) RNA into a transcription vector, pPM1, which facilitates the correct transcription initiation from the first nucleotide of the inserted double-stranded cDNA, corresponding to the 5' end of TMV RNA. When plasmid DNA is linearized at a unique restriction site (Mlu I) introduced just downstream of the double-stranded cDNA insert and used as a template for in vitro transcription by Escherichia coli RNA polymerase in the presence of m(7)GpppG, the transcribed RNAs are infectious for tobacco plants. A simple reconstitution procedure increases the infectivity >100 times. Unexpectedly, both the uncapped transcript and the transcript from the uncut plasmid DNA are also infectious, although their infectivities are very low. The progeny viruses multiplying in tobacco plants accurately reflect the cloned sequence. By the same method, we succeeded in the in vitro transcription of infectious RNA of attenuated strain L(11)A, which is phenotypically distinguishable from wild-type TMV on both tobacco and tomato plants.

Elongation in the major direction of tobacco mosaic virus assembly

Butler and Lomonossoff [Butler, P. J. G. & Lomonossoff, G. P. (1978) J. Mol. Biol. 126, 877-882] claim that the elongation in the major direction (3'-->5') proceeds by incorporation of disk protein in tobacco mosaic virus (TMV) assembly. The strongest argument they have for this theory is the periodicity of 50 or 100 nucleotides that they observed in the banding pattern of the protected RNAs during the first few minutes of the assembly reaction. We repeated their experiment using TMV-OM (a common Japanese strain) disk protein and TMV-OM RNA. We observed a banding pattern similar to theirs, but we found the long protected RNA at 6 min to be from the 260-nm intermediate particle rather than from the full-length TMV RNA. We also carried out the assembly reaction between TMV-OM disk protein, as well as cucumber green mottle mosaic virus (CGMMV) protein, and three strains of TMV RNAs. During the course of each assembly reaction, we examined the banding patterns. We demonstrated that the banding pattern of the protected RNA differs depending on what kind of RNA is used, rather than on what kind of aggregational state the protein is in. Specifically, the similar banding pattern observed for CGMMV subunit protein was also observed for TMV disk protein in the assembly reaction with TMV (OM) RNA. We showed previously that the assembly reaction between CGMMV protein and TMV RNA proceeds by incorporation of CGMMV subunit protein. This strongly indicates that the banding pattern of the protected RNA does not arise from the stepwise addition of the 20S disk protein.

Subgenomic RNAs with nucleotide sequences derived from RNAs 1 and 2 of cucumber mosaic virus can act as messenger RNAs in vitro

Encapsidated RNAs of cucumber mosaic virus (CMV) were analyzed by hybridization to specific probes after gel electrophoresis. [32P]-complementary DNA (cDNA) probes were prepared by transcription of genomic RNA 1 and RNA 2 nucleotide sequences that had been cloned in a bacteriophage M13 vector. Probes that correspond to unique sequences near the 3' ends of RNA 1 and RNA 2 revealed over 20 smaller RNAs. The subgenomic RNAs derived from each genomic RNA were analyzed more definitively by hybrid selection from total encapsidated RNA, using minus DNA clones derived from sequences in either RNA 1 or RNA 2, and a cDNA probe for the 3' sequence conserved among all the genomic RNAs. Different patterns of over 20 minor RNA species, which were 3'-coterminal with RNAs 1 and 2, were detected, and they were reproducible irrespective of the host, cucumber or Nicotiana clevelandii, from which the virus was isolated. The same RNA patterns were found in RNA extracted from the particulate fraction of CMV-infected cucumber orN. clevelandii. In order to determine whether the subgenomic RNAs could function as messenger RNAs, hybrid-selected RNAs were tested by in vitro translation, using the rabbit reticulocyte lysate. The subgenomic RNAs from RNA 1 produced over 10 major polypeptides from Mr 27,000 to Mr 90,000 all of which could be translated from a few RNA species over about 2,300 nucleotides long. The 3'-coterminal subgenomic RNAs derived from RNA 2 gave less than 10 products from Mr, 17,000 toM(r) 85,000. The smallest product (Mr 17,000) was produced by an RNA about 880 nucleotides long, whereas longer RNAs from 1400 to 2500 nucleotides were efficient mRNAs for polypeptides from Mr 30,000 up to the largest translation products consistent with the size of the RNA.

Identification of the 30K protein of TMV by immunoprecipitation with antibodies directed against a synthetic peptide

A synthetic hexadecapeptide corresponding to the predicted C-terminal sequence of the 30K protein of TMV has been coupled to bovine serum albumin and used to raise antibodies in rabbits. The resulting antiserum reacted with the 30K protein translated in vitro. We report the use of this antiserum in the first detection of the 30K protein in vivo, in TMV-infected tobacco protoplasts. Several proteins, the so called family of 30K-related peptides, were immunoprecipitated among in vitro translation products, but only the 30K protein was immunoprecipitated from TMV-infected protoplasts.

Evidence that RNA 4 of alfalfa mosaic virus does not replicate autonomously

A mutant (Tbts7) of alfalfa mosaic virus, the coat protein of which is unable to activate the viral genome (the RNA species 1, 2, and 3, which need some coat protein for infectivity) at 30 degrees , can be rescued at this temperature by adding to the inoculum wild-type RNA 3 (the genome part that contains the coat protein cistron), but not adding wild-type RNA 4 (the subgenomic messenger for the coat protein). Unless RNA 3 of Tbts 7 has a second ts mutation at a site not occurring in RNA 4, it may be concluded from the above finding that RNA 4 does not replicate autonomously.

Virus-like particles assemble in plants and bacteria expressing the coat protein gene of Indian peanut clump virus

cDNA copies of the coat protein (CP) gene of Indian peanut clump virus (IPCV)-H were introduced into cells of Nicotiana benthamiana or Escherichia coli by transformation with vectors based on pROKII or pET respectively. In both plant and bacterial cells, IPCV CP was expressed and assembled to form virus-like particles (VLP). In plant extracts, the smallest preponderant particle length was about 50 nm. Other abundant lengths were about 85 and about 120 nm. The commonest VLP length in bacterial extracts was about 30 nm. Many of the longer VLP appeared to comprise aggregates of shorter particles. The lengths of the supposed 'monomer' VLP corresponded approximately to those expected for encapsidated CP gene transcript RNA. Immunocapture RT-PCR, using primers designed to amplify the CP gene, confirmed that the VLP contained RNA encoding IPCV-H CP. The results show that encapsidation does not require the presence of the 5'-terminal untranslated sequence of the virus RNA and suggest that if there is an 'origin of assembly' motif or sequence, it lies within the CP gene. When transgenic plants expressing IPCV-H CP were inoculated with IPCV-L, a strain that is serologically distinct from IPCV-H, the virus particles that accumulated contained both types of CP.

Biophysical characterization of a designed TMV coat protein mutant, R46G, that elicits a moderate hypersensitivity response in Nicotiana sylvestris

The hypersensitivity resistance response directed by the N' gene in Nicotiana sylvestris is elicited by the tobacco mosaic virus (TMV) coat protein R46G, but not by the U1 wild-type TMV coat protein. In this study, the structural and hydrodynamic properties of R46G and wild-type coat proteins were compared for variations that may explain N' gene elicitation. Circular dichroism spectroscopy reveals no significant secondary or tertiary structural differences between the elicitor and nonelicitor coat proteins. Analytical ultracentrifugation studies, however, do show different concentration dependencies of the weight average sedimentation coefficients at 4 degrees C. Viral reconstitution kinetics at 20 degrees C were used to determine viral assembly rates and as an initial assay of the rate of 20S formation, the obligate species for viral reconstitution. These kinetic results reveal a decreased lag time for reconstitution performed with R46G that initially lack the 20S aggregate. However, experiments performed with 20S initially present reveal no detectable differences indicating that the mechanism of viral assembly is similar for the two coat protein species. Therefore, an increased rate of 20S formation from R46G subunits may explain the differences in the viral reconstitution lag times. The inferred increase in the rate of 20S formation is verified by direct measurement of the 20S boundary as a function of time at 20 degrees C using velocity sedimentation analysis. These results are consistent with the interpretation that there may be an altered size distribution and/or lifetime of the small coat protein aggregates in elicitors that allows N. sylvestris to recognize the invading virus.

Structural analysis of A-protein of cucumber green mottle mosaic virus and tobacco mosaic virus by synchrotron small-angle X-ray scattering

The size and shape of A-protein of tobacco mosaic virus coat protein (TMVP) and cucumber green mottle mosaic virus coat protein (CGMMVP) were evaluated by means of small-angle X-ray scattering (SAXS) using a synchrotron radiation source, complemented by electron microscopic observations. The results imply that TMV and CGMMV A-proteins are composed of three and two subunits, respectively, stacked in the shape of an isosceles triangular prism at lower ionic strength. Considering the difference of the A-protein structure at higher and lower ionic strength, the globular core structure was proposed as a subunit which might be modeled as a thin isosceles triangular prism composed of four globular cores joined by rather flexible segments. These cores correspond probably to four helical regions in a subunit, and rearrange their relative positions according to the external conditions. A slight rearrangement of core positions in a subunit may result in the formation of A-proteins of various shapes.

Roles of nonstructural polyproteins and cleavage products in regulating Sindbis virus RNA replication and transcription

Using vaccinia virus to express Sindbis virus (SIN) nonstructural proteins (nsPs) and template RNAs, we showed previously that synthesis of all three viral RNAs occurred only during expression of either the entire nonstructural coding region or the polyprotein precursors P123 and P34. In this report, the vaccinia virus system was used to express cleavage-defective polyproteins and nsP4 proteins containing various N-terminal extensions to directly examine the roles of the P123 and P34 polyproteins in RNA replication. Replication and subgenomic mRNA transcription occurred during coexpression of P34 and P123 polyproteins in which cleavage was blocked at either or both of the 1/2 and 2/3 sites. For all cleavage-defective P123 polyproteins, however, the ratio of subgenomic to genomic RNA was decreased, suggesting that both the 1/2 and 2/3 cleavages are required for efficient subgenomic RNA transcription. These studies indicate that the uncleaved P123 polyprotein can function as a component of the viral replicase capable of synthesizing both plus- and minus-strand RNAs. In contrast, cleavage-defective P34 was unable to function in RNA replication, even in complementation experiments in which minus-strand RNAs were provided by nsP4. A P34 polyprotein whose cleavage site was not altered could only function in RNA replication in the presence of an active nsP2 protease. Although nsP4, the putative RNA polymerase, was capable of synthesizing only minus-strand RNAs during coexpression with P123, the addition of only 22 upstream residues to nsP4 allowed both replication and transcription of subgenomic RNA to occur. These data show that the conserved domains of both nsP3 and the nsP4 polymerase do not need to be present in a P34 polyprotein to form a functional plus-strand replicase-transcriptase and suggest that the presence of an active nsP2 protease and a cleavable 3/4 site correlates with synthesis of all virus-specific RNA species.

Tobacco mosaic virus: a model antigen to study virus-antibody interactions

For more than 50 years, tobacco mosaic virus (TMV) has been used as a model system for studying various aspects of virus-antibody interactions. Distinct epitopes called neotopes and cryptotopes have been identified in intact TMV particles and dissociated viral protein respectively and a correlation has been found to exist between the location of continuous epitopes and the extent of segmental mobility along the viral polypeptide chain. The occurrence of bivalent antibody binding was shown to influence the observed affinity of TMV antibodies and kinetic measurements of antibody binding to viral peptides made it possible to analyze the mechanism of binding of monoclonal antibodies. It seems likely that the TMV model will continue to yield a rich harvest of immunochemical data relevant to many viral systems.

Developments in the understanding of the particle structure of tobraviruses

Particles of tobraviruses resemble those of tobacco mosaic tobramovirus (TMV) in having helical symmetry and in being rod-shaped. However, isolated tobravirus coat protein and TMV coat protein respond to changes in the ionic strength and pH of the solute in contrasting ways. The types of aggregate formed in solutions of coat protein also differ which may be related to differences in the apparent mechanism of reconstitution of virus particles from isolated protein and RNA. The amino acid sequences of tobravirus and tobramovirus coat proteins have been shown to be similar in some regions known to be important for the structure of TMV particles. These alignments also show that tobravirus proteins are larger than tobramoviral proteins in part because of extra residues at the C-terminus. Tobravirus particles give a signal in proton NMR spectroscopy but TMV particles do not. The signal is caused by segmental mobility of the C-terminal peptide. This difference between TMV and tobraviruses may be related to a property not shared by tobraviruses and TMV and it is therefore speculated that the mobile C-terminal peptide of tobravirus coat proteins may be important in the transmission of tobravirus particles by nematode vectors.

Mapping sequences required for productive replication of beet necrotic yellow vein virus RNA 3

Of the four genome components of beet necrotic yellow vein virus only RNAs 1 and 2 are essential for viral replication in leaves. We have mapped cis-regulatory elements on RNA 3 by introducing deletions into expressible cDNA clones and inoculating leaves with the altered transcripts along with RNAs 1 and 2. Transcripts carrying internal deletions extending to within 69 residues of the 3' poly(A) tail or to within about 300 residues of the 5' terminus were efficiently amplified and encapsidated in vivo. The 3' terminal cis-essential domain can be folded into a secondary structure which is conserved among all four genomic RNAs and which probably contains the minus-strand promoter. RNA 3 transcripts with 75% of the central core of the sequence deleted or replaced by the beta-glucuronidase (GUS) gene were also viable. GUS activity was detected in infected tissue in the latter case.

Portable encapsidation signal of the L-A double-stranded RNA virus of S. cerevisiae

The (+) single-stranded RNA (ssRNA) of the L-A virus is the species packaged to form new viral particles. Empty L-A viral particles specifically bind viral (+) ssRNA, and a sequence 400 bases from the 3' end is necessary for this activity. We show that its stem-loop structure, the A residue protruding from the stem, and the loop sequence are all important for the binding, and that this 34 base region is sufficient for the binding. M1, a satellite virus of L-A, has a similar structure on its (+) strand that is likewise sufficient for the binding. Heterologous RNA with the binding sequence from L-A or M1, when expressed in vivo, was packaged in L-A viral particles. Thus, the sites necessary to bind to empty particles are encapsidation signals for the L-A virus. Since the pol domain of the 180 kd minor coat protein appears to be responsible for the binding, this result suggests that the RNA polymerase molecule recognizes the viral genome for packaging.

Preparation and properties of recombinant DNA derived tobacco mosaic virus coat protein

Recombinant DNA derived tobacco mosaic virus (vulgare strain) coat protein (r-TMVP) was obtained by cloning and expression in Escherichia coli and was purified by column chromatography, self-assembly polymerization, and precipitation. SDS-PAGE, amino terminal sequencing, and immunoblotting with polyclonal antibodies raised against TMVP confirmed the identify and purity of the recombinant protein. Isoelectric focusing in 8 M urea and fast atom bombardment mass spectrometry demonstrated that the r-TMVP is not acetylated at the amino terminus, unlike the wild-type protein isolated from the tobacco plant derived virus. The characterization of r-TMVP with regard to its self-assembly properties revealed reversible endothermic polymerization as studied by analytical ultracentrifugation, circular dichroism, and electron microscopy. However, the details of the assembly process differed from those of the wild-type protein. At neutral pH, low ionic strength, and 20 degrees C, TMVP forms a 20S two-turn helical rod that acts as a nucleus for further assembly with RNA and additional TMVP to form TMV. Under more acidic conditions, this 20S structure also acts as a nucleus for protein self-assembly to form viruslike RNA-free rods. The r-TMVP that is not acetylated carries an extra positive charge at the amino terminus and does not appear to form the 20S nucleus. Instead, it forms a 28S four-layer structure, which resembles in size and structure the dimer of the bilayer disk formed by the wild-type protein at pH 8.0, high ionic strength, and 20 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

Decreased levels of TMV coat protein in transgenic tobacco plants at elevated temperatures reduce resistance to TMV infection

Transgenic tobacco plants that accumulate tobacco mosaic virus (TMV) coat protein (CP) are resistant to TMV infection under standard growth conditions. The amount of CP accumulated and the degree of resistance to TMV were found to be temperature dependent. Exposure to continuous high temperatures (30-35 degrees) results in a sharp decrease in the amount of CP within 6 hr with no further change for at least 6 days. Under these conditions the transgenic plants developed typical systemic disease symptoms when inoculated with TMV although disease development was delayed. Transgenic plants which were moved from 35 to 22 degrees accumulated the normal level of CP within several hours. Transgenic tobacco plants inoculated and held at 35/25 degrees day/night cycles retained resistance to TMV infection. The level of CP mRNA was constant at each temperature and was associated with polyribosomes. On the basis of these results we suggest that the low level of CP under elevated temperature is due to instability of the TMV CP. In contrast, TMV CP levels in transgenic tomato plants also dropped under elevated temperatures yet retained high resistance to TMV.

Coat protein gene sequence of tobacco mosaic virus encodes a host response determinant

The common strain and tomato strain of tobacco mosaic virus (TMV) are known to be closely related to each other. However, plants with the N' gene, such as Nicotiana sylvestris and Nicotiana tabacum L. cv. Bright Yellow, respond differently to infections by these viruses. In the N' plants, TMV-OM (common strain) spreads systemically with mosaic symptoms, whereas TMV-L (tomato strain) induces the necrotic response of plants, causing local lesions. To reveal the viral factor of TMV-L inducing the necrotic response, we have constructed several recombinant viruses between the two strains, in which TMV-L RNA was partly replaced by TMV-OM RNA. The recombinant viruses having the coat protein gene sequence of TMV-OM in place of TMV-L produced no necrotic local lesions but spread systemically with mosaic symptoms in the N' plants. On the other hand, the recombinant viruses having TMV-OM-derived sequences other than the coat protein gene sequence, and in which the coat protein gene sequence of TMV-L still remained, produced necrotic local lesions. These observations indicate that the viral factor of TMV-L responsible for the necrotic response of the N' plants is coded in the coat protein gene sequence.

Essential features of the assembly origin of tobacco mosaic virus RNA as studied by directed mutagenesis

The assembly origin of tobacco mosaic virus RNA contains three stable hairpin loops. Coat protein disks bind first to loop 1 (the 3' most) during virus assembly, but the whole region is coated in a concerted fashion even in conditions of limiting protein. It is shown by in vitro packaging assays using mutant assembly origin transcripts that rapid and specific assembly initiation occurs in the absence of loops 2 and 3, but is abolished on removal of loop 1. Deletion or alteration of the unpaired AAGAAGUCG sequence at the apex of loop 1 also abolishes rapid packaging; this sequence is therefore instrumental in disk binding. Alteration of this sequence to (A)9 leads to packaging at a very low rate (half time 12 hours) which is apparently non-sequence specific. Substitution of (CCG)3 evokes packaging with a half time of 3 hours, as compared to 15 seconds for the wild type assembly origin. These results suggest that the three-base G periodicity within this sequence element is an important feature in assembly nucleation.

In vitro mutagenesis of the putative replicase genes of tobacco mosaic virus

We have established an in vitro transcription system to produce infectious tobacco mosaic virus (TMV) RNA from a cloned cDNA copy. Using this system, several TMV mutants were transcribed in vitro from cDNA clones mutagenized at or near the leaky amber termination codon of the 130K protein gene, and their infectivity was assayed on tobacco plants. Three (two frame-shift and one non-sense) mutants with an intact 130K but a defective 180K protein gene were not infectious, while two mutants with a one-amino-acid insertion in the 180K protein gene were infectious. When the amber codon of the 130K protein gene was deleted, infectivity was lost. However, when the amber termination codon was replaced with ochre or tyrosine codon, infectivity was retained. Sequence analyses revealed that introduced mutations were retained in progeny viral sequences except in the progeny of the amber-to-tyrosine mutant, which was a mixture of the parental mutagenized virus and a pseudo-revertant with ochre codon.

Disk aggregates of tobacco mosaic virus protein in solution: electron microscopy observations

Previous studies of the coat protein of tobacco mosaic virus (TMVP) have shown that TMVP presumably exists as linear stacks of two-ring cylindrical disks in the 0.7 M ionic strength buffer used for crystallizing the disks for X-ray diffraction studies [Raghavendra, K., Adams, M.L., & Schuster, T.M. (1985) Biochemistry 24, 3298-3304]. The spectroscopic and sedimentation studies of solutions of TMVP under these crystallizing conditions have demonstrated a long-term metastability of these disk aggregates when they are placed in 0.1 M ionic strength buffers, as are used for reconstituting tobacco mosaic virus from TMVP and viral RNA. The present work describes an electron microscopic study of TMVP disk aggregates under the same solution conditions employed in the previous spectroscopic and sedimentation studies. The results show that in the pH 8.0 0.7 M ionic strength crystallization buffer TMVP exists as stacks of disks which range in size from about 6 to 24 layers, corresponding to 3-12 2-layer disk aggregates having 17 subunits per layer. These TMVP aggregates persist in a metastable form in 0.1 M ionic strength virus reconstitution buffer with no apparent changes in structure of the stacked disks. The results are consistent with the conclusions of the solution physical-chemical studies which suggest that the disk structure may not be related to the 20S TMVP aggregate that is the nucleation species in virus

Delay of disease development in transgenic plants that express the tobacco mosaic virus coat protein gene

A chimeric gene containing a cloned cDNA of the coat protein (CP) gene of tobacco mosaic virus (TMV) was introduced into tobacco cells on a Ti plasmid of Agrobacterium tumefaciens from which tumor inducing genes had been removed. Plants regenerated from transformed cells expressed TMV mRNA and CP as a nuclear trait. Seedlings from self-fertilized transgenic plants were inoculated with TMV and observed for development of disease symptoms. The seedlings that expressed the CP gene were delayed in symptom development and 10 to 60 percent of the transgenic plants failed to develop symptoms for the duration of the experiments. Increasing the concentration of TMV in the inoculum shortened the delay in appearance of symptoms. The results of these experiments indicate that plants can be genetically transformed for resistance to virus disease development.

Analysis of the genome structure of tobacco rattle virus strain PSG

The sequence of the 3'-terminal 2077 nucleotides of genomic RNA 1 and the complete sequence of genomic RNA 2 of tobacco rattle virus (TRV, strain PSG) has been deduced. RNA 2 (1905 nucleotides) contains a single open reading frame for the viral coat protein (209 amino acids), flanked by 5'- and 3'-noncoding regions of 570 and 708 nucleotides, respectively. A subgenomic RNA (RNA 4) was found to lack the 5'-terminal 474 nucleotides of RNA 2 and is the putative messenger for coat protein. The deduced RNA 1 sequence contains the 3'-terminal part of a reading frame that probably corresponds to the TRV 170K protein and reading frames for a 29K protein and a 16K protein. Proteins encoded by the first two reading frames show significant amino acid sequence homology with corresponding proteins encoded by tobacco mosaic virus. Subgenomic RNAs 3 (1.6 kb) and 5 (0.7 kb) were identified as the putative messengers for the 29K and 16K proteins, respectively. At their 3'-termini all PSG-RNAs have an identical sequence of 497 nucleotides; at the 5'-termini homology is limited to 5 to 10 bases.

Tobacco mosaic virus protein aggregates in solution: structural comparison of 20S aggregates with those near conditions for disk crystallization

Previous X-ray studies (2.8-A resolution) on the crystals of tobacco mosaic virus protein (TMVP) grown from solutions containing high salt have characterized the structure of the protein aggregate as a bilayered cylindrical disk formed by 34 identical subunits [Bloomer, A.C., Champness, J.N., Bricogne, G., Staden, R., & Klug, A. (1978) Nature (London) 276, 362-368]. Under low-salt conditions, 20S aggregates are in equilibrium with 4S species and involved in the efficient nucleation of TMV assembly in vitro [Butler, P.J.G. (1984) J. Gen. Virol. 65, 253-279]. We have investigated by sedimentation velocity and near-UV circular dichroism (CD) measurements the structure of 20S aggregates in low salt (I = 0.1 potassium phosphate at pH 7.0 and 20 degrees C) and the aggregates in high salt [0.2 M (NH4)2SO4 in I = 0.1 tris(hydroxymethyl)aminomethane hydrochloride at pH 8.0 and 20 degrees C, close to the conditions under which TMVP crystallizes as disk aggregates]. At high salt, we observe structures (presumably stacks of disks) having s20,w values around 40, 45, and 50 S, but not the 20S species present in low-salt buffers. The near-UV CD spectrum of 20S aggregates has been obtained for the first time, using computer techniques, from the spectra of the 4S-20S equilibrium mixture and the 4S species. This spectrum of 20S aggregates differs dramatically from that of the stacks of disks examined at both high and low salt (into which the stacks can be returned by dialysis), indicating that the difference is not a solvent effect.(ABSTRACT TRUNCATED AT 250 WORDS)

Sindbis virus proteins nsP1 and nsP2 contain homology to nonstructural proteins from several RNA plant viruses

Although the genetic organization of tobacco mosaic virus (TMV) differs considerably from that of the tripartite viruses (alfalfa mosaic virus [AlMV] and brome mosaic virus [BMV]), all of these RNA plant viruses share three domains of homology among their nonstructural proteins. One such domain, common to the AlMV and BMV 2a proteins and the readthrough portion of TMV p183, is also homologous to the readthrough protein nsP4 of Sindbis virus (Haseloff et al., Proc. Natl. Acad. Sci. U.S.A. 81:4358-4362, 1984). Two more domains are conserved among the AlMV and BMV 1a proteins and TMV p126. We show here that these domains have homology with portions of the Sindbis proteins nsP1 and nsP2, respectively. These results strengthen the view that the four viruses share mechanistic similarities in their replication strategies and may be evolutionarily related. These results also suggest that either the AlMV 1a, BMV 1a, and TMV p126 proteins are multifunctional or Sindbis proteins nsP1 and nsP2 function together as subunits in a single complex.

Ultrasonic absorption in tobacco mosaic virus and its protein aggregates

The structural fluctuations specific to self-assembled biological systems have been investigated further with ultrasonic techniques by using two strains of tobacco mosaic virus (TMV), as well as the helical aggregate of the common strain protein and subassemblies of it. We confirmed our earlier conclusion that protein assemblies exhibit specific structural fluctuations detected in ultrasonic experiments. As in spherical viruses, the fluctuations exhibited by the protein aggregates having a quaternary structure similar to that of the virion were modified in the virus by interaction with the RNA strand. It is unlikely that the origin for the observed effect is due either to: (1) the difference in local mobility of the segment 89 to 113 of the polypeptide chain in TMV and in the helical aggregate on the one hand, and in smaller aggregates, on the other hand; or (2) a local fluctuation associated with proton transfer reactions or ion-pair interactions. The most remarkable feature in the TMV system is the fact that the two-ring disk showed no excess of ultrasonic absorption with respect to the A-protein oligomer, while a large increase of ultrasonic absorption was observed in the rod-like aggregate that had undergone the disk-helix transition.

Striking similarities in amino acid sequence among nonstructural proteins encoded by RNA viruses that have dissimilar genomic organization

The plant viruses alfalfa mosaic virus (AMV) and brome mosaic virus (BMV) each divide their genetic information among three RNAs while tobacco mosaic virus (TMV) contains a single genomic RNA. Amino acid sequence comparisons suggest that the single proteins encoded by AMV RNA 1 and BMV RNA 1 and by AMV RNA 2 and BMV RNA 2 are related to the NH2-terminal two-thirds and the COOH-terminal one-third, respectively, of the largest protein encoded by TMV. Separating these two domains in the TMV RNA sequence is an amber termination codon, whose partial suppression allows translation of the downstream domain. Many of the residues that the TMV read-through domain and the segmented plant viruses have in common are also conserved in a read-through domain found in the nonstructural polyprotein of the animal alphaviruses Sindbis and Middelburg. We suggest that, despite substantial differences in gene organization and expression, all of these viruses use related proteins for common functions in RNA replication. Reassortment of functional modules of coding and regulatory sequence from preexisting viral or cellular sources, perhaps via RNA recombination, may be an important mechanism in RNA virus evolution.

Coordinated two-disk nucleation, growth and properties, of virus-like particles assembled from tobacco-mosaic-virus capsid protein with poly(A) or oligo(A) of different length

Assembly of nucleoprotein rods from tobacco mosaic virus (TMV) coat protein and poly(A) depends on the presence of 20S disks in a manner very similar to nucleation and growth of virions in reconstitution with TMV RNA. Products assembled with (A) approximately equal to 5000 appear to have the same buoyant density in CsCl, the same nucleotide/protein ratio and the same nuclease stability, as reconstituted and native TMV. Their rate of formation is very similar to the rate of reconstitution with TMV RNA when high-molecular-mass (A) approximately equal to 5000 is used, but becomes a function of chain length particularly with (A) less than or equal to 185. The composition of assembly products can be described sufficiently with the relation between number of capsid polypeptide monomers/particle, np, to the number of nucleotide residues/chain, nnt, of np = 1/3 (nnt + 50) with two important restrictions: (1) particles of less than four turns of helically arranged capsid subunits are unstable, and (2) particles with about 150 or less nucleotides per chain deviate in structure from mature virus and virus-like (= longer) assembly products. This is indicated by changes in both buoyant density in CsCl and optical properties, while 'dislocation' of the disk to the helical arrangement of capsid subunits ('helicalization') and nuclease stability already become established with chains as short as (A) approximately equal to 58 +/- 20. Consequently, we suggest that assembly proceeds through three distinct phases: (1) nucleation (resulting in helicalization) by interaction of nucleic acid with the first disk; (2) stabilization of the primary (unstable!) nucleation complex by addition of a second disk and formation of a four-turn virus-like and stable nucleoprotein helix, which is then fit for (3) elongation by addition of further disks. The question of what makes the TMV protein disk select specifically TMV RNA during virion assembly is discussed in some detail.

Homologous proteins encoded by yeast mitochondrial introns and by a group of RNA viruses from plants

Hensgens et al. (1983a) have demonstrated the existence of distant homology (averaging 19.6%) between the central sections of seven proteins encoded by introns (and one product of an apparently independent gene) in yeast mitochondrial DNA. The homologous regions are typically segments of about 115 amino acids within open reading frames of about 10(3) bases. Genetic studies indicate that at least two of these proteins are required for the splicing of mitochondrial transcripts. This paper reports that two distantly related proteins of Mr 30,000 that are encoded by different strains of tobacco mosaic virus both contain central sections whose amino acid sequences are 15% to 23% identical in a single alignment to those of one group of four intron-encoded proteins, and possess certain groups of conserved residues also characteristic of the mitochondrial proteins. Genetic studies implicate these proteins in the spreading of viral lesions. While this level of identity cannot establish conclusively that the proteins are related, it suggests the possibility of a functional and/or evolutionary connection that would, if borne out, have important implications.

The 5'-terminal sequence of TMV RNA. Question on the polymorphism found in vulgare strain

The complete nucleotide sequence of TMV RNA (common strain) reported in [Proc. Natl. Acad. Sci. USA (1982) 79, 5818] its 5'-end to be represented by two variants which differed in length. We have tested that result and sequenced the 5'-terminal regions of two strains of TMV RNA (common strain OM and tomato strain L) using cloned cDNA copies. The results showed that the 5'-terminal region of the TMV genome is not polymorphic and that one of the two variants cited above represents a tomato strain but not the common strain.

Molecular cloning and nucleotide sequence of the 30K and the coat protein cistron of TMV (tomato strain) genome

The cDNA copies of tobacco mosaic virus (TMV)-tomato strain (L) genome were cloned by the method of Okayama and Berg (Mol. Cell. Biol. 2, 161-170. (1982)) and the sequence of 1,614 nucleotides at the 3' end was determined. The sequence encompasses the 30K and the coat protein cistron which are located in residues 685-1, 479 and 203-682 from the 3' end of the genome respectively. The close relationship between the tomato and the common strain was shown on the level of the nucleotide sequence. Highly homologous regions are found in the 3' non-coding region, the assembly origin and the 5' flanking region of the 30K protein cistron. The comparison of the deduced amino acid sequence between the tomato and the common strain shows that the 30K protein is composed of the conserved N-terminal four-fifth and the highly divergent region near the C-terminus.

Self-assembly of brome mosaic virus protein into capsids. Initial and final states of aggregation

The pH and ionic strength dependence of the states of aggregation of brome mosaic virus protein has been investigated by small angle neutron scattering, quasielastic light-scattering, analytical centrifugation and electron microscopy. At pH above neutrality, protein oligomers are found in dynamical equilibrium, comprising monomers, dimers and aggregates of higher molecular weight. By lowering the pH, capsids assemble spontaneously with dimensions in solution which depend on ionic strength. If formed by dialysis, they contain 180 monomers, but are 30 A larger in diameter than the native virus. If formed by pH-jump, they contain less monomers: the deficiency decreases with decreasing the final pH and the initial protein concentration. Upon dehydration for electron microscopy, capsids contract by 10%.

Multiple proteins and subgenomic mRNAs may be derived from a single open reading frame on tobacco mosaic virus RNA

It has previously been shown that messenger activity for a protein of Mr = ca. 30k exists in RNA fractions extracted from particles of either native or alkali stripped U1 TMV, or from cowpea strain TMV, that are smaller than full genomic length. Analysis of sucrose gradient fractions containing this activity reveals a number of slightly smaller template activities directing synthesis of proteins between 18.5k and 29k in size. All of these messenger activities, including that for the 30k protein, respond to cap analogues in anomalous ways. Discrete RNA species that include active mRNAs for these proteins can be demonstrated in the same fractions by labelling with preparations of vaccinia capping enzyme and [alpha-32P] GTP without prior beta-elimination. Detailed analysis of three of these proteins (of Mr's ca. 30k, 29k and 23k) by peptide mapping and translation of purified vaccinia-labelled RNA demonstrates that all three are unrelated to the large early TMV proteins, but are related to each other in such a way as to form a nested set with staggered N termini and identical C termini. mRNAs of chain lengths ca. 1900 and 1500 bases direct synthesis of the 30k and 23k proteins respectively, an mRNA of about 1850 bases directs both 29k and (perhaps because of cross-contamination) 30k synthesis. Initiation codons for the 29k and 23k proteins have been mapped at positions 4960-4962 and 5191-5193 respectively on TMV RNA. Since all three encapsidated templates have similar properties we conclude that either there is a family of 30k-related proteins with unusual mRNAs, or that none of these in vitro translation products are directed by physiological templates.

Nucleotide sequence of the 30K protein cistron of cowpea strain of tobacco mosaic virus

The nucleotide sequence of cloned cDNA copies of cowpea strain of tobacco mosaic virus RNA including the 30K protein cistron was determined. The 30K protein cistron was located at residue 676-1,527 from the 3' end of the genomic RNA. The 30K protein was composed of 282 amino acid residues and was basic, similar to the 30K protein of common strain OM. However, homology of the amino acid sequences between the two strains was only 27%.

Mechanism of tobacco mosaic virus assembly: role of subunit and larger aggregate protein

Tobacco mosaic virus (TMV) was reconstituted from the RNA of a common strain (OM) and the protein of a watermelon strain of cucumber green mottle mosaic virus (CGMMV-W), which is a member of the tobamovirus group. In 0.25 M phosphate buffer at 25 degrees C, CGMMV-W protein existed mainly as 21S aggregates. When this protein was mixed with OM RNA, complexes of short rods were formed but further elongation did not occur. After the addition of subunits in 0.1 M phosphate buffer at 25 degrees C, elongation to the 5' end of the RNA proceeded as fast as in the case of reconstitution with the usual equilibrium "disk preparation" of OM protein, to give 260-nm intermediates in the first 5-7 min. The results proved that the rapid elongation we previously observed in the reconstitution of TMV-OM following the assembly initiation is the outcome of preferential incorporation of TMV subunit protein. Either preformed 21S aggregate or the subunit of CGMMV protein was added to the 260-nm intermediate. Elongation to the 3' end of the RNA was investigated in 0.1 M phosphate buffer at 25 degrees C by measuring the distribution of rod length and the RNase-resistant infectivity. The results showed that the 21S aggregate is kinetically favored as the protein source during the slow elongation process.