Inhibition of the reproduction of strains of the herpes simplex virus type 1 with drug resistance]

Inhibition of type-1 herpes simplex strains resistant to acyclovir, phosphonoacetic acid and their combination by combined use of three drugs with different mechanisms of action capable of suppressing reproduction of the acyclovir resistant strain was studied. The combinations used were the following: Ara-A + ribavirin + phosphonoformic acid, Xylo-A + ribavirin + phosphonoformic acid and Ph-ACH + Ara-A + ribavirin. The former two combinations had a synergistic action on the standard strain L2 whose drug susceptibility had not undergone changes as well as on the acyclovir resistant strain. As for the strain resistant to phosphonoacetic acid and to acyclovir + phosphonoacetic acid the effect was additive. Ph-ACH + Ara-A + ribavirin had a marked synergistic action on all the strains tested.     

Mapping of the vaccinia virus DNA polymerase gene by marker rescue and cell-free translation of selected RNA

The previous demonstration that a phosphonoacetate (PAA)-resistant (PAAr) vaccinia virus mutant synthesized an altered DNA polymerase provided the key to mapping this gene. Marker rescue was performed in cells infected with wild-type PAA-sensitive (PAAs) vaccinia by transfecting with calcium phosphate-precipitated DNA from a PAAr mutant virus. Formation of PAAr recombinants was measured by plaque assay in the presence of PAA. Of the 12 HindIII fragments cloned in plasmid or cosmid vectors, only fragment E conferred the PAAr phenotype. Successive subcloning of the 15-kilobase HindIII fragment E localized the marker within a 7.5-kilobase BamHI-HindIII fragment and then within a 2.9-kilobase EcoRI fragment. When the latter was digested with ClaI, marker rescue was not detected, suggesting that the PAAr mutation mapped near a ClaI site. The sensitive ClaI site was identified by cloning partial ClaI-EcoRI fragments and testing them in the marker rescue assay. The location of the DNA polymerase gene, about 57 kilobases from the left end of the genome, was confirmed by cell-free translation of mRNA selected by hybridization to plasmids containing regions of PAAr vaccinia DNA active in marker rescue. A 100,000-dalton polypeptide that comigrated with authentic DNA polymerase was synthesized. Correspondence of the in vitro translation product with purified vaccinia DNA polymerase was established by peptide mapping.     

Genetic characterization of the vaccinia virus DNA polymerase: cytosine arabinoside resistance requires a variable lesion conferring phosphonoacetate resistance in conjunction with an invariant mutation localized to the 3'-5' exonuclease domain.

In this report, we describe the isolation, molecular genetic mapping, and phenotypic characterization of vaccinia virus mutants resistant to cytosine arabinoside (araC) and phosphonoacetic acid (PAA). At 37 degrees C, 8 microM araC was found to prevent macroscopic plaque formation by wild-type virus and to cause a 10(4)-fold reduction in viral yield. Mutants resistant to 8 microM araC were selected by serial passage of a chemically mutagenized viral stock in the presence of drug. Because recovery of mutants required that initial passages be performed under less stringent selective conditions, and because plaque-purified isolates were found to be cross-resistant to 200 micrograms of PAA per ml, it seemed likely that resistance to araC required more than one genetic lesion. This hypothesis was confirmed by genetic and physical mapping of the responsible mutations. PAAr was accorded by the acquisition of one of three G-A transitions in the DNA polymerase gene which individually alter cysteine 356 to tyrosine, glycine 372 to aspartic acid, or glycine 380 to serine. AraCr was found to require one of these substitutions plus an additional T-C transition within codon 171 of the DNA polymerase gene, a change which replaces the wild-type phenylalanine with serine. Congenic viral stocks carrying one of the three PAAr lesions, either alone or in conjunction with the upstream araCr lesion, in an otherwise wild-type background were generated. The PAAr mutations conferred nearly complete resistance to PAA, a slight degree of resistance to araC, hypersensitivity to aphidicolin, and decreased spontaneous mutation frequency. Addition of the mutation at codon 171 significantly augmented araC resistance and aphidicolin hypersensitivity but caused no further change in mutation frequency. Several lines of evidence suggest that the PAAr mutations primarily affect the deoxynucleoside triphosphate-binding site, whereas the codon 171 mutation, lying within a conserved motif associated with 3'-5' exonuclease function, is postulated to affect the proofreading exonuclease of the DNA polymerase.     

Mutations in the herpes simplex virus DNA polymerase gene can confer resistance to 9-beta-D-arabinofuranosyladenine.

Mutants of herpes simplex virus type 1 resistant to the antiviral drug 9-beta-D-arabinofuranosyladenine (araA) have been isolated and characterized. AraA-resistant mutants can be isolated readily and appear at an appreciable frequency in low-passage stocks of wild-type virus. Of 13 newly isolated mutants, at least 11 were also resistant to phosphonoacetic acid (PAA). Of four previously described PAA-resistant mutants, two exhibited substantial araA resistance. The araA resistance phenotype of one of these mutants, PAAr5, has been mapped to the HpaI-B fragment of herpes simplex virus DNA by marker transfer, and araA resistance behaved in marker transfer experiments as if it were closely linked to PAA resistance, a recognized marker for the viral DNA polymerase locus. PAAr5 induced viral DNA polymerase activity which was much less susceptible to inhibition by the triphosphate derivative of araA than was wild-type DNA polymerase. These genetic and biochemical data indicate that the herpes simplex virus DNA polymerase gene is a locus which, when mutated, can confer resistance to araA and thus that the herpes simplex virus DNA polymerase is a target for this antiviral drug.     

Acyclovir-resistant mutants of herpes simplex virus type 1 express altered DNA polymerase or reduced acyclovir phosphorylating activities.

The biochemical properties of four acyclovir-resistant mutants are described. Two of these mutants, PAAr5 and BWr, specified nucleotidyl transferase (DNA polymerase) activities which were less sensitive to inhibition by acyclovir triphosphate than their wild-type counterparts. Another mutant, IUdRr, exhibited reduced ability to phosphorylate acyclovir. The fourth mutant, ACGr4, both induced an altered DNA polymerase and failed to phosphorylate appreciable amounts of acyclovir. BWr, a new acyclovir-resistant mutant derived from the Patton strain of herpes simplex virus type 1, induced a DNA polymerase resistant to inhibition by acyclovir triphosphate, but, unlike the polymerases induced by PAAr5 and ACGr4, still sensitive to phosphonoacetic acid. Resistance of BWr to acyclovir mapped close to the PAAr locus and was separable from mutations in the herpes simplex virus thymidine kinase gene by recombination analysis.     

Isolation of drug resistant mutants of varicella-zoster virus: cross resistance of acyclovir resistant mutants with phosphonoacetic acid and bromodeoxyuridine

Mutants of Varicella-Zoster Virus (VZV) which are resistant to phosphonoacetic acid (PAA), bromodeoxyuridine (BuDR), and acyclovir (ACV) were obtained by serial passages of VZV with increasing concentrations of these drugs. A PAA-resistant mutant and a BuDR-resistant mutant were found also to be resistant to ACV. Five of 8 ACV-resistant mutants acquired resistance to PAA, but none acquired resistance to BuDR. The BuDR-resistant mutant did not induce viral thymidine kinase (TK) activity, but all the ACV-resistant mutants selected in ACV showed viral TK activity which was suppressed with anti-VZV serum and had almost the same electrophoretic mobility as that of the parent strain on polyacrylamide gel electrophoresis in non-denaturing conditions. However, in competitive TK assay with ACV, 2 of 8 ACV-resistant mutants showed no change of phosphorylation of radioactive thymidine, while the other 6 showed decreased phosphorylation of radioactive thymidine. It was suggested that TK induced by the former 2 ACV-resistant mutants had lost affinity to ACV, and so the mutants could grow in the presence of ACV. Thus of the 8 ACV-resistant mutants selected in ACV, 2 were sensitive to PAA with altered TK activity, 5 were resistant to PAA with unaltered TK activity, and 1 was sensitive to PAA with unaltered TK activity, and may have altered DNA polymerase activity to ACV, retaining sensitivity to PAA. These results suggest that resistance of VZV to ACV results from alterations in the virus-specified TK or DNA polymerase, as demonstrated in HSV resistant to ACV.     

Susceptibilities of phosphonoacetic acid and acyclovir resistant varicella-zoster virus mutants to 9-beta-arabinofuranosyladenine and 1-beta-arabinofuranosylcytosine

The DNA polymerase activity, and susceptibilities to 9-beta-D-arabinofuranosyladenine(ara-A) and 1-beta-arabinofuranosylcytosine(ara-C) of a phosphonoacetic acid resistant mutant (PAA-R) of varicella-zoster virus (VZV) selected in the presence of PAA were examined. The DNA polymerase activity of PAA-R was inhibited less than that of the parent strain by PAA in vitro. PAA-R was resistant to acyclovir and also to both ara-A and ara-C. The susceptibilities to ara-A and ara-C of four acyclovir resistant mutants selected in the presence of acyclovir, and also resistant to PAA, were examined. Two variants were resistant, one was slightly resistant, and one was sensitive to both drugs. These cross-resistances and susceptibilities of VZV variants to PAA, ACV, ara-A and ara-C should be considered in chemotherapy of VZV infections.     

Herpes simplex virus resistance and sensitivity to phosphonoacetic acid.

Phosphonoacetic acid (PAA) inhibited the synthesis of herpes simplex virus DNA in infected cells and the activity of the virus-specific DNA polymerase in vitro. In the presence of concentrations of PAA sufficient to prevent virus growth and virus DNA synthesis, normal amounts of early virus proteins (alpha- and beta-groups) were made, but late virus proteins (gamma-group) were reduced to less than 15% of amounts made in untreated infected cells. This residual PAA-insensitive synthesis of gamma-polypeptides occurred early in the virus growth cycle when rates were identical in PAA-treated and untreated infected cells. Passage of virus in the presence of PAA resulted in selection of mutants resistant to the drug. Stable clones of mutant viruses with a range of drug sensitivities were isolated and the emergence of variants resistant to high concentrations of PAA involved the sequential selection of mutants progressively better adapted to growth in the presence of the drug. Increased drug resistance of virus yield or plaque formation was correlated with increased resistance of virus DNA synthesis, gamma-protein synthesis, and resistance of the virus DNA polymerase reaction in vitro to the inhibitory effects of the drug. PAA-resistant strains of herpes simplex virus type 1 (HSV-1) complemented the growth of sensitive strains of homologous and heterologous types in mixed infections in the presence of the drug. Complementation was markedly dependent upon the proportions of the resistant and sensitive partners participating in the mixed infection. Intratypic (HSV-1A X HSV-1B) recombination of the PAA resistance marker(s), Pr, occurred at high frequency relative to plaque morphology (syn) and bromodeoxyuridine resistance (Br, thymidine kinase-negative phenotype) markers, with the most likely order being syn-Br-Pr. Recombinant viruses were as resistant or sensitive to PAA as the parental viruses, and viruses recombinant for their PAA resistance phenotype were also recombinant for the PAA resistance character of the virus DNA polymerase. The results provide additional evidence that the herpesvirus DNA polymerase is the site of action of PAA and illustrate the potential usefulness of PAA-resistant mutants in genetic studies of herpesviruses.     

Genetic evidence for vaccinia virus-encoded DNA polymerase: isolation of phosphonoacetate-resistant enzyme from the cytoplasm of cells infected with mutant virus.

Phosphonoacetate (PAA), at concentrations of 200 micrograms/ml or more, prevented growth of vaccinia virus in HeLa and BSC-1 cells. Spontaneous vaccinia virus mutants, selected at high PAA levels, were resistant to the antiviral effects of the drug. The action of PAA was directed toward an early viral function, since the drug was inhibitory only during the first 4 h of the approximately 15-h growth cycle. Conversely, significant reversal of the antiviral effects was obtained only when the drug was removed at or before the fourth hour of infection. Incorporation of [3H]thymidine into cytoplasmic viral DNA was severely inhibited in cells infected with wild-type virus but not in cells infected with mutant virus. Virus-induced DNA polymerase isolated from the cytoplasm of cells infected with wild-type or mutant virus had indistinguishable chromatographic properties on DEAE-cellulose and phosphocellulose columns. However, the wild-type enzyme was inhibited by relatively low concentrations of PAA, whereas 10-fold higher concentrations were needed for equivalent inhibition of the mutant enzyme. Kinetic analysis indicated that PAA inhibition was noncompetitive with deoxyribonucleoside triphosphates; Ki values for wild-type and mutant DNA polymerases were approximately 25 and 300 microM, respectively. Inhibition of wild-type DNA polymerase was immediate and complete even when PAA was added after initiation of DNA synthesis in vitro, suggesting that chain elongation was affected. These results established that the DNA polymerase is a target of the antiviral action of PAA and provided genetic evidence that this enzyme is virus encoded.     

Herpes simplex virus DNA polymerase as the site of phosphonoacetate sensitivity: temperature-sensitive mutants.

Temperature-sensitive (ts) mutants in a number of complementation groups of herpes simplex virus type 1 (HSV-1) are deficient in DNA polymerase induction at the restrictive temperature. Twenty-two mutants in 15 complementation groups were tested for sensitivity to phosphonoacetate (PAA), a compound that inhibits HSV replication in vivo and the DNA polymerase in vitro. One mutant, tsD9, was resistant to PAA (Pr), whereas all others were sensitive. Revertants of tsD9 to the ts+ phenotype simultaneously lost PAA resistance. Additional Pr mutants were isolated from ts mutants belonging to several complementation groups of HSV-1. Double mutants (ts Pr phenotype) were used in three-factor recombination analyses to locate the PAA locus on the genetic map at a position indistinguishable from the ts lesion in tsD9. In all cases, resistance or sensitivity to PAA in vivo was correlated with resistance or sensitivity of DNA polymerase in vitro. These data are compatible with the temperature-sensitive lesion of tsD9 and the determinant of PAA sensitivity both residing in the structural gene for DNA polymerase.     

Escherichia coli K-12 Mutants Altered in the Transport Systems for Oligo- and Dipeptides

Two mutants of Escherichia coli K-12, defective in the oligopeptide and dipeptide transport system, are described. A mutant defective in the oligopeptide transport system (opp-1) was isolated as resistant to the inhibitory action of triornithine; this mutant is also resistant to glycylglycylvaline and does not concentrate (14)C-glycylglycylglycine, although it is still as sensitive as the parental strain to glycylvaline and valine. Starting from the opp-1 strain, a mutant defective also in the dipeptide transport system (dpp-1) was isolated; this mutant is resistant to the inhibitory action of glycylvaline, valylleucine, and leucylvaline and does not concentrate (14)C-glycylglycine, although it is still as sensitive as the parental strain to valine. The apparent kinetic constants for oligopeptide and dipeptide transport were measured. The opp marker is co-transducible with trp at 27 min on the E. coli genetic map. The dpp locus is separated from opp and is located between proC (10 min) and opp.     

Genetic analysis of the susceptibility of mouse cytomegalovirus to acyclovir.

Eight independently derived mouse cytomegalovirus (MCMV) mutants resistant to acyclovir (ACV) were obtained by the sequential plating of wild-type virus in increasing concentrations of ACV. Results of complementation studies among these eight mutants suggest that all had mutations within the same or closely associated genes. A ninth MCMV mutant resistant to phosphonoacetate (PAA) derived by plating wild-type virus in the presence of 100 micrograms of PAA per ml displayed coresistance to ACV and was unable to complement any of the ACV-derived mutants. Recombination experiments among all combinations of the nine MCMV mutants were performed and supported the complementation data in that no recombination could be detected. Seven of the eight ACV-resistant mutants demonstrated cross-resistance to PAA and hypersensitivity to aphidicolin. The one mutant not coresistant to PAA was more susceptible to PAA than was the parent virus. Only a few mutants demonstrated coresistance when the mutants were tested against 9-beta-D-arabinofuranosyladenine (ara-A). The ACV mutant that demonstrated increased susceptibility to PAA was 30-fold more susceptible to ara-A but remained unchanged in susceptibility to aphidicolin. Two of the parent-mutant combinations were selected for DNA synthesis analysis in the presence of ACV (5 microM). A significant decrease in DNA synthesis was demonstrated for both parent viruses, and there was little effect on mutant virus DNA synthesis at the same drug concentration. These results suggest that susceptibility of MCMV to ACV is confined to a product of a single gene and that a mutation of this gene can lead to an altered phenotype when compared with parent virus in susceptibility of DNA synthesis to PAA, ara-A, and aphidicolin, drugs that are known to inhibit DNA polymerase activity.     

Sensitivity of arabinosyladenine-resistant mutants of herpes simplex virus to other antiviral drugs and mapping of drug hypersensitivity mutations to the DNA polymerase locus.

Seven herpes simplex virus mutants which have been previously shown to be resistant to arabinosyladenine were examined for their sensitivities to four types of antiviral drugs. These drugs were a pyrophosphate analog, four nucleoside analogs altered in their sugar moieties, two nucleoside analogs altered in their base moieties, and one altered in both. The seven mutants exhibited five distinct phenotypes based on their sensitivities to the drugs relative to wild-type strain KOS. All mutants exhibited resistance to acyclovir and arabinosylthymine, as well as marginal resistance to iododeoxyuridine, whereas all but one exhibited resistance to phosphonoformic acid. The mutants exhibited either sensitivity or hypersensitivity to other drugs tested--2'-nor-deoxyguanosine, 5-methyl-2'-fluoroarauracil, 5-iodo-2'-fluoroarauracil, and bromovinyldeoxyuridine--some of which differed only slightly from drugs to which the mutants were resistant. These results suggest ways to detect and treat arabinosyladenine-resistant isolates in the clinic. Antiviral hypersensitivity was a common phenotype. Mutations conferring hypersensitivity to 2'-nor-deoxyguanosine in mutant PAAr5 and to bromovinyldeoxyridine in mutant tsD9 were mapped to nonoverlapping regions of 1.1 and 0.8 kilobase pairs, respectively, within the herpes simplex virus DNA polymerase locus. Thus, viral DNA polymerase mediates sensitivity to these two drugs. However, we could not confirm reports of mutations in the DNA polymerase locus conferring resistance to these two drugs. All of the mutants exhibited altered sensitivity to two or more types of drugs, suggesting that single mutations affect recognition of the base, sugar, and triphosphate moieties of nucleoside triphosphates by viral polymerase.     

Genetics of resistance to phosphonoacetic acid in strain KOS of herpes simplex virus type 1.

A DNA- temperature-sensitive mutant of herpes simplex virus type 1 exhibiting thermolabile DNA polymerase activity, tsD9, was shown to be resistant to phosphonoacetic acid (PAA) when plated at the permissive temperature. ts+ revertants of tsD9 were PAA sensitive and exhibited DNA polymerase activity intermediate between that of the wild-type virus and tsD9, indicating that both temperature sensitivity and sensitivity to PAA are controlled by the same gene. Since the position of tsD9 on the existing herpes simplex virus type 1 linkage map is known, the locus for PAA resistance--and therefore for the structural gene for viral DNA polymerase--has been identified.     

The adenosine transporter of Toxoplasma gondii. Identification by insertional mutagenesis, cloning, and recombinant expression

Purine transport into the protozoan parasite Toxoplasma gondii plays an indispensable nutritional function for this pathogen. To facilitate genetic and biochemical characterization of the adenosine transporter of the parasite, T. gondii tachyzoites were transfected with an insertional mutagenesis vector, and clonal mutants were selected for resistance to the cytotoxic adenosine analog adenine arabinoside (Ara-A). Whereas some Ara-A-resistant clones exhibited disruption of the adenosine kinase (AK) locus, others displayed normal AK activity, suggesting that a second locus had been tagged by the insertional mutagenesis plasmid. These Ara-A(r) AK+ mutants displayed reduced adenosine uptake capability, implying a defect in adenosine transport. Sequences flanking the transgene integration point in one mutant were rescued from a genomic library of Ara-A(r) AK+ DNA, and Southern blot analysis revealed that all Ara-A(r) AK+ mutants were disrupted at the same locus. Probes derived from this locus, designated TgAT, were employed to isolate genomic and cDNA clones from wild-type libraries. Conceptual translation of the TgAT cDNA open reading frame predicts a 462 amino acid protein containing 11 transmembrane domains, a primary structure and membrane topology similar to members of the mammalian equilibrative nucleoside transporter family. Expression of TgAT cRNA in Xenopus laevis oocytes increased adenosine uptake capacity in a saturable manner, with an apparent K(m) value of 114 microM. Uptake was inhibited by various nucleosides, nucleoside analogs, hypoxanthine, guanine, and dipyridamole. The combination of genetic and biochemical studies demonstrates that TgAT is the sole functional adenosine transporter in T. gondii and a rational target for therapeutic intervention.     

A single-base change within the DNA polymerase locus of herpes simplex virus type 2 can confer resistance to aphidicolin.

An aphidicolin-resistant (Aphr) mutant of herpes simplex virus (HSV) type 2 strain 186 previously has been shown to induce an altered viral DNA polymerase that is more resistant to aphidicolin and more sensitive to phosphonoacetic acid (PAA) than is wild-type DNA polymerase. In this study the mutation responsible for the aphidicolin-resistant phenotype was physically mapped by marker transfer experiments. The physical map limits for the Aphr mutation were contained in a 1.1-kilobase pair region within the HSV DNA polymerase locus. The 1.1-kilobase-pair fragment of the Aphr mutant also conferred hypersensitivity to PAA, and DNA sequence analysis revealed an AT to GC transition within this fragment of the Aphr mutant. Analysis of the three potential open reading frames within the 1,147-base-pair fragment and comparison with the amino acid sequence of DNA polymerase of HSV type 1 indicated that the Aphr mutant polymerase had an amino acid substitution from a tyrosine to a histidine in the well-conserved region of the DNA polymerase. These results indicate that this single amino acid change can confer altered sensitivity to aphidicolin and PAA and suggest that this region may form a domain that contains the binding sites for substrates, PPi, and aphidicolin.     

Clones of Aedes albopictus cells resistant to methylmercaptopurine riboside

Four clones of A. albopictus cells resistant to 6-methylmercaptopurine riboside (MMPR) (MMPR-10, -11, -12, and -21) were isolated after mutagenesis of the parental LT C-7 cells. As assayed by plating efficiencies these clones were from ten- to 20-fold more resistant to MMPR than the LT C-7 cells. Resistance was also demonstrated by the fact that concentrations of MMPR, which reduced the levels of ATP and GTP in LT C-7 cells, had no such effect in the MMPR-resistant cells. When de novo purine biosynthesis was measured by the incorporation of [14C]formate into ATP and GTP, MMPR had little effect on the MMPR-10 cells (15% inhibition) but did depress synthesis considerably in the MMPR-11 cells (80% inhibition) although not as severely as in the LT C-7 cells (95% inhibition). Three of the resistant clones which were tested also showed considerable resistance to guanosine. Although the mechanism of resistance to MMPR in these cells is not clear it likely involves some alteration in one of the early enzymes involved in purine biosynthesis. Resistant as well as sensitive cells showed a new high-performance liquid chromatography peak after treatment with MMPR suggesting that there was no defect in the uptake of MMPR. The conversion of labeled adenosine to AMP, ADP, and ATP in the resistant cells indicated that these cells were not deficient in adenosine kinase, another possible mechanism of resistance to MMPR. All clones showed a reduction in GTP following treatment with ribavirin; however, they varied considerably with respect to the amount of ribavirin triphosphate which they formed. In the case of the MMPR-11 cells the amount of ribavirin triphosphate formed was markedly sensitive to cultural conditions. The fact that the various MMPR-resistant cells responded differently to ribavirin, and that quantitative differences were also seen in their responses to MMPR (as measured by [14C]formate incorporation) and to guanosine, suggests that there are significant phenotypic differences among these resistant clones.     

The isolation of FOS-1, a gene encoding a putative two-component histidine kinase from Aspergillus fumigatus

In fungi, two-component histidine kinases are involved in response mechanisms to extracellular changes in osmolarity, resistance to dicarboximide fungicides, and cell-wall assembly. In the human opportunistic fungus, Candida albicans, each of the three histidine kinases plays a role in virulence. Here, we identify, for the first time, a gene, FOS-1, from the human pathogenic fungus Aspergillus fumigatus that predicts a protein with homology to two-component histidine kinases. The predicted FOS-1 protein is highly homologous to bacterial and other fungal histidine kinases in several functional domains, but is divergent at the amino- and carboxy-termini. A mutant lacking the FOS-1 locus, DeltaFOS-1, did not exhibit a detectable defect in either hyphal growth or morphology when grown on solid or liquid medium. However, in liquid medium, conidiophore development of the DeltaFOS-1 mutant was delayed. Compared to wild type, the DeltaFOS-1 strain was neither osmotically sensitive nor sensitive or resistant to a number of nondicarboximide antifungal drugs, but was highly resistant to dicarboximide fungicides and resistant to novozym 234, suggesting that FOS-1p may play a role in the regulation of cell-wall assembly.     

Molecular genetics of herpes simplex virus. III. Fine mapping of a genetic locus determining resistance to phosphonoacetate by two methods of marker transfer.

We have transferred a genetic locus determining resistance to phosphonoacetic acid (PAAr) from one herpes simplex viral genome to another by two methods of marker transfer. One method requires recombination between an intact DNA molecule and a restriction endonuclease DNA fragment, whereas the other requires repair of a partial heteroduplex formed between the two DNA molecules. These two methods mapped the PAAr locus between positions 0.45 and 0.53 map units on the physical map of the viral DNA. Fine mapping of the PAAr locus showed that it maps at or near an EcoRI restriction endonuclease site at either 0.46 or 0.49 map units. We also describe and compare the two methods of marker transfer.     

A cytoplasmic factor in the resistance of yeast cells to actidione and its response to uv-irradiation

A relatively high proportion of the cells of a particular strain ofSaccharomyces cerevisiae form slow-growing colonies when plated on .5p.p.m. actidione-agar.The production of this class of resistant mutant, which is not observed in unrelated strains, depends on the presence of a nuclear gene, designatedR.The slow-growing colony is comprised of both sensitive and resistant cells,i.e. resistant cells give rise to a varying proportion of daughter cells that are revertants to sensitivity during colony development.Resistance is generally stabilized and its transmission assured following a second exposure of resistant cells to the drug.Resistance of the stable mutant is inherited only by a small proportion of ascospores in crosses to sensitive strains but shows some features of mendelian transmission in crosses to a different resistant strain.The UV-induction of the slow-growing mutant shows a different pattern from that of gene mutation, although both categories have a nucleic acid action spectrum.Two alternative hypotheses are presented to explain the results, a) in which control of resistance is vested in a mutating cytoplasmic genetic unit and b) where resistance is dependent on the functional, state of a nuclear gene.