Location of the transcription defect in group I temperature-sensitive mutants of vesicular stomatitis virus

Pathogenicity and immunogenicity for mice of temperature-sensitive mutants of vesicular stomatitis virus

Temperature-sensitive (ts) mutants of vesicular stomatitis (VS) virus were tested for their pathogenicity and immunogenicity in weanling mice. Compared with the wild-type virus (ts(+)), ts mutants representing genetic complementation groups I, II, and IV were considerably less pathogenic for mice infected by the intracerebral route and caused few deaths after intranasal inoculation. Mice were completely resistant to ts(+) and ts mutants by the intraperitoneal route. Resistance to intracerebral challenge with ts(+) VS virus was only minimal in mice vaccinated intraperitoneally with ts(+) or ts mutants and only moderate in mice vaccinated intranasally with three ts mutants. Intranasal vaccination, particularly with group IV mutants, resulted in solid immunity within 3 days to intranasal challenge with ts(+) virus. VS viral neutralizing antibody was present in the bronchial secretions of mice by 12 h after intranasal inoculation of mutant ts IV44; the bronchial antibody titers declined to undetectable levels between 3 and 7 days after vaccination. Neutralizing antibody was detected in the serum of mice by the third day after intranasal vaccination with ts IV44 and persisted at high level for at least 11 days. Certain classes of ts mutants would appear to be promising candidates for use as attenuated, live virus vaccines.

Molecular characterization of the polymerase gene and genomic termini of Nipah virus

In 1998, Nipah virus (NV) emerged in peninsular Malaysia, causing fatal encephalitis in humans and a respiratory disease in swine. NV is most closely related to Hendra virus (HV), a paramyxovirus that was identified in Australia in 1994, and it has been proposed that HV and NV represent a new genus within the family Paramyxoviridae. This report describes the analysis of the sequences of the polymerase gene (L) and genomic termini of NV as well as a comparison of the full-length, genomic sequences of HV and NV. The L gene of NV is predicted to be 2244 amino acids in size and contains the six domains found within the L proteins of all nonsegmented, negative-stranded (NNS) RNA viruses. However, the GDNQ motif found in most NNS RNA viruses was replaced by GDNE in both NV and HV. The 3' and 5' termini of the NV genome are nearly identical to the genomic termini of HV and share sequence homology with the genomic termini of other members of the subfamily Paramyxovirinae. At 18,246 nucleotides, the genome of NV is 12 nucleotides longer than the genome of HV and they have the largest genomes within the family Paramyxoviridae. The comparison of the structures of the genomes of HV and NV is now complete and this information will help to establish the taxonomic position of these novel viruses within the family Paramyxoviridae.

Revertants of a mutant of vesicular stomatitis virus which has an aberrant polyadenylation activity and a temperature-sensitive transcriptase

tsG16(l), a temperature-sensitive mutant of vesicular stomatitis virus, in vitro has at least three phenotypic differences from its parental wild-type (wt) virus due to mutation of the L gene. It was not known whether (i) the temperature-sensitivity of the transcriptase, (ii) the aberrant polyadenylation phenotype, and (iii) the extent of increased polyadenylation in response to S-adenosylhomocysteine (SAH) were associated with a single mutation. Spontaneous partial revertants were selected from tsG16(I) on the basis of the ability to form plaques at 34.7 degrees (35G16 revertants) or from 35G16 revertants on the basis of the ability to form plaques at 37 degrees (37G16 revertants). All six 35G16 revertants had fully (five) or partially (one) recovered the wt polyadenylation phenotype and the former five had also fully recovered the wt polyadenylation response to SAH. This suggested that a single mutation in tsG16(I) was probably associated with both of these phenotypes and also probably conferred the inability to grow at 34.7 degrees. None of the 35G16 revertants regained the wt phenotype for thermosensitivity of the transcriptase, although both of the 37G16 revertants did. This suggested that in vitro temperature-sensitivity of transcription by tsG16(I) might be due to a mutation different than the one affecting polyadenylation in the absence or presence of SAH.

Viral transcription is necessary and sufficient for vesicular stomatitis virus to inhibit maturation of small nuclear ribonucleoproteins

Infection of baby hamster kidney cells with vesicular stomatitis virus (VSV) results in the accumulation of immature U1 and U2 small nuclear ribonucleoproteins (snRNPs) that contain precursor U RNAs and at least some of the proteins specific for U1 and U2 snRNAs but lack the Sm complex of proteins that is common to these U snRNAs. The VSV function required for this effect is not known, but direct inhibition of cellular transcription did not alter the maturation of U1 and U2 snRNPs. On the other hand, viral transcription but not viral translation was required to inhibit U1 and U2 snRNP maturation. Temperature shift experiments with the mutant G114 showed that ongoing viral transcription was necessary, but that viral mRNA was not required for this inhibition. Furthermore, the VSV function involved in the inhibition of maturation of U1 and U2 snRNPs had a small UV target size of approximately 10 to 20 nucleotides. We demonstrate that temperature-sensitive mutants of VSV can be used as a tool to initiate the assembly of snRNPs in infected cells. These results are compatible with the suggestion that perturbation of snRNP metabolism by VSV precedes and is distinct from the effect of VSV on cellular RNA synthesis, although VSV leader RNA may be involved in both these functions.

Aberrant polyadenylation by a vesicular stomatitis virus mutant is due to an altered L protein

TsG16(I) is a temperature-sensitive mutant of vesicular stomatitis virus, Indiana serotype. Our stocks of this mutant overproduce polyadenylic acid in an in vitro transcription system. The overproduction of polyadenylic acid occurs at all temperatures tested (27, 31, 35, and 39 degrees C) and is apparently not due to an alternation in the N protein-RNA template. To characterize the altered moiety in tsG16(I) responsible for this phenotype, virions were fractionated and the polyadenylation phenotype in homologous and heterologous reconstitution assays was determined. The aberrant polyadenylation phenotype correlated with the presence of ts L protein but not ts NS or ts M protein fractions. Results of experiments in which solubilized tsG16(I) and wild-type virion components were mixed indicated that the altered moiety behaved as if present in stoichiometric amounts relative to active L protein. The effects of raising the temperature from 31 to 39 degrees C in such mixes were as would be predicted upon the assumption that the polyadenylation phenotype was associated with a thermosensitive transcriptase component [the L protein of tsG16(I) is known to be thermosensitive]. We conclude that the data strongly support the hypothesis that L is the altered protein responsible for the aberrant polyadenylation phenotype of tsG16(I).

Vesicular stomatitis virus mutant with altered polyadenylic acid polymerase activity in vitro

In vitro RNA synthesis by purified virions of a stock of tsG16(I) was aberrant compared with that of wild-type (wt) vesicular stomatitis virus. RNA made in vitro by tsG16(I) contained a larger proportion of A residues in polyadenylic acid [poly(A)] tracts than did RNA synthesized by wt virus, tsG13(I), tsG21(II) or tsG41(IV). Experiments to determine whether the aberrant polyadenylation was correlated with the known thermolability of the tsG16(I) L protein were inconclusive. Total product RNA made by tsG16(I) was methylated to almost the same extent as wt RNA, contained the same major methylated 5' cap structure as wt RNA, and was translated as well in a reticulocyte cell-free system, yielding the same molecular weight proteins in similar ratios. Most polyadenylated [poly(A)+] RNA made by tsG16(I) was considerably larger than wt poly(A)+ RNA and richer in AMP:UMP residues; however, the protein-coding capacities of mutant and wt poly(A)+ RNAs were similar. This suggested that most mRNAs made in vitro by tsG16(I) might possess very long poly(A)+ tracts, and digestion of RNA by T1 RNase supported this. It appeared, therefore, that a virally coded component of vesicular stomatitis virus could affect polyadenylation. This could be the poly(A) polymerase itself, a protein involved in control of polyadenylation, or a protein which affects an event spatially and temporally connected with polyadenylation (such as initiation of the subsequent mRNA).

Inhibition of cellular DNA synthesis by vesicular stomatitis virus

DNA synthesis in mouse myeloma (MPC-11) cells and L cells was rapidly and progressively inhibited by infection with vesicular stomatitis virus (VSV). No significant difference in cellular DNA synthesis inhibition was noted between synchronized and unsynchronized cells, nor did synchronized cells vary in their susceptibility to VSV infection after release from successive thymidine and hydroxyurea blocks. Cellular RNA synthesis was inhibited to about the same extent as DNA synthesis, but cellular protein synthesis was less affected by VSV at the same multiplicity of infection. The effect of VSV on cellular DNA synthesis could not be attributed to degradation of existing DNA or to decreased uptake of deoxynucleoside triphosphates, nor were DNA polymerase and thymidine kinase activities significantly different in VSV-infected and uninfected cell extracts. Analysis by alkaline sucrose gradients of DNA in pulse-labeled uninfected and VSV-infected cells indicated that VSV infection did not appear to influence DNA chain elongation. Cellular DNA synthesis was not significantly inhibited by infection with the VSV polymerase mutant tsG114(I) at the restrictive temperature or by infection with defective-interfering VSV DI-011 (5' end of the genome), but DI-HR-LT (3' end of genome) exhibited initially rapid but not prolonged inhibition of MPC-11 cell DNA synthesis. DNA synthesis inhibitory activity of wild-type VSV was only slowly and partially inactivated by very large doses of UV irradiation. These data suggest that, as in the effect of VSV on cellular RNA synthesis (Weck et al., J. Virol. 30:746-753, 1979), inhibition of cellular DNA synthesis by VSV requires transcription of a small segment of the viral genome.

Is cytoskeleton involved in vesicular stomatitis virus reproduction?

CER cells infected with vesicular stomatitis virus showed a morphology similar to that observed after cytochalasin B treatment. Temperature-sensitive mutants affected in envelope protein maturation did not induce those morphological changes at a nonpermissive temperature. In addition, the cytoskeleton was not implicated in vesicular stomatitis virus reproduction.

Effect of temperature-sensitive mutation on activity of the RNA transcriptase of vesicular stomatitis virus New Jersey

The virion-associated RNA transcriptase activity of vesicular stomatitis virus New Jersey temperature-sensitive (ts) mutants was assayed in vitro at the permissive (31 degrees C) and restrictive (39 degrees C) temperatures. RNA synthesis at 39 degrees C by the RNA-negative ts A1 and the RNA-positive ts C1 and ts D1 mutants was similar to that of wild-type virus. The RNA-negative ts B1 synthesized only small amounts of RNA in vitro at 39 degrees C. The three mutants of complementation group E were dissimilar in the amounts of RNA they synthesized at 39 degrees C: ts E1 synthesized very little RNA, ts E2 synthesized moderate amounts, and RNA synthesis by ts E3 was not inhibited. The two mutants of group F were also dissimilar, since ts F1 synthesized very little RNA at 39 degrees C, whereas ts F2 synthesized as much RNA as wild-type virus. The revertant clones ts B1/R1, ts E1/R1, and ts F1/R1 synthesized RNA at 39 degrees C in amounts comparable to wild-type virus, indicating that the heat sensitivity of the transcriptase activity of the mutants ts B1, ts E1, and ts F1 was associated with temperature sensitivity. Similar heat sensitivities were observed when transcribing nucleoprotein complexes were used in the assays, showing that the mutated polypeptides were part of the viral core. The heat stability of the mutant ts B1 was similar to that of wild-type virus, and in vitro RNA synthesis was fully restored when the temperature was lowered to 31 degrees C after 30 min of preincubation at 39 degrees C, showing that the inhibition was due to reversible configurational change of the mutated polypeptide. When virions of the mutant ts E1 were heated for 5 h at 39 degrees C, their infectivity and transcriptase activity were as stable as those of the wild-type virus, whereas transcriptase activity became very heat labile after disruption of the viral coat with a neutral detergent. This suggests an interaction between the mutated polypeptide and a coat polypeptide which stabilizes the activity of the transcriptase. The RNA transcriptase activity of the mutant ts F1 was also heat labile, although to a lesser extent than that of ts E1. Thus, the defects in transcriptase activity of groups B, E, and F suggest that all three polypeptides of the virus core, polypeptides L, N, and NS, are involved in the transcription. In addition, we postulate that the mutated gene products of groups E and F are multifunctional, being required both in transcription and replication, and that the gene product of group E may also be involved in some late stage of virus development.

Transcription of vesicular stomatitis virus is required to shut off cellular RNA synthesis

RNA synthesis by mouse myeloma (MPC-11) cells was rapidly and progressively shut off by infection with vesicular stomatitis virus temperature-sensitive (ts) mutants permissive for transcription. In sharp contrast, mutants or defective vesicular stomatitis virions restricted in transcription were incapable of causing progressive inhibition of cellular RNA synthesis even at massive multiplicities of infection. A viral product synthesized 30 to 60 min after permissive infection with tsG114(I) appeared to be essential for prolonged inhibition of RNA synthesis in cells switched up to restrictive temperature.

Virion RNA polymerases of two salmonid rhabdoviruses

RNA-dependent RNA polymerases were found to be associated with two salmonid rhabdoviruses: infectious hematopoietic necrosis (IHN) virus and the virus of hemorrhagic septicemia (VHS). The protein composition of these rhabdoviruses closely resembles that of rabies virus rather than that of vesicular stomatitis virus (McAllister and Wagner, 1975). The optimal temperature for in vitro transcription was found to be approximately 18 degrees C for IHN virus and approximately 15 degrees for VHS,, closely approximating optimal temperatures for growth of these viruses in salmonid cells. Unlike vesicular stomatitis virus, manganese ion (1 mM) could be used as a divalent cation substitute for magnesium ion (5 mM). The in vitro transcription products of IHN and VHS viruses hybridized completely to the homologous genome but not at all to the heterologous genome.

Analysis of VSV mutant with attenuated cytopathogenicity: mutation in viral function, P, for inhibition of protein synthesis

T1026, a ts mutant of VSV which is much less cytopathogenic than its parent, HR, and which can establish persistent infection under certain conditions, is a double mutant. In addition to its ts mutation in the virion RNA polymerase, T1026 has a second non-ts mutation in a viral function termed "P". This function is responsible for the inhibition of total protein synthesis in infected cells and acts chiefly at the level of translational initiation. In some cell systems, the inhibition of protein synthesis produced by P appears to be selective for cellular protein synthesis, whereas in other cell systems, both cellular and viral protein synthesis are inhibited. T1026 and its ts revertants are phenotypically P- -that is, cells infected with them show total protein synthesis rates equal to or greater than uninfected cells, while synthesizing viral proteins at the same or even greater rates than HR-infected cells. The P- mutation is correlated with failure to increase plaque size after 2-3 days of incubation. Since viral mutants obtained from persistently infected cultures in a variety of systems appear to be double mutants with a ts mutation in the virion RNA polymerase and a small plaque marker, we suggest that T1026 could represent a model for such mutants.

Temperature-dependent host range mutation in vesicular stomatitis virus affecting polypeptide L

We established previously that the temperature-dependent host range mutant, td CE 3, of vesicular stomatitis virus (VSV) New Jersey possesses temperature-sensitive RNA transcriptase activity. In this paper, we describe dissociation and reconstitution experiments designed to determine which VSV polypeptide is affected by the td CE 3 mutation. Wild-type VSV New Jersey (ts+), the temperature-dependent host range mutant (td CE 3), and the revertant of this mutant (td CE/R1) were used. Transcribing nucleoprotein preparations, isolated from purified virus particles, were treated in the presence of digitonin with either 0.9 M LiCl to produce supernatants containing virtually only the L polypeptide or 2.0 M LiCl to produce ribonucleoprotein pellets containing only the polypeptides N and NS. Supernatant and pellet fractions synthesized either no or only trace amounts of RNA in vitro. Reconstitution of the supernatants with the pellets in all combinations at 31 degrees C restored much of the transcriptase activity of the transcribing nucleoprotein preparations. RNA synthesis occurred at 39 degrees C when the three pellets were reconstituted with wild-type and revertant supernatants. However, supernatant of the mutant td CE 3 reconstituted with any of the three pellets resulted in little or no detectable transcriptase activity at 39 degrees C. This implies that the polypeptide affected by the td CE 3 mutation is the L polypeptide.

Rabies virus protein synthesis in infected BHK-21 cells

Rabies virus specific polypeptide synthesis was examined under hypertonic conditions, which selectively inhibit cellular protein synthesis. The rabies virus proteins (L, G, N, M1, M2) were synthesized throughout the course of infection, with little change in their relative rates of synthesis. The rates of synthesis of the G and M1 polypeptides were more sensitive to increasing osmolarity than those of the L, N, and M2 polypeptides. Extrapolation to isotonicity of the results obtained under hypertonic conditions indicated that the molar ratios of the polypeptides synthesized under normal conditions were 0.4 (L), 64 (G), 100 (N), 75 (M1) and 35 (M2). A high-molecular-weight polypeptide (190,000), designated polypeptide L, was repeatedly detected both in infected cells and in extracellular virus. The estimated number of L polypeptide molecules per virion was 33. The synthesis of a viral glycoprotein precursor, designated gp78, , preceded the appearance of the mature viral glycoprotein in infected cells labeled with [3H]glucosamine under isotonic conditions. In cells labeled under hypertonic conditions, little or no mature viral glycoprotein was detected, but a virus-specific glycoprotein with an electrophoretic mobility similar to that of gp78 was observed. This glycoprotein could be chased into mature viral glycoprotein when the hypertonic conditions were made isotonic. These results suggest that a reversible block of viral glycoprotein synthesis occurs under hypertonic conditions.

Analysis of the defects of temperature-sensitive mutants of vesicular stomatitis virus: intracellular degradation of specific viral proteins

The metabolism of viral RNA and proteins has been studied in cells infected with temperature-sensitive mutant strains of vesicular stomatitis virus. Certain viral proteins encoded by the mutant strains, usually the putative mutant protein for the assigned complementation group, were shown to be degraded more rapidly at the nonpermissive temperature than were the wild-type proteins. Group III mutants (tsG33, tsM301) encode M proteins which are degraded three- to fourfold faster than the wild-type protein. This defect cannot be fully rescued by coinfection with wild-type virus, and thus the defect appears to be in the M protein itself. Mutants tsM601 (VI) and tsG41(IV) encode N proteins which are degraded much faster than the wild-type protein and also share the property of being defective in replication of viral RNA, suggesting a correlation between these phenotypic properties. Furthermore, the L proteins of tsG11(I) and tsG13(I) are more labile than the wild-type protein at the nonpermissive temperature. The G protein of tsM501(V) did not undergo the change in electrophoretic mobility previously shown to be the result of sialylation, suggesting that it is defective in maturation or glycosylation at the nonpermissive temperature. Three of the mutants previously isolated in this laboratory, tsM502(V), tsM601(VI), and tsM602(VI), were shown to be defective in viral RNA synthesis at the nonpermissive temperature. Mutant tsM601(VI) was defective mainly in viral RNA replication, whereas tsM502(V) appeared to be totally defective for viral RNA transcription and replication at the nonpermissive temperature.

RNA- temperature-sensitive mutants of vesicular stomatitis virus: L-protein thermosensitivity accounts for transcriptase restriction of group I mutants

In vitro transcriptase activity of three group I temperature-sensitive (ts) mutants of vesicular stomatitis virus restricted at 39 C was restored by L-protein fractions derived from wild-type (wt) vesicular stomatitis virion nucleo-capsids. Soluble NS protein from wt nucleocapsids did not reconstitute restricted transcriptions of the group I RNA-ts mutants. NS protein activity, but not L protein activity, was purified from the group I ts mutants; this NS fraction always displayed the wt phenotype in reconstitution assays. Neither the L nor the NS protein was capable of restoring the defective transcriptive activity of the group IV vesicular stomatitis virus mutant ts W16B.

Differential inhibition of host protein synthesis in L cells infected with RNA - temperature-sensitive mutants of vesicular stomatitis virus

The response of mouse L cells to infection with wild-type (wt) and temperature-sensitive (ts) mutants of vesicular stomatitis virus was monitored by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to delineate the synthesis of host cell and viral proteins. Experiments utilized transcriptase mutants of complementation group I (ts114 and ts13), a group IV mutant (ts44) that is restricted in total RNA synthesis (RNA-1) but not in primary transcription, and a group II mutant (ts52) variably restricted in RNA synthesis (RNA +/-). L cells infected with ts mutants at permissive temperature exhibited the wt response of progressive inhibition of host cell protein synthesis accompanied by accumulation of all five viral proteins. Mutant ts44 (IV) also switched off cell protein synthesis at restrictive temperature and accumulated all five viral proteins, but with disproportionate ratios of N and G proteins. At restrictive temperature, cells infected with group I ts mutants failed to accumulate any viral protein and did not exhibit significant reduction in host cell protein synthesis. These data suggest that vesicular stomatitis virus inhibits cell protein synthesis at a stage of viral infection after transcription and possibly translation but preceding replication of progeny viral RNA.

Inhibition by aurintricarboxylic acid and polyethylene sulfonate of RNA transcription of vesicular stomatitis virus

The in vitro activity of the ribonucleoprotein-dependent RNA transcriptase of vesicular stomatitis virions was found to be completely inhibited by low concentrations of aurintricarboxylic acid (ATA) and polyethylene sulfonic acid (PES) when these inhibitors were added before the start of the RNA polymerase reaction. However, if RNA synthesis was allowed to occur before ATA or PES was added, RNA synthesis continued for a short time (10 min or less) in the presence of either inhibitor at a concentration which completely inhibited uninitiated enzyme. The ability to continue to synthesize RNA in the presence of ATA or PES only developed if all four nucleoside triphosphates were present during the preincubation period prior to the addition of the inhibitors. The protection was apparently not due to the released products of RNA polymerization. The results are interpreted as indicating that ATA and PES probably inhibit some reaction other than elongation of RNA chains, and this reaction might be one involved at or near initiation sites.

Virion trascriptase activity differences in host range mutants of vesicular stomatitis virus

Three types of conditional lethal mutant were isolated from wild-type vesicular stomatitis virus, New Jersey serotype, after mutagenization by 5-fluorouracil: (i) conventional temperature-sensitive (ts) mutants, which form plaques at 31 C but not at 39 C; (ii) conventional host range mutants (hr CE), which grow in BHK but not in secondary chicken embryo cells; and (iii) temperature-dependent host range mutants (td CE), which form plaques both at 31 and 39 C on BHK cells but only at 31 C on chicken embryo cells. To determine whether the mutation in hr CE and td CE mutants affected the virion-associated RNA transcriptase, this enzyme was assayed in vitro at 31 and 39 C, and the results were compared with those obtained for the wild-type virus. The RNA trascriptase activity of hr CE mutants did not appear to be affected by the mutation. The td CE mutants fall into two classes: those that synthesized RNA at 39 C similar to the wild-type virus and those that did not. One mutant of the latter category, td CE 3, had heat-sensitive transcriptase regardless of whether it was grown in BHK or chicken embryo cells. A revertant to the wild-type phenotype isolated from this mutant had regained the ability to synthesize RNA at 39 C. These results strongly suggest that a polypeptide that is either the transcriptase itself or part of the transcriptase complex was made temperature sensitive by the mutation in the second class of td CE mutants. The inhibition of the transcriptase activity of the mutant td CE 3 was fully reversible by lowering the temperature of incubation from 39 to 31 C, and both inhibition and reactivation appeared to be instantaneous.

Screening procedure for complementation-dependent mutants of vesicular stomatitis virus

To isolate new types of vesicular stomatitis virus (VSV) mutants, a four-stage screen was developed which identifies and characterizes mutants capable of complementing the defect in the VSV temperature-sensitive mutant tsG11. Two types of mutants of VSV, Indiana serotype, have been found by using the screen; they are new temperature-sensitive mutants which are, of necessity, not in complementation group I and mutants which do not produce plaques under conditions of single infection at 31 C (the normal permissive temperature) and are, therefore, called complementation-dependent mutants. The newly isolated, temperature-sensitive mutants fall into three complementation groups, two of which are congruent with known complementation groups; the newly identified group extends to six the number of complementation groups of VSV Indiana. The nature of the complementation-dependent mutants has not been established, but one was shown to not contain a significant deletion in its nucleic acid.

Analysis of uridine incorporation in chicken embryo cells infected by vesicular stomatitis virus and its temperature-sensitive mutants: uridine transport

The shut-off of RNA synthesis in chicken embryo cells, after infection with vesicular stomatitis virus, is partially due to a reduced capacity of the infected cells to transport uridine. Permeability to uridine decreases exponentially after infection. This loss of ability to transport uridine may be caused either by structural components of the input virions or may result from the expression of the viral gene products. In the latter case, only minor levels of viral transcription is sufficient to modify cellular permeability, since, even at low multiplicities, RNA minus temperature-sensitive (ts) mutants of vesicular stomatitis virus bring about a significant diminution of uridine incorporation in cells infected under nonpermissive conditions. Experiments with mutants of group III suggest that the M protein of the viral envelope may play a role in the sequence of events that modifies uridine transport. In addition to this cause of the diminution of incorporation of uridine by infected cells, another mechanism is noted which requires protein synthesis.

Temperature-sensitive mutants of vesicular stomatitis virus: comparison of the in vitro RNA polymerase defects of group I and group IV mutants

When tested in vitro, certain temperature-sensitive (ts) mutants of vesicular stomatitis virus (VSV) belonging to complementation groups I and IV appear to have defects in the virion-bound polymerase. To obtain further information concerning the nature of these defects, representative mutants were dissociated by the method of S. Emerson and R. Wagner (1972), and their supernatant (S) and pellet (P) fractions were tested for transcriptase activity when combined with the P and S fractions, respectively, of VSV-HR virions. It was found that the S fractions from group I mutants tsW4, 11, 14, 15, and 28 were defective in transcriptase activity, whereas their P fractions were as active as those of VSV-HR. On the other hand, the P fraction derived from virions of the group IV mutant tsW16B showed reduced activity at 25 C and very little activity at 38 C. These results suggest that our group I mutants, like those examined by D. Hunt and R. Wagner (1974), have a defect in the soluble transcriptase enzyme, whereas mutant tsW16B (group IV) has a defect in a sedimentable component required for transcriptase activity, possibly in the ribonucleoprotein template.