Auxotrophic mutants in the selection of the rubomycin producer, Actinomyces coeruleorubidus

A total of 351 auxotrophic mutants with different antibiotic activity, including several mutants with activity higher than that of the parent prototrophic strains were obtained under the effect of gamma-rays from 3 prototrophic strains of Act. coeruleorubidus. It was shown that most of the auxotrophic mutants did not preserve the property of biochemical insufficiency on passages on complete media. A mutant strain 1059-32 with activity 2 times higher than that of the prototrophic strain 2-39 and the parent auxotrophic culture was obtained from the revertants. Requirements in 29 growth factors including 17 amino acids, 4 nitrous bases, 8 vitamins and coenzymes were determined in 46 stable auxotrophic mutants isolated. The effect of the specific and non-specific growth factors on the culture antibiotic production was studied.     

Biochemical mutants of Actinomyces griseus, a producer of the antibiotic grisin. The isolation of the mutants and a study of the level of grisin antibiotic synthesis]

Biochemical mutants of Actinomyces griseus producing grisin were obtained under the action of chemical mutagens. The mutants were divided into 2 groups. The mutants with impaired synthesis of amino acids of the aspartic acid family, i.e. lysine, homoserine and methionine were included into the 1st group. The 2nd group included the mutants with impaired synthesis of the other amino acids, i.e. histidine, arginine, tyrosine, phenylalanine and valine. The antibiotic production level in the biochemical mutants was studied. It was found that the level of the antibiotic production was decreased in most of the biochemical mutants. A necessity for increased fonds of lysine and arginine for biosynthesis of grisin was shown.     

Mutagenesis in Streptomycete cultures exposed to bleomycin

Mutagenic properties of bleomycin, an antitumor antibiotic were studied with respect to 2 species of streptomycetes producing practically important antibiotics. A multifold increase in the frequency of prototrophic revertants among the survivors of strains His- and Met- of Actinomadura carminata exposed to bleomycin was observed. Bleomycin was effective in induction of various morphological mutants, and auxotrophs at a high survival rate of the spores of Str. cremeus var. tobramycini, a tobramycin-producing organism. It was shown with the method of subsequent mutagenesis that the efficacy of induction of morphological and auxotrophic mutants in germinating spores of Actinomadura carminata, a carminomycin-producing organism by bleomycin in a concentration of 100 micrograms/ml and an exposure time of 5 minutes was much higher that in the latent spores. The mutagenic effect of bleomycin is comparable with that of ionizing radiation.     

Penicillin formation by biochemical mutants of Penicillium chrysogenum and their spontaneous revertants

The capacity for the antibiotic production in the auxotrophs of Penicillium chrysogenum with various deficiency and their revertants was studied. It was found that the capacity for penicillin synthesis was impaired to various degrees in the majority of the auxotrophs. Variants with the penicillin production levels by 13--20 per cent higher than those in the initial prototrophic strain were isolated for the first time in selection of the eukaryotes with the method of obtaining highly active revertants from auxotrophs according to the scheme "prototroph-auxotroph-prototroph".     

Effect of mutagenic factors on the variability of cultures of Actinomyces griseus--preducer of the antibiotic grisin

The study of the lethal and mutagenic effect of ethylenimine, nitrozoguanidine, nitrozomethylurea and nitrozoethylurea on Act. griseus Krainsky 15, producing grisin, an antibiotic widely used in agriculture as a stimulator of domestic animal growth showed that induction of mutants with increased antibiotic production levels was most favourable under the effect of ethylenimine. The above mutagens were highly active with respect to induction of morphological mutants. No clear correlation between the colony morphology and antibiotic production property was observed. However, it was noted that the dwarf colonies had a significantly decreased antibiotic activity.     

Cloning of grisin resistance gene gsr and the study of its functioning in Streptomyces griseus Kr. strain

S. griseus Kr. is a commercial strain producing grisin, an antibiotic of the streptothricin group used as a feed additive. It was shown earlier that genetic instability of the strain was very high which was evident from a high frequency of nonreverting Grn- Grns mutants. With densitographic analysis of chromosomal DNA electrophoregrams and DNA-DNA hybridization it was revealed that the molecular basis of the genetic instability of the S. griseus strain was deletion of a DNA fragment about 20 kb in size containing a grisin resistance gene. The resistance gene designated as gsr was cloned to S. lividans TK 64 within the plasmid vector pIJ699. The restriction map of a cloned DNA fragment with a gsr gene was constructed and its similarity to that of a nat gene resistant to norseothricin, another streptothricin was observed. Introduction of a gsr gene within the multicopy plasmid pIJ699 into S. griseus 212, a highly productive strain synthesiing the antibiotic, led to an increase in its resistance and productivity. Proceeding from the preliminary data on possible linkage of a gsr gene and grisin biosynthesis genes, it appeared possible to use the cloned gene as a molecular probe in cloning the biosynthesis genes.     

Symbiotic properties of adenine requiring mutants of Rhizobium meliloti strain L5-30

From the effective and prototrophic Rhizobium meliloti strain L5-30 two auxotrophic mutants were isolated: RM4 and RM221. These two mutants required adenine and adenine with thiamine for their growth, respectively. Both mutants nodulated lucerne plants ineffectively. Electron microscopic observations of the nodule tissue showed that its cells were not occupied by bacteria. Prototrophic revertants and transductants of these mutants showed high symbiotic effectiveness. It is assumed that adenine or adenine and thiamine requirements made impossible release of bacteria from the infection thread.     

Auxotrophic mutations related to symbiotic properties of Rhizobium meliloti strain L5-30.

Mutants isolated from effective R. meliloti strain L5-30 which required histidine (his-240), arginine+uracil (arg-55) and cysteine (cys-243, cys-244 and cys-246) showed also loss of effectiveness. Mutant requiring isoleucine+valine (ilv-74) was non-infective. Relation of the metabolic deficiency to the symbiotic properties of these mutants was tested comparing symbiotic response of their prototrophic revertants and transductants. It was found that all revertants and transductants of the strain his-240 were effective which suggests that histidine deficiency was the cause of their ineffectiveness. All revertants and transductants of the cysteine mutants were still ineffective. This result indicates two independent mutations which were not cotransductible. Prototrophic revertants of the mutant arg-55 were ineffective whereas 56.9 percent of transductants appeared effective suggesting close linkage of two mutations. i.e. auxotrophic and the other concerned with symbiotic effectiveness. Though one of 69 prototrophic transductants obtained from the non-nodulating mutant ilv-74 remained non-nodulating, it seems that changes in nodulating ability of the mutant are related to the auxotrophic requirements.     

Intraspecific heterokaryon and fruit body formation in Coprinus macrorhizus by protoplast fusion of auxotrophic mutants

Summary Fusion of protoplasts of Coprinus macrorhizus mutants with different amino acid requirements resulted in the production of prototrophic clones at frequencies of 1–4% of the protoplasts surviving the fusion treatment. The frequencies were at least 200 times higher than those of the appearance of revertants. Few prototrophic colonies appeared also when the mutant protoplasts were individually subjected to fusion treatment, or when they were mixedly cultured without fusion treatment. It was thus concluded that intraspecific heterokaryons were formed by protoplast fusion.The auxotrophic mutants did not form fruit bodies when cultured singly or mixedly with each other. In contrast, the heterokaryons produced by protoplast fusion between the mutants of compatible mating types developed into fruit bodies with intermediate morphology of those of the strains from which the mutants were derived. Heterokaryons were also formed by fusion of mutant protoplasts with identical mating genotype, but they failed to form fruit bodies.Abbreviations PEG polyethyleneglycol - HEPES N-2-hydroxyethylpiperazine-N-2-ethane sulfonic acid     

Action of grisin on the variability of an Acinomyces griseus culture and the use of the same antibiotic as a selection agent in the selection of active variants]

The effect of grisin on survival and variation of Actinomyces griseus producin grisin was studied. The efficiency of various concentrations of grisin on induction of variation according to the feature of the antibiotic production was compared. A possibility of increasing the productivity of strain. VNIIGenetics-115 by the use of the mutations of resistance to grisin is shown.     

Improved Inosine Production and Derepression of Purine Nucleotide Biosynthetic Enzymes in 8-Azaguanine Resistant Mutants of Bacillus subtilis

Improved inosine producers were found with a high frequency among the mutants resistant to a low concentration of 8-azaguanine derived from AMP deaminase negative adenine auxotrophs of Bacillus subtilis K strain. The best mutant accumulated 16~18 g/liter of inosine, 60~80% higher than the parent. PRPP amidotransferase and succino-AMP lyase of all of the improved inosine producers tested were not repressed by adenosine but still repressed by guanosine. Adenine permeability was suggested to be also altered in some of the mutants which produced inosine even in the presence of a high concentration of adenine. Adenine prototrophic revertants from all of the mutants tested accumulated a small amount of adenosine but not inosine.     

General control of amino acid biosynthesis in mutants of Candida spec. EH 15/D

The general control of amino acid biosynthesis was investigated in Candida spec. EH 15/D, using single and double mutant auxotrophic strains and prototrophic revertants starved for their required amino acids. These experiments show that starvation for lysine, histidine, arginine, leucine, threonine, proline, serine, methionine, homoserine, asparagine, glutamic acid or aspartic acid can result in derepression of enzymes. A correlation was found between the degree of derepression, growth of strains, and concentration of required amino acids. The amino acids pool pattern of mutants and revertants is different from that in the wild type strain.     

Genetic and biochemical study of threonine-overproducing mutants of Saccharomyces cerevisiae.

Three threonine-overproducing mutants were obtained as prototrophic revertants of a hom3 mutant strain of Saccharomyces cerevisiae. The gene HOM3 codes for aspartokinase (aspartate kinase; EC 2.7.2.4), the first enzyme of the threonine-methionine biosynthetic route, which is subjected to feedback inhibition by threonine. Enzymatic studies indicated that aspartokinase from the revertants has lost the feedback inhibition, resulting in overproduction of threonine. These revertants also bore one or two additional mutations, named tex1-1 and tex2-1, which alone or jointly made possible the excretion of the threonine accumulated. The effect of these two genes on excretion is potentiated by excess inositol in the medium.     

Recombination analysis of naturally diploid Candida albicans.

A multiply auxotrophic strain, hOG45, was derived from Candida albicans ATCC 10261. Prototrophic revertants of this multiple auxotroph were selected after mutagenesis. These prototrophic revertants were distinguishable from the original prototroph, ATCC 10261, because of their mitotic instability. They gave rise to auxotrophic derivatives which displayed one or more of the auxotrophic requirements characteristic of hOG45. Two of the auxotrophic requirements, those for adenine and methionine, frequently reappeared together in the auxotrophic derivatives of the prototrophic revertants. This apparent linkage of ade and met was confirmed by protoplast fusion analysis of the original auxotroph. These data indicate that C. albicans ATCC 10261 is diploid, the multiple auxotroph h0G45 is homozygous for recessive auxotrophic alleles, the prototrophic revertants are multiple heterozygotes, the auxotrophic derivatives are homozygotes produced by mitotic crossing-over, and the association between the ade and met alleles is due to linkage.     

Pectinolytic activity of revertants of auxotrophic strains of Aspergillus niger

From conidia of 4 different auxotrophic A. niger strains 400 spontaneous revertants (100 from each strain) were obtained, and in one case additionally 100 revertants induced by mutagens (UV+NTG). The revertants showed a considerable differentiation with regard to the total pectinolytic activity. Its highest increase occurred in revertants originating from auxotrophs greatly predisposed to synthesize pectinases. In the case of revertants induced by mutagenes an increase in the frequency of their formation was observed, as well as an increased participation of revertants with higher pectinolytic activity compared to both their initial auxotrophic and prototrophic strain.     

Escherichia coli Mutants Overproducing Phenylalanyl- and Threonyl-tRNA Synthetase

The structural genes for threonyl-tRNA synthetase (ThrRS) and phenylalanyl-tRNA synthetase (PheRS) are closely linked on the Escherichia coli chromosome. To study whether these enzymes share a common regulatory element, we have investigated their synthesis in mutants which were selected for overproduction of either ThrRS or PheRS. It was found that mutants isolated previously for overproduction of ThrRS as strains resistant to the antibiotic borrelidin (strains Bor Res 3 and Bor Res 15) did not show an elevated level of PheRS. PheRS-overproducing strains were then isolated as revertants of strains with structurally altered enzymes. Strain S1 is a temperature-resistant derivative of a temperature-sensitive PheRS mutant, and strain G118 is a prototrophic derivative of a PheRS mutant which shows phenylalanine auxotrophy as a consequence of an altered K(m) of this enzyme for the amino acid. In both kinds of revertants, S1 and G118, the concentration of PheRS and ThrRS was increased by factors of about 2.5 and 1.8, respectively, whereas the level of other aminoacyl-tRNA synthetases was not affected by the mutations. Genetic studies showed that the simultaneous overproduction of PheRS and ThrRS in revertants G118 and S1 is based upon gene amplification, since this property was easily lost after growing the cells in the absence of the selective stimulus, and since this loss could be prevented by the presence of the recA allele. By similar criteria, the four- and eightfold overproduction of ThrRS in strains Bor Res 3 and Bor Res 15, respectively, was very stable genetically, indicating that it is caused by a mutational event other than gene amplification. From these results, we conclude that the concomitant increase of PheRS and ThrRS in strains G118 and S1 is an expression of gene duplication and not of a joint regulation of these two aminoacyl-tRNA synthetases. This conclusion is further supported by the result that, in mutant G118 as well as in its parental strain G1, growth in minimal medium lacking phenylalanine led to an additional twofold increase of their PheRS concentration. This increase was restricted to the PheRS, since the level of other aminoacyl-tRNA synthetases, including the ThrRS, stayed unchanged.     

3-hydroxypyruvate substitutes for pyridoxine in serC mutants of Escherichia coli K-12.

Escherichia coli K-12 mutants with serC genotype required pyridoxine and serine for normal growth, as do E. coli B mutants of this type. Mutants of the K-12 strain, however, reverted easily to pyridoxine independence without regaining activity in the 3-phosphoserine oxoglutarate transaminase coded for by the serC gene. Both these revertants and the parental type synthesized pyridoxine in normal amounts when 3-hydroxypyruvate was used as a supplement, although neither of these mutants could use this compound to satisfy their serine requirement. Since serine alone was inadequate to provide the nutritional requirement of serC mutants, these mutants must have been unable to synthesize 3-hydroxypyruvate from serine. We suggest that 3-phosphoserine oxoglutarate transaminase in normal E. coli serves as a catalyst for transaminating small amounts of serine to 3-hydroxypyruvate, which is then used in pyridoxine biosynthesis. In serC mutants, this activity is blocked, and these mutants then show a double requirement for serine and pyridoxine.     

Mutants of Chinese hamster cells deficient in thymidylate synthetase

Stable mutants of Chinese hamster V79 cells deficient in thymidylate synthetase (TS; E.C. 2.1.1.45) have been selected from cultures grown in medium supplemented with folinic acid, aminopterin, and thymidine (FAT). After chemical mutagenesis, the frequency of colonies resistant to the "FAT" medium increased more than 100-fold over the spontaneous frequency. The optimal expression time of the mutant phenotype was 5-7 days after mutagen treatment. The recovery of FAT-resistant colonies in the selective medium was not affected by the presence of wild-type cells at a density below 9,000 cells per cm2. All 21 mutants tested exhibited thymidine auxotrophy; neither folinic acid nor deoxyuridine could support mutant cell growth. There was no detectable TS activity in all 11 mutants so far examined and only about 50% of wild-type activity in three prototrophic revertants, as measured by whole-cell and cell-free enzyme assays. The apparent Michaelis-Menten constant (Km) for deoxyuridine-5'-monophosphate and inhibition constant (Ki) for 5-fluoro-deoxyuridine-5'-monophosphate, measured by whole-cell enzyme assay, appear to be similar for the wild-type and revertant cell lines. Using 5-fluoro-[6-3H]-2'-deoxyuridine 5'-monophosphate as active site titrant, the relative amounts of TS in crude cell extract from the parental, revertant, and mutant cells were shown to exist in a 1:0.5:0 ratio. Furthermore, the enzymes from two revertants were more heat labile than that of V79 cells. These properties, taken together, suggest that the FAT-resistant, thymidine auxotrophic phenotype may be the result of a structural gene mutation at the TS locus. The availability of such a mutant facilitates studies on thymidylate stress in relation to DNA metabolism, cell growth, and mutagenesis.     

Accumulation of 6-Azauridine by Mutants of Brevibacterium ammoniagenes

From the inosine producing mutants of Brevibacterium ammoniagenes, KY 13761 was selected as a strain which produced 6-azauridine from 6-azauracil.

The conditions for the conversion were examined and the intermitent feeding of 6-azauracil was found effective for the accumulation.

In order to increase the accumulation, prototrophic revertants were induced from KY 13761 and KY 13021 was selected. By intermitent feeding of 6-azauracil of a final concentration of 6 mg per ml, a maximal accumulation, 12.4 mg/ml, of 6-azauridine was obtained with KY 13021.