Mutations affecting extracellular protease production in the filamentous fungusAspergillus nidulans

The extracellular proteases ofAspergillus nidulans are known to be regulated by carbon, nitrogen and sulphur metabolite repression. In this study, a mutant with reduced levels of extracellular protease was isolated by screening for loss of halo production on milk plates. Genetic analysis of the mutant showed that it contains a single, recessive mutation, in a gene which we have designatedxprE, located on chromosome VI. ThexprE1 mutation affected the production of extracellular proteases in response to carbon, nitrogen and, to a lesser extent, sulphur limitation. Three reversion mutations,xprF1, xprF2 andxprG1, which suppressxprE1, were characterised. BothxprF andxprG map to chromosome VII but the two genes are unlinked. ThexprF1, xprF2 andxprG1 mutants showed high levels of milk-clearing activity on medium containing milk as a carbon source but reduced growth on a number of nitrogen sources. Evidence is presented that thexprE1 andxprG1 mutations alter expression of more than one protease and affect levels of alkaline protease gene mRNA.     

Regulation of exocellular protease in Neurospora crassa: induction and repression under conditions of nitrogen starvation.

Exponential-phase cells of Neurospora crassa require the continued presence of a protein inducer and nitrogen starvation to induce exocellular protease under conditions where protein is the sole nitrogen source. The nature of the protein inducer appears relatively unimportant, since both soluble proteins (e.g., myoglobin) and insoluble proteins (e.g., corn zein) will effect induction. Nonstarved cells of N. crassa appear to have small nitrogen pools, since nitrogen starvation of exponential cells prior to transfer into a medium where protein is the sole nitrogen source effects starvation-time-dependent decreases in protease biosynthesis. Ammonium ion represses protease synthesis, with apparent specificity at low concentrations. The amino acids arginine, tryptophan, and threonine effect repression of protease biosynthesis under conditions of nitrogen starvation. Under conditions of sulfur starvation, the amino acids cysteine, methionine, and cystine repress protease biosynthesis. In carbon-starved cells, all of the above amino acids, plus histidine, isoleucine, leucine, lysine, phenylalanine, and valine, effect repression. Examination of amino acid pools formed when cells are grown on protein as the sole nitrogen source demonstrated that the amino acids which repress protease biosynthesis under conditions where protein is the sole carbon source accumulate in significant amounts during the course of protease induction, with kinetics consonant with the induction process.     

N-Acetyl-d-Glucosamine-Mediated Regulation of Extracellular Protease in the Entomopathogenic Fungus Beauveria bassiana

The entomopathogenic fungus Beauveria bassiana GK2016 grown in a liquid medium incorporating gelatin as the sole carbon and nitrogen source produced an extracellular serine protease (molecular weight, 35,000; pI ca. 10). Without gelatin, B. bassiana could utilize N-acetyl-d-glucosamine (GlcNAc; 2-acetamido-2-deoxy-d-glucose) as the sole source of carbon and nitrogen, and GlcNAc availability increased the storage carbohydrate content in mycelia. Synthesis of protease was repressed in gelatin medium containing GlcNAc at levels of >1.07 mumol mg of fungal dry weight. At levels below this, protease synthesis was initiated; subsequently, free amino nitrogen appeared in the medium and diauxic growth was observed. Slow feeding with GlcNAc (35.34 mug ml h) did not repress protease synthesis nor did GlcNAc accumulate in the medium above 0.5 mg ml. Increasing the rate of release of GlcNAc (83.51 mug ml h) resulted in the accumulation of GlcNAc in the medium to 2.0 mg ml, a 45% increase in growth and a decrease in protease synthesis by about 81%. Free amino acids generated from the hydrolysis of gelatin did not repress protease synthesis. These data are interpreted in terms of known interaction of B. bassiana with insect cuticular components. We suggest that the action of extracellular chitinases synthesized by B. bassiana on insect cuticle, and pursuant release of GlcNAc, may have important consequences on the regulation of other extracellular catabolic enzymes such as the protease.     

Mutations affecting extracellular protease production in the filamentous fungusAspergillus nidulans

The extracellular proteases ofAspergillus nidulans are known to be regulated by carbon, nitrogen and sulphur metabolite repression. In this study, a mutant with reduced levels of extracellular protease was isolated by screening for loss of halo production on milk plates. Genetic analysis of the mutant showed that it contains a single, recessive mutation, in a gene which we have designatedxprE, located on chromosome VI. ThexprE1 mutation affected the production of extracellular proteases in response to carbon, nitrogen and, to a lesser extent, sulphur limitation. Three reversion mutations,xprF1, xprF2 andxprG1, which suppressxprE1, were characterised. BothxprF andxprG map to chromosome VII but the two genes are unlinked. ThexprF1, xprF2 andxprG1 mutants showed high levels of milk-clearing activity on medium containing milk as a carbon source but reduced growth on a number of nitrogen sources. Evidence is presented that thexprE1 andxprG1 mutations alter expression of more than one protease and affect levels of alkaline protease gene mRNA.     

Quantitative relations for the repression of nitrogenase synthesis in Azotobacter vinelandii by ammonia

A method is described which allows the quantitative determination of small ammonia concentrations in the culture of nitrogen-fixing microorganisms. With this method the ammonia concentration range was estimated in which repression of nitrogenase synthesis in Azotobacter vinelandii occurs. Both in batch and continuous cultures there was no repression below 10 μM, whereas nitrogenase synthesis stopped completely if the ammonia concentration in the medium exceeded 25 μM.     

Levels of glutathione in Escherichia coli.

Log phase cells of Escherichia coli growing in minimal medium contain a basal level of glutathione (5 pmol/mL per Klett unit) which can increase more than sixfold when the cells reach stationary phase. Since the addition of cysteine alone to log phase cells illicits the same response, the increase in the intracellular pool of glutathione appears to be influenced by the amount of cysteine available for glutathione synthesis. Glucose depletion at low cell densities resulted in a decrease in the glutathione pool while the addition of amino acids other than cysteine did not affect the glutathione pool. Depletion of ammonia or proline as the nitrogen source also resulted in a decrease in the glutathione pool to one-third of the original basal levels as did a shift to anaerobic growth. The large glutathione pool in stationary phase cells dropped from 31.5 to 4.5 pmol/mL per Klett unit within 30 min of transfer to fresh medium. There was no apparent correlation between changes in the glutathione and coenzyme A--glutathione disulfide (CoASSG) pools after a variety of metabolic disruptions.     

Regulation of two extracellular proteases of Neurospora crassa by induction and by carbon-nitrogen and sulfur-metabolite repression.

Synthesis and release by Neurospora crassa 74A (FGSC 262) of a neutral and an alkaline protease have been studied by experiments in which mycelia grown in Vogel's minimal medium were transferred to media containing protein inducer and deficient in carbon, nitrogen, and/or sulfur sources. The kinetics of accumulation of each of the two proteases in filtrates of induced, metabolite-deprived (derepressed) cultures were found to be similar and the same two electrophoretically separable enzymes were elicited by each of the three induction and derepression treatments. Moreover, antiserum specific for the major protease (Protease 2) elicited by one of the treatments gave a reaction of identity with the major proteases elicited by the other two treatments. It would therefore appear that these two proteases are coordinately regulated by a single system of induction and repression in which successful induction by exogenous protein depends upon the lifting of any one of carbon, nitrogen, or sulfur metabolite repressions.     

An alternative insect pathogenic strategy in an Aspergillus flavus auxotroph

In order to study fungal pathogen evolution, we used a model system whereby the opportunistic fungus Aspergillus flavus was serially propagated through the insect (Galleria mellonella) larvae, yielding a cysteine/methionine auxotroph of A. flavus with properties of an obligate insect pathogen. The auxotroph exhibited insect host restriction but did not show any difference in virulence when compared with the wild-type (Scully LR, Bidochka MJ, 2006. Microbiology 152, 223-232). Here, we report that on 1 % insect cuticle medium and synthetic Galleria medium, the auxotroph displayed increased extracellular protease production, a virulence factor necessary for insect pathogenesis. In the wild-type strain, protease production was deregulated during carbon (glucose), nitrogen (nitrate), or sulphate deprivation. If all three were present, protease production was vastly reduced. However, in the cysteine/methionine auxotroph, protease production was deregulated in complete medium. We suggest that the deficiency in sulphate assimilation in the auxotroph resulted in deregulation of protease production. The auxotroph exhibited delayed germination and slower hyphal growth when compared to the wild-type but there were no differences in virulence or cuticle penetration, suggesting a shift in pathogenic strategy that compensated decreased growth with increased virulence factor (extracellular protease) production. We concluded that the biosynthetic deficiency that mediated insect host restriction also increased protease production in the slow-growing auxotroph, resulting in an alternate, more host-specific pathogenic strategy. However, we argue that transmission is not necessarily correlated with virulence as competition bioassays in insect larvae showed that the wild-type generally out-competed the auxotroph by producing the majority of the conidia on the sporulating cadavers. This is one of the few examples that highlight the effect of genome decay on nutrition acquisition, virulence, and transmission in fungal pathogen evolution.     

Derepression of asparaginase II during exponential growth of Saccharomyces cerevisiae on ammonium ion

The biosynthesis of asparaginase II in Saccharomyces cerevisiae is sensitive to nitrogen catabolite repression. In cell cultures growing in complete ammonia medium, asparaginase II synthesis is repressed in the early exponential phase but becomes derepressed in the midexponential phase. When amino acids such as glutamine or asparagine replace ammonium ion in the growth medium, the enzyme remains repressed into the late exponential phase. The three nitrogen compounds permit a similar rate of cell growth and are assimilated at nearly the same rate. In the early exponential phase the internal amino acid pool is larger in cells growing with glutamine or asparagine than in cells growing with ammonium sulfate as the sole source of nitrogen.     

Utilization of Ammonia Nitrogen by Intestinal Bacteria Isolated from Pigs

In a medium containing ammonia, proteose peptone, and cysteine as nitrogen sources, 17 of 24 Bacteroidaceae strains, 3 of Selenomonas strains, 1 of 7 curved rods, 3 of 7 Spirochaetaceae strains, 8 of 20 Eubacterium strains, 8 of 13 Peptococcaceae strains, 3 of 4 Clostridium strains, 19 of 20 Enterobacteriaceae strains, and 1 of 8 Streptococcus strains utilized ammonia nitrogen preferentially to proteose peptone nitrogen. To determine the ability of intestinal microbes to synthesize amino acids from ammonia, ammonia utilization by Bacteroides ruminicola strain 9 was studied in defined media containing ammonia and other nitrogen sources. In another medium containing ammonia, proteose peptone, and cysteine as nitrogen sources, ammonia was preferentially utilized even when the proteose peptone nitrogen content was eight times greater than that of ammonia nitrogen. In a medium containing ammonia, an amino acid, and cysteine, the lowest uptake of ammonia nitrogen was observed when the medium contained aspartic acid, glutamic acid, threonine, or alanine; but ammonia was utilized more effectively than any of the amino acids. Incorporation of ¹⁵N from [¹⁵N]ammonia into bacterial amino acids was studied. ¹⁵N was incorporated into every amino acid of B. ruminicola strain 9, and the highest uptake was observed in aspartic acid and alanine.     

Changes in Free Amino Acid Production and Intracellular Amino Acid Pools of Bacillus licheniformis as a Function of Culture Age and Growth Media

Changes in the endogenous intracellular amino acid pool and total free amino acid production in Bacillus licheniformis grown in minimal media were investigated. The total intracellular pool increased during exponential growth and then decreased rapidly after the end of growth. Most of the amino acids were present at low concentrations, but glutamate and alanine comprised 60 to 90% of the total intracellular free amino acid at most times during the growth cycle. It was concluded that, in addition to providing monomers for protein synthesis, the intracellular amino acid pool may be maintained for the storage of energy-providing metabolic intermediates and possibly as a balance to the ionic strength of the medium. The total free amino acid production by the cell was found to be dependent upon the composition of the salts medium as well as the culture age under conditions in which the carbon and nitrogen sources were the same. A 10-fold increase in extracellular amino acid was observed as the cells changed from vegetative to sporulation metabolism, mostly due to the extrusion of intracellular amino acid. The impact of this increase upon amino acid uptake and pulse-labeling studies using unwashed cells is discussed.     

The control of glutamine synthetase level in Lemna minor L.

Summary The specific activity of glutamine synthetase (E.C. 6.3.1.2) of Lemna minor L. is markedly reduced when either ammonium ions or glutamine are present in the growth medium. Combinations of 5 mM ammonia and 5 mM glutamic acid or 5 mM ammonia and 5 mM glutamine as nitrogen source, lead to a 4–5 fold reduction of the maximum activity measurable on 5 mM -aminobutyric acid. Analyses of the soluble pool of nitrogen indicate that the reduction in enzyme level is associated with an increase in the pool of glutamine. There is an inverse correlation between the apparent rate of synthesis of glutamine synthetase and the intracellular concentration of glutamine, and this relationship suggests that the glutamine synthetase of Lemna minor is subject to end product repression by the endogenous pool of glutamine.     

Effect of carnitines on Lactobacillus plantarum subjected to osmotic stress

We investigated the effect of carnitine analogues on the physiology of Lactobacillus plantarum subjected to salt stress. Salt stressed cells of L. plantarum accumulated exogenously provided carnitine and its structural analogues acetylcarnitine and propionylcarnitine to maximum concentrations of 466, 122 and 75 μmol (g dry weight of cells)⁻¹, respectively. Addition of these carnitines to osmotically stressed medium increased growth rate. Furthermore, the intracellular amino acid pool, consisting of mainly aspartate and glutamate, was reduced when carnitine, acetylcarnitine or propionylcarnitine were included in the medium. This is the first study demonstrating a role for β-substituted acylcarnitine esters in osmoadaptation of a lactic acid bacterium.     

CHANGES IN CARBOHYDRATE SUBSTRATES, AMINO ACIDS AND AMMONIA IN THE BRAIN DURING INSULIN-INDUCED HYPOGLYCEMIA

—The influence of insulin-induced hypoglycemia upon carbohydrate substrates, amino acids and ammonia in the brain was studied in lightly anaesthetized rats, and the changes observed were related to the blood glucose concentration and to the EEG. Calculations from glucose concentrations in tissue, CSF and blood indicated the presence of appreciable amounts of free intracellular glucose at blood glucose concentrations above 3 μmol/g. When the blood glucose concentration fell below 3 μmol/g, there was no calculated intracellular glucose and decreases in the concentrations of glycogen, G-6-P, pyruvate, lactate and of citric acid cycle intermediates were observed. At blood glucose levels of below 1 μmol/g the tissue was virtually depleted of glycogen, G-6-P, pyruvate and lactate. When the blood glucose concentration was reduced below about 2·5 μmol/g there were progressive increases in aspartate and progressive decreases in alanine, GABA, glutamine and glutamate, and at blood glucose concentrations below 2 μmol/g the ammonia concentration increased. It is suggested that most of the changes observed can be explained as a result of a decreased availability of pyruvate and of NADH. The decrease in the concentration of free NADH was reflected in reductions of the lactate/pyruvate and malate/oxaloacetate ratios at an unchanged intracellular pH. Slow wave activity appeared in the EEG when the hypoglycemia gave rise to reduction of the intracellular glucose concentration to zero. Convulsive activity continued until carbohydrate stores in the form of glycogen and G-6-P were depleted. When this occurred the EEG became isoelectric. In all convulsive animals the concentration of the nervous system activity inhibitor, GABA, was decreased and stimulant, aspartate, was increased.     

Controls of the expression of aspA, the aspartyl protease gene from Penicillium roqueforti

The gene (aspA) encoding the extracellular aspartyl protease from Penicillium roqueforti was cloned and characterized. Northern hybridization analyses and β-casein degradation assays revealed that aspA was strongly induced by casein in the medium and efficiently repressed by ammonia. External alkaline pH overrides casein induction, resulting in aspA repression. Cis-acting motifs known to mediate nitrogen and pH regulation of fungal gene expression are present in the aspA promoter and protein-DNA binding experiments showed that mycelial proteins interact with various regions of the promoter. Due to the efficient environmental controls on aspA expression, the promoter of aspA is an attractive candidate for the development of a controllable gene expression system in P. roqueforti.     

Extracellular expression of pullulanase from Bacillus naganoensis in Escherichia coli

The pullulanase encoding gene from Bacillus naganoensis was successfully overexpressed in Escherichia coli both intracellularly and extracellularly using expression vector pET22b (+). The distribution of recombinant protein was significantly affected by temperature and carbon and nitrogen sources. The highest levels of extracellular and intracellular production of the target protein were observed at 25 and 20 °C, respectively. The addition of maltose, dextrin, pullulan, and soluble starch to the culture medium caused significant increases in the extracellular yield of pullulanase, while glucose strongly inhibited pullulanase production. The results show that the optimal conditions for maximum yield of extracellular pullulanase required high levels of carbon source and a limited nitrogen supply, while low concentrations of carbon and nitrogen source favored intracellular pullulanase expression. High concentrations of nitrogen source strongly inhibited the production of pullulanase.     

Phosphocreatine in Ehrlich ascites tumor cells detected by noninvasive 31P NMR spectroscopy

³¹P NMR spectra of intact Ehrlich ascites tumor cells of high phosphorylation potential reveal a well-defined resonance peak assignable to phosphocreatine, corresponding to 2.3 μmoles/ml cell H₂O in adenosine-treated cells containing 5.2 μmoles ATP/ml. The NMR spectrum of Ehrlich cells incubated with iodoacetate and glucose indicates depletion of phosphocreatine and ATP to undetectable levels and substantial accumulation of fructose-1,6-bisphosphate. From the difference between the chemical shifts of internal P_i and phosphocreatine resonances, the intracellular pH was estimated to be 7.1 ± 0.1 in protein-synthesizing cells suspended in a medium of pH 7.4 at 10°C. Ehrlich cells are unable to transfer the labeled amidine group from L-(guanidino-¹⁴C)-arginine to the large intracellular glycine pool to form labeled guanidinoacetate, the demethylated precursor of creatine. These results imply that the synthesis of phosphocreatine in ATP-rich Ehrlich cells is limited primarily by the extracellular free creatine supply, the extent of which depends upon the degree of cachectic perturbation of energy and nitrogen metabolism of the tumor-bearing host.     

Bioconversion of dethiobiotin to biotin by a cell-free system of a bioYB transformant of Bacillus sphaericus

Abstract Potassium-limited cultures of Candida utilis grown with ammonium chloride as the sole nitrogen source attained a higher dry weight than similar cultures grown with sodium nitrate as the sole nitrogen source. This increase depended on the extracellular ammonia concentration and was not due to accumulation of storage polymers. We conclude that in this yeast ammonium ions can fulfill to some extent the physiological role of potassium ions and that the intracellular concentration of ammonium ions is predominantly determined by the ammonia concentration in the culture medium.