Genetic and Physiological Properties of Temperature-Sensitive Mutants of Cocal Virus

Temperature-sensitive (ts) mutants of Cocal virus (VSV Cocal) were isolated after treatment with the base analogue mutagen, 5-fluorouracil. These mutants could be classified into four mutually complementing groups. Weak complementation was detected between certain pairs of VSV Cocal ts mutants and ts mutants of vesicular stomatitis virus (VSV) Indiana, but no complementation was observed with ts mutants of VSV New Jersey. Two complementing ts mutants of Chandipura virus, an unrelated rhabdovirus, did not complement any VSV mutant, Thus, ability to complement in the VSV group appears to be correlated with serological relationships.The RNA and protein-synthesizing capacities of these ts mutants have been determined, and it is possible to establish a correspondence between the VSV Cocal and the VSV Indiana complementation groups.     

Isolation and Characterization of Temperature-Sensitive Mutants of Vesicular Stomatitis Virus, New Jersey Serotype

Forty-eight temperature-sensitive (ts) mutants have been isolated from a wild-type strain of the New Jersey serotype of vesicular stomatitis virus (VSV) after exposure to the base analogue mutagen 5-fluorouracil. Of these mutants, 47 have been classified into 6 nonoverlapping complementation groups containing 21, 17, 4, 3, 2, and 1 mutant, respectively (1 mutant remaining unallocated). The ribonucleic acid (RNA) phenotype of 23 of these mutants has been established. Four of the six groups contain one or more mutants unable to synthesize detectable amounts of viral RNA under restrictive conditions (39 C). No complementation was observed in mixed infection with ts mutants from the five established complementation groups of the Indiana serotype of VSV.     

Selective isolation of mutants of vesicular stomatitis virus defective in production of the viral glycoprotein.

We describe a procedure that enriches for temperature-sensitive (ts) mutants of vesicular stomatitis virus (VSV), Indiana serotype, which are conditionally defective in the biosynthesis of the viral glycoprotein. The selection procedure depends on the rescue of pseudotypes of known ts VSV mutants in complementation group V (corresponding to the viral G protein) by growth at 39.5 degrees C in cells preinfected with the avian retrovirus Rous-associated virus 1 (RAV-1). Seventeen nonleaky ts mutants were isolated from mutagenized stocks of VSV. Eight induced no synthesis of VSV proteins at the nonpermissive temperature and hence were not studied further. Four mutants belonged to complementation group V and resembled other ts (V) mutations in their thermolability, production at 39.5 degrees C of noninfectious particles specifically deficient in VSV G protein, synthesis at 39.5 degrees C of normal levels of viral RNA and protein, and ability to be rescued at 39.5 degrees C by preinfection of cells by avian retroviruses. Five new ts mutants were, unexpectedly, in complementation group IV, the putative structural gene for the viral nucleocapsid (N) protein. At 39.5 degrees C these mutants also induced formation of noninfectious particles relatively deficient in G protein, and production of infectious virus at 39.5 degrees C was also enhanced by preinfection with RAV-1, although not to the same extent as in the case of the group V mutants. We believe that the primary effect of the ts mutation is a reduced synthesis of the nucleocapsid and thus an inhibition of synthesis of all viral proteins; apparently, the accumulation of G protein at the surface is not sufficient to envelope all the viral nucleocapsids, or the mutation in the nucleocapsid prevents proper assembly of G into virions. The selection procedure, based on pseudotype formation with glycoproteins encoded by an unrelated virus, has potential use for the isolation of new glycoprotein mutants of diverse groups of enveloped viruses.     

Neuropeptide-induced hypothermia and the course of central nervous system disease mediated by temperature-sensitive mutants of vesicular stomatitis virus.

Mice inoculated with many temperature-sensitive (ts) vesicular stomatitis virus (VSV) mutants incur a less aggressive disease than mice infected with wild-type VSV. The normal body temperature of mice, 38 degrees C, is not a permissive temperature for replication of the temperature-sensitive VSV mutants in cell culture. To determine whether the body temperature of mice caused the alteration in disease states, a neuropeptide that induces hypothermia in rodents was injected into mice before their infection with a temperature-sensitive VSV mutant. Only 1.0 ng of the neuropeptide neurotensin, injected intracerebroventricularly, was required to lower the core temperatures of mice an average of 2.5 degrees C. A single injection of neurotensin before infection with tsG31 VSV (complementation group III) dramatically altered the course of disease. Without neurotensin only 3% of the mice infected with tsG31 VSV died, but when neurotensin was administered 24 h before the inoculation of the tsG31 VSV, 80% of the mice died. The course of disease in mice produced by infection with another temperature-sensitive VSV mutant, tsG11 VSV (complementation group I), also was altered when neurotensin was injected before inoculation of the virus. Instead of 3% of the mice dying as in a normal infection with tsG11 VSV, treatment with neurotensin before inoculation produced a rapidly fatal disease, killing 90% of the mice.     

Complementation analysis of measles virus mutants isolated from persistently infected lymphoblastoid cell lines.

Human lymphoblastoid cell lines persistently infected with measles virus release a heterogeneous population of virions. At least 80% of the infectious particles were temperature sensitive for plaque formation at 39 degrees C. Plaque-purified temperature-sensitive mutants from four persistently infected human lymphoblastoid cell lines were shown to be heterogeneous with respect to efficiency of plating at 31 and 39 degrees C, as well as to antigen and RNA production at 39 degrees C. The heterogeneity was confirmed by complementation analysis in which 21 temperature-sensitive isolates were found to represent at least four of the five previously described complementation groups of measles virus. Two isolates complemented four reference temperature-sensitive mutants. These isolates either represent new complementation groups or are members of the fifth complementation group, group E. The majority of isolates were found to have multiple mutations, and group B mutants (RNA-) predominated. Two temperature-sensitive isolates were able to interfere with production of parental measles virus at both permissive and nonpermissive temperatures.     

Nongenetic complementation of group V temperature-sensitive mutants of vesicular stomatitis virus by UV-irradiated virus.

Cells infected with temperature-sensitive (ts) mutants of complementation group V of vesicular stomatitis virus (VSV) give an enhanced yield at nonpermissive temperature when co-infected or superinfected with UV-irradiated virus. Virions produced in these mixed infections are temperature sensitive and do not complement ts V45. Rescue of group V mutants is multiplicity dependent. It can occur in the presence of cycloheximide; kinetics of rescue are similar in the absence or in the presence of the drug. Rescue is due to nongenetic complementation and is interpreted as a trigger effect on maturation of a small quantity of biologically active protein V molecules provided by UV-irradiated virus. These results are comfirmed by rescue of ts V45 by UV-irradiated, defective, interferring T particles.     

Chinese hamster cells mutant at the hypoxanthine-guanine phosphoribosyltransferase (GPRT) locus. V. Complementation analysis of ts mutants

Four temperature-sensitive HPRT clones were used for hybridological analysis, which led to increase in complementation rate about 5 times. The probability of complementation, in respect of the HPRT locus proved to be rather high: 14 of 45 hybridization-tested mutants had complementation ability (including 3 ts mutants). Analysis of the complementation rate among mutants revealed clear-cut dependence on the selection conditions: clones grown in a medium with 8-azaguanine showed most frequent complementation. The use of mutants with a new phenotype in hybridization analysis revealed four additional complementation groups, three of which are made of temperature-sensitive clones. Biochemical analysis revealed the presence of hybrid forms of the HPRT enzyme in all hybrids tested. This confirms the intragenic character of complementation. At present, the functional map of the HPRT locus is represented by 9 groups, including a group of mutants with no complementation ability.     

Preliminary Physiological Characterization of Temperature-Sensitive Mutants of Vesicular Stomatitis Virus

Different temperature-sensitive mutants of vesicular stomatitis virus have been characterized in terms of their ability to induce synthesis of viral ribonucleic acid (RNA) in BHK-21 cells at 39 C (the restrictive temperature for these mutants). Mutants belonging to complementation groups I and IV (and probably II) did not induce actinomycin-resistant RNA synthesis in infected cells incubated at 39 C. All three mutants comprising complementation group III induced viral RNA synthesis at 39 C. The temperature sensitivity of the defective viral functions has also been studied by temperature-shift experiments. The functions associated with the mutants of groups I, II, and IV were required early, whereas the function associated with the group III mutants was not required until a late stage of the viral cycle. The heat sensitivity of extracellular virion was not correlated with complementation group.     

Isolation and Preliminary Characterization of Temperature-Sensitive Mutants of Rhizobiophage C

By using mutagenesis induced by N-methyl-N'-nitro-N-nitrosoguanidine, 150 temperature-sensitive mutants of rhizobiophage c were isolated. All were able to form plaques at 14 C but not at 29 C. They were classified into 21 complementation groups. Representative temperature-sensitive mutants from each complementation group were analyzed with regard to gene function. The approximate time of expression of the genes defined by the mutants was measured by temperature-shift experiments. Most genes began to be expressed at 4.0 to 7.5 h after infection at 14 C. Four genes were found which were expressed 2.5 to 3.5 h after infection. Some mutants showed no DNA synthesis at 29 C; some showed a delay in lysis. Some produced apparently normal particles after infection and lysis at 29 C; others produced various types of defective particles. Some mutants showing no DNA synthesis at 29 C nevertheless caused lysis at the normal time together with the production of phage structural components. Representative mutants from each complementation group were mapped by using two-factor crosses. A preliminary genetic map of phage c was constructed from the data.     

Genetic Characteristics of Conditional Lethal Mutants of Vesicular Stomatitis Virus Induced by 5-Fluorouracil, 5-Azacytidine, and Ethyl Methane Sulfonate

One hundred and seventy-five temperature-sensitive (ts) mutants of vesicular stomatitis virus (type Indiana-C) induced by 5-fluorouracil (FU), 5-azacytidine (ACR), and ethyl methane sulfonate (EMS) have been assigned to four complementation groups by a qualitative test. Group I contains 151 mutants; group II, 2 mutants; group III, 1 mutant; and group IV, 15 mutants; 6 are unclassified. FU was much more effective as a mutagen than either ACR or EMS. The proportion of the mutants belonging to groups I and IV, however, was similar in the case of all three mutagens. Fifteen mutants from groups I and IV have been used to obtain quantitative complementation data. Both groups appear to be homogeneous. Complementation yields increase with increasing multiplicity, but the number of particles per cell required to elicit maximal complementation is small. The pattern of genetic recombination parallels that of complementation. No recombination could be detected in crosses within group I (<0.001%) or group IV (<0.07%), whereas recombination (0.31 to 3.4%) was observed in crosses between groups I and IV. Recombination frequency did not increase with multiplicity above an input of 0.6 plaque-forming units per cell. Many group I mutants have very low reversion rates, and BHK 21 clone 13 cells infected with one of these mutants have been "cured" of infection by prolonged exposure at the restrictive temperature.     

Mutant analysis of herpes simplex virus-induced cell surface antigens: resistance to complement-mediated immune cytolysis.

BHK-21 cells infected with temperature-sensitive mutants of herpes simplex virus type 1 strain KOS representing 16 complementation groups were tested for susceptibility to complement-mediated immune cytolysis at permissive (34 degrees C) and nonpermissive (39 degrees C) temperatures. Only cells infected by mutants in complementation group E were resistant to immune cytolysis in a temperature-sensitive manner compared with wild-type infections. The expression of group E mutant cell surface antigens during infections at 34 and 39 degrees C was characterized by a combination of cell surface radioiodination, specific immunoprecipitation, and gel electrophoretic analysis of immunoprecipitates. Resistance to immune lysis at 39 degrees C correlated with the absence of viral antigens exposed at the cell surface. Intrinsic radiolabeling of group E mutant infections with [14C]glucosamine revealed that normal glycoproteins were produced at 34 degrees C but none were synthesized at 39 degrees C. The effect of 2-deoxy-D-glucose on glycosylation of group E mutants at 39 degrees C suggested that the viral glycoprotein precursors were not synthesized. The complementation group E mutants failed to complement herpes simplex virus type 1 mutants isolated by other workers. These included the group B mutants of strain KOS, the temperature-sensitive group D mutants of strain 17, and the LB2 mutant of strain HFEM. These mutants should be considered members of herpes simplex virus type 1 complementation group 1.2, in keeping with the new herpes simplex virus type 1 nomenclature.     

Carbohydrate heterogeneity of vesicular stomatitis virus G glycoprotein allows localization of the defect in a glycosylation mutant of CHO cells

The carbohydrate portion of the G glycoprotein of vesicular stomatitis virus (VSV) grown in CHO cells (CHO/VSV) has been fractionated on BioGelP6, concanavalin A-Sepharose, and pea lectin-agarose. The results suggest that, in addition to sialic acid and fucose heterogeneity, the asparagine-linked complex carbohydrate moieties of CHO/VSV also display branching heterogeneity. Although the majority of the glycopeptides bind to concanavalin A-Sepharose in a manner typical of certain biantennary carbohydrate structures, a significant proportion do not bind to the lectin. The latter behavior is typical of tri- or tetraantennary (branched) carbohydrate structures. The CHO/VSV glycopeptides which do not bind to concanavalin A-Sepharose separate into bound and unbound fractions on pea lectin-agarose suggesting that they include at least two different types of (branched) carbohydrate structures. Glycopeptides from the G glycoprotein of VSV grown in two, independently derived CHO glycosylation mutants which belong to complementation group 4 (Lec4 mutants) were examined in the same manner. In contrast to glycopeptides from CHO/VSV, glycopeptides from Lec4/VSV which passed through concanavalin A-Sepharose did not contain a component which subsequently bound to pea lectin-agarose. A glycopeptide fraction with these lectin-binding properties was also missing from cell surface glycopeptides derived from Lec4 cells. The combined results are consistent with the hypothesis that Lec4 CHO glycosylation mutants lack a glycosyltransferase activity responsible for the addition of a (branch) N-acetylglucosamine residue linked β1,6 to mannose.     

Isolation of coxsackievirus B3 temperature-sensitive mutants and their assignment to complementation groups

Ten temperature-sensitive (ts) mutants of Coxsackievirus B3 were isolated from a parent strain capable of replication to similar yields at either 34° or 39.5°. Eight mutants were isolated following mutagenesis with 5-fluorouracil and two were spontaneous mutants. Complementation tests permitted assignment of the ts mutants into three non-overlapping groups with complementation indices of 12.4 to 2.0. One mutant was not assigned to a complementation group.     

A fluorescence photobleaching study of vesicular stomatitis virus infected BHK cells. Modulation of G protein mobility by M protein

The mobility of vesicular stomatitis virus (VSV) G protein on the surface of infected BHK cells was studied by using the technique of fluorescence photobleaching recovery. The fraction of surface G protein that was mobile in that time scale of the measurement (minutes) was at least 75%, a relatively high value among cell surface proteins so far observed. For studies of the effect of an internal viral protein (M protein) on G protein mobility, cells infected with wild-type VSV were compared with those infected with temperature-sensitive VSV mutants of complementation group III, which contains lesions in the M protein. At the permissive temperature, a pronounced decrease in the mobile fraction of surface G was observed for each of three mutants studied, while mobility of surface G at the nonpermissive temperature was indistinguishable in mutant and wild-type infected cells. A significantly lower mobile fraction of G protein was also observed in SV40 transformed 3T3 cells infected with wild-type VSV, but not in 3T3 or chick embryo fibroblast cells similarly infected. None of the variables tested had a measurable effect on the lateral diffusion coefficient of the mobile G protein. These results are interpreted as modulation of the mobility of a specific cell surface protein by a specific intracellular protein.     

Isolation and Characterization of Chromosome-Gain and Increase-in-Ploidy Mutants in Yeast

We have developed a colony papillation assay for monitoring the copy number of genetically marked chromosomes II and III in Saccharomyces cerevisiae. The unique feature of this assay is that it allows detection of a gain of the marked chromosomes even if there is a gain of the entire set of chromosomes (increase-in-ploidy). This assay was used to screen for chromosome-gain or increase-in-ploidy mutants. Five complementation groups have been defined for recessive mutations that confer an increase-in-ploidy (ipl) phenotype, which, in each case, cosegregates with a temperature-sensitive growth phenotype. Four new alleles of CDC31, which is required for spindle pole body duplication, were also recovered from this screen. Temperature-shift experiments with ipl1 cells show that they suffer severe nondisjunction at 37°. Similar experiments with ipl2 cells show that they gain entire sets of chromosomes and become arrested as unbudded cells at 37°. Molecular cloning and genetic mapping show that IPL1 is a newly identified gene, whereas IPL2 is allelic to BEM2, which is required for normal bud growth.     

Isolation and characterization of temperature-sensitive mutants of adenovirus type 7.

Fifty temperature-sensitive mutants, which replicate at 32 degrees C but not at 39.5 degrees C, were isolated after mutagenesis of the vaccine strain of adenovirus type 7 with hydroxylamine (mutation frequency of 9.0%) or nitrous acid (mutation frequency of 3.8%). Intratypic complementation analyses separated 46 of these mutants into seven groups. Intertypic complementation tests with temperature-sensitive mutants of adenovirus type 5 showed that the mutant in complementation group A failed to complement H5ts125 (a DNA-binding protein mutant), that mutants in group B and C did not complement adenovirus type 5 hexon mutants, and that none of the mutants was defective in fiber production. Further phenotypic characterization showed that at the nonpermissive temperature the mutant in group A failed to make immunologically reactive DNA-binding protein, mutants in groups B and C were defective in transport of trimeric hexons to the nucleus, mutants in groups D, E, and F assembled empty capsids, and mutants in group G assembled DNA-containing capsids as well as empty capsids. The mutants of the complementation groups were physically mapped by marker rescue, and the mutations were localized between the following map coordinates: groups B and C between 50.4 and 60.2 map units (m.u.), groups D and E between 29.6 and 36.7 m.u., and group G between 36.7 and 42.0 m.u. or 44.0 and 47.0 m.u. The mutant in group A proved to be a double mutant.