On the specificity of caffeine effects

Summary Caffeine in 0.1% or higher concentration reversibly inhibits E. coli and yeast growth. It inhibits RNA and protein synthesis (Tables 1+3) within a few minutes after being added to the incubation medium (Fig. 2). The suggestion is made that these effects of caffeine, as well as its synergism with some mutagens, are due to its ability to costack with free purines and to form complexes with single-stranded nucleic acids.     

Induction by manganese of mitochondrial antibiotic resistance mutations in yeast

Summary Manganese added to the growth medium of Saccharomyces cerevisiae to a final concentration of 4–8 mM induces not only mitochondrial respiratory-deficient mutations (Fig. 1), but also mitochondrial mutations to chloramphenicol- and erythromycin-resistance (Fig. 1, Tables 1–3). This is the first mutagen shown to be capable of inducing mitochondrial antibiotic resistance mutations in yeast. It is assumed that manganese induces mutations through its interaction with mitochondrial DNA polymerase.This work was supported by the Polish Acadmy of Sciences under the project 0.9.3.1.     

Regulation of homocysteine metabolizing enzymes in Aspergillus nidulans

Summary Mutants of Aspergillus nidulans blocked in the main pathway of cysteine synthesis show an elevated level of the enzymes involved in the synthesis of cysteine from homocysteine i.e. cystathionine -synthase and -cystathionase and a depressed level of homocysteine methyltransferase. This results in a considerable change in the sulfur amino acids pool as compared to the wild type. Upon addition of cysteine to the growth medium the first two enzymes are repressed while the level of the third one increases. These data indicate that the two diverging pathways of homocysteine metabolism are anti-coordinately regulated.     

Mutations affecting the sulphur assimilation pathway in Aspergillus nidulans: their effect on sulphur amino acid metabolism

Several sul-reg mutants of Aspergillus nidulans isolated as constitutive for arylsulphatase were studied with respect to the regulation of enzymes involved in cysteine and homocysteine synthesis and to the pool of sulphur amino acids. All mutants examined showed a decreased concentration of glutathione as compared with the wild type, and all mutants, with one exception, had a decreased total pool of sulphur amino acids. The results suggest that the mutants are leaky in the sulphate assimilation pathway. They show derepression of cysteine synthase, homocysteine synthase, cystathionine beta-synthase and gamma-cystathionase. In spite of having derepressed homocysteine synthase, the enzyme which constitutes an alternative pathway for homocysteine synthesis, the sul-reg mutations do not suppress lesions in genes required for the main homocysteine-synthesizing pathway. This indicates that the derepression of homocysteine synthase is not in itself sufficient for physiological functioning of this enzyme, but seems to depend also on the effectiveness of cysteine synthesis and sulphide formation.     

Manganese mutagenesis in yeast. A practical application of manganese for the induction of mitochondrial antibiotic-resistant mutations.

When yeast cells were incubated for 4 to 8 h in yeast extract-peptone-glucose medium, pH 6, containing 8 mM-manganese, and then plated on selective media, there was a strong induction of antibiotic-resistant mutations. Indirect evidence suggests that practically all resistant mutants selected were of independent origin. The analysis of manganese-induced resistant mutants showed that most were extranuclear, while those tested showed recombination with known mitochondrial markers. Our results suggest that manganese can be considered as a mutagen which specifically induces mitochondrial mutations in Saccharomyces cerevisiae.