Inhibition of adenine and hypoxanthine uptake by guanosine in conidia of Neurospora crassa.

Guanosine competitively inhibits the uptake of adenine and hypoxanthine by the general purine-base permease in conidia of Neurospora crassa. There is no reciprocal effect of adenine or hypoxanthine on guanosine uptake so it is suggested that guanosine can bind to the general purine-base permease to cause this inhibition but is not transported through this system. It is known that guanosine is transported by two separate nucleoside transport sites. Guanosine also noncompetitively inhibits the specific adenine uptake system of germinating conidia.

Rapid chemotaxis assay using radioactively labeled bacterial cells.

A rapid chemotaxis assay is described in which radioactively labeled cells of the assay organism are used to detect the number of cells trapped in capillaries containing attractant. The sensitivity and reproducibility of the radioactive technique is comparable to that of the dilution plating procedure of Adler (J. Adler, J. Gen. Microbiol. 17:77-91, 1973), but is faster and also permits the results of the assay to be determined on the day that the assay is run. The method could be particularly useful for environmental studies and for field experiments, since it does not rely on sterile techniques for dilution plating.

Isolation and characterization of guanine auxotrophs in Neurospora crassa.

An ad-9 strain of Neurospora crassa was mutagenized with ethylmethane sulfonate (5%) and selected for guanine auxotrophy. The resultant double adenine plus guanine mutant was backcrossed with wild type and a single guanine auxotroph was isolated from the progeny. In vitro assays indicated that the mutant had GMP synthetase activity comparable with wild type, but was completely lacking of IMP dehydrogenase activity. The guanine requirement can therefore be explained by the mutant's inability to convert IMP to XMP. Another guanosine auxotroph was able to adapt and grow on minimal medium after 3 days. This mutant had GMP synthetase activity comparable with wild type but had only 10% of the IMP dehydrogenase activity of wild type, which may possibly explain its ability to grow on minimal medium after 3 days. It was confirmed that the two isolates are not allelic by crossing the two and recovering 25% wild-type progeny. Out isolate must therefore be designated gua-2.

Guanosine metabolism in Neurospora crassa.

Two aspects of guanosine metabolism in Neurospora have been investigated. (a) The inability of adenine mutants (blocked prior to IMP synthesis) to use guanosine as a nutritional supplement; and (b) the inhibitory effect of guanosine on the utilization of hypoxanthine as a purine source for growth by these mutants. Studies on the utilization of guanosine indicated that the proportion of adenine derived from guanosine may be limiting for the growth of adenine mutants. In wild type, adenine is produced through the biosynthetic pathway when grown in the presence of guanosine. The amount of adenine produced through the de novo biosynthesis in wild type increases with increasing concentrations of guanosine in the medium. However, the total purine synthesis does not increase. Guanosine inhibits the uptake of hypoxanthine severely. In addition, guanosine and its nucleotide derivatives also inhibit the hypoxanthine phosphoribosyltransferase activity, at the same time stimulating the adenine phosphoribosyltransferase activity. Guanosine's effects on the uptake of hypoxanthine and its conversion to the nucleotide form may be the reasons why guanosine inhibits the utilization of hypoxanthine but not adenine by these mutants.

Purine biosynthesis and its regulation in Neurospora crassa.

Purine biosynthesis and its regulation was studied in Neurospora crassa by the incorporation of label from [14C]formate into total cellular purines. In general, the purine biosynthesis resulted in slightly more cellular guanine than adenine nucleotides. The acid-soluble pool however, contained more adenine compounds than guanine. Exogenous adenine was found to be an effective regulatory of the proximal steps of the de novo biosynthesis, while both adenine and guanine were equally effective in regulating the branch point activities. 6-Methyl purine inhibited the proximal steps of the purine synthesis more effectively than the branch point leading to adenine biosynthesis. A 6-methyl purine resistant mutant, Mepr-10, with defective adenine phosphoribosyl pyrophosphate transferase showed no inhibition of purine synthesis by 6-methyl purine, while 6-methyl purine resistant strains Mepr-3 and Mepr-1 showed partial inhibition. It has been suggested that Mepr-3 and Mepr-1 may be mutants of glutamine amidotransferase with altered affinities for 6-methyl purine. The rate of purine biosynthesis increased during the first 8 h of incubation of conidia in minimal medium, after which it declined even though the growth continued.

Nature of 6-methylpurine inhibition and characterization of two 6-methylpurine-resistant mutants of Neurospora crassa.

6-Methylpurine, an analog of adenine, inhibits the growth of Neurospora crassa. From kinetic studies it was found that 6-methylpurine is converted to its nucleotide form by adenine phosphoribosyltransferase (EC 2.4.2.7), and inhibits the de novo purine biosynthesis. Adenine relieves the growth inhibition caused by 6-methylpurine, whereas hypoxanthine is not very effective. Studies dealing with hypoxanthine utilization in the presence of 6-methylpurine indicated a severely reduced uptake of hypoxanthine and a general slowdown in its further metabolism. Two mutants (Mepr-3 and Mepr-10) which are resistant to 6-methylpurine were characterized. Studies of purine base uptake and the in vivo and in vitro conversion to nucleotides indicated that Mepr-10 may be an adenine phosphoribosyltransferase-defective mutant, whereas Mepr-3 may be a mutant with altered feedback response to 6-methylpurine. Both mutants showed a severely lowered hypoxanthine phosphoribosyltransferase activity, but because 6-methylpurine did not have any effect on the conversion of hypoxanthine to IMP in the wild type, it was concluded that 6-methylpurine resistance in these mutants cannot be due to lowered hypoxanthine phosphoribosyltransferase activity, but rather that the lowering of enzyme activity may be a secondary effect.

Purine base transport in nit-2 mutants of Neurospora crassa.

The nit-2 mutants possess general purine transport activity. Reduced hypoxanthine uptake in germinated conidia of these mutants may be a consequence of their defective purine metabolism.

Uptake and efflux of adenine and its derivatives in Neurospora crassa.

Conidia of wild-type Neurospora crassa, preincubated for 3 1/2 h in growth medium, showed a typical triphasic pattern of adenine uptake. The three phases consisted of a quick initial uptake, followed by a plateau phase, and then by a resume lowered uptake. A study of the relative influx and efflux of [14C] adenine showed that the plateau phase in fact is a period of transmembrane movement of adenine and adenine metabolites. The efflux during the plateau phase essentially cancelled out all the influx during the same period. The uptake curve derived after taking into account the effluxed portion of radioactivity indicated that the second phase represents a period of lowered uptake activity. The beginning of the lowered uptake activity during the second phase is correlated with the presence of a high intracellular level of ATP derived from exogenous [14C]adenine. At the end of the secod phase, the intracellular level of ATP is much smaller and the rate of adenine uptake increases again. Analysis of the acid-soluble pool after feeding [14C]adenine indicated the presence of other 14C-nucleotides, but no detectable levels of bases and nucleosides were present. However, chromatographic analysis of the medium indicated that efflux results essentially in the accumulation of bases. The significance of this finding in relation to efflux is discussed.

Developmental-stage-dependent adenine transport in Neurospora crassa.

Although germinated conidia of Neurospora crassa transport adenine through two different systems, only one of these, namely, the general purine transport system, which transports adenine, hypoxanthine, guanine, and 6-methylpurine, is present in freshly harvested conidia of the wild type. The second system develops during germination. The latter system can transport adenine and 6-methylpurine. Time course and kinetic studies of adenine transport in freshly harvested conidia of an ad-8 mutant indicated that, in contrast to the wild type, the general purine transport activity is very low in this strain and that the second adenine transport system is possibly present in the ungerminated conidia. A study of adenine and hypoxanthine uptake in ad-8 and ad-4 mutants, both of which cannot utilize hypoxanthine for growth, isolated that the two transport systems may be under different metabolic controls.

Oxidation of ethane by an Acremonium species.

Ethane oxidation was studied in ethane-grown resting cells (mycelia) of an Acremonium sp. and in cell-free preparations of such mycelia. From resting cell experiments evidence was found for a pathway of ethane oxidation via ethanol, acetaldehyde, and acetic acid. In vitro studies indicated that ethane-oxidizing activity in such mycelia occurred predominantly in the microsomal fraction of crude homogenates. Microsomal preparations were inactive in the absence of added coenzyme. Marked stimulation of activity was obtained in such preparations with reduced nicotinamide adenine dinucleotide phosphate and to a much lesser degree with nicotinamide adenine dinucleotide phosphate. Ethane oxidation was inhibited by sodium azide and carbon monoxide.

Effect of histidine on purine nucleotide synthesis and utilization in Neurospora crassa.

Histidine affects de novo purine nucleotide synthesis and purine nucleotide pool utilization in Neurospora crassa. The former effect was assessed qualitatively by the presence or absence of purple pigment production in ad3B and ad3A mutants. Tryptophan also affected the de novo purine nucleotide synthesis. The effect of histidine on purine nucleotide pool utilization resulted in stimulated germination of ad8 and ad4 mutant conidia in adenine-deficient medium. Increased germination was correlated with increased net levels of nucleic acids in these strains. Possible mechanisms for the dual action of histidine are discussed.

Endogenous purine metabolism in the conidia of wild type and certain adenine mutants of Neurospora crassa. I. The nature of the reserve pools and pool utilization during adenine starvation.

Conidia of four adenine auxotrophs (ad 9, ad 3B, ad 8 and ad 4) of Neurospora crassa differ in their ability to germinate on adenine-deficient medium. A large percentage of the ad 9 and ad 3B mutant conidia germinate while those of ad 8 and ad 4 mutant do not. No correlation was found between the size of the conidial purine reserves and the conidial ability to germinate. In all the strains the major fraction of the conidial purine reserve pools was inosine. The ad 8 and ad 4 mutants are blocked after IMP formation in the adenine biosynthetic pathway and therefore cannot use the stored inosine for germination. Pool-utilization studies indicated that in all strains investigated some of the purine reserves were lost from the conidia during incubation. In the most readily germinating strain, ad 9, only small amounts of the purine pool were lost from the conidia and a large portion of the reserve pool was used for nucleic acid synthesis. The nature of the purine reserves present in the conidia, and the ability of the strains to prevent loss of the stored purines from the conidia appear to be among the factors influencing the conidial germination of the adenine mutants of N. crassa.

Storage of brewing yeasts by liquid nitrogen refrigeration.

Many yeast strains are difficult to maintain in culture in a stable state, and long-term preservation by lyophilization, which has proved useful for other fungi, has given poor results with brewing yeasts. As an alternative to continuous subculture, which maximizes strain variability, various methods of cryogenic storage were investigated. Yeast strains were frozen with or without cryoprotectants (such as glycerol or inositol) and stored at -196 C. Recovery after warming was estimated from plate counts, and survivors were screened to detect changes in the frequency of morphological types, respiratory-deficient mutants, and glycerol-sensitive mutants. Strains varied in their sensitivity to freezing, and survival was modified by the growth medium, the freezing munstrua, and the freezing conditions. Suspension of cells in 10% (vol/vol) glycerol, cooled at 1 C/min, warmed rapidly and plated on malt-yeast extract-glucose-peptone agar produced the highest percentage of viable colonies with a minimal change in metabolic characteristics. In two of the strains tested, no significant increase in mutation rate was detected under any of the treatments; the strains were maintained in a stable state and were metabolically comparable to unfrozen strains. In one strain of Saccharomyces uvarum after some freezing treatments, the percentage of respiratory-deficient mutants increased markedly, the fermentation rate declined, and a loss of flocculation occurred. The freezing parameters which increased the level of respiratory-deficient cells should be avoided in maintaining this strain. Maintenance of cultures of brewing yeasts by cryogenic storage has several advantages over other preservation techniques: the method is simple and reproducible, the cultures have remained stable over a 3-year test period, and the viability is high.