Temperature-sensitive mutants with lesions in the vaccinia virus F10 kinase undergo arrest at the earliest stage of virion morphogenesis.

Vaccinia virus encodes two protein kinases; the B1 kinase is expressed early and appears to play a role during DNA replication, whereas the F10 kinase is expressed late and is encapsidated in virions. Here we report that the F10 kinase gene is the locus affected in a complementation group of temperature-sensitive mutants composed of ts15, ts28, ts54, and ts61. Although these mutants have a biochemically normal phenotype at the nonpermissive temperature, directing the full program of viral gene expression, they fail to form mature virions. Electron microscopic analysis indicates that morphogenesis undergoes arrest at a very early stage, prior to the formation of membrane crescents or immature virions. An essential role for the F10 protein kinase in orchestrating the onset of virion assembly is implied.     

Adenylate kinases from thermosensitive Escherichia coli strains

The adk genes from several thermosensitive (ts) mutants of Escherichia coli were cloned and sequenced. The mutations responsible for the thermolability of the gene product, the enzyme adenylate kinase, were established. From five independently isolated strains analysed, two contain a CCG to TCG transition changing proline 87 to serine (P87S), another two have a TCT to TTT transition that mutates serine 129 to phenylalanine (S129F), and the last one was found not to contain a mutation in the adk gene. Overproducing strains were constructed that contain ts genes in the genome as well as in the plasmids. These strains grow at high temperature, although much slower than wild-type. Most probably, the high rate of synthesis of adenylate kinase compensates for the destruction of the thermolabile protein by the elevated temperature. Mutated proteins were purified. The P87S but not the S129F mutation was found to cause thermosensitivity of the adenylate kinase reaction. Revertants of thermosensitivity were isolated and the nature of the mutation was determined by the RNase digestion method of RNA-DNA hybrids and by DNA sequencing. The revertants of the P87S mutation regained the wild-type sequence, whereas the revertants of the S129F strain retained the original mutation in the adenylate kinase gene. These results are discussed in the light of the three-dimensional structure of the enzyme and the possible role of adenylate kinase in phospholipid synthesis.     

Evidence for an essential catalytic role of the F10 protein kinase in vaccinia virus morphogenesis

Temperature-sensitive mutants of vaccinia virus, with genetic changes that map to the open reading frame encoding the F10 protein kinase, exhibit a defect at an early stage of viral morphogenesis. To further study the role of the enzyme, we constructed recombinant vaccinia virus vF10V5i, which expresses inducible V5 epitope-tagged F10 and is dependent on a chemical inducer for plaque formation and replication. In the absence of inducer, viral membrane formation was delayed and crescents and occasional immature forms were detected only late in infection. When the temperature was raised from 37 to 39 degrees C, the block in membrane formation persisted throughout the infection. The increased stringency may be explained by a mild temperature sensitivity of the wild-type F10 kinase, which reduced the activity of the very small amount expressed in the absence of inducer, or by the thermolability of an unphosphorylated kinase substrate or uncomplexed F10-interacting protein. Further analyses demonstrated that tyrosine and threonine phosphorylation of the A17 membrane component was inhibited in the absence of inducer. The phosphorylation defect could be overcome by transfection of plasmids that express wild-type F10, but not by plasmids that express F10 with single amino acid substitutions that abolished catalytic activity. Although the mutated forms of F10 were stable and concentrated in viral factories, only the wild-type protein complemented the assembly and replication defects of vF10V5i in the absence of inducer. These studies provide evidence for an essential catalytic role of the F10 kinase in vaccinia virus morphogenesis.     

Expression of herpes simplex virus type 1 major DNA-binding protein, ICP8, in transformed cell lines: complementation of deletion mutants and inhibition of wild-type virus

To minimize the contribution of residual activity associated with the temperature-sensitive (ts) form of ICP8 specified by available ts mutants, deletion mutations in this gene were constructed. Cells permissive for the generation and propagation of ICP8 deletion mutants were first obtained. Vero cells were cotransfected with pKEF-P4, which contains the gene for ICP8, and pSV2neo or a hybrid plasmid containing the G418 resistance gene linked to pKEF-P4. Of the 48 G418-resistant cell lines, 21 complemented ICP8 ts mutants in plaque assays at the nonpermissive temperature. Four of these were examined by Southern blot analysis and shown to contain 1 to 3 copies of the ICP8 gene per haploid genome equivalent. Cell line U-47 was used as the permissive host for construction of ICP8 deletion mutants. In addition to cell lines which complemented ts mutants, two lines, U-27 and U-35, significantly inhibited plaque formation by wild-type virus, contained 30 and 100 copies of the ICP8 gene per haploid genome equivalent, respectively, and expressed large amounts of ICP8 after infection with wild-type virus. At low but not high multiplicities of infection, this inhibition was accompanied by underproduction of viral polypeptides of the early, delayed-early, and late kinetic classes. For construction of deletion mutants, a 780-base-pair XhoI fragment was deleted from pSG18-SalIA, a plasmid which contains the gene for ICP8, to yield pDX. U-47 cells were then cotransfected with pDX and infectious wild-type DNA. Mutant d61, isolated from the progeny of cotransfection, was found to contain both the engineered deletion in the ICP8 gene and an oriL-associated deletion of approximately 55 base pairs. Because d61 contained two mutations, a second mutant, d21, which carried the engineered ICP8 deletion but an intact oriL, was constructed by cotransfection of U-47 cells with wild-type DNA and an SalI-KpnI fragment purified from pDX. Phenotypic analysis of d21 and d61 revealed that they were similar in all properties examined: both exhibited efficient growth in U-47 cells but not in Vero cells; both induced the synthesis of an ICP8 polypeptide which was smaller than the wild-type form of the protein and which, unlike the wild-type protein, was found in the cytoplasm and not the nucleus of infected Vero cells; and nonpermissive Vero cells infected with either mutant failed to express late viral polypeptides.     

Role of the aromatic residues in the near-amino terminal motif of vimentin in intermediate filament assembly in vitro

Type III and IV intermediate filament (IF) proteins share a conserved sequence motif of -Tyr-Arg-Arg-X-Phe- at the near-amino termini. To characterize significance of the aromatic residues in the motif, we prepared vimentin mutants in which Tyr-10 and Phe-14 are substituted with Asn and Ser (Vim[Y10N], Vim[F14S] and Vim[Y10N, F14S]), and examined assembly properties in vitro by electron microscopy and viscosity measurements. At 2 s after initiation of assembly reaction at pH 7.2 and 150 mM NaCl, all the vimentin mutants formed so-called unit-length filaments (ULFs) that were slightly larger than ULFs of wild-type vimentin. In following filament elongation, Vim[Y10N, F14S] and Vim[Y10N] performed longitudinal annealing of ULFs very rapidly and formed IFs within only 2.5 and 5 min, respectively, while Vim[F14S] and wild-type vimentin gave IFs by 40-60 min. The IFs of Vim[Y10N, F14S] and Vim[Y10N], however, tended to intertwine each other and formed bundles in parts of the specimens. The intertwinements decreased as the salt concentration decreased, and optimal salt concentration for the two mutants to form normal IFs was 50 mM. These results suggest that the aromatic residues, especially Tyr-10, in the motif have a role in controlling intermolecular interactions involved in IF assembly in vitro and suppress undesirable filament intertwinements at physiological ionic strength.     

Vaccinia virus B1 kinase: phenotypic analysis of temperature-sensitive mutants and enzymatic characterization of recombinant proteins.

The vaccinia virus B1 gene encodes a 34-kDa protein with homology to protein kinases. In L cells infected nonpermissively with mutants containing lesions in the B1 gene (ts2 and ts25), the infectious cycle arrests prior to DNA replication. In this report, we demonstrate that DNA synthesis ceases when cultures infected with these mutants at 32 degrees C are shifted to the nonpermissive temperature (39.5 degrees C) in the midst of DNA replication. We also show that B1 protein is synthesized transiently during the early phase of infection, even when the progression to later stages of gene expression is prevented. Although wild-type (wt) B1 is stable, the ts B1 proteins are markedly labile in both L and BSC40 cells at both permissive and nonpermissive temperatures. These results suggest that the ts phenotype of the mutants is complex and may in part reflect a temperature-dependent requirement for kinase activity, an induction of temperature sensitivity in B1 substrates under nonpermissive conditions, and/or ts complementation by host factors. To facilitate biochemical analyses, recombinant wt B1, ts2 B1, and ts25 B1 were produced in Escherichia coli. The wt protein was able to phosphorylate serine and threonine residues on several exogenous substrates in vitro. The activity of ts25 B1 was 3% that of the wt enzyme, and no detectable kinase activity was associated with ts2 B1. In light of the inactivity of the ts2 B1 protein in vitro and its extreme lability in vivo, we attempted to isolate a vaccinia virus B1 null mutant by targeted interruption of the B1 gene at 32 degrees C. No null mutants were isolated. These results indicate that the B1 protein kinase provides a vital function which cannot be supplied by the host or circumvented by incubation at 32 degrees C.     

Substitutions at a single amino acid residue in the nitrogen-regulated activator protein NTRC differentially influence its activity in response to phosphorylation

Four substitutions at serine residue 160 which increase the activity of the sigma 54-dependent activator protein NTRC in the absence of NTRB have been analysed in detail. Mutagenesis of the putative phosphoacceptor site of NTRC and analysis of double mutants indicate that the positive control function of the S160W and S160C mutants is phosphorylation-dependent, whereas the activity of the S160Y and S160F mutants is phosphorylation-independent. This was confirmed with two purified mutant proteins in vitro. Occupancy of tandem NTRC-binding sites upstream of the Klebsiella pneumoniae nifL promoter by S160W protein is also phosphorylation-dependent in contrast to occupancy by S160F protein, confirming that both the DNA-binding and activator functions of NTRC are influenced by phosphorylation. The S160W and S160C mutants are apparently more responsive than wild-type protein to 'cross-talk' by other members of the histidine protein kinase family but are less responsive to phosphorylation and dephosphorylation mediated by NTRB.     

A mammalian somatic "cell cycle" mutant defective in G1

Variants or “mutants” temperature-sensitive (ts) for growth have been isolated by selection from a near-diploid mouse cell line. Thus far. 10 ts mutants which grow normally at 33° C, but not at 39° C, have been isolated. These ts mutants were then studied to determine if any manifested their defect at a unique point or stage in the cell cycle. This type of ts mutant is termed a “cell cycle” mutant. The first screen involves observing individual cells of an asynchronous culture for residual division after a shift from 33° C (permissive temperature) to 39° (nonpermissive temperature). A cell cycle mutant should show some fraction of the cells dividing only once at a normal rate after the shift. The ts variant B54 met this first criterion for a cell cycle mutant (i.e., 50% residual division) and was further analyzed. The second screening technique monitors (1) the rate of entry into S, (2) the length of G₂, and (3) the rate and duration of cells entering mitosis after a shift of an asynchronous culture to 39°. This experiment with B54 revealed that cells in G₁ at the time of the shift to 39° failed to enter S while cells already into S completed the cycle at 39°. These results suggest that B54 is defective in a G₁ function which is required for entry into S, but which is no longer needed once cells have entered S. Other results are presented which also support this hypothesis. In addition the ts function of B54 is apparently required for recovery from a “high density” G₁ arrest.     

Analyses of Saccharomyces cerevisiae Cdc7 kinase point mutants: dominant-negative inhibition of DNA replication on overexpression of kinase-negative Cdc7 proteins

Saccharomyces cerevisiae Cdc7 kinase is required for initiation of S phase, and its kinase activity, which is positively regulated by Dbf4 protein, reaches maximum at the G1/S boundary. In this study, we constructed Cdc7 point mutants (T281E, T281A, D182N, D163N, and T167E) and examined the effect of each mutant on growth. All the mutants lost the ability to complement temperature-sensitive growth of cdc7(ts) mutants at a low protein level, whereas T281A (putative target of phosphorylation) and T167E (residue involved in substrate recognition) restored the growth of cdc7(ts) when overproduced to a high level. Three putative kinase-negative mutants (T281E, D182N, and D163N) inhibited growth when overexpressed in a wild-type strain. Analyses of DNA content and morphology revealed that most cells were arrested as dumbbells with 1C DNA, indicative of a block in the G1 to S transition. This growth inhibition was suppressed by co-overexpression of the wild-type Cdc7 or Dbf4 protein. Furthermore, deletion of the Dbf4 protein-binding region in each Cdc7 mutant resulted in loss of growth inhibitory effect. Thus, dominant-negative effects of T281E, D182N, and D163N on growth can be best explained by inactivation of the wild-type Cdc7 function through titration of Dbf4 by these inactive kinases. Our results are consistent with the notion that association of Dbf4 with Cdc7 is essential for the G1 to S transition in S. cerevisiae.     

OmpF assembly mutants of Escherichia coli K-12: isolation, characterization, and suppressor analysis.

This paper describes a novel genetic method used to isolate mutations that alter proper assembly of OmpF in the outer membrane. The thermolabile nature of assembly intermediates allowed selection of temperature-sensitive mutations within the ompF gene. A variant allele of ompF (ompF-Dex) was used because it provided a convenient selectable phenotype (Dex+). Assembly mutants were isolated in two steps. First, amber mutations were obtained that mapped in ompF-Dex. This resulted in a Dex- phenotype. Starting with these Dex- strains, Dex+ revertants were isolated. Mutants that displayed a temperature-sensitive Dex+ phenotype were further characterized. Three such mutants possessed a single substitution within ompF that reverted the nonsense codon to a sense codon which replaced W214 with either an E or Q and Y231 with a Q residue in the mature OmpF protein. All three mutant OmpF proteins showed an assembly defect. This defect led to a substantial reduction in the amount of stable OmpF trimers with the concomitant increase of a high-molecular-weight form of OmpF which migrated at the top of the gel. Suppressor mutations were sought that corrected the assembly defect of OmpF. These extragenic suppressor mutations were mapped at 45 min on the Escherichia coli chromosome. The suppressor mutations displayed no allele specificity and were recessive to the wild-type allele. In the presence of a suppressor, mutant stable trimers appeared in an almost normal manner. The appearance of stable trimers concurred with a substantial loss of the high-molecular-weight OmpF species. At this stage, it is not clear whether the high-molecular-weight species of OmpF is a normal assembly intermediate or a dead-end assembly product. The results presented in this study raise the intriguing possibility of a chaperone-like activity for the wild-type suppressor gene product.     

Target of rapamycin regulates development and ribosomal RNA expression through kinase domain in Arabidopsis

Target of rapamycin (TOR) is a central regulator of cell growth, cell death, nutrition, starvation, hormone, and stress responses in diverse eukaryotes. However, very little is known about TOR signaling and the associated functional domains in plants. We have taken a genetic approach to dissect TOR functions in Arabidopsis (Arabidopsis thaliana) and report here that the kinase domain is essential for the role of TOR in embryogenesis and 45S rRNA expression. Twelve new T-DNA insertion mutants, spanning 14.2 kb of TOR-encoding genomic region, have been characterized. Nine of these share expression of defective kinase domain and embryo arrest at 16 to 32 cell stage. However, three T-DNA insertion lines affecting FATC domain displayed normal embryo development, indicating that FATC domain was dispensable in Arabidopsis. Genetic complementation showed that the TOR kinase domain alone in tor-10/tor-10 mutant background can rescue early embryo lethality and restore normal development. Overexpression of full-length TOR or kinase domain in Arabidopsis displayed developmental abnormalities in meristem, leaf, root, stem, flowering time, and senescence. We further show that TOR, especially the kinase domain, plays a role in ribosome biogenesis by activating 45S rRNA production. Of the six putative nuclear localization sequences in the kinase domain, nuclear localization sequence 6 was identified to confer TOR nuclear targeting in transient expression assays. Chromatin immunoprecipitation studies revealed that the HEAT repeat domain binds to 45S rRNA promoter and the 5' external transcribed spacer elements motif. Together, these results show that TOR controls the embryogenesis, postembryonic development, and 45S rRNA production through its kinase domain in Arabidopsis.     

Phenotypic characterization of temperature-sensitive mutants of vaccinia virus with mutations in a 135,000-Mr subunit of the virion-associated DNA-dependent RNA polymerase

The phenotypic defects of three temperature-sensitive (ts) mutants of vaccinia virus, the ts mutations of which were mapped to the gene for one of the high-molecular-weight subunits of the virion-associated DNA-dependent RNA polymerase, were characterized. Because the virion RNA polymerase is required for the initiation of the viral replication cycle, it has been predicted that this type of mutant is defective in viral DNA replication and the synthesis of early viral proteins at the nonpermissive temperature. However, all three mutants synthesized both DNA and early proteins, and two of the three synthesized late proteins as well. RNA synthesis in vitro by permeabilized mutant virions was not more ts than that by the wild type. Furthermore, only one of three RNA polymerase activities that was partially purified from virions assembled at the permissive temperature displayed altered biochemical properties in vitro that could be correlated with its ts mutation: the ts13 activity had reduced specific activity, increased temperature sensitivity, and increased thermolability under a variety of preincubation conditions. Although the partially purified polymerase activity of a second mutant, ts72, was also more thermolabile than the wild-type activity, the thermolability was shown to be the result of a second mutation within the RNA polymerase gene. These results suggest that the defects in these mutants affect the assembly of newly synthesized polymerase subunits into active enzyme or the incorporation of RNA polymerase into maturing virions; once synthesized at the permissive temperature, the mutant polymerases are able to function in the initiation of subsequent rounds of infection at the nonpermissive temperature.     

Type 1 protein phosphatase acts in opposition to IpL1 protein kinase in regulating yeast chromosome segregation.

The IPL1 gene is required for high-fidelity chromosome segregation in the budding yeast Saccharomyces cerevisiae. Conditional ipl1ts mutants missegregate chromosomes severely at 37 degrees C. Here, we report that IPL1 encodes an essential putative protein kinase whose function is required during the later part of each cell cycle. At 26 degrees C, the permissive growth temperature, ipl1 mutant cells are defective in the recovery from a transient G2/M-phase arrest caused by the antimicrotubule drug nocodazole. In an effort to identify additional gene products that participate with the Ipl1 protein kinase in regulating chromosome segregation in yeast, a truncated version of the previously identified DIS2S1/GLC7 gene was isolated as a dosage-dependent suppressor of ipl1ts mutations. DIS2S1/GLC7 is predicted to encode a catalytic subunit (PP1C) of type 1 protein phosphatase. Overexpression of the full-length DIS2S1/GLC7 gene results in chromosome missegregation in wild-type cells and exacerbates the mutant phenotype in ipl1 cells. In addition, the glc7-1 mutation can partially suppress the ipl1-1 mutation. These results suggest that type 1 protein phosphatase acts in opposition to the Ipl1 protein kinase in vivo to ensure the high fidelity of chromosome segregation.     

Characterization of two temperature-sensitive mutants of type 5 adenovirus with mutations in the 100,000-dalton protein gene.

Complementation analysis assigned the mutations of strains H5ts115 and H5ts116, two hexon-minus mutants, to the 100,000-dalton (100K) protein gene. Heterotypic marker rescue (i.e., type 5 adenovirus [Ad5] temperature-sensitive mutants DNA X EcoRI restriction fragments of Ad2 DNA) confirmed the results of previous marker rescue mapping studies, and the heterotypic recombinants yielded unique hybrid (Ad5-Ad2) 100K proteins which were intermediate in size between Ad5 and Ad2 proteins and appeared to be as functionally active as the wild-type 100K protein. Phenotypic characterization of these mutants showed that both the hexon polypeptides and the 100K polypeptides were unstable at the nonpermissive temperature, whereas fiber and penton were not degraded, and that the 100K protein made at 39.5 degrees C could not be utilized after a shift to the permissive temperature (32 degrees C). The role of the 100K protein in the assembly of the hexon trimer was also examined by in vitro protein synthesis. Normally, hexon polypeptides synthesized during an in vitro reaction are assembled into immunoreactive hexons. However, this assembly was inhibited by preincubation of the cell extract with anti-100K immunoglobulin G; neither anti-fiber immunoglobulin G nor normal rabbit immunoglobulin G inhibited hexon assembly. It is postulated that an interaction between the 100K protein and hexon polypeptides is required for effective assembly of hexon trimers.     

Molecular genetic and biochemical analyses of FGF23 mutations in familial tumoral calcinosis

Fibroblast growth factor 23 (FGF23) is a hormone required for normal renal phosphate reabsorption. FGF23 gain-of-function mutations result in autosomal dominant hypophosphatemic rickets (ADHR), and FGF23 loss-of-function mutations cause familial hyperphosphatemic tumoral calcinosis (TC). In this study, we identified a novel recessive FGF23 TC mutation, a lysine (K) substitution for glutamine (Q) (160 C>A) at residue 54 (Q54K). To understand the molecular consequences of all known FGF23-TC mutants (H41Q, S71G, M96T, S129F, and Q54K), these proteins were stably expressed in vitro. Western analyses revealed minimal amounts of secreted intact protein for all mutants, and ELISA analyses demonstrated high levels of secreted COOH-terminal FGF23 fragments but low amounts of intact protein, consistent with TC patients' FGF23 serum profiles. Mutant protein function was tested and showed residual, yet decreased, bioactivity compared with wild-type protein. In examining the role of the FGF23 COOH-terminal tail (residues 180-251) in protein processing and activity, truncated mutants revealed that the majority of the residues downstream from the known FGF23 SPC protease site ((176)RXXR(179)/S(180)) were not required for protein secretion. However, residues adjacent to the RXXR site (between residues 188 and 202) were required for full bioactivity. In summary, we report a novel TC mutation and demonstrate a common defect of reduced FGF23 stability for all known FGF23-TC mutants. Finally, the majority of the COOH-terminal tail of FGF23 is not required for protein secretion but is required for full bioactivity.     

Analyses of Saccharomyces cerevisiae Cdc7 kinase point mutants: dominant-negative inhibition of DNA replication on overexpression of kinase-negative Cdc7 proteins

Saccharomyces cerevisiae Cdc7 kinase is required for initiation of S phase, and its kinase activity, which is positively regulated by Dbf4 protein, reaches maximum at the G1/S boundary. In this study, we constructed Cdc7 point mutants (T281E, T281A, D182N, D163N, and T167E) and examined the effect of each mutant on growth. All the mutants lost the ability to complement temperature-sensitive growth of cdc7(ts) mutants at a low protein level, whereas T281A (putative target of phosphorylation) and T167E (residue involved in substrate recognition) restored the growth of cdc7(ts) when overproduced to a high level. Three putative kinase-negative mutants (T281E, D182N, and D163N) inhibited growth when overexpressed in a wild-type strain. Analyses of DNA content and morphology revealed that most cells were arrested as dumbbells with 1C DNA, indicative of a block in the G1 to S transition. This growth inhibition was suppressed by co-overexpression of the wild-type Cdc7 or Dbf4 protein. Furthermore, deletion of the Dbf4 protein-binding region in each Cdc7 mutant resulted in loss of growth inhibitory effect. Thus, dominant-negative effects of T281E, D182N, and D163N on growth can be best explained by inactivation of the wild-type Cdc7 function through titration of Dbf4 by these inactive kinases. Our results are consistent with the notion that association of Dbf4 with Cdc7 is essential for the G1 to S transition in S. cerevisiae. Received: 17 September 1996 / Accepted: 6 January 1997     

Clustered charged-to-alanine mutagenesis of poliovirus RNA-dependent RNA polymerase yields multiple temperature-sensitive mutants defective in RNA synthesis.

To generate a collection of conditionally defective poliovirus mutants, clustered charged-to-alanine mutagenesis of the RNA-dependent RNA polymerase 3D was performed. Clusters of charged residues in the polymerase coding region were replaced with alanines by deoxyoligonucleotide-directed mutagenesis of a full-length poliovirus cDNA clone. Following transfection of 27 mutagenized cDNA clones, 10 (37%) gave rise to viruses with temperature-sensitive (ts) phenotypes. Three of the ts mutants displayed severe ts plaque reduction phenotypes, producing at least 10(3)-fold fewer plaques at 39.5 degrees C than at 32.5 degrees C; the other seven mutants displayed ts small-plaque phenotypes. Constant-temperature, single-cycle infections showed defects in virus yield or RNA accumulation at the nonpermissive temperature for eight stable ts mutants. In temperature shift experiments, seven of the ts mutants showed reduced accumulation of viral RNA at the nonpermissive temperature and showed no other ts defects. The mutations responsible for the phenotypes of most of these ts mutants lie in the N-terminal third of the 3D coding region, where no well-characterized mutations responsible for viable mutants had been previously identified. Clustered charged-to-alanine mutagenesis (S. H. Bass, M. G. Mulkerrin, and J. A. Wells, Proc. Natl. Acad. Sci. USA 88:4498-4502, 1991; W. F. Bennett, N. F. Paoni, B. A. Keyt, D. Botstein, J. J. S. Jones, L. Presta, F. M. Wurm, and M. J. Zoller, J. Biol. Chem. 266:5191-5201, 1991; and K. F. Wertman, D. G. Drubin, and D. Botstein, Genetics 132:337-350, 1992) is designed to target residues on the surfaces of folded proteins; thus, extragenic suppression analysis of such mutant viruses may be very useful in identifying components of the viral replication complex.