The Selection of Amber Mutations in Genes Required for Completion of Start, the Controlling Event of the Cell Division Cycle of S. CEREVISIAE

Using a modification of a procedure developed for the isolation of temperature-sensitive mutants defective in the start event of cell division, amber mutations were obtained for two Class-I start genes, cdc28 and cdc37. Genetic analysis demonstrated that co-segregation of an amber suppressor with such alleles was required for viability of spores subsequent to meiosis. These mutations are expected to be useful in the identification of the molecular products of the genes cdc28 and cdc37.     

Histidine regulation in Salmonella typhimurium. 8. Mutations of the hisT gene

The hisT gene, one of six genes in which mutation causes derepression of the histidine operon in Salmonella typhimurium, is shown to code for a protein that is not essential for the growth of the bacteria. This is indicated by the characterization of particular classes of mutations in the hisT gene: amber mutations, frame-shift mutations, and temperature-sensitive mutations that affect repression but not growth. In addition, the class of semilethal mutations was selected for but not found.     

The isolation of nonsense mutations in cell division cycle genes of the yeast Saccharomyces cerevisiae

Summary Nonsense mutations have been isolated in cell division cycle genes in a strain of Saccharomyces cerevisiae that carries a temperature-sensitive amber suppressor. These mutants may be valuable in identifying the products of genes involved in the cycle and in determining the pattern of their synthesis during the cell cycle.     

Mutants of bacteriophage T4 that produce infective fibreless particles

In wild type bacteriophage T4 the long tail fibres serve both in the initial attachment of the phage to its host and in the triggering of tail contraction. A two-step model for the control of triggering suggests that particles lacking the product of gene 9, which are also structurally fibreless, might be infective. This is shown to be the case, even though such phage do not plate on restrictive strains of bacteria. However, starting from phage carrying an amber mutation in gene 9 it is easy to isolate additional mutations which, under restrictive conditions, permit fibreless plating (pfp mutations). Three such pfp mutations, having also a temperature-sensitive phenotype, have been isolated and shown to map in genes coding for structural components of the baseplate. The mode of action of these pfp mutations is not clear, though they certainly destabilize the baseplate, thereby making triggering easier. The pfp mutations are effective only when in combination with an amber mutation in gene 9 and not with amber mutations in tail fibre genes, establishing the essentially inhibitory nature of the control of triggering exercised by gene 9 product.     

Isolation and characterization of amber mutations in gene dnaA of escherichia coli K-12.

Amber mutants with defects in the dnaA gene of Escherichia coli K-12 were isolated after localized mutagenesis of the tna-dnaA region of the chromosome. We isolated 36 mutants defective in the initiation of deoxyribonucleic acid replication as determined by their dependence upon integrative suppression by a P2 sig5 prophage. Three of the 36 mutants were shown to contain amber mutations through the use of a temperature-sensitive amber suppressor. These mutations, which mapped between gyrB and tna, were characterized genetically and biochemically as amber mutations in dnaA.     

Isolation and characterization of Escherichia coli dnaA amber mutants.

Specialized transducing phage lambda (formula, see text) dnaA-2 was mutagenized, and two derivatives designated lambda (formula) dnaA17(Am) and lambda (formula) dnaA452(Am) were obtained. They did not transduce such mutations as dnaA46, dnaA167, and dnaA5 when an amber suppressor was absent, but they did so in the presence of an amber suppressor. By contrast, they transduced the dna-806 and tna-2 mutations in the absence of an active amber suppressor. The dna-806 and tna-2 mutations are known to be located very close to the dnaA gene, but in separate cistrons. When ultraviolet light-irradiated uvrB cells were infected with the derivative phages and proteins specified by them were analyzed by gel electrophoresis, a 50,000-dalton protein was found to be specifically missing if an amber suppressor was absent. This protein was synthesized when an amber suppressor was present. The dnaA17(Am) mutation on the transducing phage genome was then transferred by genetic recombination onto the chromosome of an Escherichia coli strain carrying a temperature-sensitive amber suppressor supF6(Ts), yielding a strain which was temperature sensitive for growth and deoxyribonucleic acid replication. The temperature-sensitive trait was suppressed by supD, supE, or supF. We conclude that, most likely, the derivative phages acquired amber mutations in the dnaA gene whose product is a 50,000-dalton protein as identified by gel electrophoretic analysis.     

Specific Suppression of Mutations in Genes 46 and 47 by das, a New Class of Mutations in Bacteriophage T4D

Mutants in T4 genes 46 and 47 exhibit early cessation of deoxyribonucleic acid (DNA) synthesis ("DNA arrest") and decreased synthesis of late proteins and phage. In addition, mutants in genes 46 and 47 fail to degrade host DNA to acidsoluble products. It is shown here that this complex phenotype can be partially suppressed by mutation of a T4 gene external to genes 46 and 47 which has been named das for "DNA arrest suppressor." The das mutations were discovered as third-site mutations in spontaneous pseudorevertants of [46, 47] mutants; the pseudorevertants make small plaques on Escherichia coli B, whereas [46, 47] mutants make none. The [das, 46, 47] triple mutant exhibits increased DNA, late protein, and viable phage production compared to the double mutant [46, 47]. The [das, 46, 47] mutant also degrades more of the host DNA to acid-soluble products than does the [46, 47] mutant. The suppressor effect of the das mutation appears to be gene-specific: it suppresses both amber and temperature-sensitive mutations in genes 46 and 47 and does not suppress amber mutations in any of the other genes tested. The [das] single mutants make normal-sized plaques on E. coli B and exhibit nearly normal host DNA degradation, DNA synthesis, late protein synthesis, and viable phage production. The das mutations either define a new gene between genes 33 and 34 or are special mutations within gene 33.     

Transmission of amber mutants of bacteriophage T4. IV. The frequency of the phenomenon of temperature sensitivity of replication in non-permissive cells of amber mutants for the head genes

Dependence of multiplication of 42 single and double amber mutants in 16 phage head genes on the incubation temperature was studied in the cells of non-permissive host. For amber mutants in 6 head genes the birst size decreases by several orders, with the increase of the incubation temperature. Among amber mutants of the above mentioned genes, mutants in genes 4 and 65 can be distinguished as those with considerably large burst size at low temperature. Phage head genes form the groups, according to temperature sensitivity of multiplication of amber mutants. These groups, together with corresponding groups of phage tail genes, constitute common temperature-sensitive and non-sensitive gene groups on the phage genomic map.     

Two loci required for cytoplasmic organization in early embryos of Caenorhabditis elegans

We have identified five new alleles, including an amber allele, at each of two loci (zyg-11 II and zyg-9 II) previously identified by temperature-sensitive strict maternal-effect lethal mutations. Genetic analysis indicates that each of these genes is expressed specifically during oogenesis and encodes a protein product whose function is required only during embryogenesis. Temperature-pulse experiments suggest that the time of action of both products is during the one-cell stage of embryogenesis. Phenotypic analysis reveals that mutations in both loci lead to disorganization of the cytoplasm in early embryos and to abnormalities in at least one of the meiotic divisions. Mutations at the zyg-9 locus appear to specifically affect microtubule function in one-cell embryos while zyg-11 mutations affect many cytoplasmic properties.     

Isolation and characterization of a temperature-sensitive amber suppressor mutant of Escherichia coli K12

Summary By mutagenizing an E. coli strain carrying an amber suppressor supD ^- (or su _I ⁺), we isolated a mutant whose amber suppressor activity was now temperature-sensitive. The mutant suppressor gene was named sup-126, which was found to be cotransduced with the his gene by phage P1vir at the frequency of ca. 20%. At 30° C it suppresses many amber mutations of E. coli, phage T4, and phage . At 42° C, however, it can suppress none of over 30 amber mutations tested so far. The sup-126 mutation is unambiguous and stable enough to be useful for making production of an amber protein temperature-sensitive.     

Conditionally lethal amber mutations in the leader peptidase gene of Escherichia coli.

The lep gene of Escherichia coli encodes the leader peptidase which cleaves amino-terminal leader sequences of secreted proteins. To facilitate the study of structure-function relationships of the leader peptidase, 22 amber mutations in lep were isolated by localized mutagenesis. These amber mutants grew at 32 degrees C but not at 42 degrees C in the presence of a temperature-sensitive amber suppressor. Most of them were lethal under sup0 conditions. However, one amber mutant, the lep-9 mutant, exhibited temperature-sensitive growth in the sup0 strain, indicating that the amber fragment is active at 32 degrees C but not at 42 degrees C. Protein precursors of the maltose-binding protein and OmpA accumulate strikingly in the lep-9 mutant.     

Temperature sensitivity caused by missense suppressor supH and amber suppressor supP in Escherichia coli.

The temperature-sensitive missense suppressor supH and amber suppressor supP in Escherichia coli are mutations of the serU and leuX genes, respectively. The supH tRNA, tRNA(SerCAA), is expected to recognize UUG codons, which are normally read by tRNA(LeuCAA) and tRNA(LeuUAA), coded for by the leuX gene and the leuZ gene, respectively. We show that supP and supH are incompatible and that strains carrying both supP and a restrictive rpsL allele are temperature sensitive. It is suggested that the temperature sensitivity of both supH and supP strains is caused by deficient reading of UUG codons by tRNA(LeuUAA).     

Differential expression of five tRNA(UAGTrp) amber suppressors in Caenorhabditis elegans.

Caenorhabditis elegans has 12 tRNA(UGGTrp) genes as defined by Southern analysis. In order to evaluate the function of the individual members of this multigene family, we sought to recover amber (UAG)-suppressing mutations from reversion experiments with animals carrying amber mutations in a nervous system-affecting gene (unc-13) or a sex-determining gene (tra-3). Revertants were analyzed by Southern blot, exploiting the fact that the CCA to CTA change at the anticodon creates a new XbaI site. Five different members of the tRNATrp gene family were identified as suppressors: sup-7 X, sup-5 III, sup-24 IV, sup-28 X, and sup-29 IV. All five suppressor genes were sequenced and found to encode identical tRNA(UAGTrp) molecules with a single base change (CCA to CTA) at the anticodon compared with their wild-type counterparts. The flanking sequences had only limited homology. The relative expression of these five genes was determined by measuring the efficiencies of suppressers against amber mutations in genes affecting the nervous system, hypodermis, muscle, and sex determination. The results of these cross-suppression tests showed that the five members of the tRNA(Trp) gene family were differentially regulated in a tissue- or development stage-specific manner.     

Screens for Extragenic Mutations That Fail to Complement Act1 Alleles Identify Genes That Are Important for Actin Function in Saccharomyces Cerevisiae

Null mutations in SAC6 and ABP1, genes that encode actin-binding proteins, failed to complement the temperature-sensitive phenotype caused by a mutation in the ACT1 gene. To identify novel genes whose protein products interact with actin, mutations that fail to complement act1-1 or act1-4, two temperature-sensitive alleles of ACT1, were isolated. A total of 14 extragenic noncomplementing mutations and 12 new alleles of ACT1 were identified in two independent screens. The 14 extragenic noncomplementing mutations represent alleles of at least four different genes, ANC1, ANC2, ANC3 and ANC4 (Actin NonComplementing). Mutations in the ANC1 gene were shown to cause osmosensitivity and defects in actin organization; phenotypes that are similar to those caused by act1 mutations. We conclude that the ANC1 gene product plays an important role in actin cytoskeletal function. The 12 new alleles of ACT1 will be useful for further elucidation of the functions of actin in yeast.     

First identification of an amber nonsense mutation in Schizosaccharomyces pombe: major differences in the efficiency of homologous versus heterologous yeast suppressor tRNA genes

Summary In Saccharomyces cerevisiae ochre and opal, as well as amber mutations are known, whereas in the fission yeast Schizosaccharomyces pombe no amber alleles have been described. We have characterized trp1-566, an amber allele in the trp1 locus of S. pombe. The identification of trp1-566 as an amber allele is based on the following results: (a) The nonsense allele can be converted to an ochre allele by nitrosoguanidine mutagenesis. (b) trp1-566 is suppressed by a bona fide S. pombe amber suppressor tRNA, supSI. The supSI gene was obtained by primer-directed in vitro mutagenesis of a tRNASer from S. pombe. Unexpectedly, an S. cerevisiae amber suppressor tRNASer, supR21, transformed into S. pombe, failed to suppress trp1-566. Northern analysis of S. pombe transformants, containing supRL1 or S. cerevisiae tRNA^Leu or tRNA^Tyr genes reveals that these genes are not transcribed in the fission yeast. As an additional tool for the analysis of nonsense mutations in S. pombe, we obtained by nitrosoguanidine mutagenesis two unlinked amber suppressor alleles, sup13 and sup14, which act on trp1-566.     

Genetic characterization of a filament-forming, lipoprotein-deficient mutant of Escherichia coli.

The fam-715 allele of Escherichia coli ST715, previously described as a temperature-sensitive filament former with reduced levels of lipoprotein at the nonpermissive temperature (S. V. Torti and J. T. Park, Nature [London] 263: 323--326, 1976), was mapped at 74 min. This mutation appears to be amber. It is recessive and can be complemented by F' plasmids carrying the wild-type allele or by an F' plasmid carrying an amber suppressor. Isotopic labeling experiments as well as map position differentiate the fam-715 allele from lipoprotein structural gene mutations.     

Characterization of suppressible mutations in the viomycin phosphotransferase gene of the Streptomyces enteric plasmid pVE138.

The viomycin phosphotransferase gene (vph) is expressed and confers resistance to viomycin in both Streptomyces spp. and members of the family Enterobacteriaceae. We report the isolation of UGA (opal) and UAG (amber) mutations in the vph gene of shuttle plasmid pVE138. We found that the five UGA mutations in vph resulted in a temperature-sensitive phenotype in Salmonella typhimurium. Su- strains are Vior at 28 degrees C and Vios at 37 degrees C, whereas Su+UGA strains are Vior at both 28 and 37 degrees C. The single amber mutation isolated was not temperature sensitive and resulted in the expected Vios phenotype in Su- strains and Vior in Su+UAG strains.     

Variations in Genetic Recombination Due to Amber Mutations in T4D Bacteriophage

Recombination experiments were performed to assess the affect of amber mutations in 12 genes of T4D bacteriophage on genetic recombination. Crosses were performed in various suppressor-containing bacterial hosts to permit the production of progeny phage. Amber mutations in genes 32, 46, and 47 caused decreased recombination, amber mutations in genes 30, 41, 42, 43, 56, 61, and 62 caused increased recombination, whereas mutations in genes 63 and 37 showed no demonstrable effect on recombination.     

Amber dnaG mutation exerting a polar effect on the synthesis of RNA polymerase sigma factor in Escherichia coli

Summary Three amber mutants of Escherichia coli, dnaG9, dnaG24 and dnaG26, affected in the structural gene (dnaG) for primase have been isolated from a parental strain carrying a temperature-sensitive amber suppressor (supF-Ts6). These mutants grow at 30° C but not at 42° C since primase is essential for growth and is synthesized only at low temperatures. Chimeric plasmids carrying dnaG ⁺ but no other chromosomal genes of E. coli complemented the amber mutations, and the plasmid carrying a part of dnaG lost the complementing activity. Beside, plasmids carrying a dnaG amber mutation complemented a temperature-sensitive dnaG mutation only in the presence of amber suppressor. One of the amber mutation, dnaG24 which maps proximal to the NH₂-terminus of the dnaG gene, exerted a polar effect on the synthesis of RNA polymerase factor in E. coli.     

Effect of mutations in Escherichia coli genes PolAm RecA, RecB and RecC on the frequency of genetic recombination in amber-mutants involving the early genes of bacteriophage T4]

Effects of mutations in genes PolA, RecA, RecB and RecC of Escherichia coli on the recombination frequencies between rII markers of T4 have been studied in conditions of partial inhibition of some early functions. It was found that the presence of the mutations in genes PolA or RecA decreased significantly the recombination frequency of phage amber mutant in the gene 43 (DNA polymerase), increased it in the case of amber mutation in the gene 46 (exonuclease) and had no effect on the recombination of amber mutants in genes 30, 32, 33, 41, 42, 45, 44, 52. None of the amber mutants studied changed recombination frequencies in the presence of the mutations in genes RecB or RecC. Possible mechanisms of some of the effects observed are discussed.