Developmental genetics of a temperature-sensitive RNA polymerase II mutation in Drosophila melanogaster

Summary Purified RNA polymerase II (RNA nucleotidyl-transferase; EC 2.7.7.6) extracted from flies possessing lesions in the Ultrabithorax-like (Ubl) locus of Drosophila melanogaster has altered activity in vitro (Greenleaf et al. 1979, 1980; Coulter and Greenleaf 1982). This strongly suggests that the Ubl locus encodes a subunit of RNA polymerase II. Ethyl methanesulfonate was used to induce a temperature-sensitive mutation in this locus. Flies either homozygous or hemizygous for this new X–linked mutation (Ubl ^ts) display viability comparable to that of wild-type flies at 22° C but are lethal at 29° C. The temperature-sensitive period for Ubl ^ts flies is between gastrulation (6 h, 29° C) and pupation (9–10 days, 22° C). Zygotes shifted from 22° C to 29° C die at either the late embryonic or first larval instar stage while temperature shifts of second and third instar larvae result in the lethal phase occurring at the pupal stage. Most pupae shifted from 22° C to 29° C undergo metamorphosis and eclose as adults. Adults are viable if placed at 29° C; however, all females and some males become sterile if maintained at this temperature.Somatic recombination was used to induce clones homozygous for a null allele of Ubl at different stages of development. Clones of this null allele appear to be cell lethal indicating that the Ubl ⁺ gene product is required at all stages of development. The viability of Ubl ^ts pupae and adults at 29° C may result from only a partial reduction in activity caused by the mutation at this nonpermissive temperature.     

Physiological suppression of the temperature-sensitive sporulation defect in a Bacillus subtilis RNA polymerase mutant

Summary Five hundred putative RNA polymerase mutants of Bacillus subtilis were isolated by selecting for resistance to the RNA polymerase inhibitors rifampin (Rif^r), streptovaricin (Str^r) or streptolydigan (Std^r). This collection was screened for mutants that were unable to sporulate at the non-permissive temperature of 46°C, yet which sporulated well at 37°C and had normal vegetative growth (Spo^ts phenotype). Nearly one half of the Rif^r and one quarter of the Stv^r mutants were Spo^ts, whereas none of the Std^r mutants had this phenotype.The streptovaricin resistant strain stv84 was studied in detail. The stv84 mutation maps between cysA14 and strA39 on the B. subtilis chromosome, and the Stv^r and Spo^ts phenotypes cotransform at a frequency of 100%. The Spo^ts phenotype of stv84 could be physiologically corrected by supplementing the growth medium with inhibitors of RNA synthesis such as rifampin or azauracil, with carbohydrates such as ribose, mannose or glycerol, or with lipids such as Tween 40 or fatty acids native to Bacillus subtilis membranes. A Spo^ts phenotype resembling that of stv84 was produced in wild type B. subtilis by adding cerulenin, an inhibitor of fatty acid biosynthesis, to the growth medium. This cerulenin-induced sporulation defect was reversed by the same treatments that correct the temperature-sensitive genetic defect of stv84. These data indicate that the Spo^ts phenotype of strain stv84 is not due to an intrinsic inability of the mutant RNA polymerase to transcribe developmentally-specific genes at the nonpermissive temperature. Rather, the data suggest that the stv84 lesion causes a physiological imbalance which disrupts membrane structure or function in sporulating cells.     

Temperature-Sensitive Mutants of Fujinami Sarcoma Virus: Tumorigenicity and Reversible Phosphorylation of the Transforming p140 Protein

Several clones of Fujinami sarcoma virus (FSV) isolated from a laboratory stock or from mutagenized virus were temperature sensitive (ts) in transformation of cells in culture. When shifted from the permissive (37°C) to the nonpermissive (41.5°C) temperature, the cellular phenotype reverted to normal within 2 h, but it required about 48 h at 37°C to revert back to the transformed morphology. A temperature-resistant (tr) FSV clone was isolated from a tumor of an animal. All ts mutants were tumorigenic in animals but induced tumors only after latent periods of 12 to 25 days, compared to 5 to 6 days with tr virus. The ts lesions of the FSV mutants affected 90% of the phosphorylation of the nonstructural, gag-related 140,000-kilodalton phosphoprotein coded by FSV (p140), but did not affect virus replication or the synthesis of p140. Upon shifting from the permissive to the nonpermissive temperature, p140 was 90% dephosphorylated with an approximate ³²P half-life of 20 min. When shifted back to the permissive temperature, the preexisting p140 was rephosphorylated in the absence of protein synthesis within a 90-min test period. Likewise, most of the phosphate of fully phosphorylated p140 was exchanged at the permissive temperature within 30 to 90 min even when protein synthesis was inhibited. However, the protein structure of p140 had a half-life of 5 h at both temperatures. These results prove p140 to be a substrate of reversible phosphorylation. Superinfection and transformation of ts FSV-infected cells maintained at the nonpermissive temperature with acute leukemia virus MC29 failed to phosphorylate p140. It would follow that in vivo phosphorylation of ts p140 is controlled by an FSV-specific mechanism and is a prerequisite, not a consequence, of transformation. p140 of ts FSV recovered from cells maintained at 41.5°C with anti-gag serum was over 10 times less phosphorylated by associated kinase than the same protein recovered from cells at 37°C if assayed in vitro at 20°C. This kinase activity associated with or dissociated from p140 with a half-life of less than 30 min during temperature shifts of ts FSV-infected cells. However, p140 recovered from ts FSV-infected cells maintained at 37°C was phosphorylated by associated kinase in vitro not only at 20°C but also, and essentially at the same level, at 41.5°C. This suggests that the kinase associated with the immunocomplex of p140 of ts FSV is not temperature sensitive. p140 translated in vitro from ts and tr FSV RNA lacked kinase activity. We conclude that a fully phosphorylated p140 is necessary for the maintenance of transformation by FSV. This is consistent with the notion that other highly oncogenic viruses also code for nonstructural phosphoproteins with probable transforming function. A model which postulates that p140 is a substrate of reversible phosphorylation and that the lesion of the ts FSV clones described herein affects association of p140 with a cellular kinase rather than a hypothetical intrinsic kinase activity of the protein is most compatible with our data.     

A new mutation rpoD800, affecting the sigma subunit of E. coli RNA polymerase is allelic to two other sigma mutants

Summary We have characterized a new mutation rpoD800 affecting the sigma gene of E. coli. Upon transfer to high temperature, a strain with the rpoD800 mutation ceases growth within 30 min. We find that this mutation renders sigma about 10-fold more thermolabile than the wild type sigma at 45°C in vitro. We have compared the temperature profile for inactivation of wild type and mutant sigma and find that the mutant inactivates at a temperature about 9° C lower than does the wild type.The chromosomal locus affected by rpoD800 is shown to be allelic to the locus affected by the spontaneous mutants ts285 and alt-1. All three mutations result in altered sigma and in altered growth at high temperature. We argue that the single locus affected is the structural gene for the sigma subunit of E. coli RNA polymerase.     

A procedure for isolation of spontaneous mutants with temperature sensitive synthesis of RNA and/or protein

Summary A procedure for the isolation of spontaneous temperature sensitive mutants of Escherichia coli has been developed. They are selected as survivors at high temperature against the combined killing effects exerted by a temperature inducible lambda prophage and either streptomycin plus ampillicin or ampicillin plus cycloserine. The mutants so obtained are blocked in vivo in the synthesis of RNA or protein or both at restrictive temperature.     

Macrolide and aminoglycoside antibiotic resistance mutations in the Bacillus subtilis ribosome resulting in temperature-sensitive sporulation

Summary Mutants of Bacillus subtilis resistant to various macrolide antibiotics have been isolated and characterized with respect to their sporulation phenotype and the electrophoretic mobility of their ribosomal proteins (r-proteins). Two types of major alterations of r-protein L17, one probably due to a small deletion, are found among mutants exhibiting high-level macrolide resistance. These mutants are all temperature-sensitive for sporulation (Spo^ts). Low-level resistance to some macrolides is found to be associated with minor alterations in r-protein L17. These mutations do not cause a defective sporulation phenotype. All of the macrolide resistance mutations map at the same locus within the Str-Spc region of the B. subtilis chromosome. Hence, changes in a single ribosomal protein can result in different sporulation phenotypes.Mutants resistant to the aminoglycoside antibiotics neomycin and kanamycin have been isolated. Approximately 5% of these are Spo^ts. Representative mutations, neo 162 and kan25, cause concomitant drug resistance and sporulation temperature-sensitivity and map as single-site lesions in the Str-Spc region of the chromosome. Strains bearing neo162 or kan25 are equally cross-resistant to several aminoglycoside antibiotics but show no resistance to streptomycin or spectinomycin. These mutations define a new B. subtilis drug resistance locus at which mutation can cause defective sporulation.     

Isolation and characterization of temperature sensitive mutants of cyanophage LPP-1

Summary Spontaneous temperature sensitive (ts) mutants of cyanophage LPP-1 were isolated from the wild population of the virus upto a frequency of 1.7x10^-3. The reversion frequencies were 1.3x10^-4 or even less which appeared to be a clonal property. A detailed investigation of the two mutants showed that they were unable to grow at non-permissive temperature and the temperature sensitive phase lasted for 2–3 h during their intracellular growth as judged by the shift-up and down experiments. The mutants differed from the wild phage in being more sensitive to photodynamic inactivation and EDTA shock. They showed high frequency towards rapid lysis mutation following exposure of free phage particles to high temperature.     

Characterization of vaccinia virus DNA replication mutants with lesions in the D5 gene

The vaccinia virus D5 gene encodes a 90 kDa early protein that is essential for viral DNA replication. In this report we map and explore the phenotypes of the temperature sensitive mutants bearing lesions in this gene:ts17,ts24,ts69, (WR strain) andts6389 (IHD strain). Viral DNA synthesis was virtually undetectable during non-permissive infections performed withts17, and incorporation of³H-thymidine ceased rapidly when cultures were shifted to the non-permissive temperature in the midst of replication. The D5 protein may therefore be involved in DNA synthesis at the replication fork. The lesions of the four mutants were localized within the D5orf by marker rescue, and the single nucleotide changes responsible for thets phenotype of the three WR mutants were identified. Unexpectedly, the three alleles with N-terminal mutations were impaired in marker rescue when homologous recombination with small (<2 kb), intragenic DNA fragments at 39.5°C was required. This deficiency was not due to degradation of transfected DNA under non-permissive conditions. Efficient marker rescue could be restored by incubation at the permissive temperature for a brief period after transfection, suggesting a requirement for functional D5 in genome/plasmid recombination. Marker rescue under non-permissive conditions could alternatively be restored by co-transfection of unlinked but contiguous DNA sequences.     

Phenotypic Characterization of Adenovirus Type 12 Temperature-Sensitive Mutants in Productive Infection and Transformation

Eleven temperature-sensitive mutants of adenovirus type 12, capable of forming plaques in human cells at 33 C but not at 39.5 C, were isolated from a stock of a wild-type strain after treatment with either nitrous acid or hydroxyl-amine. Complementation tests in doubly infected human cells permitted a tentative assignment of eight of these mutants to six complementation groups. Temperature-shift experiments revealed that one mutant is affected early and most of the other mutants are affected late. Only the early mutant, H12ts505, was temperature sensitive in viral DNA replication. Infectious virions of all the mutants except H12ts505 and two of the late mutants produced at 33 C, appeared to be more heat labile than those of the wild type. Only H12ts505 was temperature sensitive for the establishment of transformation of rat 3Y1 cells. One of the late mutants (H12ts504) had an increased transforming ability at the permissive temperature. Results of temperature-shift transformation experiments suggest that a viral function affected in H12ts505 is required for “initiation” of transformation. Some of the growth properties of H12ts505-transformed cells were also temperature dependent, suggesting that a functional expression of a gene mutated in H12ts505 is required to maintain at least some aspects of the transformed state.     

Macromolecular synthesis in chromosome initiation mutants of Bacillus subtilis.

Summary Inactivation of the dna B or dna D gene product in Bacillus subtilis stimulates RNA and protein synthesis. Strains containing ts dna B and D mutations have been constructed by introducing the mutations by transformation into a thymine requiring strain which does not lyse during thymine starvation. The consequences of inactivation of these gene products have been assessed by comparing RNA and protein synthesis during thymine starvation at the restrictive temperature with the recipient strain. In the ts ⁺ strain, there is a doubling in rate of RNA synthesis during thymine starvation. In the ts dna B and D mutations at the restrictive temperature the rate of RNA synthesis increases four fold. By preincubating the mutants in the absence of thymine for one generation at the permissive temperature the two fold increase in rate of RNA synthesis associated with inactivation of the initiation complex can be demonstrated under conditions where the ts ⁺ strain shows a decrease in rate of RNA synthesis. The rate of protein synthesis observed largely reflects the rate of RNA synthesis in all strains. Completion of the chromosome at the restictive temperature has no significant effect on the rate of RNA synthesis. It is suggested that inactivation of the initiation complex after chromosome initiation could play an important role in control of RNA synthesis in relation to the cell cycle.     

Viral nucleocapsid melting to measure protein: RNA interactions

Thermal denaturation of nucleocapsids of wild type (WT) vesicular stomatitis virus (VSV), containing only the nucleocapsid protein (N) and viral RNA, caused a “melting” that resulted in an A_260nm absorbance increase of 140%. The nucleocapsids of two temperature-sensitive ($\text{ts}$) VSV mutants, $\text{ts}$ G31BP and $\text{ts}$ G22, both underwent larger absorbance increases of 251% and 177% respectively, suggesting these nucleocapsids are complexed by weaker N protein: RNA interactions than the WT-VSV. Two other mutants, $\text{ts}$ G31 and $\text{ts}$ G41 underwent A_260nm increases either similar to, or smaller than, that measured with WT-VSV nucleocapsids. RNA synthesis by $\text{ts}$ G31BP in infected cells was also found to be decreased at elevated temperatures. This temperature sensitive defect in viral RNA metabolism in $\text{ts}$ G31BP may be the result of weaker protein:RNA interactions associated with the nucleocapsid.     

Differential chromosomal and mitochondrial DNA synthesis in temperature-sensitive mutants ofUstilago maydis

Summary The amount and type of residual DNA synthesis was determined in eight temperature-sensitive mutants of the smut fungusUstilago maydis after incubation at the restrictive temperature (32° C) for eight hours. Mutantsts-220,ts-207,ts-432 andts-346 were found to have an overall reduction in the synthesis of both nuclear and mitochondrial DNA in comparison to the wild-type. In mutantsts-20,tsd 1-1,ts-84 andpol 1-1 nuclear DNA synthesis was depressed relative to mitochondrial synthesis. The DNA-polymerase mutantpol 1-1 had persistent nuclear synthesis at about 50% of the rate of synthesis of mitochondrial DNA and similar behavior was observed in a diploid homozygous strain. Mutantts-84 had an initial burst of DNA synthesis which was reduced for nuclear but not mitochondrial synthesis after three hours preincubation at 32°C.tsd 1-1 andts-20 had nuclear residual synthesis amounting to about 25% of the relative rate of mitochondrial synthesis with correlates to increasing UV sensitivity of these strains on incubation at 32° C. Apol 1-1ts-84 double mutant had an additive loss of nuclear DNA synthesis which indicates that the steps of replication involved may be sequential.     

Studies on the functions of the RNA polymerase components by means of mutations

Summary It had been shown earlier, that RNA polymerase 13 S particles contain the large components with a molecular weight of about 3–10⁵ and small subunits with a molecular weight of 4·10⁴-1·10⁵. These polymerase components easily dissociate and reassociate with restoration of the enzyme activity.Both temperature-sensitive (tsX) and rifamycin-resistant (rif-r-I) mutations proved to affect the large polymerase component without changing the small subunits. These mutations were mapped at different, though closely linked, loci of metB-thi region of E. coli K12 chromosome. These results as well as certain literature data allow to conclude that the large RNA polymerase component consists of at least two polypeptides, one being altered by ts mutation, and the other—by rif-r mutation.The large polymerase component when separated from the small subunits retain the ability to bind to T2 phage DNA while the separate small subunits lack this property. Rifamycin does not affect RNA polymerase-T2 DNA binding while ts mutation leads to inability of the enzyme to form stable complexes with DNA. Therefore, it is likely that the polypeptide affected by ts mutation is responsible for the attachment of RNA polymerase to specific sites of DNA template. On the other hand, the small subunits as well as polypeptide of the large component, which determines RNA polymerase sensitivity to rifamycin, seem not to participate in the enzyme binding to DNA template. It is suggested, that the catalytic site of RNA polymerase is located in the large component and formed by rifamycin-binding polypeptide. The small subunits are supposed to have regulatory function and activate the large components.     

Genetic Analysis of a Baculovirus, Autographa californica Nuclear Polyhedrosis Virus I. Isolation of Temperature-Sensitive Mutants and Assortment into Complementation Groups

Temperature-sensitive (ts) mutants were isolated from the baculovirus Autographa californica (alfalfa looper) MNPV, grown in Spodoptera frugiperda (fall armyworm) cells in the presence of N-methyl-N′-nitro-N-nitrosoguanidine. Of 567 plaque isolates screened, 27 were temperature sensitive (ts), representing a mutation frequency of 4.8%. Ten ts mutants were studied in detail: six failed to yield nonoccluded virus at 33°C (NOV mutants), whereas the other four produced nonoccluded virus but were restricted in formation of polyhedra at 33°C (Poly mutants). One of the six NOV mutants failed to synthesize viral DNA. Reversion and leak frequencies were determined, and the mutants were assorted into complementation groups based on the yield of polyhedrin synthesis in cells coinfected with pairs of mutants at 33°C, as measured by radioimmunoassay. For NOV mutants, complementation indexes were also based on virus yield and were consistent with those based on polyhedrin synthesis. Nine mutants were assorted into five complementation groups. One mutant remained unclassified.     

A mutant ofLactobacillus acidophilus with temperature-sensitive regulation of DNA synthesis

Among other temperature-sensitive mutants ofLactobacillus acidophilus the mutant “ts 9” with temperature-sensitive initiation of DNA synthesis was isolated. In this mutant, the course of DNA synthesis under non-permissive conditions proceeds in two phases. During the first 90–120 min, a slight increase (20–50%) of DNA content takes place. Then during further incubation at 40°C, the capacity for initiation of further DNA synthesis increases and a second round of DNA synthesis starts after 3–4h of incubation. The initiation of DNA synthesis is prevented by chloramphenicol and the preceding lag is temperature-dependent. It is concluded that an accumulation of an initiation factor is required for the onset of a new cycle of DNA synthesis and that in thets 9 mutant this accumulation is inhibited at non-permissive temperature.     

Complementation experiments between conditional lethal mutants of bacteriophage ?X174

Summary Complementation experiments with temperature sensitive (ts) and suppressor sensitive (sus) mutants of bacteriophage X174 unambiguously revealed five cistrons on the basis of a clear bipartition of burst sizes.A new group of sus mutants (emeralds) was found, defective in a function essential for growth in Shigella sonnei V64.The complementation between ts and sus mutants was in general asymmetric in that the yield of ts particles was lower than that of the sus particles. The mutants of one cistron (defective in RF-replication) showed a completely asymmetric complementation behaviour both of ts and sus mutants. The ts mutants of this group, which show to be early, appear to be defective in two functions.The possibility is discussed that in each cell only one phage genome is replicated. This would explain both kinds of asymmetric complementation and the low burst sizes that were obtained when mutants of particular genes were complemented.     

A slow-growing, ribosomal mutant of Salmonella typhimurium

Summary The mechanisms of S. typhimurium reversion from histidine dependence (his ^–) to histidine independence (his ⁺) were studied. Genetic and phenotypic characteristics of revertants induced by nitrosoguanidine were analyzed. Among them a class of slow-growing revertants was selected. It is found that all of these slow-growing revertants carry the original UGA nonsense mutation within the histidine operon. They are streptomycin sensitive and no specific suppressor(s) for UGA nonsense codon are demonstrable. The suppression takes place in the absence of conventional nonsense UGA suppressor(s). It is seemingly due to a ribosomal mutation which in turn is likely to produce ambiguity in the process of translation and which suppresses the UGA nonsense codon. The rate of both in vivo and in vitro protein synthesis is significantly reduced. The fact that streptomycin, at sublethal doses, reduced the growth rate of these mutants, probably because of the simultaneous burden of two ambiguity factors, suggests that the mutants described may be regarded as a kind of ram (ribosomal ambiguity) mutants with a his ^– sup ^–genotype. Their capacity to translate poly-U is reduced and in that respect they differ from ram mutants of Escherichia coli.     

Deficiency of double mutant recombinants in crosses of phage T4

Summary Only 1.4% of the double mutant recombinants expected on the basis of wild-type recombination frequencies were observed in the combined data from two-factor crosses between a gene 37 amber mutant, amB280, and eighteen different temperature sensitive mutants which were also defective in gene 37. Similar, though less extreme, deficiencies of double mutant recombinants were observed by Doermann and Parma (1968) for mutants in several other genes. In our amB280xts crosses, frequencies of wild-type recombinants were in reasonably good agreement with those expected from the map positions of the mutants determined in crosses not involving amB280. Wild-type and double mutant recombinants were found at comparable frequencies when each of three other gene 37 amber mutants was crossed to a gene 37 temperature sensitive mutant.Experiments were performed to test whether the deficiency of double mutant recombinants in the amB280xts crosses could be explained by assuming that they occurred primarily in heterozygous particles, where their expression was masked. However, no evidence in support of this explanation was found. Other possible explanations, that the deficiency of double mutants was due to their inviability or the inability of double mutant chromosomes to replicate, were also inconsistent with our observations. The hypothesis considered to most plausibly explain our evidence is that the process by which double mutant recombinant chromosomes are formed is inhibited in the vicinity of a poorly suppressed am mutation.     

Isolation of novel pre-mRNA splicing mutants of Schizosaccharomyces pombe

 New prp (pre-mRNA processing) mutants of the fission yeast Schizosaccharomyces pombe were isolated from a bank of 700 mutants that were either temperature sensitive (ts^-) or cold sensitive (cs^-) for growth. The bank was screened by Northern blot analysis with probes complementary to S. pombe U6 small nuclear RNA (sn RNA), the gene for which has a splicesomal (mRNA-type) intron. We identified 12 prp mutants that accumulated the U6 snRNA precursor at the nonpermissive temperature. All such mutants were also found to have defects in an early step of TFIID pre-mRNA splicing at the nonpermissive temperature. Complementation analyses showed that seven of the mutants belong to six new complementation groups designated as prp8 and prp10-prp14, whereas the five other mutants were classified into the known complementation groups prp1, prp2 and prp3. Interestingly, some of the isolated prp mutants produced elongated cells at the nonpermissive temperature, which is a phenotype typical of cell division cycle (cdc) mutants. Based on these findings, we propose that some of the wild-type products from these prp ⁺ genes play important roles in the cellular processes of pre-mRNA splicing and cell cycle progression. Received: 15 April 1996/Accepted: 9 July 1996