Multiple sites of action of cycloheximide in addition to inhibition of protein synthesis in Physarum polycephalum

The specificity of action of cycloheximide was tested using a cycloheximide resistant mutant of Physarum polycephalum. This resistance has previously been shown to reside with the ribosomes, making cytoplasmic protein synthesis refractile to the action of the drug. We show here that cycloheximide in the mutant strain causes specific alterations in metabolism without influencing the growth rate. These are: 1. lowered specific activity of glutamate dehydrogenase during starvation, 2. alteration of the molecular weight of glutamate dehydrogenase, 3. inhibition of uptake of amino acids from the medium into the internal pools. Possible explanations for these effects of cycloheximide outside of protein synthesis per se are considered. We conclude that cycloheximide may not be considered a specific inhibitor of protein synthesis, and that a causal relationship between protein synthesis and any biological process cannot be claimed unless such specificity is demonstrated in each case, preferably by use of mutants.     

An alkaline sucrose gradient analysis of the mechanism of nuclear DNA synthesis in the yeast Saccharomyces cerevisiae.

Summary Mutants of Schizosaccharomyces pombe were isolated as resistant either to trichodermin or to anisomycin. Growth tests showed that the majority of mutants isolated were cross resistant to both drugs and also to cycloheximide. A limited genetic analysis showed that mutants at least four loci, tri3, tri4, ani1 and ani2, had this phenotype as was also the case for mutants at three cycloheximide resistant loci, cyh2, cyh3 and cyh4 reported previously (Ibrahim and Coddington, 1976). Allelism tests showed that the tri3, ani2 and cyh4 strains were allelic. A mutant at another trichodermin resistant locus, tri5, was cross resistant to anisomycin but sensitive to cycloheximide.Ribosomes from wild type and selected strains were analysed in a poly U directed cell free protein synthesising system. Three strains, cyh1-C7, ani1-F1 and tri-N15 (probably a tri5 allele) possessed ribosomes which were more resistant than the wild type to the drugs used in their isolation. In each case the site of the resistance was in the 60S subunit. Ribosomes from the cyh2, cyh3 and cyh4 strains were as sensitive to cycloheximide as those from wild type.     

Genetic Analysis of Copper Resistance in PARAMECIUM AURELIA Syngen 4

Measurement of the median tolerance limit to cupric ion of 28 wild stocks of Paramecium aurelia syngen 4 revealed a phenotypic polymorphism: two stocks showed a much greater resistance than the others. Genetic analysis showed the resistant phenotype was produced by a recessive allele, cur, identical in both resistant wild stocks. No modification of the phenotypic expression of this allele could be detected after backcrossing into different genetic backgrounds. The results are interpreted to support the importance of mutational adaptation in this inbreeding species. Possible patterns of internal genetic organization of species which rely on mutation for adaptation are discussed.     

一株污水源多重耐药大肠杆菌的耐药性检测及全基因组测序分析

【背景】水体环境分布广、流动性强,是耐药菌和耐药基因传播的主要媒介。【目的】了解北方污水厂大肠杆菌携带的耐药基因及可移动遗传元件情况。【方法】从北方污水厂筛选出一株多重耐药大肠杆菌,通过药敏试验进行耐药性检验,采用96孔板法测定菌株的最小抑菌浓度,利用酶标仪探究亚抑菌浓度抗生素对菌株生长的影响,并对菌株进行全基因组测序,对其携带的耐药基因及可移动遗传元件进行预测。【结果】大肠杆菌WEC对四环素、环丙沙星、诺氟沙星和红霉素具有耐药性,亚抑菌浓度的四环素、环丙沙星和诺氟沙星能够延缓或抑制菌株的生长。WEC菌株的基因组中包含一条大小为4 782 114 bp的环状染色体和2个大小分别为60 306 bp (pWEC-1)和92 065 bp (pWEC-2)的环状质粒。菌株共携带129个耐药基因,其中128个位于染色体上,在染色体上预测到原噬菌体、基因岛及插入序列的存在,部分可移动遗传元件携带有耐药基因。质粒pWEC-1中无耐药基因,pWEC-2含有1个耐药基因,在质粒基因组中预测到原噬菌体和插入序列。【结论】污水源大肠杆菌WEC是一株多重耐药菌株,其基因组中携带耐药基因和多种可移动遗传元件...     

Identification of Saccharomyces cerevisiae ribosomal protein L3 as a target of curvularol, a G1-specific inhibitor of mammalian cells

The cellular target of curvularol, a G1-specific cell-cycle inhibitor of mammalian cells, was identified by a genetic approach in Saccharomyces cerevisiae. Since the wild-type W303 strain was highly resistant to curvularol, a drug hypersensitive parental strain was constructed in which various genes implicated in general drug resistance had been disrupted. Curvularol resistant mutants were isolated, and strains that exhibited a semi-dominant, curvularol-specific resistance phenotype were selected. All five strains examined were classified into a single genetic complementation group designated YCR1. A mutant gene responsible for curvularol resistance was identified as an allele of the RPL3 gene encoding the ribosomal protein L3. Sequence analysis of the mutant genes revealed that Trp255Cys and Trp255Leu substitutions of Rpl3p are responsible for curvularol resistance. Rpl3p mutants in which Trp255 residue was replaced by other amino acids were constructed. All of these replacements led to varying degrees of increased resistance to curvularol and growth defects.     

Role of ribosomes in cycloheximide resistance of Neurospora mutants

Summary In Neurospora crassa, mutants resistant against cycloheximide appear with a marked time lag after mutation induction. We have suggested (Neuhäuser et al., 1970) that this lag indicates the time needed for the synthesis of altered ribosomes (phenotypic lag), that the drug in the wildtype acts upon the ribosomes, and that resistance is due to alterations in them.By measurements of poly-U directed poly-Phe synthesis on ribosomes of the wildtype and two different cycloheximide resistant mutants in a cell free system it is shown here that mutant ribosomes indeed differ from those of the wildtype. Poly-Phe synthesis on mutant ribosomes proceeds in the presence of the drug, whereas that on wildtype ribosomes is inhibited. This means that the earlier suggestions are correct.Abbreviation CHX cycloheximide     

Transcription of bacteriophage Mu. I. Hybridization analysis of RNA made in vitro

Summary A mutation in the cyR1 gene of the fungus Podospora anserina confers resistance to cycloheximide and leads to an alteration of the 60S ribosomal protein L21 (Bégueret et al. 1977). Nine revertants of this mutant were isolated and the properties of these strains were analyzed. It was found that one revertant strain contains a new mutant form of L21. It is proposed that the cyR1 gene is the structural gene for protein L21 and that the alteration of this protein is responsible for the resistance to cycloheximide in vivo.     

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.     

Selection of a mutant strain of Lipomyces kononenkoae with dextranase synthesis resistant to catabolite repression

A mutant strain of Lipomyces kononenkoae 2896-3 synthesizing dextranase but resistant to catabolite repression was obtained using N-nitroso-N-methylurea treatment. Enzyme biosynthesis in media with dextran and other carbon sources was then characterized. The capacity of the mutant to produce dextranase when grown on hydrolysed corn starch is demonstrated.     

Interactions between viomycin resistance and streptomycin resistance on ribosomes of Mycobacterium smegmatis.

We have investigated the mechanism of the expression of resistance to high levels of viomycin and coresistance to streptomycin in a mutant strain of Mycobacterium smegmatis ATCC 14468 (AC-13) which was obtained by serial transfers of parental cells to media containing increasing concentrations of viomycin. It was shown previously that resistance to viomycin by strain AC-13 was due to an alteration in the 50 S ribosomal subunit (20). However, genetic analysis has shown that mutation in 50 S subunits alone gave only low level resistance to viomycin. When a streptomycin resistant mutation (caused by an alteration in the 30 S subunit) was introduced into the low level viomycin resistant recombinant strains, most of them were highly resistant to viomycin. Some recombinants were resistant to intermediate levels of viomycin, and the remainder were not affected by the introduction of the str^r allele. Studies with in vitro cell-free systems have shown that streptomycin resistant 30 S ribosomal subunits obtained from a high level viomycin resistant recombinant were able to modify the levels of resistance to viomycin expressed by the 50 S ribosomal subunit. These findings provide additional evidence concerning the functional relationship between 30 S and 50 S ribosomal components in ribosomes.     

Janus green resistance in Saccharomyces cerevisiae: interaction of nuclear and cytoplasmic factors.

Summary Janus green B was found to be a specific inhibitor of mitochondrial function in yeast. This is consistent with the Janus green specificity in supravital staining of mitochondria.A mutant of S. cerevisiae resistant to Janus green B was isolated. It shows cross resistance to oligomycin, ethidium bromide and a weak resistance to chloramphenicol. The mutant was found to be sensitive to cycloheximide and erythromycin.Genetic analysis of this mutant showed that mitochondrial genes are not involved in the determination of Janus green resistance. Tetrad analysis suggested that two or more nuclear genes are concerned, but many unusual genetic features suggestive of the involvement of a cytoplasmic element remain to be explained.     

Tagging of genes involved in multidrug resistance in Aspergillus nidulans

We have used a plasmid containing the Neurospora crassa pyr4 gene to transform an Aspergillus nidulans pyrG89 mutant strain in the presence of BamHI, and isolated multidrug-sensitive mutants among the transformants. Using this approach, we hoped to identify genes whose products are important for drug resistance by analyzing gene disruptions that alter the drug sensitivity of the cell. About 1300 transformants isolated following transformation were screened for sensitivity to drugs or various stress agents with different and/or the same mechanism of action. Seventy-seven of these transformants showed sensitivity to at least one drug, while fourteen transformants showed a complex phenotype of sensitivity to different drugs. The pyr4 marker was shown to be tightly linked to the mutant phenotype in only 36% of the pleiotropic mutants analyzed in sexual crosses. Genetic crosses between our multidrug-sensitive transformants and cycloheximide-sensitive and imazalil-resistant mutants of A nidulans were performed to determine whether mutations were present at the same loci. We have shown that the gene imaD that confers resistance to imazalil may also be involved in cycloheximide and hygromycin sensitivity, since this mutation is allelic to scyB (mutant scy290). In addition, the cross between the transformant R223 and the imazalil-resistant mutant ima535 showed that both mutations are in the same complementation group, suggesting that the gene imaG could also be involved in cycloheximide and itraconazole sensitivity. Received: 30 August 1999 / Accepted: 22 February 2000     

Induced Resistance to 6-Methylpurine and Cycloheximide in Tetrahymena. I. Germ Line Mutants of T. THERMOPHILA

Two new mutant lines of Tetrahymena thermophila ( T. pyriformis, syngen 1), each conferring resistance to a different agent, are described. Resistance to cycloheximide and 6-methylpurine are each determined by dominant genes, ChxA2 and Mpr; the traits show phenotypic assortment. The method used to select these mutations, the critical importance of backcrossing to wild type following mutagenesis, and the utility of these marker genes in further mutagenic selection schemes and studies of the sexual cycle of Tetrahymena are noted.     

Isolation and characterization ofPleurotus ostreatus mutant strains resistant to a carboxin-derived fungicide,flutolanil

To develop a dominant genetic marker inPleurotus ostreatus, mutant strains resistant to a carboxin-derived fungicide, flutolanil, were isolated. These mutants included strains which showed resistance to 50-fold higher concentration of fluotolanil than the wild-type strain, even after successive cultivations in the absence of the drug. Dominance of the phenotype was confirmed by back-crossing between the resistant and wild-type monokaryons. The flutolanilresistance was also shown to be stably inherited by the basidiospore-derived progenies of the mutant strains.     

Identification of the ryanodine receptor mutation I4743M and its contribution to diamide insecticide resistance in Spodoptera exigua (Lepidoptera: Noctuidae)

Insect ryanodine receptors (RyRs) are the targets of diamide insecticides. Two point mutations G4946E and I4790M (numbering according to Plutella xylostella, PxRyR) in the transmembrane domain of the insect RyRs associated with diamide resistance have so far been identified in three lepidopteran pests, P. xylostella, Tuta absoluta and Chilo suppressalis. In this study, we identified one of the known RyR target site resistance mutations (I4790M) in a field‐collected population of Spodoptera exigua. The field‐collected WF population of S. exigua exhibited 154 fold resistance to chlorantraniliprole when compared with the susceptible WH‐S strain. Sequencing the transmembrane domains of S. exigua RyR (SeRyR) revealed that the resistant WF strain was homozygous for the I4743M mutation (corresponding to I4790M in PxRyR), whereas the G4900E allele (corresponding to G4946E of PxRyR) was not detected. The 4743M allele was introgressed into the susceptible WH‐S strain by crossing WF with WH‐S, followed by three rounds of backcrossing with WH‐S. The introgressed strain 4743M was homozygous for the mutant 4743M allele and shared about 94% of its genetic background with that of the recipient WH‐S strain. Compared with WH‐S, the near‐isogenic 4743M strain showed moderate levels of resistance to chlorantraniliprole (21 fold), cyantraniliprole (25 fold) and flubendiamide (22 fold), suggesting that the I4743M mutation confers medium levels of resistance to all three diamides. Genetic analysis showed diamide resistance in the 4743M strain was inherited as an autosomal and recessive trait. Results from this study have direct implications for the design of appropriate resistance monitoring and management practices to sustainably control S. exigua.     

Intragenic recombination in the CSR1 locus of Arabidopsis

Four classes of herbicides are known to inhibit plant acetolactate synthase (ALS). In Arabidopsis, ALS is encoded by a single gene, CSR1. The dominant csr1-1 allele encodes an ALS resistant to chlorsulfuron and triazolopyrimidine sulfonamide while the dominant csr1-2 allele encodes an ALS resistant to imazapyr and pyrimidyl-oxy-benzoate. The molecular distance between the point mutations in csr1-1 and csr1-2 is 1369 bp. Here we used multiherbicide resistance as a stringent selection to measure the intragenic recombination frequency between these two point mutations. We found this frequency to be 0.008 ± 0.0028. The recombinant multiherbicide-resistant allele, csr1-4, provides an ideal marker for plant genetic transformation.     

Increase in cell size and acid tolerance response in a stepwise-adapted methicillin resistant <Emphasis Type="Italic">Staphylococcus aureus</Emphasis> mutant

A methicillin-susceptible strain of Staphylococcus aureus (MSSA) showed stepwise adaptation when grown in increasing concentrations of oxacillin, eventually reaching a maximum of 35 μg/ml. The resultant oxacillin resistant mutant strain was stable and did not revert to susceptibility on frequent subculturing. The response of the cells to different concentrations of oxacillin was examined by scanning electron microscopy, which showed that the size of the bacterium increased with increasing concentrations of oxacillin. These changes in cell size were dependent on the concentration of oxacillin and occurred only after addition of non-lethal concentrations. In the presence of lethal concentrations (≥35 μg/ml) that completely inhibited cell growth, the cell sizes were smaller than those of wild-type cells and irregular in shape. This stepwise-adapted methicillin (oxacillin) resistant S. aureus (MRSA) mutant showed a greater acid tolerance response (ATR) to lactic and citric acids than the parent susceptible strain. These data indicates that methicillin resistance alters the morphology and ATR in stepwise-adapted MRSA mutant cells.     

Resistance to l-methionine-S-sulfoximine in Chlamydomonas reinhardtii is due to an alteration in a general amino acid transport system

It was suggested that the mutant ARF1 of Chlamydomonas reinhardtii is resistant to l-methionine-S-sulfoximine (MSX, an irreversible inhibitor of glutamine synthetase, EC 6.3.1.2) because this strain degraded and utilized this compound as a nitrogen source for growth (A.R. Franco et al., 1996, Plant Physiol 110: 1215–1222). Resistance to MSX has now been characterized in a double mutant of this alga, called MPA1, which is resistant to MSX and lacks l-amino acid oxidase (LAO activity, EC 1.4.3.2). Biochemical and genetic evidence indicate that the mutant MPA1 is altered in the same MSX-resistance locus as mutant ARF1. However, mutant MPA1 neither degraded nor utilized MSX as a nitrogen source. This led us to conclude that (i) resistance to MSX is not linked to its utilization, and (ii) that LAO activity accounts for the degradation of MSX in mutant ARF1. Data indicate that C. reinhardtii possesses a broad-specificity carrier system responsible for the transport of arginine and other amino acids, including MSX. We propose that the alteration of this carrier confers resistance to MSX in mutants ARF1 and MPA1. Received: 6 April 1998 / Accepted: 8 June 1998     

Temperature sensitivity of the cdc9-1 allele of Saccharomyces cerevisiae DNA ligase is dependent on specific combinations of amino acids in the primary structure of the expressed protein.

Summary In this study we present the characterization of the temperature-sensitive mutant allele cdc9-1 encoding DNA ligase, of Saccharomyces cerevisiae strain A364A by DNA sequencing. Comparison with the published wild-type sequence from strain SKI revealed 13 nucleotide exchanges between these two sequences, which are derived from non-isogenic genetic backgrounds. Only four of these changes, distributed over the whole coding region, lead to amino acid exchanges in the protein chain. Our analysis of the sequence of the wild-type CDC9 allele from strain A364A revealed differences from the isogenic cdc9-1 allele in only two nucleotides: one silent change and one leading to a single amino acid exchange. The latter is therefore responsible for the temperature-sensitive phenotype. A mosaic protein, in which a region carrying this amino acid exchange has been inserted in place of the corresponding part of CDC9 from the non-isogenic strain SKI, is not temperature sensitive. The exchange of a longer stretch of DNA leading to atteration of three amino acids of the protein compared with the original sequence of SKI is required to obtain a temperature-sensitive DNA ligase in this strain, while in strain A364A a single amino acid change is sufficient for expression of a temperature-sensitive protein.     

Selection and Characterization of Phage-Resistant Mutant Strains of Listeria monocytogenes Reveal Host Genes Linked to Phage Adsorption

Listeria-infecting phages are readily isolated from Listeria-containing environments, yet little is known about the selective forces they exert on their host. Here, we identified that two virulent phages, LP-048 and LP-125, adsorb to the surface of Listeria monocytogenes strain 10403S through different mechanisms. We isolated and sequenced, using whole-genome sequencing, 69 spontaneous mutant strains of 10403S that were resistant to either one or both phages. Mutations from 56 phage-resistant mutant strains with only a single mutation mapped to 10 genes representing five loci on the 10403S chromosome. An additional 12 mutant strains showed two mutations, and one mutant strain showed three mutations. Two of the loci, containing seven of the genes, accumulated the majority (n = 64) of the mutations. A representative mutant strain for each of the 10 genes was shown to resist phage infection through mechanisms of adsorption inhibition. Complementation of mutant strains with the associated wild-type allele was able to rescue phage susceptibility for 6 out of the 10 representative mutant strains. Wheat germ agglutinin, which specifically binds to N-acetylglucosamine, bound to 10403S and mutant strains resistant to LP-048 but did not bind to mutant strains resistant to only LP-125. We conclude that mutant strains resistant to only LP-125 lack terminal N-acetylglucosamine in their wall teichoic acid (WTA), whereas mutant strains resistant to both phages have disruptive mutations in their rhamnose biosynthesis operon but still possess N-acetylglucosamine in their WTA.