Interferon inducibility of mammalian tryptophanyl-tRNA synthetase: new perspectives.

Mammalian aminoacyl-tRNA synthetases are indispensible components of the cell's protein-synthesizing machinery. Surprisingly, recent experiments have demonstrated that synthesis of tryptophanyl-tRNA synthetase (WRS) is markedly enhanced after incubation of human cells with interferons. Why is this housekeeping enzyme interferon-inducible? Several hypotheses have been suggested. One hypothesis, that premature termination of protein synthesis was involved, was boosted by the discovery that the deduced amino acid sequence of the mammalian peptide chain release factor (RF) closely resembled that of WRS. Further investigation, however, suggests that the DNA encoding RF was wrongly identified and in fact encodes a rabbit WRS subunit. Other hypotheses on the interferon-inducibility of WRS, including the possibility that the protein performs other, regulatory functions in addition to its core enzymic activity, remain to be explored.

Transgenic plants that express genes including the 3' untranslated region of the turnip yellow mosaic virus (TYMV) genome are partially protected against TYMV infection.

In order to evaluate new possibilities for protecting plants against virus infection by interference with viral replication, two chimeric genes were constructed in which the (+) strand 3'-terminal 100 nucleotides (nt) of the noncoding region of the turnip yellow mosaic virus (TYMV) genome were placed downstream from the sense or antisense cat coding region. The two chimeric genes were then introduced into the genome of rapeseed (Brassica napus) using an Agrobacterium rhizogenes vector system. Plants expressing high levels of either chimeric gene showed partial protection against infection by TYMV RNA or virions. One interesting feature of the protection is that a proportion of the inoculated transgenic plants does not become infected. Protection was overcome when the inoculum concentration was increased. RNA complementary to the initial transcript was detected after infection.

The 3' promoter region involved in RNA synthesis directed by the turnip yellow mosaic virus genome in vitro.

We have previously shown that the last 100 nucleotides from the 3' end of turnip yellow mosaic virus (TYMV) RNA compete in vitro with genomic RNA for the TYMV-specific RNA-dependent RNA polymerase (RdRp). To further characterize the promoter on genomic RNA that produces complementary RNA strands, shorter fragments corresponding to the 3' region of the viral RNA were generated and used in in vitro assays. Fragments as short as 38 nucleotides corresponding to the 3' end of TYMV RNA compete with the viral RNA for the RdRp suggesting that the 3' promoter on plus strand RNA is probably less than or equal to 38 nucleotides long. These transcripts are themselves used as templates in vitro.

Fluorescence labeling of an aminoacyl-tRNA at the 3'-end and its interaction with elongation factor Tu.GTP.

A new approach for the fluorescence labeling of an aminoacyl-tRNA at the 3'-end is applied to study its interaction with bacterial elongation factor Tu (EF-Tu) and GTP at equilibrium. The penultimate cytidine residue in yeast tRNATyr-C-C-A was replaced by 2-thiocytidine (s2C). The resulting tRNATyr-C-s2C-A was aminoacylated and then alkylated at the s2C residue with N-(iodoacetylaminoethyl)-5-naphthylamine-1-sulfonic acid (1,5-I-AEDANS). A greater than 100% increase in the intensity of fluorescence emission of the modified Tyr-tRNATyr-C-s2C(AEDANS)-A was observed upon interaction with EF-Tu.GTP. A ternary complex dissociation constant of 1.27 X 10(-8) M was calculated from this direct interaction. Using such fluorescent aminoacyl-tRNA, the affinity of any unmodified aminoacyl-tRNA can be determined by competition experiments. By this approach, we show here that the affinity of unmodified Tyr-tRNATyr-C-C-A is identical to that of the modified Tyr-tRNATyr. This indicates that the fluorescence labeling procedure applied does not alter the affinity of the aminoacyl-tRNA for EF-Tu.GTP. The introduction of 2-thiocytidine into nucleic acids and their labeling with spectroscopic reporter groups may provide a unique means of investigating various types of nucleic acid-protein interactions.

Elongation in a Dictyostelium in vitro translation system is affected by calmodulin antagonists.

We have previously shown that the Dictyostelium discoideum ribosomal protein L19 specifically binds Ca2+/calmodulin [Sonneman et al. (1991) J. Biol. Chem. 266, 23091-23096]. To investigate the role of calmodulin in the regulation of protein synthesis, we have now established an in vitro protein synthesizing system from Dictyostelium cells which can elongate polypeptide chains with high efficiency. Various calmodulin antagonists affected translation in this system. The inhibitory effects of the antagonists could be partially reversed by addition of calmodulin. A monoclonal antibody against D. discoideum calmodulin also specifically inhibited protein synthesis. Similar effects of calmodulin antagonists were found in a standard wheat germ in vitro translation system.

Codon context effect in virus translational readthrough. A study in vitro of the determinants of TMV and Mo-MuLV amber suppression.

To assess the role of codon context on the efficiency of eukaryotic suppression of termination codons, we have compared, in a rabbit cell-free translation system, the readthrough efficiency related to two synthetic transcripts differing by the codon context around an amber codon. The codon contexts are derived from tobacco mosaic virus (TMV) and Moloney murine leukemia virus (Mo-MuLV) RNAs. The Mo-MuLV-like codon context does not promote suppression. Substituting TMV-derived triplets in the Mo-MuLV-like codon context shows that the two codons downstream from the TMV UAG signal are important determinants of suppression, as recently demonstrated in vivo.

Viruses: exquisite models for cell strategies.

Because of the small size of their genome, viral genes have been forerunners in helping us understand gene expression. It is also because of their small size that viruses have elaborated the amazing variety of strategies that enables them to produce all the proteins they require for their multiplication. As a consequence, many of the strategies of expression known to occur in cell systems were first demonstrated in viruses. The aim of this review is to highlight the contribution of viruses to our knowledge of cell processes.

Comparison of three different cell-free systems for turnip yellow mosaic virus RNA translation.

The two proteins of molecular weights 150,000 and 195,000 specific of turnip yellow mosaic virus (TYMV) RNA translation in reticulocyte lysates have now also been detected in two other cell-free systems programmed with TYMV RNA: the wheat germ extract and the Ehrlich ascites cell-free system. The wheat germ extract contains proteases that affect the nascent TYMV polypeptide chains. The specific post-translational maturation of the protein of molecular weight 195,000 known to occur in the reticulocyte lysate has been investigated in the ascites system. An N-terminal fragment and a C-terminal fragment of molecular weights 120,000 and 78,000, respectively, could be detected co-migrating with the post-translational cleavage products observed in the reticulocyte lysate. Similarly, a C-terminally labelled 78,000 molecular weight fragment could be observed in the wheat germ system. The differences between the three in vitro systems with respect to TYMV RNA translation are discussed.

Plant viruses and new perspectives in cross-protection.

Cross-protection in plants is the phenomenon whereby a plant preinoculated with a mild virus strain becomes resistant to subsequent inoculation by a related severe strain. It has been used on a large scale in cases where no resistant plants are available. Although several hypotheses have been proposed to explain the molecular mechanism underlying cross-protection, no single hypothesis can account for all the data obtained. Recently, a phenomenon akin to cross-protection has been achieved in transformed plants harboring the cDNA of a part of a viral RNA genome. These results obtained by genetic engineering raise new hopes for obtaining plants resistant to virus 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.

An enigma: the role of viral RNA aminoacylation.

The first demonstration on the aminoacylation capacity of the RNA genome of a plant virus appeared more than 25 years ago. Shortly thereafter, aminoacylation of the RNA genome of a number of other plant viruses was observed. This led to considerable work on the tRNA-like region of these viral RNAs, and to the first demonstration of the presence of pseudoknots in their folding pattern. In spite of the vast amount of efforts put into trying to understand the reason for the aminoacylation capacity of certain viral RNA genomes, as yet no clear general conclusion emerges. It rather looks as though the reason for aminoacylation may be different for different viruses, and that aminoacylation may operate at different levels in the virus life cycle. Given that certain RNA viruses possess structures which resemble that of tRNAs at their 5'- or 3'-termini, it is most likely that convergent evolution may have dominated the appearance of such structures in the virus world.

Early events in virus-plant interactions.

1. Plant viruses can only enter their host through a wounded plant cell. Once in the cytoplasm, the virion must be disassembled, and for certain viruses with a "+" RNA genome, cotranslational disassembly of virus particles has been described. 2. Subsequent to viral protein synthesis which requires the host translational machinery, the "+" RNA genome is replicated in the cytoplasm. Viral genome amplification requires at least one viral-coded non-structural protein in conjunction with one or more host factors. 3. Early events in virus infection can be studied in systems that hinder these events. This is the case of natural hosts that are resistant to viruses: mutant viruses which overcome such resistance have been described. It is also the case of genetically engineered plants that are protected from virus infection. Both types of systems should help in determining the mode of interaction involved, and possibly also the host factor(s) involved in the various steps of virus infection.