Temperature-sensitive mutants of foot-and-mouth disease virus with altered structural polypeptides. I. Identification by electrofocusing

The foot-and-mouth disease virus cis-acting replication element (cre) can be complemented in trans within infected cells

A temperature-sensitive (ts) mutation was identified within the 5'-untranslated region of foot-and-mouth disease virus (FMDV) RNA. The mutation destabilizes a stem-loop structure recently identified as a cis-acting replication element (cre). Genetic analyses indicated that the ts defect in virus replication could be complemented. Thus, the FMDV cre can function in trans. It is suggested that the cre be renamed a 3B-uridylylation site (bus).

The foot and mouth disease virus type O outbreak of 1992 is not related to vaccine strain (O/R2/75)

Vaccination is the only pragmatic approach to control foot and mouth disease in India. Strict quality control measures are essential to supply potent vaccine to the field application, in addition to monitoring the performance of the vaccine in the field. During the process of monitoring, an outbreak of FMD in vaccinated animals caused by type "O" virus in Tanjavur district of Tamil Nadu and a type "O" virus from unvaccinated herd of Karnataka were studied. Field isolates and vaccine virus were sequenced and analyzed. Data indicated that the virus from the outbreak in vaccinated cattle was a variant which could escape neutralization by antibodies against vaccine virus.

Characterization of an acid-resistant mutant of foot-and-mouth disease virus

A foot-and-mouth disease virus mutant which is stable at pH 6.4 has been isolated from a virus of serotype A. In contrast to the parent (P) virus, which gave a mixture of large and small plaques in BHK21 cells and in a bovine kidney cell line, the acid-resistant (AR) virus gave small plaques which did not increase markedly in size after 24 hr. The infectivity titer of the acid-resistant virus was about 100-fold lower in suckling mice than in BHK21 cells, whether the inoculation was made intraperitoneally or intracerebrally, whereas the parent virus gave similar titers in both systems. Furthermore, in mice the AR virus reached its end point two to three times more slowly. The diameter of the AR virus was almost 20% less than that of the P virus and it had a more distinct topography, but the two viruses cosedimented in sucrose gradients. However, the buoyant density in CsCl of the AR virus was slightly lower (1.42 compared with 1.43 g/cc) in coruns. The RNAs and capsid proteins of the two viruses gave similar profiles in sucrose gradients and by SDS-PAGE, respectively. However, isoelectric focusing of the capsid proteins revealed considerable differences between the two viruses. Whereas the P virus gave four protein bands, corresponding to VP1-VP4, the AR virus gave one band for VP4, two for VP3, two for VP2, and four for VP1. Sequence analysis of the genes coding for the capsid protein regions of the two viruses showed four changes (one silent), resulting in an Ala-3-->Ser substitution in VP1 and Glu-131-->Lys and Asp-133-->Ser substitutions in VP2.

Microheterogeneity of S-glycoprotein of mouse hepatitis virus temperature-sensitive mutants

Mouse hepatitis virus (MHV) strain JHM (MHV-JHM) is a neurotropic coronavirus that causes acute fatal encephalomyelitis in 75-99% of infected mice. The surviving animals may subsequently develop demyelinating disease. We compared the S peplomer protein of the wild type (wt) and five temperature-sensitive (ts) mutants of MHV-JHM. In contrast with the wt, none of these five cause fatal disease (mortality less than 10%). Three of these ts mutants did not induce any demyelinating disease, a fourth caused demyelinating disease in 5% of the animals and a fifth, designated ts8, exhibited strong demyelinating properties and caused demyelination in 99% of the animals. SDS-PAGE analysis revealed no differences in the molecular weight of S peplomer protein of wt or ts MHV-JHM mutants. However, isoelectric focusing of the S protein of these five ts mutants and the wt MHV-JHM, followed by transfer to nitrocellulose sheets and immunoblotting with anti-S specific antibody revealed significant differences in the microheterogeneity of the S protein.

Further characterization of an RNA defective mutant of the foot-and-mouth disease virus

In this paper a further characterization of a foot-and-mouth disease virus (FMDV) temperature-sensitive mutant, ts 6, is described. This mutant presents a defective RNA synthesis at non-permissive temperature (NPT) by comparison to the wt capacity. However, a low level of viral RNA synthesis (below 10%) was sufficient to achieve an almost normal protein synthesis including a normal pattern of protein cleavage. In addition, morphogenetic precursor particles, 14S and 75S, are formed, indicating that the structural proteins VP0, VP1 and VP3 provide the necessary signal for self-assembly, and that the RNA is not necessary for such assemblage. Finally, although an almost normal synthesis of viral proteins and morphogenetic precursors (14S and 75S) occurs, the induction of cellular protein shut-off was not evident, indicating that this viral effect appears late in the viral cycle once complete viral replication has occurred.

Rapid selection of genetic and antigenic variants of foot-and-mouth disease virus during persistence in cattle

Rapid evolution of foot-and-mouth disease virus (FMDV) is documented during persistent infections of cattle. The carrier state was established experimentally with plaque-purified FMDV of serotype C3. Virus was recovered from the esophageal pharyngeal area of the animals up to 539 days postinfection. Analysis of capsid proteins by electrofocusing and by electrophoretic mobility of the genomic poly(C)-rich tract suggested heterogeneity in several isolates and sequential dominance of viral subpopulations. Nucleotide sequences of the VP1-coding region of the parental FMDV C3 clones and of seven isolates from the carrier cattle showed point mutations that represented rates of fixation of mutations of 0.9 X 10(-2) to 7.4 X 10(-2) substitutions per nucleotide per year; 59% of the base changes led to amino acid substitutions, some of which were located within residues 135 to 151, a region involved in neutralization of FMDV. In the esophageal pharyngeal fluid samples, FMDV C3-neutralizing activity was present. Antigenic variation was demonstrated with monoclonal antibodies raised against FMDV C3. Two isolates from carrier cattle differed from the parental virus by 10(2)- or 10(3)-fold decreased reactivity with neutralizing monoclonal antibodies. We suggest that persistent, inapparent infections of ruminants, in addition to being a reservoir of virus, may promote the rapid selection of antigenically variant FMDVs.

Biochemical characterization of an aphthovirus type C3 strain Resende attenuated for cattle by serial passages in chicken embryos

We have compared several aspects of an aphthovirus strain attenuated for cattle (C3R-O/E) with the original strain (C3Res) from which it was derived after serial passages in chicken embryos. Biochemical differences detected by protein analysis in regular polyacrylamide gels (SDS-PAGE) and on electrofocusing gels (NEPHGE) suggest the presence of mutations throughout the genome. Changes were located in coat proteins VP1 and VP3 and in the polymerase precursor P100 (P3/ABCD). No other differences were found at the protein level by means of the techniques used. Polypeptide P100 of the attenuated strain showed a faster electrophoretic mobility in SDS-PAGE with respect to that of the wild-type strain, and the change seems to be located on its amino terminus half. Several functional differences were also found between the two viruses. Both strains grew equally well in BHK cells reaching roughly similar titers in plaque assays. However, the wild-type strain maintained its titer in cells of bovine origin (BK), whereas the titer of C3R-O/E strain decreased approximately one log in this cell system; moreover, plaques elicited by the attenuated strain were much smaller than the ones produced by C3Res. A diminution in the rate of RNA synthesis induced by C3R-O/E in BK cells compared with that of the wild-type strain was also detected; this trait was not observed in BHK cells. A delay in the kinetics of RNA synthesis was also detected in this strain. The virus yield of attenuated strain in BK cells was four times lower than in BHK cells.

Isolation and characterization of recombinants between attenuated and virulent aphthovirus strains

A guanidine-resistant mutant of the attenuated strain of aphthovirus type 01 strain Campos and the original wild-type strain were crossed to generate recombinant viruses. Two independently derived recombinant viruses were isolated. One isolate (RI) contained the P1 (structural proteins) gene region of attenuated strain and P3 (polymerase precursor) gene region of the wild-type strain. The other isolate (RII) had a genomic structure complementary to that of RI, this is, P1 of the wild-type strain and P3 of the attenuated virus. Recombinant RII inherited some in vitro phenotypic markers that were characteristic of the attenuated strain, whereas the RI recombinant had in vitro behavior that was similar to that of the wild-type strain. The data obtained suggest that the polymerase precursor (P3) of the attenuated strain (01 Campos) could be involved in the determination of the attenuated phenotype for fetal bovine kidney cells and, eventually, for cattle.

Recombination and oligonucleotide analysis of guanidine-resistant foot-and-mouth disease virus mutants

Guanidine resistance (gr) mutations of foot-and-mouth disease virus were mapped by recombining pairs of temperature-sensitive mutants belonging to different subtypes. In each cross, one parent possessed a gr mutation. Recombinants were isolated by selection at the nonpermissive temperature and assayed for the ability to grow in the presence of guanidine. From the progeny of three crosses, four different types of recombinant were distinguished on the basis of protein composition and RNA fingerprint. The sequences of the RNase T1-resistant oligonucleotides were determined and located in the full-length sequence of foot-and-mouth disease virus. The resulting maps show that (i) each recombinant was generated by a single genetic crossover, and (ii) both of the gr mutations studied were located within an internal 2.9-kilobase region which spans the P34 gene. This supports our hypothesis that guanidine inhibits the growth of foot-and-mouth disease virus by acting on nonstructural polypeptide P34. Additional evidence was provided by RNA fingerprinting gr mutants. In two of four cases the gr mutation was associated with a change in an oligonucleotide located near the 3' end of the P34 gene; in one of these the nucleotide substitution was identified.

Multiple sites of recombination within the RNA genome of foot-and-mouth disease virus

Recombinant foot-and-mouth disease viruses were isolated from cells infected with a mixture of temperature-sensitive (ts) mutants belonging to different subtype strains. In order to select for recombination events in many different regions of the genome, crosses were performed between various pairs of mutants, with ts mutations in different regions of the genome. ts+ progeny were analysed by electrofocusing virus-induced proteins and RNase T1 fingerprinting of their RNA. All but 5 out of 43 independent isolates, from nine crosses, proved to have recombinant RNA genomes. Maps of these genomes, based on a knowledge of the locations of the unique oligonucleotides, were constructed. Most could be interpreted as being the products of single genetic cross-overs, although three recombinants were formed by two cross-overs each. Cross-overs in at least twelve distinct regions of the genome were identified. This evidence of a large number of recombination sites suggests that RNA recombination in picornaviruses is a general, as opposed to a site-specific, phenomenon.

Biochemical characterization of an aphthovirus type 0(1) strain campos attenuated for cattle by serial passages in chicken embryos

The biochemical properties of a virulent and an attenuated strain of foot-and-mouth disease virus (FMDV) Type 0(1) Campos (0(1)C) were compared in order to establish differences that could account for their altered biological functions. The avirulent strain (0(1)C-O/E) was derived from the virulent strain 0(1)C by serial passages in chicken embryos. Analysis of the RNase T1-generated oligonucleotides of the viral RNA through one- and two-dimensional (2D) gel electrophoresis (fingerprints) revealed a few changes in the genome structure of the 0(1)C-O/E strain compared to the wild type strain. In addition there was a significant decrease in the length of the poly(C) rich tract of the 0(1)C-O/E RNA. All virion structural proteins, except VP4, their precursors, and the viral RNA polymerase (p56a) show charge differences. In addition a significant decrease in the apparent molecular weight of polypeptide p100 (primary translational product from the 3' end region of the genome) of the attenuated strain was observed.

Comparison of structural and nonstructural proteins of virulent and less virulent Theiler's virus isolates using two-dimensional gel electrophoresis

The Theiler's murine encephalomyelitis viruses (TMEV) are important neurotropic picornaviruses because they persist in the central nervous system (CNS) and produce an inflammatory demyelinating disease in the mouse, their natural host. Insight into the pathogenesis of this disease may come from studying the genetic and biochemical compositions of these viruses; therefore, in this report, the structural and nonstructural proteins specified by both highly and less virulent TMEV were examined. Using two-dimensional gel electrophoresis, structural and nonstructural proteins, originating from each of the three regions of the picornavirus genome (Kitamura et al., 1981; Rueckert and Wimmer, 1984), from nine TMEV isolates were compared on the basis of isoelectric points (pI). Proteins of two virulent TMEV (GDVII and FA viruses) had almost indistinguishable pI values, whereas two of the three major capsid proteins of the less virulent TMEV varied considerably. For example, the structural proteins VP1 and VP3 from seven less virulent viruses ranged from pI 6.3 to 6.9 and 6.5 to 8.3, respectively. On the other hand, the pI values of VP2 and nonstructural proteins from the less virulent TMEV varied relatively little. In general, structural proteins of each TMEV group had pI ranges unique to their respective biological group, while most nonstructural proteins were similar for all TMEV. The virus-specified proteins of Vilyuisk virus, which is serologically related to the TMEV and a possible cause of encephalomyelitis in man, had pI values similar to the less virulent TMEV. Finally, VP3 not only showed the greatest variation in pI among the less virulent TMEV, but it also was preferentially radioiodinated in intact virus from each of the two biological groups using the lactoperoxidase technique.

Evidence for at least two dominant neutralization antigens on human rhinovirus 14

A collection of 28 mutants of human rhinovirus 14, selected for resistance to 10 individual neutralizing monoclonal antibodies, was used to identify two major neutralization antigens, N-Ag I and N-Ag II. Isoelectric analysis showed that all 16 of the N-Ag I mutants analyzed were charge altered in VP1;8 of 12 N-Ag II mutants were altered in VP3. These results suggest that N-Ag I resides on VP1, whereas N-Ag II lies on VP3. The frequency of charge alterations was much higher than predicted by the genetic code, suggesting that charged amino acids on the antigenic sites play an important role in interaction with neutralizing antibody. Antibodies against N-Ag I and N-Ag II neutralize with widely different efficiencies.

RNP template of vesicular stomatitis virus regulates transcription and replication functions

Small leader RNAs, copied from the extreme 3' ends of the minus and plus strands of the vesicular stomatitis virus (VSV) genome, are thought to play a central role in the regulation of viral transcription and replication. We describe here a novel class of VSV mutants, denoted pol R, in which termination at leader sites in vitro is specifically suppressed. We have assayed for the presence of leader RNAs and readthrough transcripts in reaction products from standard virion templates (plus leader) and defective interfering particle templates (minus leader). In both cases, mutant virions gave rise to a much higher proportion of readthrough transcripts than wild type (greater than 80% vs approximately 10%). Reconstitution experiments with separated ribonucleoprotein (RNP) templates and polymerase protein fractions revealed, surprisingly, that the N protein moiety of the RNP template was responsible for readthrough. This conclusion was further supported by protein analyses that showed a similar charge change in the N protein of two independently isolated pol R VSV mutants. These results lead us to propose that modification of the N protein may regulate termination at leader RNA sites.

Isolation of capsid proteins of foot-and-mouth disease virus by chromatofocusing

A method for the isolation of foot-and-mouth disease virus (FMDV) capsid proteins was developed. The FMDV capsid proteins VP1, VP2, VP3 and VP0 were isolated from sucrose gradient purified virus by chromatofocusing in a pH 7.4-4.0 gradient on Polybuffer exchanger PBE 94. Under the conditions used the proteins eluted in the sequence VP1, VP2, VP0 (when present) and VP3. Capsid protein VP4 did not elute and could not be isolated by this method. Protein concentration in the eluate was monitored by the use of a radiolabelled marker and recoveries of approximately 50% of the input marker could be achieved when using up to 15 mg of virus and a 30-ml column. The high capacity and relative simplicity of chromatofocusing make it a useful alternative to other methods of purifying proteins.

Analysis of genetic variation in Theiler's virus during persistent infection in the mouse central nervous system

The genetic changes occurring in the BeAn strain of Theiler's murine encephalomyelitis virus (TMEV) during persistent infection in the mouse central nervous system (CNS) were studied. RNase T1-oligonucleotide fingerprinting of the RNAs of 28 BeAn viruses isolated at various times postinfection (p.i.) demonstrated that mutation occurred throughout the infection. Although plaque-purified BeAn virus was used to inoculate mice intracerebrally, genetically different viruses were recovered from the CNS. One to three oligonucleotide changes were found up to Day 152 p.i., but all three viruses isolated at Day 180 had four to nine oligonucleotide changes. No pattern of oligonucleotide changes occurring in different virus isolates was found, yet three viruses isolated from different animals at Day 180 had the same four new oligonucleotides. Overall, the number of oligonucleotide changes represented a 0.1 to 1.2% change in the virus genome. In addition, the analytical two-dimensional gel technique of P.Z. O'Farrell, H.M. Goodman, and P.H. O'Farrell (Cell 12, 1133-1142, 1977) suggested that mutation occurred in all virus isolates. In nine isolates, one to three proteins were found to have charge changes, and in general, as many nonstructural proteins had charge changes as structural proteins. P20, a nonstructural protein probably equivalent to the protease described for encephalomyocarditis virus, was found to have shifted cathodally in six different viruses. Several virus isolates had doublet patterns, suggesting the possibility that within the CNS, subpopulations existed which had proteins of slightly different charge or that virus-specified proteins had been modified after translation. Finally, antigenic variation of neutralizing site(s) on BeAn virus isolates as a way for virus to evade immune surveillance and thereby maintain the persistent state was studied. The ability of mouse serum to neutralize persisting virus isolates was not significantly different from the ability to neutralize the infecting virus. Therefore, antigenic variation does not appear to be a factor in TMEV persistence.

Point mutations in polypeptide VP1 of foot-and-mouth disease virus affect mouse virulence and BHK21 cell pathogenicity

Virus produced in the first four days after infection of a BHK21 culture was shown to differ from that produced later in the infection. The early virus caused large plaques in IB-RS-2 cell sheets, had a slow cytopathic effect in BHK21 cultures and showed a high virulence for suckling mice. In contrast, the late virus caused small plaques, was rapid in its cytopathic effect and was of low virulence for mice. Comparison between one clone each of the early and late virus showed that no change in immunogenic specificity had taken place, but that charge changes had occurred both in VP3 and in the large trypsin-resistant fragment of VP1. The early, large plaquing clone gave rise spontaneously to small plaquing virus during the destructive phase of a single passage in BHK21 cultures. Conversely, the late, small plaquing clone gave rise to large plaquing virus after a single passage in mice. Each new virus was cloned and it was shown that they differed in VP1. This indicated that missense mutations in the genome coding for the trypsin resistant fragment of VP1 were responsible for the biological changes observed.

Preliminary characterization of coxsackievirus B3 temperature-sensitive mutants

Prototype temperature-sensitive (ts) mutants of a coxsackievirus B3 parent virus capable of replication to similar levels at 34 or 39.5 degrees C were examined for the nature of the temperature-sensitive event restricting replication in HeLa cells at 39.5 degrees C. The ts mutant prototypes represented three different non-overlapping complementation groups. The ts1 mutant (complementation group III) synthesized less than 1% of the infectious genomic RNA synthesized by the coxsackievirus B3 parent virus at 39.5 degrees C and was designated an RNA- mutant. Agarose gel analysis of glyoxal-treated RNA from cells inoculated with ts1 virus revealed that cell RNA synthesis continued in the presence of synthesis of the small amount of viral RNA. This mutant was comparatively ineffective in inducing cell cytopathology and in directing synthesis of viral polypeptides, likely due to the paucity of nascent genomes for translation. The ts5 mutant (complementation group II) directed synthesis of appreciable quantities of both viral genomes (RNA+) and capsid polypeptides; however, assembly of these products into virions occurred at a low frequency, and virions assembled at 39.5 degrees C were highly unstable at that temperature. Shift-down experiments with ts5-inoculated cells showed that capsid precursor materials synthesized at 39.5 degrees C can, after shift to 34 degrees C, be incorporated into ts5 virions. We suggest that the temperature-sensitive defect in this prototype is in the synthesis of one of the capsid polypeptides that cannot renature into the correct configuration required for stability in the capsid at 39.5 degrees C. The ts11 mutant (complementation group I) also synthesized appreciable amounts of viral genomes (RNA+) and viral polypeptides at 39.5 degrees C. Assembly of ts11 virions at 39.5 degrees C occurred at a low frequency, and the stability of these virions at 39.5 degrees C was similar to that of the parent coxsackievirus B3 virions. The temperature-sensitive defect in the ts11 prototype is apparently in assembly. The differences in biochemical properties of the three prototype ts mutants at temperatures above 34 degrees C may ultimately offer insight into the differences in pathogenicity observed in neonatal mice for the three prototype ts mutants.

Recombination in RNA

The aphthovirus genome consists of a single molecule of single-stranded RNA that encodes all the virus-induced proteins. We isolated recombinant aphthoviruses from cells simultaneously infected with temperature-sensitive mutants of two different subtype strains. Analysis of the proteins induced by 16 independently generated recombinants revealed two types of protein pattern, which were consistent with single genetic crossovers on the 5' side and 3' side, respectively, of the central P34-coding region. Recombinants invariably inherited all four coat proteins from the same parent, and novel recombinant proteins were not observed. RNAase T1 fingerprints of virus RNA, prepared from representatives of each recombinant type, confirmed the approximate crossover sites that had been deduced from the inheritance of proteins. These fingerprints provide molecular evidence of recombination at the level of RNA and demonstrate the potential of RNA recombination for producing genetic diversity among picornaviruses.

Guanidine-resistant mutants of aphthovirus induce the synthesis of an altered nonstructural polypeptide, P34

Extracts of cells infected with guanidine-resistant mutants of aphthovirus were examined for differences in virus-induced polypeptides by using electrofocusing. Four of 1 independent spontaneous mutants induced the synthesis of an altered nonstructural polypeptide, P34. The precursor of P34, P52, and a previously unmapped polypeptide, P20c, also carried these charge-change mutations. No mutations in other regions of the genome were detected, and the remaining six guanidine-resistant mutants appeared entirely normal by electrofocusing. However, when the P34 of one of the latter mutants was examined by tryptic peptide fingerprinting, it too differed from that of the guanidine-sensitive parent. The frequency of P34 alterations among guanidine-resistant mutants suggests that P34 is functionally involved in the antiviral action of guanidine.

Poliovirus empty capsid morphogenesis: evidence for conformational differences between self- and extract-assembled empty capsids

In this paper we describe the use of specific proteinases, surface-specific radioiodination, and antigenic reactivity in conjunction with isoelectric focusing for probing the conformations of different polioviral empty capsid species. Naturally occurring empty capsids (called procapsids) with an isoelectric point of 6.8 were resistant to proteolytic digestion by trypsin or chymotrypsin, as were empty capsids assembled in vitro in the presence of a cytoplasmic extract prepared from poliovirus-infected HeLa cells. In contrast, self-assembled empty capsids (isoelectric point, 5.0) were sensitive to both proteinases. Capsid proteins VP0 and VP1 were attacked predominantly, whereas VP3 was resistant to cleavage. Unpolymerized 14S particles possessed a trypsin sensitivity which was qualitatively similar to that of self-assembled empty shells. Surface-specific iodination of virions and procapsids labeled VP1 exclusively. In contrast, radioiodination of self-assembled empty capsids labeled predominantly VP0. After radioiodination the sedimentation coefficient corrected to water at 20 degrees C, the isoelectric point, and the trypsin resistance of the procapsids remained unchanged. Procapsids and extract-assembled empty capsids were N antigenic, whereas self-assembled empty capsids were H antigenic. Self-assembled empty capsids were not converted to pH 6.8 trypsin-resistant structures by incubation with a virus-infected cytoplasmic extract. However, 14S particles assembled in the presence of a mock-infected extract formed empty capsids, 20% of which resembled extract-assembled empty shells as determined by the above-described criteria. These and related findings are discussed in terms of empty capsid structure and morphogenesis.

The nucleotide sequence of cDNA coding for the structural proteins of foot-and-mouth disease virus

The complete nucleotide sequence of cDNA coding for the structural capsid polypeptides of foot-and-mouth disease virus (FMDV) (strain A(10)61) has been determined. Portions of the flanking sequence coding for the nonstructural proteins p20a and p52 are also provided. The three larger structural polypeptides VP1, VP2 and VP3 have unmodified Mrs of 23248, 24649 and 24213, respectively. The size of the smaller polypeptide, VP4, can only be estimated at 7360 because the 5'-limit of its coding region is not yet known with certainty. The sequence data for VP1 (the major immunising antigen) and the amino-terminal quarter of p52 are compared with the data of Kurz et al. (Nucl. Acids Res. 9 (1981) 1919-1931) for a different serotype (O1K). This shows that variation is much greater in the region coding for VP1 than in that coding for p52. This is reflected in the level of amino acid sequence variation predicted for the two proteins. Analysis of relative codon usage reveals a strong bias in favour of C and G over U and A in the third base position. The dinucleotide frequencies show a bias against A-U and U-A, and for A-C and C-A.

Biochemical evidence of recombination within the unsegmented RNA genome of aphthovirus

Four different pairs of temperature-sensitive mutants, derived from the same strain of aphthovirus, were crossed by using an infectious center recombination test. Each parental mutant carried an unselected marker affecting the isoelectric point of a virus-coded polypeptide; progeny of the crosses, able to grow at the nonpermissive temperature, were screened for these unselected markers. Polypeptide charge was shown to be a stable, inheritable character, and three of the four crosses yielded genetic recombinants that possessed the polypeptide marker from both parents. Peptide fingerprinting and high-resolution isoelectric focusing of the polypeptides ruled out the explantation that these viruses were generated by mutation.

Temperature-sensitive RNA polymerase mutants of a picornavirus

Temperature-sensitive (ts) RNA polymerase mutants of a picornavirus are reported. Two foot-and-mouth disease virus (FMDV) mutants designated ts 22 and ts 115 have been characterized. As judged by isoelectric focusing, both have charge alterations in P56a, the FMDV RNA polymerase protein. Virus RNA synthesis in cells infected with the mutants is severely impaired at the nonpermissive temperature. RNA polymerase purified from baby hamster kidney cells infected with these mutants exhibits a marked ts transcribing activity in vitro. Spontaneous revertants of both mutants have P56a polypeptides that are indistinguishable from the parental proteins on the basis of charge. The revertants regain the ability to synthesize virus RNA in vivo at the nonpermissive temperature. RNA polymerase purified from the revertants remains transcriptionally active at the nonpermissive temperature.

Two-dimensional electrophoretic analysis of encephalomyocarditis viral proteins

All four capsid proteins of encephalomyocarditis virus and the precursor to two of these were resolved from purified virions with two-dimensional gel electrophoresis. In addition, all of the known stable virus-specific proteins found in infected cells, but not the primary and intermediate precursor proteins, could be resolved with these techniques.

The structural polypeptides of aphthovirus are phosphoproteins

Analysis of aphthovirus A12, strain 119ab, grown in the presence of inorganic 32P revealed that two of the major viral polypeptides, VP4 and trypsin-sensitive protein VP3, were highly phosphorylated. The other major polypeptides, VP1 and VP2, were also phosphorylated but to a much lesser extent. Polypeptides VP0 and P56, of which there are approximately one of two copies per aphthovirion, were also labeled with 32P. Phosphoserine and phosphothreonine appeared to be the amino acids labeled with 32P.

Temperature-sensitive mutants of foot-and-mouth disease virus with altered structural polypeptides. II. Comparison of recombination and biochemical maps

The structural polypeptides of foot-and-mouth disease virus were digested with Staphylococcus aureus V8 protease in the presence of sodium dodecyl sulfate. The protease-resistant peptides derived from temperature-sensitive mutants were compared with those of the wild type by electrofocusing in a polyacrylamide gel. Covariation between the charge shifts of different peptides indicated that they shared common sequences: only five independent peptides in all were derived from VP1, VP2, and VP3, accounting for approximately 50% of the polypeptide sequences. In two instances, amino acid substitutions that caused similar shifts in the isoelectric point were found to be located in different peptides. However, 15 mutants that possessed identical shifts in VP2 could not be distinguished by peptide analysis. The polypeptides of revertants able to grow at the nonpermissive temperature were compared with those of the parental mutants. By this test, 6 of the 12 distinguishable classes of coat protein mutations were found to covary with temperature sensitivity. In addition to true revertants, several phenotypic revertants which possessed a second charge change, either in a different structural polypeptide or in a different region of the same polypeptide, were isolated. The orientation of the recombination map was deduced from the loci of the coat protein mutations.