Isolation and characterization of temperature-sensitive mutants of vesicular stomatitis virus, New Jersey serotype

Recent developments and potential of robotics in plant eco-phenotyping

Automated acquisition of plant eco-phenotypic information can serve as a decision-making basis for precision agricultural management and can also provide detailed insights into plant growth status, pest management, water and fertilizer management for plant breeders and plant physiologists. Because the microscopic components and macroscopic morphology of plants will be affected by the ecological environment, research on plant eco-phenotyping is more meaningful than the study of single-plant phenotyping. To achieve high-throughput acquisition of phenotyping information, the combination of high-precision sensors and intelligent robotic platforms have become an emerging research focus. Robotic platforms and automated systems are the important carriers of phenotyping monitoring sensors that enable large-scale screening. Through the diverse design and flexible systems, an efficient operation can be achieved across a range of experimental and field platforms. The combination of robot technology and plant phenotyping monitoring tools provides the data to inform novel artificial intelligence (AI) approaches that will provide steppingstones for new research breakthroughs. Therefore, this article introduces robotics and eco-phenotyping and examines research significant to this novel domain of plant eco-phenotyping. Given the monitoring scenarios of phenotyping information at different scales, the used intelligent robot technology, efficient automation platform, and advanced sensor equipment are summarized in detail. We further discuss the challenges posed to current research as well as the future developmental trends in the application of robot technology and plant eco-phenotyping. These include the use of collected data for AI applications and high-bandwidth data transfer, and large well-structured (meta) data storage approaches in plant sciences and agriculture.

Control of Human T-Cell Leukemia Virus Type 1 (HTLV-1) Infection by Eliminating Envelope Protein-Positive Cells with Recombinant Vesicular Stomatitis Viruses Encoding HTLV-1 Primary Receptor

Human T-cell leukemia virus type 1 (HTLV-1) infection causes adult T-cell leukemia (ATL), which is frequently resistant to currently available therapies and has a very poor prognosis. To prevent the development of ATL among carriers, it is important to control HTLV-1-infected cells in infected individuals. Therefore, the establishment of novel therapies with drugs specifically targeting infected cells is urgently required. This study aimed to develop a potential therapy by generating recombinant vesicular stomatitis viruses (rVSVs) that lack an envelope glycoprotein G and instead encode an HTLV-1 receptor with human glucose transporter 1 (GLUT1), neuropilin 1 (NRP1), or heparan sulfate proteoglycans (HSPGs), including syndecan 1 (SDC1), designated VSVΔG-GL, VSVΔG-NP, or VSVΔG-SD, respectively. In an attempt to enhance the infectivity of rVSV against HTLV-1-infected cells, we also constructed rVSVs with a combination of two or three receptor genes, designated VSVΔG-GLN and VSVΔG-GLNS, respectively. The present study demonstrates VSVΔG-GL, VSVΔG-NP, VSVΔG-GLN, and VSVΔG-GLNS have tropism for HTLV-1 envelope (Env)-expressing cells. Notably, the inoculation of VSVΔG-GL or VSVΔG-NP significantly eliminated HTLV-1-infected cells under the culture conditions. Furthermore, in an HTLV-1-infected humanized mouse model, VSVΔG-NP was capable of efficiently preventing HTLV-1-induced leukocytosis in the periphery and eliminating HTLV-1-infected Env-expressing cells in the lymphoid tissues. In summary, an rVSV engineered to express HTLV-1 primary receptor, especially human NRP1, may represent a drug candidate that has potential for the development of unique virotherapy against HTLV-1 de novo infection.

IMPORTANCE Although several anti-ATL therapies are currently available, ATL is still frequently resistant to therapeutic approaches, and its prognosis remains poor. Control of HTLV-1 de novo infection or expansion of HTLV-1-infected cells in the carrier holds considerable promise for the prevention of ATL development. In this study, we developed rVSVs that specifically target and kill HTLV-1 Env-expressing cells (not ATL cells, which generally do not express Env in vivo) through replacement of the G gene with HTLV-1 receptor gene(s) in the VSV genome. Notably, an rVSV engineered to express human NRP1 controlled the number of HTLV-1-infected Env-expressing cells in vitro and in vivo, suggesting the present approach may be a promising candidate for novel anti-HTLV-1 virotherapy in HTLV-1 carriers, including as a prophylactic treatment against the development of ATL.

Nucleotide sequence of the L gene of vesicular stomatitis virus (New Jersey): identification of conserved domains in the New Jersey and Indiana L proteins

The nucleotide sequence of the L gene of vesicular stomatitis virus, New Jersey serotype (Hazelhurst subtype), was determined. Primer extension dideoxy sequencing of genomic RNA using reverse transcriptase initiated within the adjacent G gene provided a consensus sequence of 6522 nucleotides. The G/L intergenic junction spanned 21 nucleotides and contained a pseudo transcription start signal as well as two sequences (10 and 6 nucleotides in length) which are reiterated within the L coding region. The predicted L mRNA was 6398 nucleotides long and contained a single open reading frame corresponding to an L protein encompassing 2109 amino acids with a MW of 241,546. Comparison of the amino acid sequence of this New Jersey serotype L protein to that previously reported for the L protein of the serologically and genetically distinct Indiana serotype (M. Schubert, G. G. Harmison, and E. Meier (1984). J. Virol. 51, 505-514.) revealed a high degree of functional homology. In addition, six regions (43 to 103 amino acids in length) which displayed a high percentage of identical amino acids (85 to 96%) were identified. Five of these regions were clustered within the amino-terminal half of the L protein. Two of these regions contained sequences, 41 amino acids in length, which were significantly similar to corresponding regions of the L proteins of the paramyxoviruses Sendai and Newcastle disease virus. These structurally conserved regions may correspond to functional domains of the multifunctional L protein.

Functional analysis of hypomethylation variants of the New Jersey serotype of vesicular stomatitis virus

The ts mutant F1 of vesicular stomatitis virus, New Jersey serotype, directs the synthesis of undermethylated 5'-terminal cap structures in vitro. In order to determine the relationship between the ts and hypomethylation phenotypes, a spontaneous revertant rev(ts)F1 of the ts phenotype was analyzed. The revertant retained the hypomethylation phenotype. The four cap structures (GpppA, 7mGpppA, GpppAm, and 7mGpppAm) synthesized in mutant and revertant-directed reactions in the presence of low as well as high concentrations of AdoMet were resolved by HPLC. Quantitation of the data and analysis of cap substrate to product ratios revealed that despite apparent similarities between the two hypomethylation phenotypes, the functional lesions in F1 and rev(ts)F1 were different. F1 displayed an AdoMet concentration-dependent alteration in the GpppA----GpppAm reaction and an AdoMet concentration-independent alteration in the GpppA----7mGpppA reaction. In contrast, rev(ts)F1 displayed AdoMet concentration-dependent alterations in the reactions GpppA----7mGpppA and GpppAm----7mGpppAm.

Sequences of Chandipura virus N and NS genes: evidence for high mutability of the NS gene within vesiculoviruses

The nucleotide sequence of the 3' end of the genome of Chandipura (CHP) virus, including the complete sequences of the nucleocapsid (N) and phosphoprotein (NS) genes was determined, principally from cloned cDNAs of the N and NS mRNAs. The NS mRNA of CHP virus is 908 bases in length and encodes a protein of 293 amino acids. Comparison of the CHP virus NS protein sequence with those of vesicular stomatitis virus of the New Jersey serotype (VSV (NJ)) and of the Indiana serotype (VSV (IND] revealed homologies of only 23 and 21%, respectively, with no consecutive stretches of more than four amino acids identical among the three sequences. As with the two VSV serotypes, the highest homology between the NS proteins of CHP and VSV was in a 20-amino acid region near the carboxy termini of the proteins. Of the potential phosphorylation sites, there are eight conserved serine or threonine residues among the three sequences. Despite the dissimilarity among primary sequences of the NS proteins, their overall structure, as assessed by amino acid composition and by the relative hydropathicities of the sequences, has been conserved throughout evolution. The N mRNA of CHP virus is 1291 bases long and encodes a protein of 422 amino acids. In contrast to the NS protein, the CHP N protein is at least 50% homologous to the N proteins of each of the VSV serotypes. We have identified a region near the center of these N protein sequences which is conserved among members of both the rhabdovirus and paramyxovirus families. This extent of conservation of the N protein sequences underscores the high rate of mutability of the NS protein sequences among the vesiculoviruses.

Genome RNA terminus conservation and diversity among vesiculoviruses

Sequence analysis of the RNA genome termini of various vesiculovirus standard and defective interfering (DI) particles demonstrated that some virus regulatory sequences and domains of virus N protein are highly conserved while others show considerable divergence. Clearly, distinct RNA signal sequences and protein-coding regions of these virus genomes have quite different evolutionary pressures or constraints. Terminal regions of DI-particle RNA genomes of these viruses were found to possess self-complementary stems at the RNA termini, demonstrating the conservation of this DI-particle structural feature throughout the vesiculovirus group. A high degree of conservation of the 3'-terminal sequences of recent and historic isolates of vesicular stomatitis virus New Jersey was also demonstrated.

Assignment of the temperature-sensitive lesion in the replication mutant A1 of vesicular stomatitis virus to the N gene

The replication defect in the temperature-sensitive mutant A1 of the New Jersey serotype (Hazelhurst subtype) of vesicular stomatitis virus was confirmed by the absence of intracellular nucleocapsids in infected cells incubated at the restrictive temperature. After preamplification, the relative yield of the A1 N protein accumulated intracellularly after 1 h of incubation at the restrictive temperature was decreased by 50% that of the wild-type or revertant A1 N protein. This difference was not as apparent in pulse-chase experiments. The functional lesion in A1 was correlated with a structural alteration in the N protein on the basis of the thermolability of the template activity of the A1 N protein-RNA complex in in vitro transcription reactions and the covariance of this phenotype with the temperature-sensitive phenotype in a spontaneous A1 revertant. This correlation was consistent with a direct role of the N protein in replication and allowed the assignment of the N gene to complementation group A.

Specific interactions of vesicular stomatitis virus L and NS proteins with heterologous genome ribonucleoprotein template lead to mRNA synthesis in vitro

Two dissociable proteins, L and NS, and N-RNA template were purified from two serologically distinct vesicular stomatitis viruses, Indiana [VSV(IND)] and New Jersey [VSV(NJ)]. Requirements for RNA synthesis in heterologous reconstitution reactions in vitro were studied. The L and NS proteins of VSV(NJ) failed to synthesize full-length leader RNA and mRNAs in vitro when reconstituted with N-RNA(IND) template. However, when purified homologous NS(IND) was added to the reaction mixture, mRNA synthesis ensued. The requirements for transcription of N-RNA(NJ) template were different from those for N-RNA(IND). For RNA synthesis, transcription specifically required L(NJ), but the NS(NJ) and NS(IND) proteins were interchangeable. This suggests that there are specific domains on the L(NJ) protein, at which NS proteins of both serotypes may interact to form an active RNA polymerase complex, whereas L(IND) lacked such domains for interaction with NS(NJ). The function of the L protein appeared primarily to initiate RNA chains, and the NS protein was required for chain elongation. The results of these in vitro complementation experiments are discussed in light of previous in vivo complementation studies.

Primary structure of the vesicular stomatitis virus polymerase (L) gene: evidence for a high frequency of mutations

A consensus sequence of the polymerase (L) gene of vesicular stomatitis virus, derived from three genomic cDNA copies, is presented. This analysis completes the primary structure of the vesicular stomatitis virus genome, totaling 11,162 bases. The L gene alone spans 6,380 nucleotides and codes for a basic 2,109-amino-acid protein with a molecular weight of 241,012. Sixteen point mutations were detected among cDNA clones prepared from viral RNA of the same strain, representing direct evidence for either the high mutability of vesicular stomatitis virus, the infidelity of reverse transcription during cDNA synthesis, or a combination of both. Some mutation, if present in the viral genome, would result in the translation of incomplete L proteins. For example, two out of four cDNA copies which covered the same region of the L gene had a single-base deletion in the exact same position, whereas the other two clones did not, strongly suggesting that a subpopulation of the genomic RNA may contain this lethal mutation. These lethal mutants define a new class of defective and most likely interfering particles which are indistinguishable in size from the parental virus and can be distinguished only by direct sequencing. We suggest that because of its infidelity, the viral polymerase itself introduces mutations and because of its size, most of these mutations are localized within the polymerase gene. In persistently infected cells in which the selective pressures on the polymerase are different, some of these L gene mutations may further erode the accuracy of the polymerase and thereby lead to the increased mutation rate that is characteristic of this type of infection.

Structural and functional characterization of the RNA-positive complementation groups, C and D, of the New Jersey serotype of vesicular stomatitis virus: assignment of the M gene to the C complementation group

The structural and functional lesions in the RNA-positive complementation groups, C and D, of the New Jersey serotype (Hazelhurst subtype) of vesicular stomatitis virus have been characterized. The M protein of the temperature-sensitive mutant C1, the prototype of the C complementation group, was degraded at the restrictive temperature in vivo, and was resolved from the wild-type M protein by SDS-polyacrylamide gel electrophoresis and nonequilibrium pH gradient electrophoresis. Coreversion of these properties and the temperature-sensitive phenotype was observed in a spontaneous revertant. On the basis of these results, the M gene was assigned to the C complementation group. Intracellular nucleocapsids could not be isolated from New Jersey serotype infections by procedures developed for Indiana serotype infections. Therefore, in order to assess the ability of New Jersey ts mutants to accumulate nucleocapsids at the restrictive temperature, a procedure for their isolation was developed. Hypertranscription was observed in C1-infected cells incubated at the restrictive temperature, but was not accompanied by proportionate increases in intracellular viral nucleocapsids or protein synthesis. The G and N proteins of the temperature-sensitive mutant D1, the sole representative of the D complementation group, were electrophoretic variants. The relative yield of intracellular D1 N protein was lower at the restrictive than at the permissive temperature, and the D1 L protein was thermolabile. No intracellular viral nucleocapsids were detected in D1 infected cells incubated at the restrictive temperature; however, more 40 S and less message-sized RNA were synthesized at the restrictive than at the permissive temperature. These results suggested functional defects in both the N protein and polymerase of D1.

Nongenetic complementation in VSV: asymmetric contribution of the L proteins of each parent in the rescue of group I ts mutants

Complementation group I temperature-sensitive mutants of vesicular stomatitis virus (VSV) are rescued at nonpermissive temperature by UV-irradiated virus. Rescue is a nongenetic process mediated by the structural L protein molecules of the parental irradiated virus. This is shown by action spectra analysis (V. Deutsch, B. Muel, and G. Brun (1977), Virology 77, 294-305), efficiency of rescue at doses high enough to inactivate every gene I, and rescue by irradiated defective-interfering short particles. Viral molecular synthesis at 39.6 degrees using the ts genomes as templates and stimulated by UV-irradiated virus is shown by gel electrophoresis of rescued virion proteins. Parental strain ts 053(I) is thermolabile in vitro while the thermostability of the rescued virions, genetically characterized as ts group I virus, is identical to that of helper wt or ts+ revertant. This suggests that some parental Lwt molecules are reincorporated in the rescued virions, together with newly synthesized Lts molecules. Efficiency variation of the rescue as a function of the multiplicity of infection of the UV-irradiated virions depends on the m.o.i. of the unirradiated ts I mutants. This result suggests that rescue depends on the concentration of the helper L molecules and also of that of the L initially bound to the ts template. That L of both parents contribute to rescue is supported by the observations that (1) rescue by UV-wt is strongly diminished after in vitro heating of thermolabile ts O53(I). (2) Intragenic rescue can be demonstrated: The helper activity of a given UV-ts I mutant is different according to the unirradiated ts I mutant used; the activity of helper L associated with different templates in intragenic heterologous combinations is higher or lower than its activity in the homologous combination (self-rescue control), instead of being equal as expected. (3) Efficiency of rescue by UV-wt also varies according to the ts I mutant. The initially bound Lts seems therefore to play a role important and different from that of the helper L. Contribution of both parent L to rescue seems thus to be qualitatively different.

Use of a hybrid infectivity assay to analyze primary transcription of temperature-sensitive mutants of the New Jersey serotype of vesicular stomatitis virus

A hybrid infectivity assay specific for primary transcription was developed to analyze the production of functional mRNAs by vesicular stomatitis virus. A template prepared from wild-type virions of the New Jersey serotype of vesicular stomatitis virus was reconstituted with RNA polymerase proteins from the wild type or temperature-sensitive mutants, and the in vivo temperature sensitivity of the polymerase was determined by infectivity assay. The data demonstrate that the New Jersey temperature-sensitive mutants A1 and E1 have non-temperature-sensitive transcriptases, whereas the B1 and F1 mutants both have temperature-sensitive L proteins which are defective in primary transcription.

Linear mapping of tryptophan residues in Vesiculovirus M and N proteins by partial chemical cleavage

Nonlimit chemical cleavage at tryptophan residues of protein labeled at the amino terminus afforded a simple procedure for generating specific fragments and for mapping tryptophan positions. A comparison of the matrix (M) and nucleocapsid (N) proteins of four members of the Vesiculovirus group by this procedure suggests considerable conservation of tryptophan number and location in the four serotypes examined.

Rapid evolution of RNA genomes

RNA viruses show high mutation frequencies partly because of a lack of the proofreading enzymes that assure fidelity of DNA replication. This high mutation frequency is coupled with high rates of replication reflected in rates of RNA genome evolution which can be more than a millionfold greater than the rates of the DNA chromosome evolution of their hosts. There are some disease implications for the DNA-based biosphere of this rapidly evolving RNA biosphere.

Enhanced mutability associated with a temperature-sensitive mutant of vesicular stomatitis virus

Temperature-sensitive (ts) mutant tsD1 of vesicular stomatitis virus, New Jersey serotype, is the sole representative of complementation group D. Clones derived from this mutant exhibited three different phenotypes with respect to electrophoretic mobility of the G and N polypeptides of the virion in sodium dodecyl sulfate-polyacrylamide gel. Analysis of non-ts pseudorevertants showed that none of the three phenotypes was associated with the temperature sensitivity of mutant tsD1. Additional phenotypes, some also involving the NS polypeptide, appeared during sequential cloning, indicating that mutations were generated at high frequency during replication of tsD1. Furthermore, mutations altering the electrophoretic mobility of the G, N, NS, and M polypeptides were induced in heterologous viruses multiplying in the same cells as tsD1. These heterologous viruses included another complementing ts mutant of vesicular stomatitis virus New Jersey and ts mutants of vesicular stomatitis virus Indiana and Chandipura virus. Complete or incomplete virions of tsD1 appeared to be equally efficient inducers of mutations in heterologous viruses. Analysis of the progeny of a mixed infection of two complementing ts mutants of vesicular stomatitis virus New Jersey with electrophoretically distinguishable G, N, NS, and M proteins yielded no recombinants and excluded recombination as a factor in the generation of the electrophoretic mobility variants. In vitro translation of total cytoplasmic RNA from BHK cells indicated that post-translational processing was not responsible for the aberrant electrophoretic mobility of the N, NS, and M protein mutants. Aberrant glycosylation could account for three of four G protein mutants, however. Some clones of tsD1 had an N polypeptide which migrated faster in sodium dodecyl sulfate-polyacrylamide gel than did the wild type, suggesting that the polypeptide might be shorter by about 10 amino acids. Determination of the nucleotide sequence to about 200 residues from each terminus of the N gene of one of these clones, a revertant, and the wild-type parent revealed no changes compatible with synthesis of a shorter polypeptide by premature termination or late initiation of translation. The sequence data indicated, however, that the N-protein mutant and its revertant differed from the parental wild type in two of the 399 nucleotides determined. These sequencing results and the phenomenon of enhanced mutability associated with mutant tsD1 reveal that rapid and extensive evolution of the viral genome can occur during the course of normal cytolytic infection of cultured cells.

Transcriptional activities of different phosphorylated species of NS protein purified from vesicular stomatitis virions and cytoplasm of infected cells

Vesicular stomatitis virus contains a phosphorylated NS protein which is necessary along with L protein and RNP template for transcription of mRNA. To further define the structure of the NS protein and its function in transcription and replication, virion NS was purified and separated into two different phosphrylated forms (NSI and NSII) on DEAE-cellulose columns. Cytoplasmic preparations of NS contained one phosphorylated species which eluted from the column in the same place as the virion NSI. When electrophoresed in sodium dodecyl sulfate-polyacrylamide gels containing urea, NSI and NSII each resolved into two components, whereas cell NS migrated as a single band. NSI and cell NS exhibited little activity in a reconstituted transcription assay, whereas the more highly phosphorylated NSII was very active in the same system. Addition of NSI or cell NS to a transcription system containing NSII resulted in even higher levels of activity, indicating that the various NS species might have different enzymatic functions.

Comparisons of nucleotide sequences in the genomes of the New Jersey and Indiana serotypes of vesicular stomatitis virus

Nucleotide sequences of around 200 residues were determined adjacent to the 3' terminus of the genome RNA of vesicular stomatitis virus, New Jersey serotype, and adjacent to the 3'-terminal polyadenylic acid tract of the N protein mRNA of the same virus. These sequences were compared with the corresponding sequences previously determined for the Indiana serotype of vesicular stomatitis virus. The sequences obtained for the two strains were readily aligned, showing 70.8% homology overall. Examination of the sequences allowed identification of the translation initiation and termination codons for the N mRNA of each serotype. The deduced N-terminal and C-terminal amino acid sequences of the two N polypeptides were each similar, and most of the differences between them consisted of substitution by a clearly homologous amino acid. It was proposed that these nucleotide sequences, within limits imposed by their functions, comprise reasonably representative measures of the extent of sequence homology between the genomes of the two serotypes, and that this is higher than previously estimated, but with little exact homology over extended regions.

Temperature-sensitive mutants of complementation group E of vesicular stomatitis virus New Jersey serotype possess altered NS polypeptides

In vesicular stomatitis virus New Jersey serotype polyacrylamide gel electrophoresis was unable to distinguish the polypeptides of the temperature-sensitive (ts) mutants of complementation groups A, B, C, and F from those of the wild-type virus. However, the NS polypeptide of the representative mutant of group E, ts E1, had a significantly greater electrophoretic mobility than that of the wild-type virus NS polypeptide. The electrophoretic mobilities of the NS polypeptides of the three mutants of complementation group E varied, being greatest in the case of ts E1, slightly less for ts E2, and only a little greater than that of wild-type virus NS polypeptide in the case of ts E3. Since the NS polypeptides of the revertant clones ts E1/R1 and ts E3/R1 have mobilities identical to that of wild-type NS polypeptide, the observed altered mobilities of the group E mutants are almost certainly the direct result of the ts mutations in the E locus. The electrophoretic mobilities of the intracellular NS polypeptides of the group E mutants were indistinguishable from those of their virion NS polypeptides. The electrophoretic mobilities of the NS polypeptides of the group E mutants synthesized in vitro using mRNA synthesized in vitro by TNP were identical to those of the NS polypeptides of their purified virions. The NS polypeptides of all three mutants were labeled with (32)P(i) to approximately the same extent as wild-type virus NS polypeptide, indicating that gross differences in phosphorylation of this polypeptide are unlikely to account for the altered mobilities. We propose a model in which the NS polypeptide consists of at least three loops held in this configuration by hydrophobic or ionic forces or both and stabilized by phosphodiester bridges. If a mutation affects one of the amino acids to which the phosphate is covalently linked, the phosphodiester bridge cannot be formed, and, as a result, in the presence of sodium dodecyl sulfate the affected loop opens and thus the NS polypeptide migrates further into the gel. Such a configuration may also explain the multifunctional nature of the NS polypeptide.

Proposed replicative role of the NS polypeptide of vesicular stomatitis virus: structural analysis of an electrophoretic variant

The structural lesion in the temperature-sensitive mutant E1 of the New Jersey serotype of vesicular stomatitis virus has been assigned to the NS protein. Although the packaged wild-type and mutant NS proteins were similarly phosphorylated, the mutant NS protein migrated faster than the wild-type NS protein in polyacrylamide slab gels electrophoresed in the presence of sodium dodecyl sulfate. The resolution appears to be the result of conformational rather than size differences since the two proteins comigrated in polyacrylamide gels which contained 4 M urea in addition to sodium dodecyl sulfate. Peptide maps, obtained by limited proteolysis of 32P-labeled wild-type and mutant NS proteins with Staphylococcus aureus V8 protease and papain, revealed striking differences which suggested that the mutant alteration could involve an aspartic or glutamic acid residue. Since NS proteins obtained from naturally occurring revertants of E1 were indistinguishable from the wild-type protein in all of these analyses, the structural alteration in the mutant NS protein correlates with the functional lesion. Because E1 is defective in the RNA replication pathway at the restrictive temperature, a replicative role is proposed for the NS protein.

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.

In vitro RNA transcription by the New Jersey serotype of vesicular stomatitis virus. I. Characterization of the mRNA species

The in vitro RNA synthesis by the virion-associated RNA polymerase of vesicular stomatitis virus (VSV), New Jersey serotype, was compared with that of the serologically distinct Indiana serotype of VSV. The New Jersey serotype of VSV synthesized five distinct mRNA species in vitro, three of which were smaller than the corresponding species synthesized by the Indiana serotype of VSV. These included the mRNA's coding for the G, M, and NS proteins. By hybridization experiments, virtually no sequence homology was detected between the mRNA's of the two serotypes. Despite this lack of overall homology, the 12 to 18S mRNA species of both serotype contained a common 5'-terminal hexanucleotide sequence, G(5')ppp(5')A-A-C-A-G. The signicance of this finding in light of specific interactions between the two serotypes of VSV in vivo is discussed.

Classification of the New Jersey serotype of vesicular stomatitis virus into two subtypes

We propose a reclassification of five strains of the New Jersey serotype of vesicular stomatitis virus into two subtypes designated Concan and Hazelhurst. This subclassification into two subtypes is based on reciprocal differences in antibody neutralization of virion infectivity, nucleotide base sequence homology, oligonucleotide maps of virion RNA, and interference by defective-interfering particles.

Oligonucleotide fingerprints of RNA species obtained from rhabdoviruses belonging to the vesicular stomatitis virus subgroup

The relationships among the genomes of various rhabdoviruses belonging to the vesicular stomatitis virus subgroup were analyzed by an oligonucleotide fingerprinting technique. Of 10 vesicular stomatitis viruses, Indiana serotype (VSV Indiana), obtained from various sources, either no, few, or many differences were observed in the oligonucleotide fingerprints of the 42S RNA species extracted from standard B virions. Analyses of the oligonucleotides obtained from RNA extracted from three separate preparations of VSV Indiana defective T particles showed that their RNAs contain fewer oligonucleotides than the corresponding B particle RNA species. The fingerprints of RNA obtained from five VSV New Jersey serotype viruses were easily distinguished from those of the VSV Indiana isolates. Three of the VSV New Jersey RNA fingerprints were similar to each other but quite different from those of the other two viruses. The RNA fingerprints of two Chandipura virus isolates (one obtained from India and one from Nigeria) were also unique, whereas the fingerprint of Cocal virus RNA was unlike that of the serologically related VSV Indiana.

Synthesis of RNA by mutants of vesicular stomatitis virus (Indiana serotype) and the ability of wild-type VSV New Jersey to complement the VSV Indiana ts G I-114 transcription defect

The ability of certain vesicular stomatitis virus (VSV; Indiana serotype) temperature-sensitive (ts) mutants to synthesize intracellular viral complementary RNA (vcRNA) at permissive or nonpermissive temperatures for productive infections has been investigated. Mutants belonging to complementation groups II, III, and V synthesize RNA at nonpermissive temperature in amounts essentially equivalent to that obtained at permissive temperatures. Mutant ts G I-114 possesses a thermolabile transcriptase and does not synthesize vcRNA at 40 degrees C; however, mutants ts O I-5, O I-53, O I-78, and O I-80 possess thermostabile transcriptases that are capable of some vcRNA synthesis at 40 degrees C. All five group I mutants are defective in their secondary transcription ability at 40 degrees C. Wild-type VSV New Jersey virus is able to complement the transcription defect of ts G I-114 at 40 degrees C. This complementation is inhibited by puromycin, suggesting that a viral gene product of VSV New Jersey (e.g., its transcriptase or a transcriptase component) is involved. Mokola virus is not able to complement the ts G I-114 defect, although Mokola does synthesize vcRNA in infected cells (in the presence or absence of cycloheximide).

Genetic exclusion and stable complementation of Sindbis virus

In an effort to enhance genetic interactions by eliminating spatial or physical barriers between variants of Sindbis virus MgCl2 was used to aggregate infecting viral particles. Mixing viral samples in a 1:1 ratio with 0.5 M MgCl2 produced maximal reduction in plaque forming units (PFU) with minimal cell damage due to MgCl2. Aggregate size was determined to be about 7 PFU. Samples taken at 3,5 and 10 hours after infection with mixed aggregates composed of large and small plaque forming virus indicated that only one type of genome was represented among the progeny particles. In addition, aggregation enhanced complementation and the progeny were stable after several cycles of sonication and passage.

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.

Inhibition of viral transcriptase by immunoglobulin directed against the nucleocapsid NS protein of vesicular stomatitis virus

In search of an anti-transcriptase, antibody was raised in rabbits to partially purified, soluble NS protein present in cytoplasmic extracts of cells infected with the Indiana serotype of vesicular stomatitis (VSInd) virus. This antiserum gave specific reactions of identity by agar immunodiffusion with both cytoplasmic and virion NS protein. NS antiserum also preferentially precipitated NS 3-H-labeled protein from infected cytoplasmic extracts, whereas anti-whole VSInd virion serum also precipitated N 3-H-labeled protein from extracts both of infected cytoplasm and virion nucleocapsids. Transcriptase activity of VSInd cytoplasmic or virion-derived nucleocapsids was effectively inhibited by ribonuclease-free immunoglubulin prepared from homologous NSInd antiserum or from anti-whole vesicular stomatitis virus serum. Transcriptase activity of heterologous New Jersey serotype (VSNJ) nucleocapsids and virions was not appreciably affected by anti-NSInd or by anti-whole VSInd virion gamma globulin. Anti-NS gamma glubulin immediately switched off RNA synthesis by actively transcribing VSInd nucleocapsids, a finding which suggests that NS antibody inhibits RNA chain elongation.

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.

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.

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.

Ribonucleic acid species of intracellular nucleocapsids and released virions of vesicular stomatitis virus

Infection of chicken embryo cells with vesicular stomatitis (VS) virus resulted in variable production of three classes of intracellular viral ribonucleocapsids with sedimentation coefficients of approximately 140S, 110S, and 80S, as well as three corresponding classes of released virions designated B, LT, and T. Intracellular nucleocapsids of each class contained three proteins of which the major N protein was firmly bound, and the minor L and NS1 proteins were readily dissociated with 0.5 m NaCl. The ribonucleic acid (RNA) species extracted from B, LT, and T virions, and from corresponding intracellular nucleocapsids, contained RNA species with approximate molecular weights of 3.2 x 10(6), 2.0 x 10(6), and 10(6), respectively, as determined by polyacrylamide gel electrophoresis. These values are roughly equivalent to sedimentation coefficients of 42S, 28S, and 23S for each of the virion and nucleocapsid RNA species. Cells infected at high multiplicity with undiluted passage VS virus gave rise primarily to virions and nucleocapsids containing 23S RNA, whereas cells productively infected with purified B virions produced predominantly B and LT virions and nucleocapsids. At late stages in the productive cycle of infection, more virions containing 42S RNA were produced, but the intracellular pool of nucleocapsids containing 28S and 23S RNA remained relatively constant. Additional studies by more refined techniques are required to test the hypothesis that nucleocapsids containing 28S and 23S RNA are precursors of the 42S RNA in infectious VS-B virions and that production of defective T and LT virions results from failure of ligation of the RNA precursors.