Temperature-sensitive mutants of mouse hepatitis virus strain A59: isolation, characterization and neuropathogenic properties

Twenty 5-fluorouracil-induced temperature-sensitive (ts) mutants of mouse hepatitis virus strain A59 were isolated from 1284 virus clones. Mutants were preselected on the basis of their inability to induce syncytia in infected cells at the restrictive temperature (40 degrees) vs the permissive temperature (31 degrees). Of these mutants, only those with a relative plating efficiency 40 degrees/31 degrees of 3 x 10(-3) or smaller were kept. Virus yields at 40 degrees compared to 37 degrees and 31 degrees (leakiness) were determined. Most mutants (16) were RNA-, i.e., unable to synthesize virus-specific RNA at the restrictive temperature. The other four were RNA+. No qualitative differences were detected in the virus-specific RNAs in cells infected with RNA+ ts-mutants, both at 31 degrees and 40 degrees. Virus-specific proteins present in cells infected with ts-171 (RNA-) and the RNA+-mutants (ts-43, ts-201, ts-209, and ts-279) were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of immunoprecipitates. No qualitative differences in the pattern of virus-specific cellular proteins were detected among the mutants except for an additional polypeptide of about 46,000 daltons in ts-209-infected cells. Finally, the neuropathogenic properties of eight of the mutants were investigated. Whereas 10(2) PFU of wild-type virus injected intracerebrally killed 50 to 100% of 4-week-old Balc/c mice within 1 week, the mutants were highly attenuated. A dose of 10(5) PFU lead to no or transient disease. However, 4 weeks after infection with ts-342, ts-43, or ts-201 obvious histological changes were observed in brain and spinal cord of clinically healthy mice.     

A temperature-sensitive mutant of the baculovirus Autographa californica nuclear polyhedrosis virus defective in an early function required for further gene expression

Fifteen temperature-sensitive (ts) mutants of the baculovirus Autographa californica nuclear polyhedrosis virus (AcNPV) have been analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of proteins synthesized in infected cells. One of the mutants, tsB821, was found to be defective in a very early function. Seven virus-induced proteins were synthesized by 2 hr postinfection. In marked contrast to wild-type virus and the other 14 ts mutants, the synthesis of further virus-induced proteins did not occur in tsB821-infected cells at the restrictive temperature (33 degrees ). Host protein synthesis continued as normal after transient expression of the seven early proteins. Viral-specific DNA synthesis was blocked or significantly delayed in tsB821-infected cells at 33 degrees . The relative synthesis of certain viral-induced proteins, particularly P31, P32, P42, P66, and P69, varied considerably in the remaining 14 mutants at 33 degrees. Three mutants exhibited alterations in specific polypeptides; P75 was approximately 1 kDa smaller in tsB1075, P40 was approximately 1 kDa smaller in tsB951, and P25 was greatly reduced in quantity or altered in tsB305.     

Evaluation of five temperature-sensitive mutants of respiratory syncytial virus in primates: II. Genetic analysis of virus recovered during infection.

Five temperature-sensitive (ts) mutants of respiratory syncytial (RS) virus (ts-1, ts-1 NG-1, ts-1 NG-16, ts-2, and ts-7), previously evaluated forinfectivity and virulence in chimpanzees and owl monkeys, were also assayed for in vivo genetic stability. None of the five mutants tested was completely stable genetically. Thus, virus which had lost some or all of the ts property was recovered from each infected chimpanzee. Significantly, each ts-1 NG-1 isolate retained some degree of temperature sensitivity and hence was not true wild-type virus. Clonal analysis of viruses shed by ts-1, ts-1 NG-1, ts-1 NG-16, or ts-7 infected chimpanzees indicated that in most instances only a minority of the virus shed was altered genetically. Of five chimpanzees infected with the ts-2 mutant, three shed only ts virus, and the remaining two chimpanzees shed only ts+ virus. Such ts+ virus proved to be avirulent when evaluated in chimpanzees or owl monkeys, indicating that loss of the ts property did not restore virulence. Based upon these findings, the ts-2 mutant appears to be a suitable candidate for clinical trials in man.     

Temperature-sensitive herpes simplex virus type 1 mutants defective in the shutoff of cellular DNA synthesis and host polypeptide synthesis

Two temperature-sensitive herpes simplex virus type 1 mutants, ts 1-8 and ts 199, belonging to different complementation groups, were isolated. Both mutants were defective in the shutoff of host DNA synthesis at 39.5 degrees C (nonpermissive temperature). ts 1-8 exhibited intermediate levels of viral DNA synthesis at 39.5 degrees C, while ts 199 was completely deficient in viral DNA synthesis at 39.5 degrees C. Comparative polyacrylamide gel electrophoresis of the ts 1-8, ts 199 and wild-type viral-coded polypeptides and cellular proteins produced in vivo at 34 degrees C and 39.5 degrees C during various periods post infection was performed. The results indicated that ts 1-8 and ts 199 were temperature-sensitive for the secondary suppression of host polypeptide synthesis. Production of the beta (early) and gamma (late) viral polypeptides was slightly delayed in the mutant-infected cells at early times post infection at both 34 degrees C and 39.5 degrees C. This delayed protein production was not evident at later times post-infection. The ts 1-8 and ts 199 mutants were distinct from the HSV-1 viron-associated host shutoff (vhs) mutants of Read and Frenkel (J. Virol. 46 (1983) 498).     

Identification of the point mutations in two vaccinia virus nucleoside triphosphate phosphohydrolase I temperature-sensitive mutants and role of this DNA-dependent ATPase enzyme in virus gene expression

The biological function of the nucleoside triphosphate phosphohydrolase I (NTPase I) enzyme of vaccinia virus is not yet known. In this investigation we have identified the genetic lesion of two temperature-sensitive mutants of vaccinia virus, ts50 and ts36, as single point mutations contained within the 5'615 nucleotides of the NTPase I gene (ts50, G to A at position 131; ts36, C to T at position 556). The point mutations result in amino acid substitutions of Gly to Glu-44 (ts50) and Pro to Ser-186 (ts36). In monkey BSC-40 cells, ts50 and ts36 behave phenotypically like wild-type virus with respect to replication and synthesis of viral DNA but are defective in late polypeptide synthesis. However, these two ts mutants displayed a drastically different phenotype in virus-infected human HeLa cells at the restrictive temperature; viral DNA replication did not occur and late polypeptide synthesis was absent. Moreover, if the early block was overcome by a temperature shift-up, then HeLa cells infected with the ts mutants displayed a profile characteristic of defective late viral polypeptide synthesis. Our results reveal that vaccinia NTPase I enzyme functions early and late in the viral replication cycle and that the phenotype of these ts mutants is dependent upon the cell type.     

Electron microscopic studies of temperature-sensitive mutants of herpes simplex virus type 1

Fifteen temperature-sensitive (ts) mutants of herpes simplex virus type 1, each representing a single complementation group, were found to fall into three classes with regard to the degree of defectiveness in virion synthesis which they exhibited at the nonpermissive temperature (39°) when examined by electron microscopy. Mutants in class A, one DNA and one DNA⁺, failed to synthesize detectable particles. Mutants in class B, three DNA^? and four DNA⁺, synthesized small to moderate numbers of empty nucleocapsids. An unique cylindrical core form was observed in particles synthesized after infection with a class B mutant at 39°. Six DNA⁺ mutants in class C synthesized large numbers of virus particles most of which contained apparently empty nucleocapsids. In addition, five of the six mutants synthesized small to moderate numbers of dense-cored nucleocapsids and of these, two formed enveloped, dense-cored particles. The ultrastructural appearance of cells infected with one class C mutant at 39° resembled wild-type virus-infected cells at this temperature, yet it produced 10,000-fold less infectious virus than cells infected with the wild-type virus.     

Control of protein synthesis in herpesvirus-infected cells: analysis of the polypeptides induced by wild type and sixteen temperature-sensitive mutants of HSV strain 17.

The polypeptides induced in cells infected with a Glasgow isolate of HSV-I (17 syn+) have been characterized by SDS polyacrylamide gel electrophoresis. Study of the kinetics of synthesis in three cell lines has detected a total of 52 polypeptides, 33 of which can be identified in polypeptide profiles of purified virions. These include six low mol. wt. polypeptides that have not been previously reported. Several polypeptides were labelled with glucosamine in infected BHK cells. The different polypeptide patterns obtained at permissive (31 degrees C) and nonpermissive (38 degrees C) temperature in cells infected with 16 temperature-sensitive (ts) mutants are reported. The effect of multiplicity of infection (m.o.i.) on the polypeptide profile has been examined for two of the DNA -ve mutants: below ten, the profile varied with the m.o.i. whereas above ten it was constant. All mutants were therefore examined at an m.o.i. of approx. 20. Mutants from the same complementation group showed very similar profiles. A number of general conclusions concerning control of protein synthesis in HSV infected cells can be made: (I) As most of the 16 ts mutants affected the synthesis of several or many polypeptides it follows that a large proportion of genome specifies controlling functions. (2) The high frequency with which some polypeptides were affected suggests they are at or near the terminus of biosynthetic pathways which are under multiple control. (3) Conversely, some polypeptides were affected with a low frequency suggesting that their synthesis is not dependent on the expression of many virus functions. (4) Several individual ts mutations lead to the synthesis of increased amounts of different large polypeptides. (5) Analysis of every band detectably affected by at least one ts mutation has disclosed nine classes of dependence relationship between polypeptide synthesis and the DNA phenotype of the mutants, illustrating that this relationship is complex and different for different polypeptides. (6) The inhibition of host protein synthesis by the virus may not be a simple single step process.     

Short communications Decapsidation of polyoma virus mutants.

The decapsidation of several temperature-sensitive mutants of polyoma virus was compared with that of wild-type by infecting mouse embryo cells at low multiplicity simultaneously with ¹³¹I-labeled mutant and ¹²⁵I-labeled wild-type virus. Analysis of the cytoplasm revealed that the noncomplementing mutant ts-3 virutally failed to give rise to the subviral particles which are characteristic of wild-type virus decapsidation. Correspondingly, little or no DNA from the infecting ts-3 particles was found in the cell nucleus. In contrast, the late mutants ts-10 and ts-1260 were decapsidated to a greater extent than wild-type virus. The results obtained with these three mutants can be accounted for on the basis of mutational changes in structural polypeptides, conferring either increased or decreased stability to the viral particle. A decapsidation pattern similar to that of wild-type virus was registered for the early mutant ts-a. These data support a model for Py decapsidation which we have proposed (1).     

Phenotypic characterization and physical mapping of a temperature-sensitive mutant of Autographa californica nuclear polyhedrosis virus defective in DNA synthesis

A ts mutant of Autographa californica nuclear polyhedrosis virus (AcMNPV), ts8, was shown to be defective in viral DNA synthesis at the nonpermissive temperature. Ts8-infected cells synthesized only early viral polypeptides at the nonpermissive temperature, and in contrast to wild-type (WT)-infected cells, showed no inhibition of host cell protein synthesis. The effect of the mutation on viral DNA synthesis was not immediately reversed after shifting infected cells down from the nonpermissive temperature to the permissive temperature; rather, a delay of several hours occurred before viral DNA synthesis was detected. The rate of accumulation of viral DNA in ts8-infected cells failed to increase after a shift from the permissive temperature to the nonpermissive temperature. This indicated that the ts8 mutation was involved in the synthesis of proteins required for viral DNA synthesis. The mutation was mapped by marker rescue to the region lying between 60.1 and 62.0% of the AcMNPV physical map.     

Poliovirus temperature-sensitivie mutants defective in cytopathic effects are also defective in synthesis of double-stranded RNA.

The proportion of cells absorbing trypan blue (tb-+ character) can be used to measure the late c.p.e. of wild-type poliovirus (ts-+. tb-+), which was the same at restrictive (39-2 to 39-6 degrees C) or permissive (37 degrees C) temperatures. Of twenty ts mutants, seven showed normal c.p.e. at 37 degrees C but were defective in C.P.E. (TB) AT 39-5 degrees C; all seven tb mutants have previously been shown (Cooper et al. 1971) to give evidence of a primary defect in replicase 1 activity (to make the complementary or minus strand of virus RNA). The remainder (tb-+) have all previously been shown to give evidence of a primary defect either in replicase II activity (to make progeny plus strands) or in structural protein. Thus, the late c.p.e. is dependent on a product of the replicase I gene, of which the in vivo effector is probably double-stranded RNA. Late c.p.e. is not caused by prevention of host protein, RNA or DNA synthesis and is not necessarily correlated with lysosomal enzyme release. The tb mutants were also defective in inducing early changes in chromatin (chr) and in prevention of thymidine incorporation (pti), but the tb and pti/chr characters are probably independent expressions of replicase I activity. Virus growth does not depend on repression of DNA synthesis. Poliovirus represses the activities of host DNA-dependent RNA polymerase I and II to an equal extent. There is no evidence that repression of DNA or RNA synthesis results from direct interaction of virus protein with the DNA.     

Functional analysis of the A complementation group mutants of Sindbis HR virus

The 10 members of the A complementation group of temperature-sensitive (ts) mutants of SIN HR, the heat-resistant strain of Sindbis virus, were divided into two phenotypic subgroups. Subgroup I mutants (ts15, ts17, ts21, ts24, and ts133) demonstrated temperature-sensitive 26 S mRNA synthesis, whereas subgroup II mutants (ts4, ts14, ts16, ts19, and ts138) did not; both ts4 and ts19 demonstrated defective 26 S mRNA synthesis at 30 degrees. None of the A group mutants demonstrated temperature-sensitive 49 S plus-strand synthesis. Temperature-sensitive cleavage of ns230 was demonstrated by subgroup I mutants, except ts21, but not by subgroup II mutants. A revertant of ts133 that grew at 40 degrees retained temperature-sensitive 26 S mRNA synthesis but lost temperature-sensitive cleavage of ns230 and the RNA-negative phenotype. Only ts4, like ts11 of the B complementation group, demonstrated temperature-sensitive minus-strand RNA synthesis. In addition to ts24, cells infected with ts17 or ts133 continued to synthesize minus strands after shiftup in the absence of continued protein synthesis, and resumed synthesis of minus strands if shifted to the nonpermissive temperature after minus-strand synthesis had ceased at the permissive temperature.     

Respiratory syncytial virus infection in owl monkeys: viral shedding, immunological response, and associated illness caused by wild-type virus and two temperature-sensitive mutants.

Intranasal inoculation of owl monkeys with wild-type respiratory syncytial virus induced upper respiratory tract disease in each of seven animals. The response of owl monkeys to two highly defective, temperature-sensitive, multiple-lesion mutants was then compared to the pattern seen with wild-type respiratory syncytial virus. These mutants, ts-1 NG-1 and ts-1 NG-16, were derived from the ts-1 mutant that had been remutagenized with nitrosoguanidine (NG). Previously the ts-1 NG-1 and ts-1 NG-16 mutants had been shown to be more temperature sensitive and more stable genetically than their ts-1 parent. Both ts-1 NG-1 and ts-1 NG-16 produced infection that was delayed in onsent compared to wild-type virus infection. However, the mutants were shed from the upper respiratory tract for the same period of time and at the same titer as wild-type virus. The serum neutralizing antibody response to infection with the mutants was nearly equivalent to that elicited by wild-type virus. However, the extent of disease induced by the mutants was significantly less than that seen with wild-type virus. These observations suggest that the mutants are potential vaccine condidates and should be subjected to additional in vivo testing in primates and, ultimately, humans.     

Establishment of persistent infection in BHK-21 cells by temperature-sensitive mutants of Sindbis virus

Twelve temperature-sensitive (ts) mutants of Sindbis were examined for their ability to establish persistent infection in BHK-21 cells at 39 degrees C. Five of these mutants were able to initiate colony formation in infected cultures, which followed an extensive c.p.e. Two of the mutants were able to establish persistent infections which survived beyond the fifth cell passage p.i. The ability to initiate colony formation was correlated with low reversion of the ts mutation, or with ability to interfer with the multiplication of the wild-type virus. Virus released from persistently infected cultures was not temperature-sensitive. The restriction of virus multiplication in persistently infected cells operated prior to virus-specified RNA synthesis. It is concluded that in this system establishment of persistent infection depends on an inhibition of virus multiplication early in infection and occurs in only a small proportion of infected cells.     

The isolation of interferon-inducing mutants of vesicular stomatitis virus with altered viral P function for the inhibition of total protein synthesis

We have previously reported that T1026, a temperature-sensitive (ts) noncytocidal mutant of VSV, and its ts revertant, T1026-R1, are nonconditional mutants in the VSV function "P" for the inhibition of total protein synthesis (viral plus cellular) in infected cells (C. P. Stanners, A. M. Francoeur, and T. Lam, 1977, Cell 11, 273-281; C. P. Stanners, S. Kennedy, and L. Poliquin, 1987, Virology 160, 255-258). We have also shown that P- mutants such as these are superior interferon inducers relative to their parental P+ wild-type virus, HR, and that P- mutants may be distinguished from P+ virus using the plaque interferon production of PIF assay. (A. M. Francoeur, T. Lam, and C. P. Stanners, 1980, Virology 105, 526-536). In order to carry the analysis of VSV P function further, a number of independent mutants in the VSV P function are required. We show here that the PIF assay may be used to isolate spontaneously occurring interferon-inducing mutants (PIF+ mutants) from wild-type VSV (PIF- virus) populations. About one-half of the PIF+ mutants isolated with the PIF assay were found to have alterations in the VSV P function. As well as mutants that were defective for the inhibition of total protein synthesis, the assay yielded a new class of VSV P function mutants which appear to inhibit protein synthesis more severely than does P+ virus. The majority of newly isolated PIF+ mutants was also found to be temperature sensitive for growth. The ts phenotype, however, could be reverted for most PIF+ mutants with little effect on the PIF or P phenotype. These findings show that interferon induction and P function are related functions of VSV; this fact has allowed the isolation of a repertoire of mutants with widely varying P function.     

Characterization of a temperature-sensitive mutant of frog virus 3 defective in DNA replication

We have characterized the defect of a temperature-sensitive (ts) DNA^? mutant (ts 6642) of frog virus 3 (FV 3). At the nonpermissive temperature (30°) ts 6642 synthesized <3% of the viral DNA that was synthesized at the permissive temperature (23°). When ts 6642-infected cells were incubated at 30° for 4.0 hr and then shifted to permissive temperature, viral DNA synthesis started immediately even when protein synthesis was inhibited at the time of shiftdown. This result implies that at 30°, ts 6642 synthesized all the proteins required for viral DNA replication but that one of these was nonfunctional at the nonpermissive temperature. Further characterization revealed that ts 6642 was probably defective in the initiation of DNA replication. This conclusion was based on the following data: When ts 6642-infected cells incubated at 23° for 4.0 hr were shifted to 30°, there was a gradual decrease in viral DNA synthesis. By 1 to 1.5 hr after the shiftup, viral DNA synthesis was completely inhibited. Analysis of the density of the DNA synthesized after a shiftup in the presence of BUdR and FUdR suggested that residual viral DNA synthesis represented chain elongation, and not initiation of new rounds of DNA replication. The defective protein was therefore involved in the initiation process. Both wild-type FV 3 (FV 3⁺) and ts 6642 induced the synthesis of thymidine kinase and DNA polymerase at 30°. Therefore, neither of these enzymes was involved in the DNA replication defect of ts 6642.At the nonpermissive temperature, ts 6642 synthesized all the viral proteins that were detectable at the permissive temperature. However, synthesis of late proteins was delayed, and never reached wild-type levels. Furthermore, the rate of synthesis of late proteins at 30° became dependent upon the multiplicity of infection. These results reinforce our previous conclusion (R. Goorha and A. Granoff, 1974, Virology60, 237–250) that in FV3⁺-infected cells late proteins (and by implication late mRNAs) were synthesized in the absence of viral DNA replication.     

Replication and interaction of virus DNA and cellular DNA in mouse cells infected by a human adenovirus

C57 black mouse cells infected with human adenovirus type 5 (Ad5) produced large amounts of early virus proteins, small amounts of late virus proteins and less than 0.2 infectious units (i.u.)/cell of infectious virus. Many cells died but the cultures recovered. Virus DNA and cellular DNA were synthesized. Some Ad5 DNA sedimented with cell DNA in alkaline sucrose, but virus DNA was rapidly lost from the culture after recovery and none of 28 unselected cloned survivors contained detectable amounts of virus DNA or antigens. Ad5 ts36 was temperature-sensitive for virus DNA replication in mouse cells, but ts125 was detective at 32.5 degrees C as well as at 39.9 degrees C. No difference was detected in the percentage of virus DNA that sedimented in alkali with cell DNA, in mouse cells infected by Ad5 ts+, ts36 or ts125 at 32.5 or 39.9 degrees C. All parts of the virus genome were equally represented in virus DNA that sedimented with cell DNA, in mouse cells infected by Ad5 ts+ or ts36 at either temperature.     

Synthesis and processing of the nonstructural polyproteins of several temperature-sensitive mutants of Sindbis virus

We have examined the synthesis and processing of nonstructural polyproteins by several temperature-sensitive mutants of Sindbis virus, representing the four known RNA-minus complementation groups. Four mutants that possess mutations in the C-terminal domain of nonstructural protein nsP2 all demonstrated aberrant processing patterns when cells infected with these mutants were shifted from a permissive (30 degrees) to a nonpermissive (40 degrees) temperature. Mutants ts17, ts18, and ts24 showed severe defects in processing of nonstructural polyproteins at 40 degrees, whereas ts7 showed only a minor defect. In each case, cleavage of the bond between nsP2 and nsP3 was greatly reduced whereas cleavage between nsP1 and nsP2 occurred almost normally, giving rise to a set of polyprotein precursors not seen in wild-type-infected cells at this stage of infection. The nsP1 produced by these mutants was unstable and only small amounts could be detected in infected cells at the nonpermissive temperature. Submolar quantities of nsP2 were also present. We suggest that nsP1 and nsP2 may function as a complex and that free nsP1, and possibly nsP2, is degraded. Cleavage between nsP3 and nsP4 appeared to be normal in the mutants except in the case of ts17, where upon shift to 40 degrees P34 was unstable and nsP4 accumulated. We propose that the change in the P34/nsP4 ratio upon shift is responsible for the previously observed temperature sensitivity of subgenomic 26 S RNA synthesis in ts17 and for the failure of the mutant to regulate minus strand synthesis at 40 degrees. Other mutations tested, including ts21, which is found in the N-terminal half of nsP2, ts11, which has a mutation in nsP1, and ts6, which has a mutation in nsP4, all demonstrated nonstructural polyprotein processing indistinguishable from that in wild-type-infected cells. These results support our conclusion, based upon deletion mapping studies, that the C-terminal domain of nsP2 contains the nonstructural proteinase activity.     

Herpesvirus proteins: DNA polymerase and pyrimidine deoxynucleoside kinase activities in temperature-sensitive mutants of herpes simplex virus type 2.

Eleven temperature-sensitive mutants of herpes simplex virus type 2 strain HG52 were examined for ability to induce DNA polymerase activity in BHK 21/C13 cells. All mutants induced DNA polymerase at a permissive temperature, (31 degrees C) and all DNA-positive mutants at a non-permissive temperature (38 degrees C). Three DNA-negative mutants induced no DNA polymerase (ts 6, ts 9) or very little DNA polymerase (ts 11), at a non-permissive temperature, while ts 1, also DNA negative, induced a little more DNA polymerase than wild-type, often at both temperatures. The DNA polymerase induced by ts 6 at 31 degrees C was temperature-sensitive in vivo, but only slightly so in vitro. These results were confirmed immunologically and suggest that HSV-2 codes for at least part of a DNA polymerase activity, necessary for infection, and that full expression of this enzyme involves at least three viral genes.