Stimulation of bikaverin production by sucrose and by salt starvation in Fusarium fujikuroi

The fungus Fusarium fujikuroi (Gibberella fujikuroi mating group C) exhibits a rich secondary metabolism that includes the synthesis of compounds of biotechnological interest, such as gibberellins, bikaverin, and carotenoids. The effect of the carbon source on their production was checked using a two-phase incubation protocol, in which nine different sugars were added upon transfer of the fungus from repressed to appropriate inducing conditions, i.e., nitrogen starvation for gibberellins and bikaverin and illumination for carotenoids production. Most of the carbon sources allowed the synthesis of these metabolites in significant amounts. However, bikaverin production was strongly increased by the presence of sucrose in comparison to other carbon sources, an effect not exhibited for the production of gibberellins and carotenoids. The bikaverin inducing effect was enhanced in the absence of phosphate and/or sulfate. Similar results were also observed in carotenoid-overproducing strains known to be altered in bikaverin production. The induction by salt starvation, but not by sucrose, correlated with an increase in messenger RNA levels of gene bik1, encoding a polyketide synthase of the bikaverin pathway.     

Regulation of Carotenogenesis and Secondary Metabolism by Nitrogen in Wild-Type Fusarium fujikuroi and Carotenoid-Overproducing Mutants

The fungus Fusarium fujikuroi (Gibberella fujikuroi MP-C) produces metabolites of biotechnological interest, such as gibberellins, bikaverins, and carotenoids. Gibberellin and bikaverin productions are induced upon nitrogen exhaustion, while carotenoid accumulation is stimulated by light. We evaluated the effect of nitrogen availability on carotenogenesis in comparison with bikaverin and gibberellin production in the wild type and in carotenoid-overproducing mutants (carS). Nitrogen starvation increased carotenoid accumulation in all strains tested. In carS strains, gibberellin and bikaverin biosynthesis patterns differed from those of the wild type and paralleled the expression of key genes for both pathways, coding for geranylgeranyl pyrophosphate (GGPP) and kaurene synthases for the former and a polyketide synthase for the latter. These results suggest regulatory connections between carotenoid biosynthesis and nitrogen-controlled biosynthetic pathways in this fungus. Expression of gene ggs1, which encodes a second GGPP synthase, was also derepressed in the carS mutants, suggesting the participation of Ggs1 in carotenoid biosynthesis. The carS mutations did not affect genes for earlier steps of the terpenoid pathway, such as fppS or hmgR. Light induced carotenoid biosynthesis in the wild type and carRA and carB levels in the wild-type and carS strains irrespective of nitrogen availability.     

Regulation of Gibberellin Biosynthesis in Gibberella fujikuroi

Gibberellin production by Gibberella fujikuroi started only after the nitrogen source was depleted and ceased upon its renewal. Nitrogen repression of gibberellin biosynthesis is not an indirect effect of the growth arrest that follows the depletion of an essential nutrient because gibberellins were not produced upon depletion of phosphate. Mycelia produced gibberellins when suspended in a glucose solution. Production ceased some time after depletion of glucose and resumed upon its readdition. Under certain conditions, the gibberellin production rate was inversely proportional to the glucose concentrations. The specific regulation of gibberellin biosynthesis by the nitrogen source imposes a revision of the concept that gibberellins are secondary metabolites whose production is triggered by imbalance or cessation of growth.     

Redirection of pigment biosynthesis to isocoumarins in Fusarium

Colonies of Fusarium species often appear red due to production of pigments, such as aurofusarin or bikaverin. The primary compounds in these biosynthetic pathways are YWA1 and pre-bikaverin, respectively, catalyzed by two multidomain polyketide synthases (PKSs), which both have a claisen-type cyclase domain (CLC) in their N terminal. Disruption of the CLC domains has been shown to result in formation of the lactones citreoisocoumarin and SMA93 instead of YWA1 and pre-bikaverin. In the present study we have discovered a medium with low nitrogen content which partially redirects the aurofusarin and bikaverin pathways to produce citreoisocoumarin and SMA93, respectively. This is first time that SMA93 is identified in a fungus and we suggest that it is renamed bikisocoumarin, as it is derived from the bikaverin pathway. The redirection of the aurofusarin and bikaverin biosynthetic pathways was reverted by adding inorganic nitrogen to the medium, whereas organic nitrogen in form of arginine or glutamine stimulated isocoumarin production. This suggests that nitrogen source can influence isocoumarin production. Production of isocoumarin was also repressed by alkaline conditions, which suggests that nitrogen supply is not the sole regulatory factor in the pathway. The redirection was observed in all producers of aurofusarin (6) and bikaverin (2), suggesting the presence of a conserved regulatory mechanism.     

Bikaverin production and applications

Bikaverin is a reddish pigment produced by different fungal species, most of them from the genus Fusarium, with antibiotic properties against certain protozoa and fungi. Chemically, bikaverin is a polyketide with a tetracyclic benzoxanthone structure, resulting from the activity of a specific class I multifunctional polyketide synthase and subsequent group modifications introduced by a monooxygenase and an O-methyltransferase. In some fungi, bikaverin is found with smaller amounts of a precursor molecule, called norbikaverin. Production of these metabolites by different fungal species depends on culture conditions, but it is mainly affected by nitrogen availability and pH. Regulation of the pathway has been investigated in special detail in the gibberellin-producing fungus Fusarium fujikuroi, whose genes and enzymes responsible for bikaverin production have been recently characterized. In this fungus, the synthesis is induced by nitrogen starvation and acidic pH, and it is favored by other factors, such as aeration, sulfate and phosphate starvation, or sucrose availability. Some of these inducing agents increase mRNA levels of the enzymatic genes, organized in a coregulated cluster. The biological properties of bikaverin include antitumoral activity against different cancer cell lines. The diverse biological activities and the increasing information on the biochemical and genetic basis of its production make bikaverin a metabolite of increasing biotechnological interest.     

Adenylyl cyclase plays a regulatory role in development, stress resistance and secondary metabolism in Fusarium fujikuroi

The ascomycete fungus Fusarium fujikuroi (Gibberella fujikuroi MP-C) produces secondary metabolites of biotechnological interest, such as gibberellins, bikaverin, and carotenoids. Production of these metabolites is regulated by nitrogen availability and, in a specific manner, by other environmental signals, such as light in the case of the carotenoid pathway. A complex regulatory network controlling these processes is recently emerging from the alterations of metabolite production found through the mutation of different regulatory genes. Here we show the effect of the targeted mutation of the acyA gene of F. fujikuroi, coding for adenylyl cyclase. Mutants lacking the catalytic domain of the AcyA protein showed different phenotypic alterations, including reduced growth, enhanced production of unidentified red pigments, reduced production of gibberellins and partially derepressed carotenoid biosynthesis in the dark. The phenotype differs in some aspects from that of similar mutants of the close relatives F. proliferatum and F. verticillioides: contrary to what was observed in these species, ΔacyA mutants of F. fujikuroi showed enhanced sensitivity to oxidative stress (H(2)O(2)), but no change in heavy metal resistance or in the ability to colonize tomato tissue, indicating a high versatility in the regulatory roles played by cAMP in this fungal group.     

Regulation by ammonium of nitrate and nitrite assimilation in Chlamydomonas reinhardtii

The inhibitor of mRNA synthesis, 6-methylpurine, inhibited nitrate reductase derepression in either ammonium-grown or methylammonium-treated wild-type cells of Chlamydomonas reinhardtii, but not in nitrogen-starved cells. In contrast, 6-methylpurine did not inhibit nitrate reductase synthesis in the methylammonium-resistant mutant 2170 (ma-1) either grown on ammonium, treated with methylammonium or nitrogen starved, but did inhibit the continuous synthesis of nitrate reductase, which required the presence of nitrate in the media. In both wild-type and mutant 2170 grown on ammonium and transferred to nitrate media, cycloheximide immediately prevented nitrate reductase derepression when added either at the beginning or at different times of induction treatment. Unlike wild-type cells, mutant 2170 was able to take up either nitrate or nitrite simultaneously with ammonium in whose presence nitrate and nitrite reductases were synthesized. However, synthesis of nitrate reductase was progressively inhibited in the mutant cells when the intracellular ammonium levels were raised as a result of an increase in either the external pH or the extracellular ammonium concentrations. The results rule out the existence of maturase-like proteins in Chlamydomonas and indicate that ammonium has a double effect on the regulation of nitrate reductase synthesis: (a) it prevents nitrate reductase mRNA production; and (b) it controls negatively the expression of this mRNA.     

Production of gibberellins and bikaverin by cells of Gibberella fujikuroi immobilized in carrageenan

The production of gibberellins and bikaverin by immobilized and free cells of Gibberella fujikuroi strains was followed. Both types of cells, free and immobilized, produced similar titers of the secondary metabolites during the normal growth cycle. The kinetics of nutrient use and product formation by the immobilized cells lagged behind that of the free cells and this was assumed to be the result of diffusional limitations imposed on the immobilized cells. A noticeable difference was that in the immobilized cells, all of the bikaverin was excreted into the medium for both strains of G. fujikuroi tested but in the free cell fermentation 44% was excreted for strain ACC 917 and only 10% for strain GF1a. Gibberellin and bikaverin could be produced in a semi-continuous fashion with both free and immobilized cells for a period of 16 d in a resuspension medium containing 0.12 mM or 0.60 mM ammonium chloride. No definite advantage, on a productivity basis, for using immobilized cells over free cells could be seen.     

Impact of ammonium permeases mepA, mepB, and mepC on nitrogen-regulated secondary metabolism in Fusarium fujikuroi

In Fusarium fujikuroi, the production of gibberellins and bikaverin is repressed by nitrogen sources such as glutamine or ammonium. Sensing and uptake of ammonium by specific permeases play key roles in nitrogen metabolism. Here, we describe the cloning of three ammonium permease genes, mepA, mepB, and mepC, and their participation in ammonium uptake and signal transduction in F. fujikuroi. The expression of all three genes is strictly regulated by the nitrogen regulator AreA. Severe growth defects of ΔmepB mutants on low-ammonium medium and methylamine uptake studies suggest that MepB functions as the main ammonium permease in F. fujikuroi. In ΔmepB mutants, nitrogen-regulated genes such as the gibberellin and bikaverin biosynthetic genes are derepressed in spite of high extracellular ammonium concentrations. mepA mepB and mepC mepB double mutants show a similar phenotype as ΔmepB mutants. All three F. fujikuroi mep genes fully complemented the Saccharomyces cerevisiae mep1 mep2 mep3 triple mutant to restore growth on low-ammonium medium, whereas only MepA and MepC restored pseudohyphal growth in the mep2/mep2 mutant. Overexpression of mepC in the ΔmepB mutants partially suppressed the growth defect but did not prevent derepression of AreA-regulated genes. These studies provide evidence that MepB functions as a regulatory element in a nitrogen sensing system in F. fujikuroi yet does not provide the sensor activity of Mep2 in yeast, indicating differences in the mechanisms by which nitrogen is sensed in S. cerevisiae and F. fujikuroi.     

Effect of the gln-1b mutation on nitrogen metabolite repression in Neurospora crassa.

In Neurospora crassa, synthesis of the enzymes of nitrate assimilation, nitrate reductase and nitrite reductase, was repressed by the presence of ammonium, glutamate, or glutamine. This phenomenon was a manifestation of the regulatory process termed nitrogen metabolite repression whereby alternative pathways of nitrogen acquisition are not expressed in cells enjoying nitrogen sufficiency. However, the glutamine synthetase mutant gln-1b had derepressed levels of the nitrate assimilation enzymes. The inability of glutamine to achieve nitrogen metabolite repression in this mutant militated against its potential role as the direct effector of this regulation.     

Interactions of polyamines and nitrogen nutrition in plants

Biogenic amines occupy an important position among the many nitrogenous plant compounds. Polyamines are part of the overall metabolism of nitrogenous compounds, yet they do not seem to function in the 'normal' nitrogen nutrition. Rather, these widespread polycations (e. g. putrescine, spermidine and spermine) are involved in the regulation of growth and stress, probably by binding to negatively charged macromolecules. In addition, some diamines and polyamines are metabolized to yield 'secondary 'metabolites such as nicotine and other alkaloids. Previous studies have indicated that the ratio of nitrate to ammonium nutrition affects polyamine biosynthesis and content in intact plants. Thus, an increase in putrescine accumulation was found under conditions of excess ammonium ions, relative to nitrate. Modifications of nitrogen sources in the culture medium of tobacco cell suspensions (depletion of ammonium nitrate, or potassium nitrate, or both) resulted in marked changes in the content of cellular free polyamines. Considerable changes in the content of specific polyamines were also found with exposure to specific inhibitors of polyamine biosynthesis (difluoromethyl ornithine, difluoromethyl arginine, cyclohexylamine, methylglyoxal-bis-guanylhydrazone). However, a combination of nitrogen depletion of the medium and some inhibitors resulted in a very marked over-production of spermidine and spermine. The significance of these findings is discussed in relation to the assumption that polyamines act as a metabolic buffer, and maintain cellular pH under conditions where ammonium assimilation produces an excess of protons.     

The effect of changes in pH on phosphate and potassium uptake by Monascus rubiginosus ATCC 16367 in submerged shaken culture.

Monascus rubiginosus ATCC 16367 was cultivated aerobically in media containing ammonium and nitrate as nitrogen source. The pH of the medium was adjusted at different times, the pH of the nitrate medium being lowered to the pH of the ammonium medium and the pH of the ammonium medium raised to that of the nitrate. More phosphate was taken up on the nitrate medium, but potassium uptake did not start until 24h. On the ammonium medium, both were taken up in parallel from the beginning, but the amount of phosphate taken up never reached the same level as on nitrate medium. When the pH was adjusted, the uptakes changed, especially on the ammonium medium where a great increase in phosphate uptake was observed. More conidia were formed on the nitrate medium and more pigment on the ammonium medium. When the pH of either media was adjusted, the development of conidia and pigment production changed to that of the other control medium where the pH evolved normally in the direction of the change, regardless of the source of nitrogen. The reasons for the development of conidia on nitrate medium or where the pH is high, and the production of pigment on ammonium medium or at low pH is discussed.     

Loci controlling nitrate reductase activity in maize: ultraviolet‐B signaling in aerial tissues increases nitrate reductase activity in leaf and root when responsive alleles are present

Environmental factors, such as ultraviolet‐B (UV‐B) irradiation, have the ability to affect pathways such as nitrogen metabolism. As fixed nitrogen is the keystone mineral nutrient that controls grain crop yield, any alteration in this cycle can be detrimental to plant productivity. Nitrate reductase enzyme activity is responsible for the reduction of nitrate to nitrite, and nitrate is the major form of nitrogen assimilated in plants. In maize (Zea mays L.) production, nitrate assimilation kinetics are important for both high‐ and low‐input agricultural systems. Nitrate reductase protein activity is controlled by phosphatases and kinases. Nitrate reductase activity is responsive to environmental signals such as light–dark cycles and UV‐B radiation, although the regulatory controls are not yet fully understood. We have determined the location of maize genetic factors that control nitrate reductase activity and the extent of contribution of each of these factors, both locally in the leaf tissue and via long‐distance signaling loci that affect root nitrate reductase activity upon leaf UV irradiation. In the IBM94 recombinant inbred mapping population, the loci controlling regulation of nitrate reductase activity under UV‐B map to different positions than the loci controlling nitrate reductase activity in unexposed plants.     

The effect of pH and amino acids on conidiation and pigment production of Monascus major ATCC 16362 and Monascus rubiginosus ATCC 16367 in submerged shaken culture.

Monascus major ATCC 16362 and Monascus rubiginosus ATCC 16367 were cultivated aerobically on media containing nitrate or ammonium as nitrogen source to which the following modifications were made: (1) pH adjusted to 2.5 before sterilization; (2) addition of yeast extract; (3) addition of amino acids in identical proportions and concentrations to those found in yeast extract; (4) adjustment of pH to 2.5 after addition of amino acids. The addition of amino acids in the form of yeast extract increased mycelium formation and reduced conidiation and pigment production. The addition of an amino acid mixture did not increase mycelium formation to the same extent as yeast extract but increased the number of conidia, while pigment production was reduced, especially when nitrate was the nitrogen source. As the amino acids are taken up after conidial formation has started, it would appear that it is not the amino acids themselves which are directly responsible for the induction of conidiation. The addition of amino acids inhibits nitrate and ammonium uptake suggesting the need for an early intracellular nitrogen limitation to induce conidiation. Lowering the pH inhibits the formation of conidia and increases pigment production; also the effect of amino acid addition is totally annulled. The pH of the medium is all important in regulating the formation of conidia and pigment production. The possible effects of the pH on the uptake of certain medium components is discussed, as well as their possible control of certain metabolic pathways which ultimately determines the availability of intermediates for conidiation and pigment production.