The nucleotide sequence at the origin for assembly on tobacco mosaic virus RNA

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.

Nucleotide sequence of tobacco mosaic virus RNA

Oligonucleotide primers have been used to generate a cDNA library covering the entire tobacco mosaic virus (TMV) RNA sequence. Analysis of these clones has enabled us to complete the viral RNA sequence and to study its variability within a viral population. The positive strand coding sequence starts 69 nucleotides from the 5' end with a reading frame for a protein of Mr 125,941 and terminates with UAG. Readthrough of this terminator would give rise to a protein of Mr 183,253. Overlapping the terminal five codons of this readthrough reading frame is a second reading frame coding for a protein of Mr 29,987. This gene terminates two nucleotides before the initiator codon of the coat protein gene. Potential signal sequences responsible for the capping and synthesis of the coat protein and Mr 29,987 protein mRNAs have been identified. Similar sequences within these reading frames may be used in the expression of sets of proteins that share COOH-terminal sequences.

Sequence specificity of trinucleoside diphosphate binding to polymerized tobacco mosaic virus protein

The binding of trinucleoside diphosphates to long helical rods of tobacco mosaic virus (TMV) protein is shown to depend on base sequence, 5' AAG 3' binding being the strongest of the 25 trinucleoside diphosphate sequences measured. As TMV has a stoichiometry of three nucleotides per protein subunit, the sequence of TMV RNA suggested to be the nucleation site for self-assembly of the virus has three possible binding frames. From our binding constant data the most likely frame is predicted and shown to have two contiguous AAG sequences in a hairpin loop region.

A "bulged" double helix in a RNA-protein contact site

The binding of ribosomal protein L18 affects specific nucleotides in Escherichia coli 5S RNA as detected by dimethyl sulfate alkylation and RNase A digestion of the 5S-L18 complex. Most of the affected nucleotides are clustered and localize a site of RNA-protein interaction in and around the defined central helix [Fox, G. E. & Woese, C. (1975) Nature (London) 256, 505-507] of 5S RNA. Chemical carbethoxylation of the native 5S RNA with diethyl pyrocarbonate shows that a striking feature of this region is an unstacked adenosine residue at position 66. We propose that this residue exists as a singly bulged nucleotide extending the Fox and Woese central helix by two base pairs in the E. coli sequence (to positions 16-23/60-68) as well as in each of 61 (prokaryotic and eukaryotic) aligned 5S RNA sequences. In each case, the single bulged nucleotide is at the relative position of adenosine-66 in the RNA sequences. The presence of this putative bulged nucleotide appears to have been conserved in 5S RNA sequences throughout evolution, and its identity varies with major phylogenetic divisions. This residue is likely involved in specific 5S RNA-protein recognition or interaction in prokaryotic and eukaryotic ribosomes. The uridine-65 to adenosine-66 internucleotide bond is protected from RNase A digestion in the complex, and carbethoxylation of E. coli adenosine-66 prior to L18 binding affects formation of a stable RNA-protein complex. Thus, we identify a region of E. coli 5S RNA protected by the ribosomal protein L18 and propose that it contains a bulged nucleotide residue important in stable formation of this RNA-protein complex. This bulged residue appears to be evolutionarily conserved and phylogenetically defined in 5S RNA sequences in general, and consideration of other known RNA-protein binding sites shows that such a "bulged helix" may be a common feature of RNA-protein contact sites.

Nucleotide sequence of a cloned cDNA copy of TMV (cowpea strain) RNA, including the assembly origin, the coat protein cistron, and the 3' non-coding region

The cloned cDNA derived from the 3' end of cowpea strain (Cc) RNA of tobacco mosaic virus (TMV) has been sequenced. Substantial sequence information of 1,060 nucleotides from the 3' end of the RNA reveals some interesting features: (1) the coat protein cistron corresponds to residues 210-701 from the 3' end. Some errors in the amino acid sequence previously reported have been corrected and the revised total length of the coat protein is 162 amino acid residues. The capping site of the coat protein mRNA is at residue 711 from the 3' end of genome RNA. (2) The assembly origin of reconstitution is positioned within the coat protein cistron at residue 369-461 which can be formed into a highly base-paired hairpin loop structure. The sequence, GAXGUUG, in the loop region and a triplet-repeated purine base tract surrounding the loop are found. These structural features are common to assembly origins of both Cc and vulgare strains. (3) We find the sequence highly homologous to, but distinct from, the genuine assembly origin. It will be called the pseudo-assembly origin, which is located in the corresponding region to the assembly origin of the vulgare strain, outside the coat protein cistron. There is also the sequence, GAXGUUG, in the middle of the region. (4) In the 5' flanking region of the coat protein cistron, a long reading frame, probably of 30 K protein, is found. The coding region is terminated in the coat protein cistron and thus the 30 K protein and the coat protein cistrons overlap. (5) The 3' non-coding region is 209 residues long and can be folded into a possible tRNA-like structure. Surprisingly, we find that the 3' terminal sequence of Cc RNA is not very similar to that of vulgare RNA but extensively homologous to that of turnip yellow mosaic virus (TYMV) RNA.

Wild-type tRNATyrG reads the TMV RNA stop codon, but Q base-modified tRNATyrQ does not

Although protein synthesis usually terminates when a stop codon is reached along the messenger RNA sequence, there are examples, mainly in viruses, of the stop codon being suppressed by a tRNA species. A strong candidate for this phenomenon occurs in tobacco mosaic virus (TMV) in the form of two proteins (110K and 160K, of molecular weights 110,000 and 160,000, respectively)¹, sharing an N-terminus sequence, which are translated in vitro from a purified species of viral RNA. We have investigated the identity of the tRNA responsible for production of the 160K protein and show here that it is one of the tyrosine tRNAs. Another tyrosine tRNA, in which the first base of the anticodon is highly modified, does not act as a suppressor, indicating the possible regulatory function of such modifications.

Mechanism of RNA-protein interactions in tobacco mosaic virus: analysis of the pH stability of virus protein complexes with synthetic polynucleotides

TMV-like RNP complexes were reconstituted from TMV protein and synthetic polynucleotides. Analysis of the pH stability of RNP with polynucleotides containing U, G, or their analogues reveals a correlation between the stability of their structure and the pK values of the bases, and indicates that the -NH-CO-groups of U and G are involved in hydrogen bonding with protein. It is suggested that TMV protein has two U- and one G-specific binding sites which, according to the phase position of the protein subunits relative to the origin of TMV assembly (D. Zimmern (1977), Cell 11, 463) are likely to be organized as UGU. The binding of the A and C residues of RNA with TMV protein is nonspecific. TMV protein groups with pK 6.3, 7.5 and 9.7 were found to be essential in the protein-protein interactions in RNP. A group of the protein with pK 8.2 is also involved in RNP stabilization. Both protein-protein interactions and interactions of protein with RNA phosphate groups were shown to be mediated by a conformational change in the protein induced by base binding. The effect of bases on both types of interactions changes in the order G approximately equal to much greater than A, and incorporation of C in RNP proceeds in a compulsory way at the expense of interaction of the neighbouring nucleotide residues in polynucleotides with protein. The data obtained are used to discuss the principles of the cooperativity of the interactions between TMV components and the mechanism of initiation and elongation in TMV self-assembly.

RNA-protein interactions in the assembly of tobacco mosaic virus

Assembly of tobacco mosaic virus is initiated by the binding of a specific loop of the RNA into the central hole of the disk aggregate of protein subunits. Since the nucleation loop is located about five-sixths along the RNA molecule, subsequent elongation must be bidirectional. We have now measured the rates of elongation in the two directions by determining the lengths of RNA protected from nuclease digestion at different times and using either intact TMV rNA, or RNA with most of the longer tail removed. Comparison of the rates with the protein supplied as either a mixture of disks with A-protein (a mixture of less aggregated states) or just A-protein, shows that different mechanisms and protein aggregates are used for the most rapid growth. When disks are present, they add more rapidly along the longer RNA tail but do not appear to add directly on the shorter tail. In contrast, smaller aggregates (A-protein) can add at both ends of the rod, but do so more slowly. Mechanisms for these processes are discussed. Preliminary results on the binding of the specific hexanucleotide AAGAAG to the disk are given and compared with the known changes on binding nonspecific hexanucleotides or the trinucleotide AAG.

Studies on the mechanism of assembly of tobacco mosaic virus

Sedimentation and proton binding studies on the endothermic self-association of tobacco mosaic virus (TMV) protein indicate that the so-called "20S" sedimenting protein is an interaction system involving at least the 34-subunit two-turn yield cylindrical disk aggregate and the 49-subunit three-turn helical rod. The pH dependence of this overall equilibrium suggests that disk formation is proton-linked through the binding of protons to the two-turn helix which is not present as significant concentrations near pH 7. There is a temperature-induced intramolecular conformation change in the protein leading to a difference spectrum which is complete in 5 x 10(-6) s at pH 7 and 20 degrees C and is dominated at 300 nm by tryptophan residues. Kinetics measurements of protein polymerization, from 10(-6) to 10(3) s, reveal three relaxation processes at pH 7.0, 20 degrees C, 0.10 M ionic strength K (H) PO4. The fastest relaxation time is a few milliseconds and represents reactions within the 4S protein distribution. The second fastest relaxation is 50-100 x 10(-3) s and represents elementary polymerization steps involved in the formation of the approximately 20 S protein. Analysis of the slowest relaxation, approximately 5 x 10(4) s, suggests that this very slow formation of approximately 20 S protein may be dominated by some first order process in the overall dissociation of approximately 20S protein. Sedimentation measurements of the rate of TMV reconstitution, under the same conditions, show by direct measurements of 4S and approximately 20S incorporation at various 4S to approximately 20S weight ratios that the relative rate of approximately 20S incorporation decreases almost linearly, from 0 to 50% 4S. There appears to be one or more regions of TMV-RNA, approximately 1-1.5 kilobases long, which incorporates approximately 20S protein exclusively. Solutions of approximately 95-100% approximately 20S protein have been prepared for the first time and used for reconstitution with RNA. Such protein solutions yield full size TMV, but at a slower rate than if 4S protein is added. Thus the elongation reaction in TMV assembly, following nucleation with approximately 20S protein, is not exclusively dependent upon the presence of either 4S or approximately 20S protein aggregates. The initial, maximum, rate of reconstitution increases about threefold when the protein composition is changed from 5% to 30% 4S protein, at constant total protein concentration at pH 7.0, 20 degrees C in 0.10 M ionic strength K (H)PO4. The probable binding frame at the internal assembly nucleation site of TMV-RNA has been determined by measuring the association constants for the binding of various trinucleoside diphosphates to helical TMV protein rods. The -CAG-AAG-AAG-sequence at the nucleation site is capable of providing at least 10-14 kcal/mol of sites of binding free energy for the nucleation event in TMV self-assembly.

Infectivity and reconstitution of TMV RNA modified with N-acetoxy-2-acetylaminofluorene or benzol [a] pyrene 7,8-dihydrodiol 9,10 oxide

TMV RNA was modified by two bulky carcinogens, N-acetoxy-2-acetylamino-fluorene (AAAF) and (+/-)-7beta, 8alpha- dihydroxy-9alpha, 10alpha-epoxy-7,8,9,10-tetrahydrobenzo[alpha]pyrene (BPDE), and the effects of such substituents on biological and physical properties was studied. For both types of modification, the loss of infectivity was directly proportional to the number of chemical modifications indicating that all modifications are lethal. Neither AAAF nor BPDE produced measurable mutations. Reconstitution of modified RNA with TMV protein was partially inhibited, but such inhibition occurred to similar extents with either carcinogen and a varying levels of modification. The data suggest that both types of substitution of TMV RNA generally permit the TMV coat protein to aggregate normally around the RNA, but that AAAF and BPDE may induce some conformational change in the initiation region that inhibits the initiation step.

Binding of oligonucleotides to the disk of tobacco-mosaic-virus protein

The trinucleoside diphosphate A-A-G and the hexanucleotide fraction from a ribonuclease I digest of yeast RNA have been soaked into crystals of the disk aggregate of tobacco mosaic virus protein. At high concentrations these cause disruption of the crystal, probably by mimicking the normal nucleation of assembly. At lower nucleotide concentrations the crystals remain intact and the differences caused by nucleotide binding have been studied by X-ray diffraction. The most obvious change is an upwards movement of about 0.3 nm at the low-radius end of the left radial helix in the protein with some stiffening of the helix so that it now extends visibly in from 4 nm to 6 nm radius. Similar shifts also occur in the right radial and left slewed helices. A positive peak, which is tentatively identified with the bound oligonucleotide, is seen around 4 nm radius and below the right radial helix. The amino acid residues in possible contact with this feature are discussed.

Location and encapsidation of the coat protein cistron of tobacco mosaic virus. A bidirectional elongation of the nucleoprotein rod

The coat protein cistron of tobacco mosaic virus has been located on the viral RNA starting between 975 and 1050 nucleotides from the 3'-hydroxyl end. This locates its 5' end close to the origin for virus assembly, where the first protein disk interacts with RNA. It also means that the coat protein mRNA must have a short 5'-untranslated tail and a long (over 500 nucleotides) 3' one. The recovery of characteristic oligonucleotides in nuclease-protected rods during the growth from RNA and a protein disk preparation shows that elongation of the nucleated rods proceeds independently in both directions though, on average, much more rapidly along the longer 5' tail than the shorter 3' tail. Protected RNA of length equal to that in the complete virion is first seen within 6 min, showing that the most rapidly elongated particles are substantially complete by this time.

Protein-RNA interactions during TMV assembly

A review of the structural studies of tobacco mosaic virus (TMV) is given. TMV is essentially a flat helical microcrystal with 16 1/3 subunits per turn. A single strand of RNA runs along the helix and is deeply embedded in the protein. The virus particles form oriented gels from which high-resolution X-ray fiber diffraction data can be obtained. This may be interpreted by the use of six heavy-chain derivatives to give an electron density map at 0.4 nm resolution from which the RNA configuration and the form of the inner part of the protein subunit may be determined. In addition, the protein subunits form a stable 17-fold two-layered disk which is involved in virus assembly and which crystallizes. By the use of noncrystallographic symmetry and a single heavy-atom derivative, it has been possible to solve the structure of the double disk to 0.28 nm resolution. In this structure one sees that an important structural role is played by four alpha-helices, one of which (the LR helix) appears to form the main binding site for the RNA. The main components of the binding site appear to be hydrophobic interactions with the bases, hydrogen bonds between aspartate groups and the sugars, and arginine salt bridges to the phosphate groups. The binding site is between two turns of the virus helix or between the turns of the double disk. In the disk, the region proximal to the RNA binding site is in a random coil until the RNA binds, whereupon the 24 residues involved build a well-defined structure, thereby encapsulating the RNA.

Sequence from the assembly nucleation region of TMV RNA

In an effort to isolate RNA sequences containing the assembly nucleation region, uniformly 32P-labeled tobacco mosaic virus RNA was partially digested with pancreatic ribonuclease, and the mixture of fragments was incubated with limited amounts of tobacco mosaic virus protein disks in conditions favorable for reconstitution. The RNA fragments which became encapsidated were purified and sequenced by conventional techniques. The sequence of the first 139 nucleotides of P1, the principal encapsidated fragment, is AGGUUUGAGAGAGAAGAUUACAAGCGUGAGAGACGGAGGGCCCAUGGAACUUACAGAAGAAGUUGUUGAUGAGUUCAUGGAAGAUGUCCCUAUGUCAAUCAGACUUGCAAAGUUUCGAUCUCGAACCGGAAAAAAGAGU. Residues 1--110 of P1 overlap the assembly origin isolated and characterized in the accompanying papers by Zimmern (1977) and Zimmern and Butler (1977). Our results, taken in conjunction with the two accompanying papers, define the sequence of much of the nucleation region as well as sequences flanking it on both sides. The features of the P1 sequence which may have role in the nucleation reaction are discussed in detail in the text.