Identification and characterization of a brilliant yellow pigment produced by Bordetella pertussis

Culture supernatants of Bordetella pertussis are a brilliant yellow; however, the structure and biological role of the responsible pigment have not been investigated. In this study, a brilliant yellow‐colored fraction was extracted from culture supernatants of B. pertussis and analyzed by HPLC. UV–visible spectral analysis and mass spectrometry identified the brilliant yellow pigment as riboflavin. Riboflavin production was high in lag and early log phases and riboflavin was found to enhance growth of B. pertussis in low‐density cultures. Riboflavin production is not regulated by the BvgAS system. In addition, it was found that other Bordetella species, such as B. parapertussis , B. holmesii and B. bronchiseptica, also release riboflavin into their culture supernatants. This is the first report that B. pertussis secrets riboflavin to the extracellular space and that riboflavin may promote its growth. The mechanism may be associated with pathogenesis of B. pertussis .

     

Modulation of the Purine Pathway for Riboflavin Production in Flavinogenic Recombinant Strain of the Yeast Candida famata

Riboflavin (vitamin B₂) is an indispensable nutrient for humans and animals, since it is the precursor of the essential coenzymes flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD), involved in variety of metabolic reactions. Riboflavin is produced on commercial scale and is used for feed and food fortification purposes, and in medicine. Until recently, the mutant strains of the flavinogenic yeast Candida famata were used in industry for riboflavin production. Guanosine triphosphate is the immediate precursor of riboflavin synthesis. Therefore, the activation of metabolic flux toward purine nucleotide biosynthesis is a promising approach to improve riboflavin production. The phosphoribosyl pyrophosphate synthetase and phosphoribosyl pyrophosphate amidotransferase are the rate limiting enzymes in purine biosynthesis. Corresponding genes PRS3 and ADE4 from yeast Debaryomyces hansenii are modified to avoid feedback inhibition and cooverexpressed on the background of a previously constructed riboflavin overproducing strain of C. famata. Constructed strain accumulates twofold more riboflavin when compared to the parental strain.     

Improving the <Emphasis Type="Italic">Clostridium acetobutylicum</Emphasis> butanol fermentation by engineering the strain for co-production of riboflavin

Solvent-producing clostridia are well known for their capacity to use a wide variety of renewable biomass and agricultural waste materials for biobutanol production. To investigate the possibility of co-production of a high value chemical during biobutanol production, the Clostridium acetobutylicum riboflavin operon ribGBAH was over-expressed in C. acetobutylicum on Escherichia coli–Clostridium shuttle vector pJIR750. Constructs that either maintained the original C. acetobutylicum translational start codon or modified the start codons of ribG and ribB from TTG to ATG were designed. Riboflavin was successfully produced in both E. coli and C. acetobutylicum using these plasmids, and riboflavin could accumulate up to 27 mg/l in Clostridium culture. Furthermore, the C. acetobutylicum purine pathway was modified by over-expression of the Clostridium purF gene, which encodes the enzyme PRPP amidotransferase. The function of the plasmid pJaF bearing C. acetobutylicum purF was verified by its ability to complement an E. coli purF mutation. However, co-production of riboflavin with biobutanol by use of the purF over-expression plasmid was not improved under the experimental conditions examined. Further rational mutation of the purF gene was conducted by replacement of amino acid codons D302 V and K325Q to make it similar to the feedback-resistant enzymes of other species. However, the co-expression of ribGBAH and purFC in C. acetobutylicum also did not improve riboflavin production. By buffering the culture pH, C. acetobutylicum ATCC 824(pJpGN) could accumulate more than 70 mg/l riboflavin while producing 190 mM butanol in static cultures. Riboflavin production was shown to exert no effect on solvent production at these levels.     

Submerged culture conidial germination and conidiation of the bioherbicideColletotrichum truncatum are influenced by the amino acid composition of the medium

Summary Submerged culture experiments were conducted to determine the optimal nitrogen source for rapidly producing conidia of the bioherbicide,Colletotrichum truncatum. Germination ofC. truncatum conidial inocula in submerged culture occurred most rapidly (>95% in 6 h) in media provided with a complete complement of amino acids. When (NH₄)₂SO₄, urea, or individual amino acids were provided as the sole nitrogen source, conidial germination was less than 20% after 6 h incubation. Conidia production was delayed inC. truncatum cultures grown in media with urea or individual amino acids as nitrogen sources compared to cultures supplied with Casamino acids or complete synthetic amino acid nitrogen sources. The use of methionine, lysine, tryptophan, isoleucine, leucine or cysteine as a sole nitrogen source severely inhibitedC. truncatum conidia production. Media with synthetic amino acid mixtures less these inhibitory amino acids produced significantly higher conidia yields compared to media with amino acid mixtures containing these amino acids. When various amounts of each individual inhibitory amino acid were added to media which contained amino acid mixtures, cysteine and methionine were shown to be most effective in reducing conidiation. An optimal nitrogen source forC. truncatum conidiation in submerged culture should contain a complete mixture of amino acids with low levels of cysteine, methionine, leucine, isoleucine, lysine and tryptophan for rapid conidiation and optimal conidia yield.The mention of firm names or trade products does not imply that they are endorsed or recommended by the US Department of Agriculture over other firms or similar products not mentioned.     

Negative effect of ammonium nitrate as nitrogen source on the production of water-soluble red pigments by Monascus sp.

Ammonium salts, especially ammonium nitrate, have been used as nitrogen sources for production of traditional water-insoluble Monascus pigments. However, we noted that defined media employing NH₄NO₃ as the sole nitrogen source in fermentations supported only poor pigment production by Monascus sp., and the pigments produced were mainly cell-bound. NH₄NO₃ was found not to (a) repress pigment synthase formation, (b) enhance synthase decay, or (c) serve as a nitrogen source for pigment production by resting cells; it had a weak inhibitory effect on the action of pigment synthase(s). The high level of cell-bound did not exert a feedback effect on the further synthesis of pigments. These observations indicate that the reason why NH₄NO₃ supports only low pigment production during fermentations is the poor ability of NH₄NO₃ to donate nitrogen in the Schiff-base reaction converting orange pigments to red ones.     

Gluconic Acid Fermentation by Pullularia pullulans

During the study on the sugar metabolism of molds, several strains of Pullularia pullulans were found to produce large amounts of gluconic acid from glucose. Thirty seven strains of P. pullulans were then tested for their acid-producing abilities. Seven strains did not produce any amount of gluconic acid. However, all of the other strains were shown to be capable of producing this acid. The superior strains produced yiclds of gluconic acid as high as about 90%, based on glucose available, in shaking cultures at 30°C after 2 days. The yields were increased up to approximately 100% during later stages. In addition to high yields, gluconic acid was produced exclusively by these strains. Glutamic acid and inorganic ammonium salts, such as (NH₄)₂SO₄, NH₄Cl and (NH₄)₂HPO₄, were favorable nitrogen sources for acid production. In the case of (NH₄)₂SO₄, the optimum concentration was 0.05%. The addition of CaCO₃ was essential for gluconic acid production by P. pullulans and a 3% concentration of CaC0₃ appeared to be desirable for the maximum conversion to gluconic acid in a medium containing 10% glucose.     

Glutamic Acid Independent Production of Poly(γ-glutamic acid) by Bacillus subtilis TAM-4

A bacterium that produced a large amount of poly(γ-glutamic acid) (PGA) when it was grown aerobically in a culture medium containing ammonium salt and sugar as sources of nitrogen and carbon, respectively, was isolated from soil. The bacterium, strain TAM-4, was classified as Bacillus subtilis. The maximum PGA production (22.1 mg/ml) was obtained when it was grown in a medium containing 1.8% ammonium chloride and 7.5% fructose at 30°C for 96 h with shaking. Some properties of the PGA obtained at different times of cultivation were investigated by gel permeation chromatography, SDS–PAGE, and measurement of viscosity, and calculation of the d/l ratio of glutamic acid constituting PGA. The results suggested that PGA was elongated with no changes in the diastereoisomer ratio in the molecule.     

Production of vitamins by Azospirillum brasilense in chemically-defined media

The production of vitamins by Azospirillum brasilense was studied in chemically-defined media amended with malate, gluconate and fructose. The liberation of vitamins was significantly affected by the presence of different carbon sources and the age of the culture. Thiamine, niacin and pantothenic acid were produced in large amounts. Thiamine and riboflavin were produced only in culture containing malate or fructose. Biotin was not detected in the supernatants of the culture media.     

Effect of Different Carbon and Nitrogen Sources on Clostridium argentinense Toxigenicity in Coculture withPseudomonas mendocina

The effect of different carbon and nitrogen sources on the production of toxin by Clostridium argentinense was examined. The toxin production by C. argentinense in coculture with Pseudomonas mendocina increased in all the cases in relation to that produced by monocultures independent of the nature of the source. Using dextrin as carbon source C. argentinense produced the highest levels of toxin both in monocultures (300 LD₅₀/mL) and in cocultures with P. mendocina (5000 LD₅₀/mL). Experiments run in a microfermenter showed that the slow growth of cocultures associated with the assimilation of dextrin and the pH and Eh profiles favoured the production of toxin. Of the nitrogen sources assayed, corn steep liquor sustained the highest levels of toxin in both monocultures and cocultures with 3 and 2.8 fold increases with respect to that obtained using proteose peptone. The toxin production by C. argentinense cultures and C. argentinense–P. mendocina cocultures was highly dependent on the nature of the carbon and nitrogen sources used in the culture media. Growth of C. argentinense on substrates slowly assimilated stimulated the production of toxin.     

Riboflavin Biosynthesis by Candida robusta

Metal ions had little influence on riboflavin production by Candida robusta, except that Ag, Cu and Hg were strongly inhibitory. The inhibiting action of iron on its production was comparatively small, so that any previous treatment for the removal of iron from the medium was not necessary. Addition of GaCO₃ was found to be essential in media containing sucrose or acetate as a carbon source, as pointed out in the previous paper. This effect of CaCO₃ was attributed to its neutralizing action. When the reaction of the medium was kept at the optimum pH, about 7.0, high yields of riboflavin could be obtained without the presence of CaCO₃.     

Studies on Osmophilic Yeasts

Various conditions were studied which gave influences on polyalcohol production by Pichia miso. Pichia miso gave an excellent yield of polyalcohol showing good growth in the vitamin-free medium. Unlike Zygosaccharomyces high concentrations of phosphate such as 2% as KH₂PO₄ in the medium showed no detrimental effect on polyalcohol production. Remarkable reduction in polyalcohol yield was observed in the medium of high concentration of nitrogen sources, among which yeast extract showed the most striking effect. Polyalcohol fermentation was provoked in the medium of 0.1% yeast extract while the metabolic activity distinctly converted to ethanol fermentation when the organisms were incubated in the medium of 4.0% yeast extract. The fact that a large amount of ethanol more than 6% in the medium was produced aerobically by genus Pichia of oxidative dissimilation type seemed to be very interesting and noticeable. For the purpose of industrial production, it was shown that polyalcohol production in jar-fermenter scale was achieved with as good yield as that in shaking flask culture.     

Production of citric acid with immobilized Aspergillus niger

Summary The spores of Aspergillus niger were entrapped in calcium-alginate beads and precultivated in growth media with various amounts of nitrogen. During the following citric acid production in shaking cultures an optimum of acid formation and yield was observed after the precultivation with 100–200 mg/l NH₄NO₃. The productivity of the immobilized Aspergillus was found to be 1.5 times higher than in the case of free pellets. The outgrowth of free mycelia into the medium could be provided by increasing the ratio particle-volume: medium volume, using a 1-l air-lift fermenter, by which means the productivity was increased twice as much as obtained in shaking culture.     

Optimization of carotenoid production by Umbelopsis ramanniana

Umbelopsis ramanniana was investigated to increase carotenoid production. Nine different carbon sources and six different nitrogen sources were evaluated for the maximum carotenoid production. The most effective nitrogen and carbon sources were KNO₃ and lactose, respectively. Then, the optimization of medium components for enhancement of carotenoid production by Umbelopsis ramanniana was achieved using Plackett–Burman design. Box–Behnken response surface methodology was applied to further optimize carotenoid and biomass production. Carbon to nitrogen ratio, lactose concentration, and shaking speed were studied as variables in Box–Behnken design. The optimum conditions for carotenoid and biomass production were determined as 32.42 g/L of lactose concentration, 20:1 of carbon to nitrogen ratio, and shaking speed of 130 rpm. The maximum carotenoid and biomass production under optimized conditions were 1141 μg/L (β-carotene-Eq) and 13.14 g/L, respectively. When compared to the control fermentation, carotenoid, and biomass production were increased by about 2 and 1.3 folds, respectively.     

Bioproduction of riboflavin: a bright yellow history

Riboflavin (vitamin B₂) is an essential nutrient for humans and animals that must be obtained from the diet. To ensure an optimal supply, riboflavin is used on a large scale as additive in the food and feed industries. Here, we describe a historical overview of the industrial process of riboflavin production starting from its discovery and the need to produce the vitamin in bulk at prices that would allow for their use in human and animal nutrition. Riboflavin was produced industrially by chemical synthesis for many decades. At present, the development of economical and eco-efficient fermentation processes, which are mainly based on Bacillus subtilis and Ashbya gossypii strains, has replaced the synthetic process at industrial scale. A detailed account is given of the development of the riboflavin overproducer strains as well as future prospects for its improvement.     

Production of Monascus-Pigment in a Submerged Culture

The production of pigment by the molds belonging to the genus Monascus in a submerged culture was examined. The extracellular pigment was mainly studied. Monascus sp. No. 2 was found to be the most potent pigment producer. The optimum cultural conditions were: pH of the medium, 6.5; the temperature, 25°C; carbon sources, glucose or ethyl alcohol; nitrogen sources, polypeptone, yeast extract, monosodium glutamate or casamino acids. Glycine, l-threonine, l-arginine, l-alanine and l-tyrosine were found to be the most effective substances promoting pigment production.

Mycelial forms of this strain were correlated with pigment formation in submerged culture. As it grew into pellet type, the yield of pigment was at high level.

The Monascus-pigment in the fermentation liquid seemed to be firmly bound to the protein-like substances which made the pigment apparently soluble.     

Sophorolipids: improvement of the selective production by Starmerella bombicola through the design of nutritional requirements

Microtiter plates were used as minireactors to study Starmerella bombicola growth and sophorolipid (SL) production. Compositional analysis of SL mixtures by liquid chromatography with electrospray ionization tandem mass spectrometry showed similar results on SLs produced using the laboratory scale (shake flask) and the microscale (24-well microtiter plates (MTP)) approach. MTP suitability on SL production was proven, being this approach, especially advantageous on SL screening. Several hydrophilic carbon sources, hydrophobic co-substrates and nitrogen sources were supplied to culture media, and their influence on SL production was evaluated. The selection of specific hydrophobic co-substrate and nitrogen sources influenced the ratio acidic/lactonic SLs. In fact, it was observed that the production of acidic C18:1 diacetylated hydroxy fatty acid SLs was favoured when culture media was supplied with avocado, argan, sweet almond and jojoba oil or when NaNO₃ was supplied instead of urea. This last case was observed after 144 h of cultivation. A new SL, lactonic C18:3 hydroxy fatty acid diacetylated SL, was detected when borage and onagra oils were used individually as co-substrates. Overall results indicated the potential of the selective production of different and new sophorolipids by Starmerella bombicola based on the selection of carbon and nitrogen sources to culture media.     

Influence of Nitrogen Source, Thiamine, and Light on Biosynthesis of Abscisic Acid by Cercospora rosicola Passerini

Abscisic acid production by Cercospora rosicola Passerini in liquid shake culture was measured with different amino acids in combination and singly as nitrogen sources and with different amounts of thiamine in the media. Production of abscisic acid was highest with aspartic acid-glutamic acid and aspartic acid-glutamic acid-serine mixtures as nitrogen sources. Single amino acids that supported the highest production of abscisic acid were asparagine and monosodium glutamate. Thiamine was important for abscisic acid production. Leucine inhibited abscisic acid production. C. rosicola produced abscisic acid in the dark, but production more than doubled in the presence of light.     

Utilization of carbon and nitrogen sources and acid/alkali production by cowpea rhizobia

Summary Sixteen slow-growing strains of rhizobia (15 cowpea rhizobia and oneR. japonicum) were examined to determine the effects of carbon and nitrogen sources on acid/alkali production in culture media. We found that the pH changes of the medium were more influenced by nitrogen sources than carbon sources (with the exception of ribose). When ammonium sulphate was used as a nitrogen source, all the cowpea rhizobia strains produced acid. When yeast-extract was used as a nitrogen source, however, a heterogenous pattern for acid/alkali production was found. The majority of the strains produced alkali from nitrate, glutamate and urea irrespective of carbon sources and acid from ribose irrespective of nitrogen sources.     

Induction of carotenoid pigments in callus cultures of Calendula officinalis L. in response to nitrogen and sucrose levels

In vitro carotenoid pigment production in callus cultures of Calendula officinalis L. was investigated using two basal media, semi-solid versus liquid media and varied concentrations of sucrose, ammonium, and nitrate nitrogen. Of the two explants that were evaluated, floret explants were best for callus induction using Murashige and Skoog (MS) medium supplemented with 2.0 mg l⁻¹ 2,4-dichlorophenoxyacetic acid under complete darkness. Carotenoid pigment induction was significantly augmented when the sucrose concentration was increased. Low sucrose concentrations in the culture medium deferred the onset of pigment induction and reduced the overall levels of carotenoid pigments produced. The highest amount of carotenoid pigments was observed when the callus was grown on the MS medium without ammonium nitrogen. The quantity of carotenoids was slightly elevated in cultures grown on semi-solid medium than those grown in liquid medium. In vitro carotenoid production was optimized by modifying the concentration of ammonium nitrogen to nitrate nitrogen in the culture medium and enhancing the sucrose concentration.     

Pigmentation and autofluorescence of Cryptococcus species after growth on tryptophan and anthranilic acid media

Cryptococcus neoformans and Candida albicans produced a pink pigment from media containing tryptophan. Approximately 30% of the C. neoformans strains produced large amounts of the pink (purple after 6 days) pigment in the absence of light whereas 70% of the Cryptococcus neoformans strains, as well as C. laurentii, C. albidus, C. diffluens, and C. albicans also produced the pink pigment with light being required for significant early production (2–6 days). Significant production did occur for Cryptococcus but not Candida species in the dark after extended incubation (10–25 days). C. terreus produced brown pigments from tryptophan and C. luteolus produced a trace of a buff pigment. Most Candida species produced either pink or brown pigments but not both. In contrast, many Cryptococcus species producing the pink pigment simultaneously produced brown pigments. C. terreus, C. albidus, and C. diffluens produced brown pigments from anthranilic acid whereas C. neoformans, C. laurentii, C. luteolus, and the medically important Candida species did not produce significant amounts of pigments from anthranilic acid. Cryptococcus and Candida species were autofluorescent when tryptophan was a major nitrogen source whereas yeast cell autofluorescence was not observed when anthranilic acid was used. Pigmentation of some Cryptococcus species also the substrate.Operated for the U.S. Department of Energy under contract number EY-76-C-05-0033This article is based on work supported by the Division of Biomedical and Environmental Research.