Aflatoxin formation,lipid synthesis,and glucose metabolism by Aspergillus parasiticus during incubation with and without agitation

Glucose utilization, growth of mold, and synthesis of aflatoxin and total lipid by Aspergillus parasiticus were studied with cultures that were incubated statically and with agitation. With both cultural conditions, maximal toxin formation occurred at 5 days which coincided with the end of rapid mold growth and rapid uptake of glucose. The toxin concentration decreased as incubation continued. The pattern for formation and depletion of total lipid was similar to that for aflatoxin. Maximal yields of toxin and of total lipid did not coincide with maximal production of mold mycelium. Incubation with agitation enhanced mold growth, consumption of glucose, and production of aflatoxin and total lipid during the first 3 days. Generally, more growht occured in agitated cultures, but maximal yields of aflatoxin and total lipid were lower than in quiescent cultures. The need for limited, but not excessive, O₂ for synthesis of aflatoxin and lipid also was demonstrated by varying the volume of medium in flasks that were incubated quiescently. Incorporation of [1-¹⁴C] glucose into aflatoxin indicated that limiting the O₂ supply and thereby favoring glucose catabolism via the Embden-Meyerhof pathway enhanced toxin formation. Aflatoxin formation also was greater when oxidative respiration of the mold was restricted by a metabolic inhibitor. Results suggest that the degree of aeration of the culture is important in controlling biosynthesis of aflatoxin.     

Quinones and respiratory activity in Spoendonema epizoum

Conidia, gemmae, submerged mycelium and surface cultures of different ages of Sporendonema epizoum were analyzed for isoprenoid quinones. Respiratory activities of the fungus, metabolizing endogenous substrates and glucose, were determined. Q-9 was the only quinone detected; its concentration, lowest in conidia, increases during germination and then decreases in submerged culture. Q-9 concentrations in surface cultures are much higher than those in submerged cultures and are not related to culture age. Changes in Q-9 concentration and respiratory activity are roughly parallel; a peak is reached during gemma formation.     

Growth morphology of Streptomyces akiyoshiensis in submerged culture: influence of pH, inoculum, and nutrients.

Most media in which the growth of shaken submerged cultures of Streptomyces akiyoshiensis was examined did not support the formation of well-dispersed mycelial suspensions. Investigation of the culture conditions promoting dispersed growth showed the pH of the culture medium to be of critical importance; an initial value of 5.5 minimized aggregation of the mycelium while supporting adequate biomass production. In cultures started at this pH, spore inocula gave better mycelial dispersal than did vegetative inocula; with spore inocula, growth morphology was also less affected by inoculum size. The composition of the nutrient solution influenced the extent of mycelial dispersal; slow growth was often associated with clumping but no clear correlation was observed between pellet formation and the ability of carbon or nitrogen sources to support rapid growth. Increasing the phosphate concentration from 0.5 to 15 mM caused a modest decrease in mycelial aggregation. Conditions promoting a well-dispersed mycelium suitable for studying the physiological control of secondary metabolism also supported the formation of 5-hydroxy-4-oxonorvaline by S. akiyoshiensis.     

Copper uptake inAspergillus niger during batch growth and in nongrowing mycelial suspensions

Copper accumulation by the filamentous fungusAspergillus niger from a glucose mineral salts medium containing copper in the concentration range 16 to 157 μM was maximal in the lag phase of growth. In the subsequent linear growth phase, the mycelial copper contents were dramatically reduced on a per gram dry weight basis. The fungal mycelium exhibited pelleted morphology and exponential growth was not apparent. The medium pH was reduced during growth in flask cultures, but this was not responsible for the reduction in copper uptake as indicated by the similar effect in cultures grown in a stirred-tank fermenter with electronic maintenance of pH at 5.5. Voltammetric analysis of medium which had supported growth of the fungus showed that copper added at a final concentration of 40 μM was complexed. Energy-dependent copper uptake from 2-(N-morpholino)ethanesulfonic acid buffer at pH 5.5 containing 40 μM copper could not be demonstrated in nongrowing mycelium. Incubation at 4°C reduced copper uptake while the presence of 10 mM glucose or preincubation of the mycelium in 1 mM sodium azide had no effect on copper uptake.     

In vitro studies of Coelomomyces punctatus from Anopheles quadrimaculatus and Cyclops vernalis

Attempts to grow mycelium of Coelomomyces punctatus from Anopheles quadrimaculatus larvae were made using more than 50 combinations of known vertebrate and invertebrate tissue culture media and microbiological media. Growth and/or differentiation of mycelium into sporangia were observed in several media. Significant growth of hyphal fragments and differentiation into young resting sporangia occurred in conditioned Mitsuhashi-Maramorosch insect tissue culture medium. This medium was conditioned by growth for 3 weeks in it of Varma's Anopheles stephensi tissue culture cells and was supplemented with 20% heat-inactivated fetal bovine serum and a synthetic tripeptide, glycyl-histidyl-lysine. Limited growth and elongation of lateral hyphal branches and subsequent development into resting sporangia with typical outer wall markings and pigmentation of mature forms were observed in a modified brain-heart infusion medium. Some media stimulated hyphae to develop into smooth-walled, spherical bodies of size and appearance typical of young sporangium initials but with no further maturity. In most media, no growth or development of mycelium occurred, but the fungus remained alive for 2–4 weeks. Mycelium of C. punctatus dissected from Cyclops vernalis did not grow and develop in any of the media utilized. However, in one case the mycelium differentiated into gametes shortly after dissection into modified brain-heart infusion medium.     

Changes in the fungus-specific,soluble-carbohydrate pool during rapid and synchronous ectomycorrhiza formation of Picea abies with Pisolithus tinctorius

A simple and convenient culture system has been developed for the analysis of ectomycorrhiza formation under controlled conditions. Rapid and synchronous mycorrhiza synthesis was observed when thin and even layers of Pisolithus tinctorius (Pers.) hyphae were brought at once into contact with the entire root system of 3-month-old Picea abies (L. Karst) plants. Suitable fungal layers were grown on cardboard with limiting glucose supply in the medium to maximize radial growth. The glucose was almost consumed by the time the fungus had spread over the whole cardboard and was ready for inoculation of the roots. At this stage, the fungus contained trehalose and arabitol as the main soluble carbohydrates. A few hours after the assembly of the culture system, contacts between roots and aerial hyphae were observed and a sheath was formed 3 days later, suggesting very rapid ectomycorrhiza formation under these conditions. The pool of soluble carbohydrates of the inoculum, i.e. the extramatrical mycelium, declined after inoculation of the roots and was almost zero after 2 weeks. The supply of carbon by the plant was then sufficient for the fungus to expand the soluble pool efficiently in both the mycorrhizas and the extramatrical mycelium. The kinetics of the carbohydrate pool and the observed differentiation of the short roots to mycorrhizas imply that in our culture system fully functional symbiosis was established no later than 14 days after the plants were inoculated with the fungus.     

A Unique Pattern of Mycelial Elongation of Blakeslea trispora and Its Effect on Morphological Characteristics and β-Carotene Synthesis

The mycelial morphology of Blakeslea trispora was of crucial importance in the production of β-carotene in submerged cultures of B. trispora. After the spores were inoculated, the time-course variation of mycelial morphology was closely examined under the microscope. With the addition of the non-ionic surfactant (Span 20: Sorbitan monolaurate, E493) to the culture medium, a unique pattern of mycelial elongation was observed: 1) slow formation of germ tubes from spores and 2) appearance of mycelia with very short length, which allowed a well-dispersed growth of B. trispora without significant pellet aggregation. Span 20 appears to act like a paramorphogen. Without Span 20, however, the fungal culture finally formed a big clump of mycelium owing to heavy cross-linking of long mycelia. But the short mycelium maintained in the course of cultivation seemed to be irrelevant to growth inhibition, because the final concentration of dry mycelium was much higher with Span 20 after 3-day cultivation. The 20-fold increase in specific yield of β-carotene (mg β-carotene produced per g mycelium) was achieved with this drastic change in the pattern of mycelial elongation. The reason for this result might be more effective mass transfer and/or enhanced sensitivity to environmental oxidative stress in the well-dispersed mycelial cultures of B. trispora.     

Non-species-specific effects of unacylated homoserine lactone and hexylresorcinol, low molecular weight autoregulators, on the growth and development of bacteria

We conducted a comparative study of the effects of α-amino-γ-butyrolactone, the common structural element of extracellular microbial regulators of the homoserine lactone (HSL) group, and of 4-n-hexylresorcinol, an autoregulator of the alkylhydroxybenzene (AHB) group, on the growth and development of grampositive and gram-negative bacteria. We revealed non-species-specific effects of HSL and AHB and characterized their concentration dependencies. The addition of 10^?5?10^?3 M HSL or 10^?5?10^?4 M AHB during the exponential growth phase of the cultures grown on balanced media resulted in cell division arrest and accelerated the transition to the stationary phase that culminated in endospore formation in Bacillus cereus, Alicyclobacillus tolerans, and Sulfobacillus thermosulfidooxidans. When bacilli grew under the cultivation conditions that resulted in a low-zero spore percentage, 10^?4?10^?3 M HSL cancelled the inhibition of spore formation. In the gram-negative bacteria Pseudomonas aurantiaca and Azotobacter vinelandii, AHB at concentrations of 10^?4 to (1.5?2.5)×10^?4 M induced the formation of dormant cells. Studies with the actinobacterium Streptomyces avermitilis revealed that the HSL effect varied depending on the age of the test cultures. The addition of 10^?4 M HSL during the lag phase of a submerged streptomycete culture accelerated its transition to the stationary phase and induced the formation of endospores, the dormant cells that are regarded as alternatives to exospores (conidia). If HSL (3.64 and 4.55 mg per 1 cm² disc) was locally added to a surface S. avermitilis culture, the growing mycelium formed rings that differed in their density, in the extent of the development of aerial mycelium, and in the presence/absence of exospores. Ring-shaped growth of streptomycete mycelia was also induced by 0.075–0.75 mg of AHB; however, unlike HSL, AHB repressed exospore formation. The data on non-species-specific effects of HSL and AHB suggest that they may perform regulatory functions at the microbial community level.     

Improvement of transglutaminase production by extending differentiation phase of Streptomyces hygroscopicus: mechanism and application

Streptomyces transglutaminase (TGase) is an important industrial enzyme that catalyzes cross-linking of proteins. It is secreted as a zymogene and then is activated by proteases under physiological conditions. Although the activation process of TGase has been well investigated, the physiological function of TGase in Streptomyces has not been revealed. In this study, physiological function of TGase from Streptomyces hygroscopicus was found to be involved in differentiation by construction of a TGase gene interruption mutation strain (Δtg). The mutant Δtg showed an absence of differentiation compared with the parent strain. Furthermore, the production of TGase was found to be increased with the extending growth arrest phase of mycelium in submerged cultures. Thus, to enhance yield of TGase, the mycelium differentiation of Streptomyces was regulated via low temperature stress in a 3-L stirred-tank fermenter. The production of TGase increased by 39 % through extending the growth arrest phase for 4 h. This study found that TGase is involved in Streptomyces differentiation and proposed an approach to improve TGase production by regulation of mycelium differentiation in submerged cultures.     

Spore Yield and Microcycle Conidiation of Colletotrichum gloeosporioides in Liquid Culture

The effect of V8 juice concentration (5 to 40%, vol/vol), spore inoculum density (10⁵ and 10⁷ spores per ml), and liquid batch or fed-batch culture condition on mycelium and spore production by Colletotrichum gloeosporioides was evaluated. The amount of mycelium produced, the time required for initiation of sporulation following attainment of maximum mycelium, and the time for attainment of maximum spore concentration increased with increasing V8 juice concentration in batch culture. Cultures containing V8 juice at >10% achieved a similar spore density (apparent spore-carrying capacity) of about 0.8 mg of spores per ml (1 × 10⁷ to 2 × 10⁷ spores per ml) independent of inoculum density and V8 juice concentration. The relative spore yield decreased from a high of 64% of the total biomass for the low-inoculum 5% V8 culture, through 13% for the analogous 40% V8 culture, to a low of 2% for the high-inoculum 27% V8 culture. Fed-batch cultures were used to establish conditions of high spore density and low substrate availability but high substrate flux. The rate of addition of V8 juice was adjusted to approximate the rate of substrate utilization by the (increasing) biomass. The final spore concentration was about four times higher (3.0 mg of spores per ml) than the apparent spore-carrying capacity in batch culture. This high spore yield was obtained at the expense of greatly reduced mycelium, resulting in a high relative spore yield (62% of the total biomass). Microcycle conidiation occurred in the fed-batch but not batch systems. These data indicate that substrate-limited, fed-batch culture can be used to increase the amount and efficiency of spore production by C. gloeosporioides by maintaining microcycle conidiation conditions favoring allocation of nutrients to spore rather than mycelium production.     

Fat synthesis from supplemented beet molasses by penicillium soppi zaleski in still and shaken cultures

Media composed of molasses alone did not support good growth nor high fat formation even when used at high concentrations. Peptone supplement as an external source of nitrogen accelerated both growth and fat formation in still as well as in shake cultures. But shaking mankedly suppressed growth and fat formation in media of molasses alone or molasses and peptone.Addition of corn steep liquor (CSL) to molasses gave rise in still cultures to rapid growth that was further accelerated by shaking. Effect of CSL supplement on fat formation, as measured by fat percentage in dry mycelium, was suppressive in still cultures. In shaken cultures, fat formation was promoted by the lowest concentration only. With higher concentrations of CSL, fat content increased but fat percentage in mycelium decreased.     

Comparative Study of Metals Accumulation in Cultured In Vitro Mycelium and Naturally Grown Fruiting Bodies of Boletus badius and Cantharellus cibarius

Cantharellus cibarius Fr. (chanterelle) and Boletus badius Pers. (bay bolete) harvested from natural sites in Poland were used to derive in vitro cultures. The optimal medium composition for cultures was developed. Concentrations of the chosen elements (Zn, Cu, Fe, Mg, Ni, and Cd) in mycelium samples were measured by means of atomic absorption spectrometry. Fe concentration in the analyzed mushroom materials was in the range 215.4–680.3 μg/g dry weight. Mean values of Mg were respectively (in micrograms per gram dry weight) 541.8 for mycelium of C. cibarius cultured in vitro and 1,004.1 for C. cibarius fruiting bodies and 928.9 for the mycelium of B. badius cultured in vitro and 906.4 for B. badius fruiting bodies. The mean concentrations of Zn were 442.7 μg/g dry weight in mycelium from in vitro cultures of B. badius and 172.1 in B. badius fruiting bodies and 131.9 in the case of C. cibarius in mycelium from in vitro cultures and 95.5 for the C. cibarius fruiting bodies. Cu exhibited a reversal tendency, i.e., the element concentrations in naturally grown mushrooms were significantly higher (43.57 μg/g dry weight for C. cibarius and 43.54 μg/g for B. badius) than in cultured in vitro mycelium (12.47 μg/g for C. cibarius and 4.17 μg/g for B. badius). Ni was found in lowest concentrations ranging from 0.33 to 1.88 μg/g dry weight. Toxic metal Cd was found in relatively high concentrations in naturally grown species (0.79 μg/g dry weight—1.02). The lowest was the concentration of Cd in C. cibarius mycelium from in vitro culture—0.06 μg/g dry weight—a bit higher than it was in the B. badius mycelium (0.21 μg/g).     

Roles of in vitro plantlet age and growing period in the phenolic constituent yields of acclimatized Hypericum polyanthemum

The influences of culture period on growth, plant survival rate and content of phenolic compounds were investigated in vitro and in acclimatized field-grown plants of Hypericum polyanthemum. The growth kinetics of micropropagated plantlets cultured in MS modified medium and the concomitant transference to ex vitro conditions showed that cultures achieved maximum biomass and yield of bioactive compounds after 12 weeks of in vitro growth, with field-grown plants displaying the same survival pattern. Differences in yield among plants cultured in vitro for 8 and 12 weeks that were acclimatized and followed over two years showed that the physiological age of the in vitro cultures influenced biomass production. However, benzopyrans and total phenolic compounds (TPC) contents did not vary significantly, with the exception of the 5-hydroxy-6-isobutyryl-7-methoxy-2,2-dimethyl-benzopyran (HP3) concentration in the reproductive parts, which was higher in the plants grown in vitro for 12 weeks over the two years of the study. All analyzed plant parts from the spring harvest accumulated lower benzopyran levels than plants harvested after 18 weeks of growth in both treatments, except for the levels of 6-isobutyryl-5,7-dimethoxy-2,2-dimethyl-benzopyran (HP1) and 7-hydroxy-6-isobutyryl-5-methoxy-2,2-dimethyl-benzopyran (HP2) in the new vegetative parts of the plants, which did not vary. The concentration of TPC, which was detected at low levels in the old vegetative parts in both treatments, was not altered in other plant parts. The information provided by this work will help structure plant growth and collection periods designed to optimize the yield of each required bioactive metabolite.     

Establishment of cultivating strategy for highly aggregated mycelia of Morchella esculenta in a stirred-tank bioreactor

Mycelia of Morchella esculenta were found to aggregate rapidly in a submerged culture, which caused the decrease in dispersed mycelia and the problem of diffusion limitation. The effect of different agitation schemes on the growth of mycelia was investigated in a stirred-tank bioreactor. At the constant speed of 100 or 300?rpm, rapid aggregation caused the biomass concentration to drop to zero in 30?h, which was even worse than achieved under static culture. Intermittent agitation maintained a higher mycelium fragment concentration for 48?h and enhanced the biomass concentration to 4.73?g/L at 120?h. The operation with a polytron connection disrupted effectively mycelium aggregation, thus increasing the specific growth rate, biomass concentration and maximum productivity to 0.0613 1/h, 7.73?g/L and 0.0878?g/L?h at 88?h, respectively. Moreover, logistic equations and genetic algorithm (GA) were used for the simulation of biomass growth and estimation of all kinetic coefficients. The operating strategy developed in this study could be used for the production of highly aggregated mycelia, which could also achieve a high cell-density culture in a stirred tank reactor.     

Assay and Characteristics of Circadian Rhythmicity in Liquid Cultures of Neurospora crassa

Previous work on circadian rhythms of Neurospora crassa has been done almost exclusively with cultures expressing rhythmic conidiation and growing on solid agar medium. Such conditions severely restrict the kinds of biochemical experiments that can be carried out. We have now developed systems which allow indirect assay of circadian rhythmicity in liquid culture. Neurospora was grown in glucose and acetate liquid media under conditions which result in a range of growth rates and morphologies. Liquid media were inoculated with conidia and the cultures were grown in constant light for 33 or 48 hours, by which time floating mycelial pads had formed. Experimental pieces of mycelium then were cut and placed in fresh new liquid medium. As controls, other pieces of mycelium were cut and put directly on solid agar medium in race tubes. All cultures were transferred to constant darkness at this time. This light-to-dark transition set the phase of the circadian clock of both the liquid and solid cultures. At various times after the light-to-dark transition, the mycelial pieces in the liquid were transferred in the dark to solid medium in race tubes, where they grew normally and conidiated rhythmically. Comparison of the phase of the rhythm in these race tubes to the controls demonstrated that, under appropriate conditions, the circadian clock of the liquid cultures functions normally for at least two cycles in constant conditions. Using these culture systems, a significantly greater variety of biochemical studies of circadian rhythmicity in Neurospora is now possible.     

Effect of Culture Conditions on Ergosterol as an Indicator of Biomass in the Aquatic Hyphomycetes

Ergosterol is a membrane component specific to fungi that can be used to estimate fungal biomass using appropriate factors of conversion. Our objectives were to determine the limits of use of ergosterol content as a measure of biomass for aquatic hyphomycetes, and to evaluate a previously established ergosterol-to-biomass conversion factor. We varied inoculum quality, growth medium, and degree of shaking of four aquatic hyphomycete species. In cultures inoculated with homogenized mycelium, we found a significant effect of shaking condition and culture age on ergosterol content. In liquid cultures with defined medium, ergosterol content reached 10 to 11 μg/mg of mycelium (dry mass) and varied by factors of 2.2 during exponential growth and 1.3 during stationary phase. The increase in ergosterol content during exponential phase could be attributed, at least in part, to rapid depletion of glucose. Oxygen availability to internal hyphae within the mycelial mass is also responsible for the differences found between culture conditions. Ergosterol concentration ranged from 0.8 to 1.6 μg/mg in static cultures inoculated with agar plugs. Ergosterol content varied by a factor of 4 in two media of different richnesses. For different combinations of these parameters, strong (r² = 0.83 to 0.98) and highly significant (P 0.001) linear relationships between ergosterol and mycelial dry mass (up to 110 mg) were observed. Overall, the ergosterol content varied by a factor of 14 (0.8 to 11 mg/g). These results suggest that care must be taken when the ergosterol content is used to compare data generated in different field environments.     

Rifamycin: XXXIII. Isolation of Actinophages Active on Streptomyces mediterranei and Characteristics of Phage-Resistant Strains

Five actinophages highly specific for Streptomyces mediterranei were isolated from lysed broth cultures. Studies were performed on the effect of plating conditions on plaque formation. The development of phage-resistant strains of S. mediterranei not only eliminated the phage but also significantly increased rifamycin yields. The phage-resistant cultures proved to be more unstable than the original sensitive strain. Maintenance of the cultures as frozen vegetative mycelium assured culture stability and reproducibility of the results. Strict aseptic precautions throughout the laboratories and fermentation areas did not eliminate the danger of phage infection; effective control was obtained only with the introduction of resistant strains. S. mediterranei phages proved to be highly specific for calcium as an adsorption cofactor; addition of calcium-sequestering agents to sensitive mycelium completely prevented its lysis by the phage. The resistant strains developed were capable of adsorbing the phage and of releasing it without multiplication upon aging of the mycelium. No marked morphological, cultural, or biochemical differences were found among the various phage-resistant strains.     

Rifamycin: XXXIV. Physicochemical Characterization of Actinophages Active on Streptomyces mediterranei

Five actinophages highly specific for Streptomyces mediterranei were isolated from lysed broth cultures. Studies were performed on the effect of plating conditions on plaque formation. The development of phage-resistant strains of S. mediterranei not only eliminated the phage but also significantly increased rifamycin yields. The phage-resistant cultures proved to be more unstable than the original sensitive strain. Maintenance of the cultures as frozen vegetative mycelium assured culture stability and reproducibility of the results. Strict aseptic precautions throughout the laboratories and fermentation areas did not eliminate the danger of phage infection; effective control was obtained only with the introduction of resistant strains. S. mediterranei phages proved to be highly specific for calcium as an adsorption cofactor; addition of calcium-sequestering agents to sensitive mycelium completely prevented its lysis by the phage. The resistant strains developed were capable of adsorbing the phage and of releasing it without multiplication upon aging of the mycelium. No marked morphological, cultural, or biochemical differences were found among the various phage-resistant strains.     

Effects of Bicarbonate on Growth of Neisseria gonorrhoeae: Replacement of Gaseous CO2 Atmosphere

The effect of NaHCO₃ on the growth of Neisseria gonorrhoeae cultures was studied in a liquid and a semisolid growth medium. With a broth culture, NaHCO₃ (0.009 M) greatly reduced the lag phase and also increased the total growth. The same concentration of bicarbonate supported rapid growth when added to the semisolid medium if the plates were individually incubated in sealed plastic bags. In a container with a large air space, a higher concentration of NaHCO₃ was necessary to support growth. The assimilation of ¹⁴C-labeled NaHo₃ by growing cultures was also investigated.     

Respiration of a puff morphological mutant of Schizophyllum commune

Summary The growth kinetics of wild-type mycelium and a puff morphological mutant of Schizophyllum commune revealed greater acid production and slower growth by this mutant. The compact mycelium growth habit of puff in defined liquid medium facilitated manometric studies of cellular respiration during culture aging. Basal oxygen consumption was highest in young, 2-day cultures as was exogenous glucose stimulation while both responses declined rapidly as the mycelial pellets aged. Respiratory stimulation by certain l-amino acids including histidine, arginine and serine was only demonstrated in aged cultures of puff mycelium. A qualitative shift in terminal respiration was considered unlikely because the metabolic poison sodium azide was a potent inhibitor of mycelial oxygen consumption regardless of either the culture age or the respective exogenous substrates employed.