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 reserved 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 reserved 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.     

Glutamine metabolism in nitrogen-starved conidia of Neurospora crassa.

During nitrogen deprivation, de novo synthesis of glutamine synthetase was induced in non-growing conidia of Neurospora crassa. When ammonia or glutamine was added to conidia which had been deprived of nitrogen, glutamine and arginine accumulated at a higher rate than in condia not deprived of nitrogen. The degradation of exogenous glutamine to glutamate is apparently a necessary step in the accumulation of glutamine and arginine within the conidia. In non-growing conidia, a cycle probably operates in which glutamine is degraded and resynthesized. The advantages of such a cycle would be that the carbon and nitrogen could be used to synthesize amino acids in general, as well as for the synthesis and accumulation of arginine and/or glutamine in particular.     

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.     

Hydroxylamine-induced purple adenine (ad-3) mutants in Neurospora crassa. I. Characterization of mutants by genetic tests

The genetic effects of hydroxylamine (HA) on Neurospora crassa were studied in an effort to understand the difference between the results obtained on very simple prokaryotic systems and those obtained with mammalian systems. A 2-component heterokaryon was used to study the inactivation of conidia and the induction of recessive lethal mutations at specific loci and over the entire genome. The heterokaryon is heterozygous for 2 closely linked loci, ad-₃A and ad-₃B, in the ad-₃ region. Specific locus mutations can result from either point mutation or chromosome deletion. The results were as follows: (1) Both homokaryotic and heterokaryotic conidia had multi-hit survival curves, and there was no difference between the survival levels of the two as a function of treatment time. (2) The frequency of recessive lethal mutations in the ad-₃ region increased as the square of treatment time.     

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.     

Gene topography and function. I. Gene expression in germinating conidia of Neurospora crassa

In an attempt to find clues for the significance of the gene ordering along the eukaryotic chromosome, a system consisting of germinating conida of Neurospora crassa was studied. Thirteen enzyme activities corresponding to genes widely distributed on five chromosomes were determined in dormant and in germinating conidia. Ten of these enzymes showed lower activities in the resting state, and the time patterns of their increase were determined during germination. The results obtained do not support a scheme of sequential expression of genes during the emergence from dormancy as a counterpart of the sequence of the corresponding genes along the chromosome. Two of the loci studied were analyzed both in the normal (wild-type) ordering and in a translocated position in which the two genes are located in an inverted order respective to the centromere and farther apart from it. The altered order of the genes did not influence significantly the time and pattern of increase in the activities of the corresponding enzymes.     

Changes in the glutathione thiol-disulfide status of Neurospora crassa conidia during germination and aging.

Improved methods were developed for the determination of reduced glutathione (GSH), glutathione disulfide (GSSG), and protein-glutathione disulfide (PSSG) and applied to determine the glutathione status at various stages of the asexual life cycle for the band strain of Neurospora crassa. The GSH-GSSG ratio in freshly harvested dry conidia was found to be about 150 but decreased to around 6 when dryconidia were aged (stored) for 10 days after harvest. When conidia were germinated, this ratio increased to about 300 during the first 10 min of the 6-h germination process. In mycelia, during log-phase growth, the ratio was about 10-3. Changes in the ratio occurred primarily through changes in the GSSG content, which ranges from about 0.023 (mycelia) to 2(10-day aged conidia) mumol per g (dry weight) of residue, whereas GSH levels varied by a factor of about two. The PSSG content varied from 0.02 (mycelia) to 0.6 (10-day aged conidia) mumol per g (dry weight) of residue and generally paralleled the GSSG content. The results demonstrate the potential importance of thiol-disulfide reactions as a mechanism for the control of physiological properties associated with dormancy, and the observed changes in GSSG level are found to be compatible with the view that GSSG plays a role in the regulation of protein synthesis through control of polysome formation.     

Amino acid induction of conidiation and morphological alterations in wild type and morphological mutants of Neurospora crassa

Summary Casamino acids, utilized in a growth medium as sole source of both carbon and nitrogen strikingly changed the morphology of wild type and several morphological mutants of Neurospora. Some of the changes that were seen include: (1) loss of colonial characteristic; (2) stimulation of conidiation (even in a strain previously thought aconidial); (3) modification of mycelial branching; (4) pigment changes. Certain other morphological mutants responded weakly or not at all to the casamino acids media. Of the group which did respond however, addition of certain sugars negated partially or completely the effect of the casamino acids while other carbon sources such as pyruvate, acetate, and Krebs cycle intermediates had no effect. Electron micrographs of the morphological mutant amycelial revealed important modifications of the cell wall and endoplasmic reticulum accompanying an induction of conidiation using the casamino acids system or the acetate+succinate combination.     

Synthesis of polyadenylic acid-containing ribonucleic acid during the germination of Neurospora crassa conidia.

Ribonucleic acid (RNA) synthesized during the first 1 h of conidial germination (15 to 20, 25 to 30, and 55 to 60 min) has been characterized by sucrose-sodium dodecyl sulfate gradient centrifugation, binding to polyuridylic acid filters, and oligo(dT)-cellulose chromatography. At all labeling periods examined, polyadenylic acid-containing RNA is synthesized, processed, and incorporated into polysomes. Approximately 40% of the labeled RNA sedimenting between 5 and 17S binds to polyuridylic acid filters. RNA which binds to oligo(dT)-cellulose displays a heterogeneous distribution in sucrose-sodium dodecyl sulfate gradients with a major, broad peak at 10-16S. In addition, some polyadenylic acid-containing RNA sediments beyond the 25S marker. Approximately 3% of the [3H]adenosine in pulse-labeled polysomal RNA is in polyadenylic acid segments resistant to pancreatic and T1 ribonucleases.     

Regulation of the purine catabolic enzymes in Neurospora crassa.

Neurospora crassa can utilize purines and their metabolic products as a nitrogen source. Regulation of the five enzymes required for uric acid metabolism was studied. The first three enzymes of this catabolic pathway are controlled in a complex manner that involves both induction and repression. Both uricase and allantoicase were induced by uric acid while allantoinase was induced by either uric acid or allantoin. Synthesis of all three of these enzymes was repressed by the end product, ammonia. The ure-2 mutant, which is urease deficient and cannot derive ammonia from purines, shows a hyperinducibility of these same three enzymes. The last two enzymes of the pathway, ureidoglycollase and urease, were found to be constitutive.     

One-carbon metabolism in Neurospora crassa wild-type and in mutants partially deficient in serine hydroxymethyltransferase.

1. The concentrations of folate-dependent enzymes in Neurospora crassa Lindegren A wild type (FGSC no. 853), Ser-l mutant, strain H605a (FGSC no. 118), and for mutant, strain C-24 (FGSC no. 9), were compared during exponential growth on defined minimal media. Both mutants were partially lacking in serine hydroxymethyltransferase, but contained higher concentrations of 10-formyltetrahydrofolate synthetase than did the wild type. Mycelia of the mutants contained higher concentrations of these enzymes when growth media were supplemented with 1mM-glycine. In the wild-type, this glycine supplement also increased the specific activities of 5,10-methylenetetrahydrofolate dehydrogenase and 5,10-methylenetetrahydrofolate reductase. 5. During growth, total folate and polyglutamyl folate concentrations were greatest in the wild-type. Methylfolates were not detected in mutant Ser-l, and were only present in the for mutant after growth in glycine-supplemented media. Exogenous glycine increased folate concentration threefold in the wild type, mainly owing to increases in unsubstituted polyglutamyl derivatives. 3. Feeding experiments using 14C-labelled substrates showed that C1 units were generated from formate, glycine and serine in the wild type. Greater incorporation of 14C occurred when mycelia were cultured in glycine-supplemented media. Formate and serine were precursors of C1 units in the mutants, but the ability to cleave glycine was slight or lacking.