Aqueous soluble tetrazolium/formazan MTS as an indicator of NADH- and NADPH-dependent dehydrogenase activity.

Recently a new tetrazolium was described for the use of monitoring cell viability in culture. This tetrazolium, commonly referred to as MTS [3-(4,5-dimethylthiazol-2-yl)- 5-(3-carboxymethonyphenol)-2-(4-sulfophenyl)-2H-tetrazolium, inner salt], has the unusual property that it can be reduced to a water-soluble formazan. beta-Nicotinamide adenine dinucleotide/reduced (NADH) and beta-nicotinamide adenine dinucleotide phosphate/reduced (NADPH) are examples of physiologically important reducing agents. In cell-free studies, MTS was reduce to the soluble formazan in the presence of NADH and NADPH, and reaction were compared to those with dithiothreitol (DTT) or 2-mercaptoethanol (2-ME). The efficiency of these reactions was enhanced 1000-fold by the presence of phenazine methosulfate. Selectivity in the electron transfer from NADPH was slightly greater than NADH, and NADPH or NADH was much greater than the thiols DTT or 2-ME. Generation of either NADH or NADPH in solution by malate dehydrogenase or isocitrate dehydrogenase, respectively, was monitored by the MTS reduction reaction. The rate of formazan formation was comparable to the formation of NADH or NADPH. This system represents a useful tool for evaluating reaction kinetics in solutions of NAD- or NADP-dependent dehydrogenase enzymes, and these reactions can be performed in typical biological buffers containing reducing agents without significant interference to the MTS/formazan system.

Capping of tobacco mosaic virus RNA. Analysis of viral-coded guanylyltransferase-like activity.

The 5' end of tobacco mosaic virus (TMV) genomic RNA is capped with 7-methylguanosine. A virus-coded polypeptide with guanylyltransferase activity has been investigated. This enzyme is responsible for forming the 5'----5' linkage of guanosine 5'-monophosphate to the 5'-diphosphate of an acceptor RNA, thereby forming the cap. A critical step in the mechanism for cap formation in the eukaryotic nucleus is for guanylyltransferase to bind covalently to guanosine 5'-monophosphate with the hydrolysis of pyrophosphate when guanosine 5'-triphosphate is the substrate. The TMV 126-kilodalton protein, which is most probably a component of the TMV replicase, was found to have this activity. The mechanism of this reaction has been characterized biochemically.

Serine/threonine protein phosphatase is required for tobacco mosaic virus-mediated programmed cell death.

A major gap in our understanding of host response to virus infection is how the molecular signals are passed within infected cells. Tobacco mosaic virus-mediated programmed cell death in genotype NN tobaccos was used to evaluate the hypothesis that these molecular signals are transduced via reversible-protein phosphorylation. Nicotiana tabacum L. (genotype NN) confers a hypersensitive response at the site of virus infection when incubated at a permissive temperature. Activation of serine/threonine protein phosphatase correlated with the temperature-dependent induction of the death program. The serine/threonine protein phosphatase inhibitor okadaic acid inhibited the onset and extent of the hypersensitive response in vivo. Biochemical analysis indicates that protein phosphatase type 1 is activated early in the death program. This is the first indication that serine/threonine protein phosphatase is required in an early event of the host response to virus infection.

Lack of correlation between the accumulation of plus-strand leader RNA and the inhibition of protein and RNA synthesis in vesicular stomatitis virus infected mouse L cells.

The inhibition of protein synthesis in mouse L cells infected by vesicular stomatitis virus (VSV) requires expression of two regions (one large and one small) of the viral genome, as determined by target size analysis. The inhibition of host RNA synthesis was also shown to be dependent on expression of two regions of the VSV genome, most likely the same ones. In some cases, such as in cells infected by mutants T1026R1, or tsG41 at 40 degrees, or moderately uv irradiated VSV, only one of the two regions was expressed, yet cellular protein and RNA synthesis was decreased. This suggests that the product of each region of the viral genome can act independently. In these instances the severity of the inhibition was dependent on both the length of the infection period and the multiplicity of infection. The identity of neither gene product is known, but it has been suggested that small product is plus-strand leader RNA. As shown herein, however, there was no correlation between the extent of host macromolecular synthesis inhibition and the quantity of leader RNA in infected cells.

In vitro translation products of mrnas derived from TMV-infected tobacco exhibiting a hypersensitive response.

Expression of the hypersensitive response (HSR) to tobacco mosaic virus (TMV) infection in Nicotiana tabacum L. cv. Xanthi-nc (genotype NN) is controlled by the single dominant "N" gene and is temperature sensitive. TMV-infected Xanthi-nc tobacco plants grown at the HSR-restrictive temperature of 31 degrees for 3 days postinoculation show necrosis approximately 8 hr after the temperature shift to the HSR-permissive temperature of 25 degrees . Both polyribosomal and total cytoplasmic poly(A)-containing RNAs were isolated at various times after the temperature shift from leaves of TMV-infected and mock-infected Xanthi-nc tobacco plants and from TMV-infected Turkish Samsun tobacco plants (genotype nn; systemic for TMV infection). The RNAs were translated in vitro and the products were analyzed by polyacrylamide gel electrophoresis. A minimum of four polypeptide translation products specific to both the polyribosomal and total cytoplasmic poly(A)-containing RNAs derived from hypersensitively responding Xanthi-nc were observed.

Two transcription products of the vesicular stomatitis virus genome may control L-cell protein synthesis.

When mouse L-cells are infected with vesicular stomatitis virus, there is a decrease in the rate of protein synthesis ranging from 20 to 85% of that in mock-infected cells. Vesicular stomatitis virus, irradiated with increasing doses of UV light, eventually loses this capacity to inhibit protein synthesis. The UV inactivation curve was biphasic, suggesting that transcription of two regions of the viral genome is necessary for the virus to become inactivated in this capacity. The first transcription product corresponded to about 373 nucleotides, and the second corresponded to about 42 nucleotides. Inhibition of transcription of the larger product by irradiating the virus with low doses of UV light left a residual inhibition of protein synthesis consisting of approximately 60 to 65% of the total inhibition. This residual inhibition could be obviated by irradiating the virus with a UV dose of greater than 20,000 ergs/mm(2) and was thus considered to represent the effect of the smaller transcription product. In the R1 mutant of C. P. Stanners et al. (Cell 11:273-281, 1977), inhibition of transcription of the larger product sufficed to restore protein synthesis to the mock-infected level, suggesting that the smaller transcription product is nonfunctional with respect to protein synthesis inhibition. It thus appears that the inhibition of protein synthesis by wild-type vesicular stomatitis virus involved at least two separate viral transcription products, and the inhibition by the R1 mutant involved only one. Extracts from cells infected with virus irradiated with low doses of UV light showed a protein synthesis capacity quite similar to that of their in vivo counterparts, indicating that these extracts closely reflect the in vivo effects of virus infection.

Tobacco mosaic virus particles contain ubiquitinated coat protein subunits.

Virions of tobacco mosaic virus (TMV) are composed of a single strand of RNA, encapsidated in about 2130 copies of a coat protein of MW 17,500. Asselin and Zaitlin [Virology 91, 173-181 (1978)] demonstrated that virion preparations also contained small amounts of a second protein of MW 26,500, which they termed "H protein." H protein, detectable to an average frequency of one per virion, was thought to be a protein of host origin. Subsequent studies [Collmer, Vogt, and Zaitlin, Virology 126, 429-448 (1983)] showed the H protein was comprised of a backbone of TMV coat protein, linked by a postulated isopeptide bond to a small protein that probably was of host origin. The host-derived moiety of H protein is shown here to be ubiquitin, most probably coupled to the coat protein at lysine 53. This finding is based on microsequencing of the H protein, and is substantiated by immunoblotting analysis with antibodies to human ubiquitin. Conjugated ubiquitin was detected in virions of all five strains of the virus tested. To our knowledge, this is the first report of a ubiquitinated viral structural protein.

Immunogold localization of the intracellular sites of structural and nonstructural tobacco mosaic virus proteins.

Antibodies raised against the 126K nonstructural protein (replicase) encoded by tobacco mosaic virus (TMV) RNA or the viral coat protein have been used to localize these proteins within virus-infected tobacco leaf cells by an immunogold labeling technique. A protocol is given for low-temperature fixation to facilitate immunogold labeling. In cells of TMV-infected leaf tissue, the 126K protein immunogold label was found almost exclusively in "viroplasms" in the cytoplasm and in pockets of virus particles at the viroplasmic periphery. When utilizing the coat protein antiserum, very little labeling was seen within the viroplasms, although virus particles throughout the cytoplasm were heavily labeled. Viroplasms contained electron-dense rope-like structures embedded in a ribosome-rich matrix. In their "mature" form, viroplasms are the well-known "X body" inclusions. The rope-like structures were up to 1.2 micron long and appear twisted, undergoing several revolutions throughout their length, but were not of a constant pitch. In transverse section, they appeared to be composed of several hollow, radially segmented cylinders 21 nm in diameter, with a 9-nm hole. Antibody labeling showed them to be composed, at least in part, of the 126K protein. Clusters of virus particles at the edge of or within the viroplasms were also labeled with the 126K antiserum, in contrast to virus particles in other areas of the cell, which were not. TMV-infected tobacco mesophyll protoplasts cultured for up to 27 hr did not contain the rope-like ribbons. Instead, isolated protoplasts contained amorphous cytoplasmic areas which were labeled with 126K antibody. Since the 126K protein is most probably a constituent of the TMV RNA-replicating enzyme (replicase), its intracellular location is considered to be indicative of the site of replication of TMV RNA. Therefore these results suggest that replication occurs at the edges of the viroplasms.