Aspartokinase III repression in a thialysine-resistant mutant of E. coli

A thialysine-resistant mutant of the E. coli KL16 strain was isolated. It can grow equally well in the presence and in the absence of thialysine. The properties of the two lysine transport systems, of the lysyl-tRNA synthetase and of the aspartokinase III (AK III) were studied in the mutant and in the parent strain. AK III is the first enzyme of the lysine biosynthetic pathway and its activity is involved in the regulation of lysine biosynthesis by feed-back and repression mechanism. No difference between the two strains was evidenced as regards 1) the affinity of the transport systems for lysine and thialysine 2) the activity of the lysyl-tRNA synthetase 3) the allosteric inhibition of the AK III by lysine and thialysine. A marked difference between the two strains has been evidenced in the AK III repression: in the mutant the enzyme is much less repressed both by lysine and thialysine. The possible correlation between the activity of AK III and the thialysine-resistance is discussed in this paper.     

Thialysine- and selenalysine-resistance in a E. coli mutant

A thialysine-resistant mutant of E. coli strain KL16 also shows a lower sensitivity to selenalysine, the lysine analog containing selenium. No difference between the mutant and the parental strain has been shown regarding the affinities of the transport systems and the lysyl-tRNA synthetase for selenalysine, thialysine and lysine as well as the inhibitory effects of these three aminoacids on the activity of the lysine biosynthetic pathway. A marked difference between the two strains has been evidenced in the AK III repression: in the mutant the repression by selenalysine, thialysine and lysine is much lower than in the parental strain.     

Biochemical characterization of a thialysine-resistant clone of CHO cells

The intracellular transport and the activation of lysine, thialysine and selenalysine have been investigated in a thialysine-resistant CHO cell mutant strain in comparison with the parental strain. The cationic amino acid transport system responsible for the transport of these 3 amino acids shows no differences between the 2 strains as regards its affinity for each of these amino acids. On the other hand the Vmax of the transport system in the mutant is about double that in the parental strain. The lysyl-tRNA synthetase, assayed both as ATP = PPi exchange reaction and lysyl-tRNA synthesis, shows a lower affinity for thialysine and selenalysine than for lysine in both strains; in the mutant, however, the difference is even greater. Thus the thialysine resistance of the mutant is mainly due to the properties of its lysyl-tRNA synthetase, which shows a greater difference of the affinities for lysine and thialysine with respect to the parental strain.     

The role of glutathione biosynthesis in heavy metal resistance in the fission yeast Schizosaccharomyces pombe

Abstract: Plants and the fission yeast Schizosaccharomyces pombe synthesize small cadmium-binding peptides, called phytochelatins, in response to cadmium. Derived from glutathione (GSH: λ-Glu-Cys-Gly), they have the general structure (λ-Glu-Cys) n Gly, where n is 2–11. In order to study the biosynthesis of phytochelatins, we used the mutagen N -methyl- N '-nitro- N nitrosoguanidine (MNNG) to select mutants with a lowered GSH content. GSH-deficient mutants show a Cd-sensitive phenotype, whereas resistance to Cu is only slightly influenced. These Cd-sensitive mutants contain 2–15% of the wild-type GSH level. For three mutants a lowered activity of λ-glutamylcysteine synthetase was measured. One of the mutants was transformed to Cd-resistance and the complementing fragment was analyzed further. The complementing fragment hybridized with chromosome III. In the transformants, GSH content was restored up to wild-type levels, whereas the activity of λ-glutamylcysteine synthetase was significantly increased compared with the wild-type. Possible mechanisms for Cd-resistance in the transformants are discussed.     

Inhibition of growth and aspartokinase activity of Salmonella typhimurium by thialysine

Thialysine (S-2-aminoethyl cysteine) is an analog of lysine and has been reported to inhibit the lysyl-tRNA synthetase activity of Escherichia coli. This analog inhibits the growth of Salmonella typhimurium when added to glucose minimal medium at concentrations of 1.25 mM or greater. The addition of lysine with thialysine restores the normal growth rate, whereas, methionine, valine, or leucine each enhances the growth inhibition caused by thialysine. Enzyme assays demonstrate that thialysine inhibits not only the lysyl-tRNA synthetase from S. typhimurium, but also the aspartokinase activity. Lysine and thialysine appear to inhibit the same 40% of the total aspartokinase because simultaneous addition of the two compounds to the reaction mixture does not increase the inhibition caused by either alone. Furthermore, the slow growth of cells in the presence of 2.5 mM thialysine decreases the level of aspartokinase activity, suggesting that thialysine causes repression of enzymes synthesis as well as inhibition of activity.     

Inhibition of growth and aspartokinase activity of Salmonella typhimurium by thialysine.

Thialysine (S-2-aminoethyl cysteine) is an analog of lysine and has been reported to inhibit the lysyl-tRNA synthetase activity of Escherichia coli. This analog inhibits the growth of Salmonella typhimurium when added to glucose minimal medium at concentrations of 1.25 mM or greater. The addition of lysine with thialysine restores the normal growth rate, whereas, methionine, valine, or leucine each enhances the growth inhibition casued by thialysine. Enzyme assays demonstrate that thialysine inhibits not only the lysyl-tRNA synthetase from S. typhimurium, but also the aspartokinase activity. Lysine and thialysine appear to inhibit the same 40% of the total aspartokinase because simultaneous addition of the two compounds to the reaction mixture does not increase the inhibition caused by either alone. Furthermore, the slow growth of cells in the presence of 2.5 mM thialysine decreases the level of aspartokinase activity, suggesting that thialysine causes repression of enzyme synthesis as well as inhibition of activity.     

Isolation of glutathione-deficient mutants of the yeast Saccharomyces cerevisiae

Glutathione-deficient (gsh-) mutants of the yeast Saccharomyces cerevisiae were isolated after UV treatment using MNNG as selective agent. For genetic and biochemical characterization 5 mutant strains were chosen which exhibited considerably decreased residual GSH contents varying from 2 to 6% of the wild-type levels. All 5 isolates showed a 2:2 segregation of the gsh-:GSH+ phenotypes alluding to a monogenic recessive mutation. Complementation analysis indicates that all gsh- mutants belong to one complementation group.     

Two modes of metabolic regulation of lysyl-transfer ribonucleic acid synthetase in Escherichia coli K-12.

Lysyl-transfer ribonucleic acid (tRNA) synthetase activity was compared in three independently isolated Escherichia coli K-12 mutants of the enzyme S-adenosyl-L-methionine synthetase (metK mutants) and their isogenic parents. In all three cases the activity of the lysyl-tRNA synthetase was elevated two- to fourfold in the mutant strains. Glycyl-L-leucine (3 mM) usually enhanced lysyl-tRNA synthetase activity two- to threefold in wild-type cells but did not further stimulate the synthetase activity in metK mutants. By two other criteria, the lysyl-tRNA synthetase from wild-type cells grown with the peptide and from the metK mutant RG62, grown in minimal medium, were similar. These criteria are enhanced resistance to thermal inactivation and altered susceptibility to endogenous proteases when compared with the synthetase from wild-type cells grown in minimal medium. In a separate set of experiments, the activities of the lysyl-, arginyl-, seryl-, and valyl-tRNA synthetases were measured in an isogenic pair of relt and rel strains of E. coli grown in a relatively poor growth medium (acetate) and in enriched medium. In the rel+ strain the level of all four synthetases was higher (two- to fourfold) in the enriched medium as expected. In the rel strain the difference in the activities of the synthetases between the two media were diminished. In all four cases the activities of the synthetases were higher in acetate medium in the rel strain. Evidence is presented that these two modes of metabolic regulation act independently.     

Escherichia coli K-12 lysyl-tRNA synthetase mutant with a novel reversion pattern

Fast-growing revertants have been selected from a slow-growing lysyl-tRNA synthetase mutant. All of the revertants had increased lysyl-tRNA synthetase activity compared with the mutant (5- to 85-fold), and in some revertants this amounted to two to three times the wild-type synthetase activity. Two-dimensional gel electrophoresis of a whole-cell extract of revertant IH2018 (1.5- to 2-fold wild-type synthetase activity) showed that the increase in synthetase activity is due to the induction of cryptic lysyl-tRNA synthetase forms and not to a change in the constitutive lysyl-tRNA synthetase. Genetic studies have shown that a locus termed rlu (for regulation of lysU ) which is cotransducible with purF at 49.5 min influences the amount of the cryptic lysyl-tRNA synthetase.     

Defects of two temperature-sensitive lysyl-transfer ribonucleic acid synthetase mutants of Bacillus subtilis

Two temperature-sensitive mutants (lysS1 and lysS2) of the lysyl-transfer ribonucleic acid synthetase (l-lysine:tRNA ligase [adenosine 5'-monophosphate], EC 6.1.1.6) of Bacillus subtilis have been isolated. Although protein synthesis is inhibited in both mutants at the restrictive temperature (42 to 45 C), the mutants remain viable in a minimal medium. In comparison with the wild-type lysyl-tRNA synthetase, the l-lysine-dependent exchange of [(32)P]pyrophosphate with adenosine 5'-triphosphate (ATP) for both mutant enzymes is decreased. The lysS1 enzyme is completely defective in the ATP-dependent attachment of l-lysine to tRNA, whereas the lysS2 enzyme has 3- to 10-fold reduced levels of this activity. Temperature-resistant transformants have wild-type enzyme levels, whereas partial revertants to temperature resistance have varied levels of enzyme activity. The attachment and exchange activities of the lysS2 enzyme are more heat labile in vitro than the wild-type enzyme, as is the attachment activity of a partial revertant of the lysS1 mutant. The lysS1 and the lysS2 lysyl-tRNA synthetases have higher apparent K(m) values for lysine and ATP, in both the activation and the attachment reactions. The lysS2 enzyme has a V(max) for tRNA(lys) one-third that of the wild-type enzyme. Molecular weights of approximately 150,000 for the wild-type and lysS2 enzymes and approximately 76,000 for the lysS1 enzyme were estimated from sedimentation positions in sucrose density gradients assayed by the ATP-pyrophosphate exchange activity. We propose that the two mutations (lysS1 and lysS2) directly affect the sites for exchange activity, but indirectly alter attachment activity as a consequence of defective subunit association.     

Isolation and properties of Bacillus brevis mutants unable to produce tyrocidine.

Mutants of Bacillus brevis ATCC 10068 were isolated which produced less than 1/100 of the amount of tyrocidine produced by the parent strain. These mutants produced spores at the same frequency and which were as resistant to heating at 80 degrees C for up to 3 h as were those produced by the parent strain. A partially purified tyrocidine synthetase from strain ATCC 10068 catalyzed [32P]PPi-ATP exchange reactions dependent on added tyrocidine-constituent amino acids. These activities were separated into three groups (I, II, and III) by fractionation on an Ultrogel AcA34 column. Each group was similar to one of the three components (heavy, intermediate, and light, respectively) found previously for strain ATCC 8185 except that glutamate-dependent activity was not detected in the group I activities and some amino acyl-tRNA synthetase activities were associated with the group III activities. Some of the mutants were shown to have defective tyrocidine synthetase enzymes. Mutant BH30 was defective in two of the group II amino acid-dependent [32P]PPi-ATP exchange reactions, mutant BH16 was defective in one of the group I and one of the group II reactions, and mutant BH34 had alterations to activities in all of the groups. It is unlikely that any of these mutants could synthesise tyrocidine. We conclude that tyrocidine is not involved in either the sporulation process or the resistance of spores of B. brevis ATCC 10068 to heating at 80 degrees C for up to 3 h.     

Characterization of a Schizosaccharomyces pombe morphological mutant altered in the galactomannan content

In a search for Schizosaccharomyces pombe mutants resistant to the antifungal agent papulacandin B, a morphological mutant was isolated. The mutant is round shaped in contrast to the rod shaped parental strain. This morphological defect segregated as a recessive Mendelian character and was not observed in other papulacandin B resistant mutants belonging to the same complementation group. The mutation mapped in the right arm of S. pombe chromosome III very close to pap1 marker. Mutant cell walls were more susceptible to alkali extraction and Novozyme degradation than those from the wild-type. A specific reduction in the cell wall galactomannan fraction was the only significant difference detected as compared to the wild-type strain. Levels of beta (1,3)-glucan and mannan synthases as well as other enzymic periplasmic mannoproteins were very similar in wild type and mutant strains.     

Isolation of Saccharomyces cerevisiae Mutants Defective in Acyl Coenzyme A Synthetase

Mutants of Saccharomyces cerevisiae defective in acyl-CoA synthetase (EC 6.2.1.3) were isolated. The mutants were concentrated by the radiation-suicide technique with the use of tritiated palmitic acid. Selection of the mutants was based on the premise that acyl-CoA synthetase activity would become indispensable when yeast cells in which fatty acid synthesis de novo is blocked are grown in a medium supplemented with fatty acid. The mutant strains isolated exhibited low acyl-CoA synthetase activity in vitro. Furthermore, they accumulated markedly more of the incorporated palmitic acid in the nonesterified form than did the wild- type strain. Some of the mutants showed thermosensitive acyl-CoA synthetase activity, indicating a mutation of the structural gene of the enzyme. Genetic studies on these mutants indicated that their phenotype resulted from a single, recessive mutation of a nuclear gene, designated faa 1 (fatty acid activation).     

Nikkomycin-resistant mutants ofMucor rouxii: physiological and biochemical properties

We isolated three nikkomycin-resistant mutants of the dimorphic fungusM. rouxii which were physiologically characterized regarding their response to yeast-phase inducing conditions and their sensitivity to bacilysin. Mutant strains G21 and G23, showed a qualitatively normal, though delayed, dimorphic transition and partial cross-resistance to bacilysin. Mutant strain G27 showed an altered dimorphism, producing a high proportion (50%) of hyphal cells, and a wild-type sensitivity to bacilysin. Cell-free extracts from this mutant exhibited an activity of both basal and protease-activated chitin synthetase which was overexpressed as compared with the parental strain and mutants G21 and G23. Results are discussed in terms of the different genetic background of the mutants.Abbreviations NTG N-methyl-N-nitro-N-nitrosoguanidine - UDP-GlcNAc uridine 5-diphospho-N-acetylglucosamine - GlcNAc N-acetylglucosamine     

Biochemical and genetic characterization of three hamster cell mutants resistant to diphtheria toxin

We describe here three different hamster cell mutants which are resistant to diphtheria toxin and which provide models for investigating some of the functions required by the toxin inactivates elongation factor 2 (EF-2). Cell-free extracts from mutants Dtx(r)-3 was codominant. The evidence suggests that the codominant phenotype is the result of a mutation in a gene coding for EF-2. The recessive phenotype might arise by alteration of an enzyme which modifies the structure of EF-2 so that it becomes a substrate for reaction with the toxin. Another mutant, Dtx(r)-2, contained EF-2 that was sensitive to the toxin and this phenotype was recessive. Pseudomonas aeruginosa exotoxin is known to inactivate EF-2 as does diphtheria toxin and we tested the mutants for cross-resistance to pseudomonas exotoxin. Dtx(r)-1 and Dtx(r)-3 were cross-resistant while Dtx(r)-2 was not. It is known that diphtheria toxin does not penetrate to the cytoplasm of mouse cells and that these cell have a naturally occurring phenotype of diphtheria toxin resistance. We fused each of the mutants with mouse 3T3 cells and measured the resistance. We fused each of the mutants with mouse 3T3 cells and measured the resistance of the hybrid cells to diphtheria toxin. Intraspecies hybrids containing the genome of mutants Dtx(r)-1 and Dtx(r)-3 had some resistance while those formed with Dtx(r)-2 were as sensitive as hybrids derived from fusions between wild-type hamster cells and mouse 3T3 cells.     

Dominant-and-recessive epistasis in a homeotic mosquito mutant.

Following selection for 15 generations a pure strain of a homeotic mutant spur was isolated from a Brazilian population of the mosquito Culex pipiens fatigans. Monohybrid crosses showed a 13:3 segregation indicating dominant-and-recessive epistasis for wild-type vs. spur. This implies that a dominant allele at one locus and a recessive at the other interact to produce the mutant phenotype. Dihybrid crosses with linkage group II markers yellow and ruby gave 39:13:9:3 ratios indicating independent segregation. However, the dihybrid cross with linkage group I marker maroon showed a highly significant departure from 39:13:9:3 ratio. Data available indicate that the phenotype spur is controlled by a dominant epistat in linkage group III and a recessive epistat (approximately 31.9 crossover units from maroon) in linkage group I.     

Isolation and characterization of Schizosaccharomyces pombe mutants defective in cell wall (1-3)beta-D-glucan.

Schizosaccharomyces pombe thermosensitive mutants requiring the presence of an osmotic stabilizer to survive and grow at a nonpermissive temperature were isolated. The mutants were genetically and biochemically characterized. In all of them, the phenotype segregated in Mendelian fashion as a single gene which coded for a recessive character. Fourteen loci were defined by complementation analysis. Studies of cell wall composition showed a reduction in the amount of cell wall beta-glucan in three strains (JCR1, JCR5, and JCR10) when growing at 37 degrees C. Galactomannan was diminished in two others. Strains JCR1 and JCR5, with mutant alleles cwg1-1 and cwg2-1, respectively, were further studied. The cwg1 locus was mapped on the right arm of chromosome III, 18.06 centimorgans (cM) to the left of the ade5 marker; cwg2 was located on the left arm of chromosome I, 34.6 cM away from the aro5 marker. (1-3)beta-D-Glucan synthase activities from cwg1-1 and cwg2-1 mutant strains grown at 37 degrees C were diminished, as measured in vitro, compared with the wild-type strain; however, Km values and activation by GTP were similar to the wild-type values. Mutant synthases behaved like the wild-type enzyme in terms of thermostability. Analyses of round shape, lytic behavior, and low (1-3)beta-D-glucan synthase activity in cultures derived from ascospores of the same tetrad showed cosegregation of all these characters. Detergent dissociation of (1-3)beta-D-glucan synthase into soluble and particulate fractions and subsequent reconstitution demonstrated that the cwg1-1 mutant was affected in the particulate fraction of the enzymatic activity while cwg2-1 was affected in the soluble component. The antifungal agents Papulacandin B and Aculeacin A had similar effects on the enzymatic activities of the wild type and the cwg2-1 mutant strain, whereas the cwg1-1 mutant, when growing at 37 degrees C, had a more inhibitor-resistant (1,3)beta-D-glucan synthase. It is concluded that the cwg1+ and cwg2+ genes are related to (1,3)beta-D-glucan biosynthesis.     

Effect of mutations affecting lysyl-tRNAlys on the regulation of lysine biosynthesis in Escherichia coli.

Summary When studying mutants affecting lysyl-tRNA synthetase or tRNA^Lys (hisT, hisW), a lack of correlation is clearly observed between the amount of lysyl-tRNA and the level of derepression of several lysine biosynthetic enzymes. This excludes the possible role of lysyl-tRNA as the specific corepressor of the lysine regulon. However, the level of derepression of DAP-decarboxylase, the last enzyme of the lysine pathway, is very low in the hisT mutant; this indicates that tRNA^Lys is a secondary effector involved in the regulation of the synthesis of this enzyme.Abbreviations DAP diaminopimelate - KRS lysyl-tRNA synthetase - L-lysine tRNA ligase (AMP) (EC6.1.16) - AK III lysinesensitive aspartokinase (EC 2.7.24) - ASA-dehydrogenase aspartic semialdehyde dehydrogenase (EC 1.2.1.10) - DHDP-reductase dihydrodipicolinic acid reductase - DAP-decarboxylase diaminopimelate decarboxylase (EC 4.1.1.20) - AK I threonine-sensitive aspartokinase - HDHI threonine-sensitive homoserine dehydrogenase     

Role of the Escherichia coli glnALG operon in regulation of ammonium transport.

Escherichia coli expresses a specific ammonium (methylammonium) transport system (Amt) when cultured with glutamate or glutamine as the nitrogen source. Over 95% of this Amt activity is repressed by growth of wild-type cells on media containing ammonia. The control of Amt expression was studied with strains containing specific mutations in the glnALG operon. GlnA- (glutamine synthetase deficient) mutants, which contain polar mutations on glnL and glnG genes and therefore have the Reg- phenotype (fail to turn on nitrogen-regulated operons such as histidase), expressed less than 10% of the Amt activity observed for the parental strain. Similarly, low levels of Amt were found in GlnG mutants having the GlnA+ Reg- phenotype. However, GlnA- RegC mutants (a phenotype constitutive for histidase) contained over 70% of the parental Amt activity. At steady-state levels, GlnA- RegC mutants accumulated chemically unaltered [14C]methylammonium against a 60- to 80-fold concentration gradient, whereas the labeled substrate was trapped within parental cells as gamma-glutamylmethylamide. GlnL Reg- mutants (normal glutamine synthetase regulation) had less than 4% of the Amt activity observed for the parental strain. However, the Amt activity of GlnL RegC mutants was slightly higher than that of the parental strain and was not repressed during growth of cells in media containing ammonia. These findings demonstrate that glutamine synthetase is not required for Amt in E. coli. The loss of Amt in certain GlnA- strains is due to polar effects on glnL and glnG genes, whose products are involved in expression of nitrogen-regulated genes, including that for Amt.     

Identification of novel single amino acid changes that result in hyperactivation of the unique GTPase, Rheb, in fission yeast

Rheb GTPase is a key player in the control of growth, cell cycle and nutrient uptake that is conserved from yeast to humans. To further our understanding of the Rheb pathway, we sought to identify hyperactivating mutations in the Schizosaccharomyces pombe Rheb, Rhb1. Hyperactive forms of Rhb1 were found to result from single amino acid changes at valine-17, serine-21, lysine-120 or asparagine-153. Expression of these mutants confers resistance to canavanine and thialysine, phenotypes which are similar to phenotypes exhibited by cells lacking the Tsc1/Tsc2 complex that negatively regulates Rhb1. The thialysine-resistant phenotype of the hyperactive Rhb1 mutants is suppressed by a second mutation in the effector domain. Purified mutant proteins exhibit dramatically decreased binding of GDP, while their GTP binding is not drastically affected. In addition, some of the mutant proteins show significantly decreased GTPase activities. Thus the hyperactivating mutations are expected to result in an increase in the GTP-bound/GDP-bound ratio of Rhb1. By using the hyperactive mutant, Rhb1(K120R), we have been able to demonstrate that Rhb1 interacts with Tor2, one of the two S. pombe TOR (Target of Rapamycin) proteins. These fission yeast results provide the first evidence for a GTP-dependent association of Rheb with Tor.