RNA-RNA hybridisation using 125I-labelled RNA from tobacco necrosis virus and its satellite

CARNA 5, the Small Cucumber Mosaic Virus--Dependent Replicating RNA, Regulates Disease Expression

CARNA 5, the small cucummber mosaic virus-dependent replicating RNA which is the causal agent of lethal tomato necrosis disease, causes a drastic reduction of disease symptoms in at least two other plant species. Satellite-like RNA's associated with plant viruses have a disease-regulating function.

Analysis of the genome of satellite panicum mosaic virus

The relatedness of the genomes of satellite panicum mosaic virus (SPMV) and its helper virus, panicum mosaic virus (PMV), were investigated by nucleic acid hybridization. The results show that the satellite and helper virus RNAs have no appreciable homology or complementarity as assessed by hybridization with cDNA probes derived from the genomes of PMV and SPMV and with a probe complementary to the 3' terminus of SPMV RNA. The complete nucleotide sequence of SPMV RNA reveals that the genome is 826 nucleotides (nt) long. The ability to label SPMV RNA with polynucleotide kinase only after phosphatase treatment suggests that the 5' terminus is phosphorylated, but the extent of phosphorylation was not determined. The first open reading frame (ORF), encountered after an 88-nt 5'-untranslated region, encodes a 17,000 mol wt protein of a size and amino acid composition that are consistent with analysis of SPMV coat protein. An additional short ORF, located near the 3' end of the RNA, could encode a 6300 mol wt polypeptide. The minus strand also contains two ORFs that could potentially encode polypeptides of 7100 and 11,000 mol wt. No evidence is available to determine whether the second positive-strand ORF or the two minus-strand ORFs are expressed. The data presented here clearly show the SPMV RNA is distinct from the RNAs of other satellite viruses, in both size and nucleotide sequence. However, the 5'-untranslated portions of SPMV and satellite tobacco mosaic virus RNAs share some structural features that may be important in initiation of translation.

The stability of satellite viral RNAs in vivo and in vitro

Like the satellite RNA (Sat-RNA) of cucumber mosaic virus (CMV), the RNA of satellite tobacco necrosis virus (STNV-RNA) was shown to be capable of surviving in vivo without replication for at least 10 days in the absence of its helper tobacco necrosis virus (TNV). However, under similar conditions, the genomic RNA 3 of CMV failed to survive for 48 hr. It has been demonstrated that both STNV-RNA and Sat-RNA are significantly more resistant to inactivation in vitro than the RNAs of their helper viruses. The thermal denaturation kinetics of STNV-RNA and Sat-RNA, unlike those of TNV-RNA and CMV-RNA, are more like those of transfer RNA (tRNA) indicating that a high proportion of their nucleotides are involved in base pairing. STNV-RNA, Sat-RNA, and tRNA also show similar degrees of resistance to degradation by the single strand-specific S(1) nuclease. It is suggested that both STNV-RNA and Sat-RNA may owe their in vitro stability to features of their molecular structure which may also account for their ability to survive in vivo for prolonged periods without replication. Similarities and differences between satellites and viroids are discussed and it is concluded that these two classes of RNAs are unlikely to be related. The possible evolutionary origins of the satellites are also considered.

Genome structure of tobacco necrosis virus strain A

An almost complete sequence of the RNA genome of tobacco necrosis virus (TNV) strain A has been determined. The genome organization is very similar to that of carnation mottle virus (CarMV) and turnip crinkle virus (TCV). The 5'-proximal open reading frame (ORF) encodes a 23-kDa protein and read-through of its amber codon into the second ORF is presumably used for the translation of a 82-kDa protein. The third large ORF encodes the 30-kDa coat protein. Two small ORFs are located upstream and one immediately downstream of this coat protein cistron. Extensive sequence similarity was found between the TNV 82-kDa protein and the putative polymerases of TCV, CarMV, cucumber necrosis virus (CNV), maize chlorotic mottle virus (MCMV), red clover necrotic mosaic virus (RCNMV), and barley yellow dwarf virus (BYDV). The TNV coat protein is very similar to southern bean mosaic virus (SBMV) capsid protein. Of the predicted small proteins only a 7.9-kDa protein shows some sequence similarity with a corresponding protein of MCMV, CarMV, and TCV. The others are unique to TNV. Except for the first four nucleotides at the 5' end no homology was found with the RNA of STNV (satellite of TNV).

Nucleotide sequence and translation of satellite tobacco mosaic virus RNA

Satellite tobacco mosaic virus (STMV) is a plant virus with a 17-nm icosahedral particle encapsidating a 0.3 X 10(6) Mr ssRNA genome that depends on tobamoviruses for its replication. The complete nucleotide sequence of STMV RNA deduced in the experiments described here was 1059 nucleotides in length. The efficiency of labeling viral RNA with [gamma-32P]ATP using T4 polynucleotide kinase was not affected by treatment with tobacco acid pyrophosphatase and/or bacterial alkaline phosphatase, indicating that the majority of the 5' termini of encapsidated STMV RNAs were not phosphorylated. The 240 3'-terminal nucleotides of STMV RNA and either tobacco mosaic virus (TMV) U1 RNA or TMV U2/U5 RNA had greater than 65% overall sequence similarity, with two nearly identical regions of 40 and 50 bases, respectively. There were no other regions of sequence relatedness to TMV RNA. The 19 5'-terminal nucleotides of STMV RNA had greater than 65% sequence similarity with the 16 5'-terminal nucleotides of brome mosaic virus (RNA 3 and 50% sequence similarity with the 12 5'-terminal nucleotides of the Q strain of cucumber mosaic virus RNA 3. The first open reading frame (ORF) beginning at base 53 encoded a 6800 Mr protein that corresponded in size to a major in vitro translation product directed by STMV RNA. A second ORF, beginning at nucleotide 163, had the capacity to code for a protein that corresponded in size (17,500 Mr) to the other major in vitro translation product. The first 12 codons of this ORF corresponded to the sequence of the N-terminal amino acids of the capsid protein. Western-blot analysis of the in vitro translation products revealed that the 17,500 Mr protein had the same electrophoretic mobility as the authentic capsid protein; it was also antigenically related to the capsid protein, but the 6800 Mr protein was not. Time course analysis of in vitro translation demonstrated that the 6800 Mr protein was synthesized at the same time as the capsid protein and did not arise by the proteolytic cleavage of a larger precursor polypeptide. These results suggest that the genome of STMV functioned as a polycistronic messenger RNA. It has not been determined if the 6800 Mr protein is synthesized in vivo. STMV RNA had untranslated regions of 52 and 418 nucleotides at its 5' and 3' termini, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

Terminal structure of hypovirulence-associated dsRNAs in the chestnut blight fungus Endothia parasitica

The 3'- and 5'-terminal sequences of the five large double-stranded RNA species (L-dsRNA; 4.5-6.0 X 10(6) daltons) of EP713, a hypovirulent strain of Endothia parasitica, were determined by mobility-shift and enzymatic methods. All the L-dsRNAs appeared to have identical terminal sequences. A heteropolymer sequence was found at one 3'-terminus and a poly(A) sequence of variable length at the other. It was possible to label only one 5'-terminus using polynucleotide kinase and [gamma-32P]ATP, and this was shown to be a poly(U) sequence of variable length. We propose that the dsRNAs have the following structure, where X represents a blocking group: (Formula: see text). A recombinant plasmid containing dsRNA-related sequences was constructed. Hybridization analysis using the recombinant probe indicated that the sequence homology among the L-dsRNAs extended beyond these terminal regions and was also shared by small dsRNAs (0.3-0.45 X 10(6) daltons).

Heat inactivation of vaccinia virus particle-associated functions: properties of heated particles in vivo and in vitro

The heat inactivation characteristics of several vaccinia virus particle-associated functions known to be involved in the transcription of the genome were examined. All functions were more resistant to heat than infectivity. Noninfectious particles were generated which exhibited significant levels of activity of all enzymes examined, and their properties were investigaed both in vitro and in vivo. RNA was synthesized in vitro by such particles, although transport of the RNA into the surrounding medium was defective. This RNA was larger than that made in normal particles but it was polyadenylated and functioned in vitro as a message coding for normal early proteins. The sequences transcribed were similar to those transcribed in normal particles, and we suggest that the production of abnormally large RNA is due to a defect in transcriptional termination. We could not detect any virus-specific protein or RNA synthesis in cells exposed to these inactivated particles and conclude that the loss of infectivity caused by heating is due to a general decline in the activities of a number of particle functions.

Cucumber Mosaic Virus Associated RNA 5: Causal Agent for Tomato Necrosis

A small replicating RNA, encapsidated with and dependent on, but not part of the viral genome, modifies disease expression depending on the host. In tomato plants, it causes a lethal necrotic disease which is probably the same as that which, in 1972, destroyed most of the field tomato crop in large regions of the French Alsace.

The detection of virus DNA sequences in a herpes type 2 transformed hamster cell line (333-8-9)

Herpes simplex virus type 2 DNA labelled in vitro with 125I has been used as a probe to search for virus DNA sequences in the 333-8-9 line of transformed primary hamster cells and in clines derived from the line. Virus DNA sequences were present when the cells were examined initially but these sequences were lost on subsequent handling. No virus sequences were detected in clones derived from the line. It is suggested that the presence of virus DNA is an unstable characteristic of the cell line and that these sequences may be lost at cell division. The possibility that a small fragment of the genome remains cannot be excluded.

Synthesis of tobacco mosaic virus coat protein following migration of viral RNA into isolated mouse liver mitochondria

RNA of Tobacco Mosaic Virus is shown to be able to migrate into isolated mouse liver mitochondria, whence it can be reisolated intact. The migration of RNA is accompanied by enhanced rate of protein synthesis, which is sensitive to chloramphenicol, but not to cycloheximide. Evidence is presented showing that, among the products formed is the coat protein of Tobacco Mosaic Virus.