Translation of TYMV RNA into high molecular weight proteins

Turnip yellow mosaic virus RNA-replicase contains host and virus-encoded subunits

The enzyme (RNA-replicase) involved in the synthesis of viral RNA has been purified from turnip yellow mosaic virus (TYMV)-infected chinese cabbage leaves. The RNA-replicaset contains two major subunits: one of apparent molecular weight 115,000 (115K) and the other of 45K. We have raised antisera against the purified TYMV-RNA-replicase and have demonstrated by immunoaffinity chromatography and immunoblotting that the 115K polypeptide is coded by the viral RNA but that the 45K protein is of host origin. Furthermore the TYMV RNA-replicase is clearly different from the RNA-dependent RNA polymerase that occurs in healthy as well as in infected plants.

Properties of the tobacco mosaic virus intermediate length RNA-2 and its translation

The existence of subgenomic RNAs is well established in the case of plant viruses such as tobacco mosaic virus (TMV). However, except for the subgenomic coat protein mRNA, it is not known whether the other subgenomic RNAs have a function in the life cycle of the virus. In search of more information about one of the major subgenomic RNAs-intermediate length RNA-2 or I2 RNA-of TMV, in vitro and in vivo translational studies were performed. The I2 RNA, which codes in vitro for the synthesis of a 30K (K = kilodalton) protein, appears to be uncapped as judged by the need of different in vitro translation conditions for the synthesis of this protein, compared to the conditions required for the synthesis of the 126K and 183K proteins coded by the capped genomic RNA. In vivo a protein migrating in the same position as the 30K protein synthesized in vitro can be detected in infected tobacco leaves. Since this protein occurs transiently early upon infection, whether it is virus-coded or virus-induced, it could have an early function during infection.

An improved protocol for the preparation of protoplasts from an established Arabidopsis thaliana cell suspension culture and infection with RNA of turnip yellow mosaic tymovirus: a simple and reliable method

An improved method for preparation of protoplasts of Arabidopsis thaliana cells grown in suspension culture is presented. This method is fast, reliable and can be used for the production of virtually an unlimited number of protoplasts at any time. These protoplasts can be transformed efficiently with RNA from turnip yellow mosaic tymovirus (TYMV) by polyethyleneglycol-mediated transfection. The simple transfection procedure has been optimized at various steps. Replication of TYMV can be monitored routinely by detection of the coat protein in as few as 2 x 10(4) infected protoplasts.

In vitro transcripts of turnip yellow mosaic virus encompassing a long 3' extension or produced from a full-length cDNA clone harbouring a 2 kb-long PCR-amplified segment are infectious

Two types of full-length cDNA clones have been constructed corresponding to the entire genome of turnip yellow mosaic virus (TYMV), from which infectious transcripts devoid of 5' non-viral extensions can be synthesized in vitro. The first type of transcript (tTYFL7) harbours 75 non-viral nucleotides at its 3' end, whereas the second type (tTYFL84) possesses only 2 non-viral nucleotides at its 3' end. The 2 kilobase-long 3' region of tTYFL84 derives from amplification by the polymerase chain reaction of the corresponding TYMV cDNA. Both tTYFL7 and tTYFL84 are infectious in rapeseed protoplasts and plants. tTYFL7 is far less infectious than wild-type TYMV RNA and somewhat less infectious than tTYFL84. The possible effects of the 3' extraviral sequences of tTYFL7 and the heterogeneity observed in the infectivity of other transcripts prepared as was tTYFL84 are discussed.

Proteolytic maturation of the 206-kDa nonstructural protein encoded by turnip yellow mosaic virus RNA

The longest open reading frame of turnip yellow mosaic virus genomic RNA (ORF-206) encodes a 206-kDa nonstructural protein. The most prominent in vitro translation products of ORF-206 are the full-length p206 and a shorter N-coterminal 150-kDa protein. We have confirmed these assignments by immunoprecipitation of in vitro translation products with antisera raised to N-terminal and C-terminal regions encoded by ORF-206. The mechanism by which the 150-kDa protein arises from ORF-206 was investigated by in vitro translation of deletion and substitution derivatives transcribed from pTYMC, a cDNA clone of TYMV RNA. The following observations demonstrate that the 150-kDa protein and a C-terminal 70-kDa protein arise from ORF-206 by autoproteolysis: (1) Two regions encoded by ORF-206 were necessary for the formation of the 150-kDa protein: a domain between amino acids 555 and 1051, postulated to encode a protease, and the region between amino acids 1253 and 1261, thought to constitute the protease recognition and/or cleavage site. (2) Mutants with substitutions between amino acids 1253 and 1261 that produce low levels of the 150-kDa protein in in vitro translations also have high levels of p206 and low levels of the 70-kDa protein. (3) The rate of formation of the 150-kDa protein is dilution insensitive, suggesting that proteolysis occurs mainly in cis.

Analysis of putative active site residues of the poliovirus 3C protease

It was recently suggested that the picornavirus 3C proteases are homologous to the chymotrypsin-like serine proteases. The two structural models proposed differ in one of the postulated active site residues, Glu/Asp71 or Asp85. We changed Glu71 of the poliovirus type 1 protease to Asp or Gln and Asp85 to Glu by oligonucleotide-directed site-specific mutagenesis of an infectious cDNA, and attempted to recover virus after transfection. Both Glu71 changes were lethal for the virus and proteolytic activity was abolished in vitro with the exception of the primary cleavage event at the P2/P3 junction. In contrast, the Asp85----Glu virus was viable. This mutant was temperature-sensitive for growth at 39 degrees and exhibited a minute plaque phenotype at permissive temperature. This defect correlated with low levels of viral-specific RNA and protein syntheses and slow virus growth. Proteolytic processing at the COOH-terminus of 3C was impaired, reducing the production of mature 3C and the viral replicase 3D. In addition, 3C-mediated cleavage events within the P2 region of the polyprotein seemed to occur rather inefficiently. 3C-specific processing within P1 and elsewhere within P3 was unaffected. We suggest that Asp85 does not form part of the active site of 3C, but could be important for the specific recognition of cleavage sites within P2.

Proteolytic origin of the 150-kilodalton protein encoded by turnip yellow mosaic virus genomic RNA

Turnip yellow mosaic virus genomic RNA codes in vitro for two overlapping proteins, 150-kilodalton (150K protein) and 206-kilodalton (206K protein) proteins. The proteolytic maturation known to affect the 206K protein has been further characterized by in vitro translation assays in a reticulocyte lysate or wheat germ extract. Cleavage is inhibited at 37 degrees C and restored when the temperature is shifted to 30 or 25 degrees C. Temperature shift experiments are used here to demonstrate that the 150K protein and the previously characterized 78K protein are the two fragments resulting from a primary cleavage phenomenon that affects the 206K protein in a cotranslational manner under usual translation conditions. This processing is prevented by several cysteine and serine proteinase inhibitors.

Infectious TYMV RNA from cloned cDNA: effects in vitro and in vivo of point substitutions in the initiation codons of two extensively overlapping ORFs

Full-length cDNA of the 6.3 kb turnip yellow mosaic virus (TYMV) genome was placed between a T7 promoter and a unique Hind III site. In vitro transcription of Hind III-linearized DNA of clone pTYMC yielded full-length RNA transcripts. In inoculations of Chinese cabbage protoplasts and plants, capped transcripts and virion RNA had similar specific infectivities and produced similar systemic symptoms. We have used the pTYMC clone in studies of the expression of two overlapping open reading frames (1.9 kb and 5.5 kb ORFs) by making mutants with alterations in the initiation codons. Evidence is presented from in vitro translations of mutant and wild type RNAs that both ORFs are expressed from TYMV RNA. A mutant in the initiation codon of the 5.5 kb ORF did not replicate in protoplasts, while mutants in the initiation codon of the 1.9 kb ORF replicated at low levels. The two groups of mutants were not able to complement each other.

A centrifugation method for separation of plant viral genomic and subgenomic RNAs

Using alfalfa mosaic virus (AMV) as a model, a simple method for separating plant viral genomic RNAs from their subgenomic counterparts was established. The method relies on sucrose gradient fractionation under carefully selected conditions of centrifugation and fraction collection. The RNA components are recovered in nearly quantitative yield and have full biological activity as measured by infectivity of the reconstituted RNAs in suitable protoplasts and plant hosts. The individual RNAs, on the other hand, show no such infectivity, indicating that the separation is indeed complete.

Overlapping open reading frames revealed by complete nucleotide sequencing of turnip yellow mosaic virus genomic RNA

The complete nucleotide sequence of turnip yellow mosaic virus (TYMV) genomic RNA has been determined on a set of overlapping cDNA clones using a sequential sequencing strategy. The RNA is 6318 nucleotides long, excluding the cap structure. The genome organization deduced from the sequence confirms previous results of in vitro translation. A novel open reading frame (ORF) putatively encoding a Pro-rich and very basic 69K (K = kilodalton) protein is detected at the 5' end of the genome. It is initiated at the first AUG codon on the RNA and overlaps the major ORF that encodes the non structural 206K (previously referred to as 195K) protein of TYMV; its function is unknown. Several amino acid consensus sequences already described among plant and animal viruses are also found in the TYMV-encoded polypeptides. A comparison with other viruses whose RNA sequence is known leads to the conclusion that TYMV belongs to the "Sindbis-like" supergroup of viruses and could be related to Semliki forest virus.

Proteolytic maturation of the turnip-yellow-mosaic-virus polyprotein coded in vitro occurs by internal catalysis

The genomic RNA of turnip yellow mosaic virus is translated in vitro into two major high-molecular-weight proteins, the larger of which (Mr 195 000) undergoes post-translational cleavage. The mechanism of formation of the primary cleavage products (Mr 120 000 and Mr 78 000) of the 195 000-Mr protein has been examined. The fact that cleavage partly occurs at a rate insensitive to dilution of the 195 000-Mr protein is suggestive of an intramolecular mechanism of proteolytic maturation.

Effect of freezing and thawing on the structure of turnip yellow mosaic virus

The uncoating of turnip yellow mosaic virus in vitro induced by freezing and thawing has been investigated using a variety of biochemical techniques including the aminoacylation capacity of the viral RNA and the ability of the RNA to stimulate protein synthesis, as well as physico-chemical techniques such as sucrose gradient centrifugation and electron microscopy by negative staining. In particular a fluorescence test has been developed that can serve as a routine method to quantify the RNA liberated during the freeze-thaw process. Escape of the viral RNA is a highly cooperative phenomenon: it depends critically on the virus concentration during freezing and thawing. Increasing the ionic strength or including foreign proteins diminish the escape of the RNA. The RNA is not damaged by this treatment and its liberation occurs without disruption of the viral capsid.

Translation of Southern Bean Mosaic Virus RNA in Wheat Embryo and Rabbit Reticulocyte Extracts

Southern bean mosaic virus RNA was translated in wheat embryo extracts and in nuclease-treated rabbit reticulocyte lysates. Four principal products were synthesized: two related products with molecular weights of 105,000 and 75,000, a product with a molecular weight of 29,000 that closely resembled coat protein, and a product with a molecular weight of 14,000. Their proportion depended on ionic conditions and the translational system used.

Post-Translational Proteolytic Cleavage of In Vitro-Synthesized Turnip Yellow Mosaic Virus RNA-Coded High-Molecular-Weight Proteins

In a reticulocyte lysate, turnip yellow mosaic virus genomic RNA directs the synthesis of two proteins with molecular weights of 150,000 (150K) and 195K. We present evidence that the larger protein is processed in vitro, after its completion, in at least three fragments. The NH 2 -terminal fragment (82K) and the COOH-terminal fragment (78K) have been well characterized by different methods. The fact that the 150K protein is not cleaved in vitro, although it contains the regions that are processed in the 195K protein, could be of fundamental biological significance for the expression of the viral genes: a single polypeptide chain could be processed in several ways, leading to different peptides with distinct biological activities.

Polyamines stimulate suppression of amber termination codons in vitro by normal tRNAs

Polyamines, such as spermine and spermidine, are able to stimulate reading of amber termination codons on viral messenger RNAs in vitro. This phenomenon is not due to an overall increase of error frequency during translation, but to a specific effect on a normal tRNA that is present in various eukaryotic cell preparations. The enhancement of reading of termination codons by normal tRNAs should be of major importance for the expression of specific genes in eukaryotic cells.

Interferon enhances 2-5A synthetase in embryonal carcinoma cells

Mouse teratocarcinomas provide a useful model of mammalian differentiation, because the malignant embryonal carcinoma (EC) stem cells of such tumours may produce various differential cell types in vivo or in vitro. Many EC cell lines have now been established and classified on the basis of their ability to differentiate in vivo into cell types characteristically derived from any of the three germ layers. There is convincing evidence that EC cells can neither produce interferon, nor respond to it by becoming resistant to virus, whereas differentiated cells derived from EC lines behave normally in both respects. We investigated the lack of responsiveness of EC cells towards interferon by measuring the levels of two double-stranded RNA-dependent enzyme activities recently shown to be enhanced by interferon. We report here that on treatment with interferon, EC cells show increased 2-5A synthetase levels comparable to those found in differentiated cells, while there is little or no effect on kinase activity in EC cells, in contrast to their differentiated counterparts.

Translation of alfalfa-mosaic-virus RNA 1 in the mRNA-dependent translation system from rabbit reticulocyte lysates

Translation of alfalfa mosaic virus (AMV) RNAs in the mRNA-dependent rabbit reticulocyte cell-free system was examined using different RNA concentrations. The pattern of products synthesized under the direction of AMV RNA 2, 3 and 4 was not or almost not influenced by their concentration. However, depending on the RNA 1 concentration either a very large protein of Mr 115,000 or a mixture of two smaller proteins, Mr 58,000 and 62,000 respectively, was formed. These three proteins represent overlapping peptide chains with identical N-termini. Addition of the cap analogue 7-methylguanosine 5'-monophosphate (m7GMP) or AMV RNA 3 stimulated the production of the 115,000-Mr protein at the expense of the 58,000-Mr and 62,000-Mr proteins. Both m7GMP and RNA 3 probably reduce the active concentration of RNA 1 by competing for (a) cellular component(s) necessary for translation. These experimental results suggest that the rate of translation beyond the C termini of the 58,000-Mr and 62,000-Mr proteins is reduced or completely inhibited owing to the limited availability of the succeeding tRNA(s).