Phenotypic characterization of temperature-sensitive mutants of vaccinia virus with mutations in a 135,000-Mr subunit of the virion-associated DNA-dependent RNA polymerase

The phenotypic defects of three temperature-sensitive (ts) mutants of vaccinia virus, the ts mutations of which were mapped to the gene for one of the high-molecular-weight subunits of the virion-associated DNA-dependent RNA polymerase, were characterized. Because the virion RNA polymerase is required for the initiation of the viral replication cycle, it has been predicted that this type of mutant is defective in viral DNA replication and the synthesis of early viral proteins at the nonpermissive temperature. However, all three mutants synthesized both DNA and early proteins, and two of the three synthesized late proteins as well. RNA synthesis in vitro by permeabilized mutant virions was not more ts than that by the wild type. Furthermore, only one of three RNA polymerase activities that was partially purified from virions assembled at the permissive temperature displayed altered biochemical properties in vitro that could be correlated with its ts mutation: the ts13 activity had reduced specific activity, increased temperature sensitivity, and increased thermolability under a variety of preincubation conditions. Although the partially purified polymerase activity of a second mutant, ts72, was also more thermolabile than the wild-type activity, the thermolability was shown to be the result of a second mutation within the RNA polymerase gene. These results suggest that the defects in these mutants affect the assembly of newly synthesized polymerase subunits into active enzyme or the incorporation of RNA polymerase into maturing virions; once synthesized at the permissive temperature, the mutant polymerases are able to function in the initiation of subsequent rounds of infection at the nonpermissive temperature.     

Physiological characterization of temperature-sensitive mutants of mengovirus.

Twenty-four temperature-sensitive mutants of mengovirus were characterized physiologically with respect to phenotype. The mutants were separated into four classes on the basis of viral RNA synthesis. L-67-S cells infected with five of the mutants synthesized little viral RNA at 39.5 C. These mutants are designated RNA-. One mutant is designated RNA* since its RNA synthesis is altered at both 39.5 and 31.5 C. The other mutants were divided into two groups, RNA plus or minus (25 TO 49% of wild-type RNA synthesis) and RNA plus (50 to 100% of wild-type RNA synthesis). The time of expression of the mutation in the RNA- mutants was estimated from the results of reciprocal temperature-shift experiments. The mutatation in ts12 appears to be expressed at the time RNA synthesis normally begins. The defect in three of the mutants was expressed 1 to 2 h before RNA synthesis is normally detectable. Protein synthesis is required before RNA synthesis begins when the cells are shifted from 39.5 to 31.5 C. The RNA polymerase synthesized by cells infected with these RNA- mutants at 31.5 C was stable and fully active when assayed at 39.5 C in vitro. The sedimentation profiles of the viral RNA synthesized by cells infected with RNA plus and RNA plus or minus mutants are similar to wild-type profiles with the exception of ts148. Cells infected with this RNA plus or minus mutant synthesize RNA that sediments in a sucrose gradient like replicative-intermediate RNA, but little mature viral RNA is evident. The results of step-up experiments indicate that the temperature-sensitive period for the majority of the RNA plus and RNA plus and minus mutants extends through most of the replicative cycle. The temperature-sensitive defect of four of the mutants, however, was expressed in the first hour, suggesting that some undefined early function is required for the eventual maturation of mengovirus. The virions of three of the RNA- mutants were more thermolabile than wild-type virions. Five of the RNA plus and RNA plus or minus mutants were also thermolabile. Genetic complementation at a significant level was not detectable in mixed infections of the mutants described.     

Genetic Analysis of Simian Virus 40 III. Characterization of a Temperature-Sensitive Mutant Blocked at an Early Stage of Productive Infection in Monkey Cells

A temperature-sensitive mutant of simian virus 40 (SV40), ts(*)101, has been characterized during productive infection in monkey kidney cells. The mutant virion can adsorb to and penetrate the cell normally at the restrictive temperature, but cannot induce the synthesis of cellular deoxyribonucleic acid (DNA) nor initiate the synthesis of SV40-specific tumor, virion, or U antigens or viral DNA. First-cycle infection with purified ts(*)101 DNA is normal at the restrictive temperature, but the resulting progeny virions are still temperature-sensitive. The mutant neither complements nor inhibits other temperature-sensitive SV40 mutants or wild-type virions. The affected protein in the ts(*)101 mutant may be a regulatory structural protein, possibly a core protein, that is interacting with the viral DNA.     

Formation of a Sindbis virus nonstructural protein and its relation of 42S mRNA function.

Chicken embryo fibroblasts infected with an RNA- temperature-sensitive mutant (ts24) of Sindbis virus accumulated a large-molecular-weight protein (p200) when cells were shifted from the permissive to nonpermissive temperature. Appearance of p200 was accompanied by a decrease in the synthesis of viral structural proteins, but [35S]methionine tryptic peptides from p200 were different from those derived from a 140,000-molecular-weight polypeptide that contains the amino acid sequences of viral structural proteins. Among three other RNA- ts mutants that were tested for p200 formation, only one (ts21) produced this protein. The accumulation of p200 in ts24- and ts21-infected cells could be correlated with a shift in the formation of 42S and 26S viral RNA that led to an increase in the relative amounts of 42S RNA. These data indicate that p200 is translated from the nonstructural genes of the virion 42S RNA and further suggest that this RNA does not function effectively in vivo as an mRNA for the Sindbis virus structural proteins.     

Studies of two temperature-sensitive mutants of Mengo virus.

Studies of the synthesis of viral ribonucleates and polypeptides in cells infected with two RNA- ts mutants of Mengo virus (ts 135 and ts 520) have shown that when ts 135 infected cells are shifted from the permissive (33 degrees C) to the nonpermissive (39 degrees C) temperature: (i) the synthesis of all three species of viral RNA (single stranded, replicative form, and replicative intermediate) is inhibited to about the same extent, and (ii) the posttranslational cleavage of structural polypeptide precursors A and B is partially blocked. Investigations of the in vivo and in vitro stability of the viral RNA replicase suggest that the RNA- phentotype reflects a temperature-sensitive defect in the enzyme. The second defect does not appear to result from the inhibition of viral RNA synthesis at 39 degrees C, since normal cleavage of polypeptides A and B occurs in wt Mengo-infected cells in which viral RNA synthesis is blocked by cordycepin, and at the nonpermissive temperature in ts 520 infected cells. Considered in toto, the evidence suggests that ts 135 is a double mutant. Subviral (53S) particles have been shown to accumulate in ts 520 (but not ts 135) infected cells when cultures are shifted from 33 to 39 degrees C. This observation provides supporting evidence for the proposal that this recently discovered particle is an intermediate in the assembly pathway of Mengo virions.     

Regulation of viral and cellular RNA turnover in cells infected by eukaryotic viruses including HIV-1.

The following reviews the role of mRNA stability in the regulation of both viral and cellular gene expression in virus-infected cells. Indeed, several eukaryotic viruses, including the human immunodeficiency virus, HIV-1, regulate cellular protein synthesis via such control mechanisms. The following systems will be discussed: (i) the degradation of viral and cellular mRNAs in cells infected by herpes simplex virus (HSV) and advances made using the HSV virion host shutoff mutant; (ii) the degradation of viral and cellular mRNA and ribosomal RNA in cells infected by vaccinia virus and the possible role of the oligoadenylate synthetase-RNase L pathways; (iii) the turnover of RNAs in cells infected by encephalomyocarditis virus, reovirus, and La Crosse virus; and finally (iv) recent studies from our laboratory on the degradation of cellular mRNAs in cells infected by HIV-1.     

The herpes simplex virus virion host shutoff function.

The virion host shutoff (vhs) function of herpes simplex virus (HSV) limits the expression of genes in the infected cells by destabilizing both host and viral mRNAs. vhs function mutants have been isolated which are defective in their ability to degrade host mRNA. Furthermore, the half-life of viral mRNAs is significantly longer in cells infected with the vhs-1 mutant virus than in cells infected with the wild-type (wt) virus. Recent data have shown that the vhs-1 mutation resides within the open reading frame UL41. We have analyzed the shutoff of host protein synthesis in cells infected with a mixture of the wt HSV-1 (KOS) and the vhs-1 mutant virus. The results of these experiments revealed that (i) the wt virus shutoff activity requires a threshold level of input virions per cell and (ii) the mutant vhs-1 virus protein can irreversibly block the wt virus shutoff activity. These results are consistent with a stoichiometric model in which the wt vhs protein interacts with a cellular factor which controls the half-life of cell mRNA. This wt virus interaction results in the destabilization of both host and viral mRNAs. In contrast, the mutant vhs function interacts with the cellular factor irreversibly, resulting in the increased half-life of both host and viral mRNAs.     

Translation of Sindbis virus 26 S RNA and 49 S RNA in lysates of rabbit reticulocytes

Sindbis virus-specific polypeptides were synthesized in lysates of rabbit reticulocytes in response to added 26 S or 49 S RNA. Sindbis 26 S RNA was translated into as many as three polypeptides which co-migrate in acrylamide gels with proteins found in infected cells.Wild type 26 S RNA was translated primarily into two polypeptides, which appear to be the Sindbis nucleocapsid protein (mol. wt 30,000) and the precursor of the two glycoproteins of the virion (mol. wt 100,000). A larger polypeptide (mol. wt 130,000) was synthesized in response to ts2 26 S RNA, a species of RNA which was isolated from cells infected with the ts2 mutant of Sindbis virus. This large polypeptide is apparently the protein which accumulates in cells infected with the mutant virus and which is thought to be a precursor of all three viral structural proteins.These results support the hypothesis that 26 S RNA is the messenger for the three structural proteins of the virion and that the RNA codes for one large polypeptide precursor. The precursor may then be cleaved at a specific site to yield the nucleocapsid protein and a second polypeptide which, in infected cells, is cleaved in a series of steps to yield the two glycoproteins of the virion.Sindbis 49 S RNA was translated into eight or nine polypeptides ranging from 60,000 to 180,000 molecular weights. The viral structural proteins, as such, were not synthesized in response to the added 49 S RNA.     

Coupled translation and replication of poliovirus RNA in vitro: synthesis of functional 3D polymerase and infectious virus.

Poliovirus RNA polymerase and infectious virus particles were synthesized by translation of virion RNA in vitro in HeLa S10 extracts. The in vitro translation reactions were optimized for the synthesis of the viral proteins found in infected cells and in particular the synthesis of the viral polymerase 3Dpol. There was a linear increase in the amount of labeled protein synthesized during the first 6 h of the reaction. The appearance of 3Dpol in the translation products was delayed because of the additional time required for the proteolytic processing of precursor proteins. 3Dpol was first observed at 1 h in polyacrylamide gels, with significant amounts being detected at 6 h and later. Initial attempts to assay for polymerase activity directly in the translation reaction were not successful. Polymerase activity, however, was easily detected by adding a small amount (3 microliters) of translation products to a standard polymerase assay containing poliovirion RNA. Full-length minus-strand RNA was synthesized in the presence of an oligo(U) primer. In the absence of oligo(U), product RNA about twice the size of virion RNA was synthesized in these reactions. RNA stability studies and plaque assays indicated that a significant fraction of the input virion RNA in the translation reactions was very stable and remained intact for 20 h or more. Plaque assays indicated that infectious virus was synthesized in the in vitro translation reactions. Under optimal conditions, the titer of infectious virus produced in the in vitro translation reactions was greater than 100,000 PFU/ml. Virus was first detected at 6 h and increased to maximum levels by 12 h. Overall, the kinetics of poliovirus replication (protein synthesis, polymerase activity, and virus production) observed in the HeLa S10-initiation factor in vitro translation reactions were similar to those observed in infected cells.     

Association of Viral Ribonucleic Acid with Cellular Membranes in Chick Embryo Cells Infected with Sindbis Virus

Membranes from cells infected with Sindbis virus had associated with them viral ribonucleic acid (RNA) polymerase and about 60 to 70% of the viral RNA labeled when short pulses were used. This RNA contained most of the replicative intermediate and replicative form of viral RNA found in the infected cells. The use of "Mg(2+) sarkosyl crystals" permitted the isolation of membrane-bound nucleic acids and allowed the demonstration that Sindbis virus RNA was synthesized on a membrane-viral RNA complex. Viral RNA from the infecting virions first became associated with the membranes during the latent period and, subsequently, slowly detached. The attachment of the viral RNA to the membranes did not require active viral RNA polymerase, since RNA from ts6, an RNA(-) temperature-sensitive mutant of Sindbis virus, associated with cellular membranes at a nonpermissive temperature. However, the subsequent detachment of the RNA from the membranes was restricted in the absence of viral RNA synthesis. The results indicate that association of viral RNA with cellular membranes may represent an early step occurring during the replication of Sindbis virus RNA.