Growth of Saccharomycopsis fibuliger and Candida utilis in mixed culture on apple processing wastes

Sequential cultures of the yeasts Saccharomycopsis fibuliger and Candida utilis were grown on selected wastes from the processing of apples. Effluent from cider manufacture supported the growth of 45.4 g cells/100 g substrate and C. utilis formed 96% of the viable cells in the harvested biomass. Whole, unripe apples yielded 44 g cells/100 g substrate with a reduction in the substrate viscosity of 84%. C. utilis formed 56% of the viable cells in the harvested biomass. Effluent from pectin manufacture contained a substantial proportion of reducing compounds and supported the growth of C. utilis without prehydrolysis by S. fibuliger, to yield 33 g cells/100 g substrate.     

Regulation of a mixed culture of Streptococcus lactis and Saccharomycopsis fibuliger

Summary In a mixed culture of Saccharomycopsis fibuliger Y76 and Streptococcus lactis 65.1 on starch the main interactions are commensalism and competition. Oxygen-limited batch and continuous cultures of S. fibuliger showed accumulation of sugars. When oxygen was used as an external regulatory parameter in the mixed culture lactic acid, acetic acid and formic acid were formed. Ethanol produced by S. lactis was most likely assimilated by S. fibuliger. Continuous mixed cultures were stable under conditions of oxygen limitation at the dilution rates tested (0.10 h^–1 and 0.15 h^–1). Conversion yields of 35 to 40% were obtained but may be improved.     

An investigation into the pectolytic activity of the yeast Saccharomycopsis fibuliger

Saccharomycopsis fibuliger cells produce an inducible hydrolase, tentatively characterized as a polygalacturonase [poly(1,4-α-d-galacturonide) glycanohydrolase, EC 3.2.1.15], which is associated with the yeast cells and which causes the partial hydrolysis of pectin or poly-d-galacturonic acid. No evidence of pectinesterase (pectin pectyl hydrolyase, EC 3.1.1.11) or pectate lyase [poly(1,4-α-d-galacturonide) lyase, EC 4.1.1.1] activity has been found. Enzyme production took place at an optimum temperature of 28°C, whereas optimum activity was at ～45°C. The optimum pH for pectolytic activity was similar to the optimum pH for cell growth. A reduction in the concentration of dissolved oxygen in the culture medium and an increase in cell age caused an increase in the rate of pectin decomposition within the limits employed. Products of pectin decomposition consisted of a mixture of uronides including d-galacturonic acid.     

Studies on the growth of Candida utilis on d-galacturonic acid and the products of pectin hydrolysis

Candida utilis was found to utilize d-galacturonic acid for cell growth, the incubation conditions being similar to those reported for growth on other substrates. At concentrations of d-galacturonic acid below 3 g l⁻¹cell yields were similar to those obtained using glucose, although at higher concentrations cell yields were reduced. Small, regular increases in the concentration of d-galacturonic acid substantially increased cell yields under the incubation conditions employed. Poly-d-galacturonic acid, hydrolysed by a fungal polygalacturonase [poly(1,4-α-d-galacturonide) glycanohydrolase, EC 3.2.1.15] prior to cell growth, yielded 27 g C. utilis cells/100 g substrate. Acid-hydrolysed pectin yielded 23 g cells/100 g substrate but no cell growth was found using pectin which had been degraded by alkali. The possibility of using pectin materials for the production of singlecell protein in a modified Symba process is discussed.     

Production of polygalacturonase byByssochlamys fulva

Summary Byssochlamys fulva was grown in two fermentation media using shake flasks, stirred fermentor and disc fermentor under conditions to give maximum production of pectolytic enzymes. Only polygalacturonase activity was detected in the culture filtrates during all fermentations. In all production conditions studied, no evidence of pectin methylesterase, pectin lyase, cellulase or proteinase activities were found. The maximum polygalacturonase activity (4.5 units/ml) was achieved when the microorganism was grown on medium II in shake flasks at pH 4.0–4.5 and 30°C after 12 days of fermentation.     

Purification and Properties of a Pectate Lyase in Erwinia aroideae

A strain of Erwinia aroideae produced an extracellular pectolytic enzyme under growth conditions with pectin or pectic acid as the inducer. This strain also produced a pectin lyase when nalidixic acid is added to a culture medium. The pectolytic enzyme produced under the growth conditions was purified approximately 40-fold from the culture fluid by carboxy- methyl cellulose and Sephadex G-75 gel column chromatographies. The purified enzyme was almost homogeneous on sodium dodecyl sulfate polyacrylamide gel electrophoresis, having a molecular weight of about 36,000 to 38,000. This enzyme, with optimal activity at pH 9.0 to 9.2, produced reaction products which had a strong absorption at 230 nm indicating a lyase type of the reaction. The enzyme activity was markedly stimulated by calcium ion and completely inhibited by cobalt and mercuric ions and by ethylenediaminetetraacetate. Pectic acid or pectin with lower methoxyl content was a good substrate for this enzyme, while no significant activity was observed when pectin with higher methoxyl content was used as a substrate. It was concluded that the enzyme produced under the normal growth conditions is an endo-pectate lyase and differs from the pectin lyase induced by nalidixic acid.     

Studies on the growth of Saccharomycopsis fibuliger on pectic materials

Growth experiments have indicated that the yeast Saccharomycopsis fibuliger is able to utilize pectic materials as a carbon source for cell growth. Small quantities of yeast extract or mycological peptone and maltose are necessary to initiate growth. Cell yields of 35 g/100 g pectin were obtained after modification of the pH value, the concentration of calcium ions and pectin in the growth medium. The optimum pH for cell growth was 4.8, which is similar to the reported optimum for cell growth on starch. Cell yields declined at higher concentrations of pectin, as a result of the reduced rate of oxygen absorption into the growth medium. Neither the concentration of ammonium and phosphate ions nor the type of inorganic nitrogen source significantly affected cell growth within the experimental conditions employed.     

Effects of Temperature on Composition and Cell Volume of Candida utilis

Candida utilis NCYC 321 was grown in steady-state culture in a chemostat under glucose limitation or NH₄⁺ limitation at temperatures of 30, 25, 20, and 15 C and at dilution rates (equal to growth rates) in the range of 0.35 to 0.05 hr⁻¹. Deoxyribonucleic acid contents of cells grown under the various conditions remained approximately constant, but the contents of several other cell components varied. Over the range of 30 to 15 C, the greatest differences were in the ribonucleic acid (RNA) and protein contents of cells grown under NH₄⁺ limitation, which increased as the temperature was decreased. The contents of other components, particularly adenosine triphosphate in cells grown under glucose limitation, varied more when the cells were grown at different rates at a fixed temperature. Cells grown at a fixed rate under NH₄⁺ limitation increased in volume as the temperature was decreased below 30 C. The increase in volume was closely correlated with increases in the proportions of RNA and protein in the dry weight of cells. Cells grown under glucose limitation showed much smaller increases in volume; these increases were poorly correlated with the increased RNA content and hardly at all with the increased protein content. Increases in volume with a decrease in growth temperature from 30 to 20 C were also demonstrated in cells grown under phosphate limitation and to a much smaller extent in cells grown under glycerol limitation. The increased RNA synthesized at low temperatures by cells grown under NH₄⁺ limitation was found almost exclusively in the 40,000 × g supernatant fluid, but only about 40% of it sedimented at 100,000 × g. Cells grown at a fixed rate under NH₄⁺ limitation synthesized less total carbohydrate when the temperature was decreased from 30 to 15 C. This decrease was mainly in the trichloroacetic acid-soluble fraction (probably trehalose) and in the intracellular hot alkali-soluble glucan (probably glycogen). Cells grown at a fixed rate under glucose limitation showed a small increase in carbohydrate content as the temperature was decreased from 30 to 15 C.     

Commensalistic Interaction Between Lactobacillus acidophilus and Propionibacterium shermanii

Propionibacterium shermanii and Lactobacillus acidophilus were grown in batch mixed culture in a 5-liter fermenter under controlled conditions of pH 5.8 and 35°C on a semisynthetic medium with glucose as an energy source. Cellular efficiencies and fermentation balances were developed for this pair and compared with P. shermanii grown in pure culture on glucose, lactate, and a mixture of these substrates and with L. acidophilus grown on glucose. P. shermanii had ATP yield coefficient values of 17 for each substrate alone but had an average value of 30 for substrate mixtures. Growth rates were similar for P. shermanii on glucose or lactate but higher cell yields were observed for glucose. P. shermanii used both lactate and glucose in mixed substrate until lactate was exhausted, and growth rates slowed thereafter. L. acidophilus had a similar ATP yield coefficient of 15 but produced lower cell yields than did P. shermanii on glucose. Mixed culture of both microorganisms on glucose resulted in much faster and nearly equal growth rates for both and no lactate accumulation in the medium. Acetic acid production rates per generation were lower in mixed culture, suggesting use by the growing culture. The cause of the synergistic effect was not determined but may be due to the rapid production and removal of lactate or CO₂ enhancement in mixed culture.     

Studies in the Physiology of Parasitism: XX. The Pathogenicity of Botrytis cinerea, Sclerotinia fructigena, and Sclerotinia laxa, with special reference to the part played by pectolytic enzymes

1. Though Sclerotinia fructigena, S. laxa, and Botrytis cinereacause rotting of apple tissue and death of the protoplasts,little or no pectolytic activity was detectable in extractsof the rotted tissue. 2. Pectic materials were extracted from normal and parasitizedapple tissue in three fractions and precipitated as calciumpectate. There was a loss of total, total insoluble, and solublepectic substances in the invaded tissues. This was most markedwith B. cinerea and S. laxa and least with S. fructigena. 3. Pectolytic activity was measured by methods involving (a)maceration of plant tissues, (b) viscosity and reducing groupdeterminations in pectic substrates, (c) increase in acidityof pectin. By these methods it was shown that pectolytic enzymeswere produced by all three fungi in synthetic media. With S.fructigena, which was the only fungus studied in detail, replacementof glucose by pectin increased the formation of pectolytic enzymes. 4. When various apple extracts were used as culture media, littleor no pectolytic activity was detectable. With all three fungithe presence of apple juice in a culture medium, which by itselfwas suitable for enzyme formation, resulted in the suppressionof pectolytic activity. 5. Oxidized apple juice had a pronounced effect in deactivatingcertain pectolytic enzymes, an effect which was especially markedwith B. cinerea. This points to an interaction between the pectolyticand oxidizing systems and introduces a new line of approachto the study of the biochemical interaction between host andparasite.     

I. Cytochrome oscillations in continuous culture: Action of chloramphenicol on Saccharomyces carlsbergensis and Candida utilis

Oscillations in the A, B and C group cytochromes of Saccharomyces carsbergensis and Candida utilis have been observed in continuous culture following the addition and removal of chloramphenicol. With S. carlsbergensis reproduction of these oscillations proved difficult due to the fermentative nature of the yeast. With C. utilis at D = 0.1 h⁻¹ the oscillations in teh A group cytochromes were statistically significant and 3–6 times the standard deviation observed in steady sate. The oscillations provide evidence of a feedback loop controlling cytochrome synthesis and have a period of the same order of that predicted by Goodwin for the protein (enzyme) component of his model (viz. 6–8 h). With C. utilis the period of these oscillations was a function of the growth rate varying from approx. 10 h at a growth rate of 0.1 h⁻¹ (mean generation time 6.9 h) to 3 h at a growth rate of 0.3 h⁻¹ (mean generation time 2.3 h).     

Cell yields of bacteria grown on methane

Several mixed cultures of methane-oxidizing bacteria have been isolated. Among them, culture HR (consisting of two gram-negative rods, one 0.5 × 1.0 μ, the other 0.8 × 2 to 3 μ) was found to be the fastest-growing and to give the highest yields. Optimal conditions for rapid growth and high cell yields from methane were found to be: 30 C, NH₄⁺ as nitrogen source, and pH 6.5. Requirements for CO₂ and Cu⁺⁺ were observed. Under these conditions, generation times of approximately 3 hr and cell yields from methane between 65 and 70% could be attained. Culture HR can utilize methane, methanol, ethyl alcohol, 1-propanol, n-butyl alcohol, and glucose, but not propane, for growth. Yeast and beef extracts are inhibitory. Carbon balances demonstrate that few if any products other than cells and CO₂ are produced from methane under the growth conditions used. Cell analyses for carbon, hydrogen, nitrogen, and amino acid content of culture HR were also made.     

Effects of organism type and growth conditions on cell disruption by impingement

Data for disruption of C. utilis, S. cerevisiae and B. subtilis cells by impingement of a high velocity jet of suspended cells against a stationary surface are compared. Differences between organisms were observed, but there were no general differences found between yeast and bacteria. In addition, growth conditions were found to have an effect on disruption with cells grown at a high specific growth rate easier to disrupt than cells grown at a low rate.Nomenclature a exponent of pressure (dimensionless) - D dilution rate (h^\s-1) - K dimensional rate constant (Pa ^\s-) - N number of passes (dimensionless) - P operating pressure (Pa) - R fraction of cells disrupted (dimensionless) - u_m maximum specific growth rate (h^\s-1)     

Production of lipid from starch by a nitrogen-controlled mixed culture of Saccharomycopsis fibuliger and Rhodosporidium toruloides

Summary Production of lipid from starch in a two-component mixed culture in a fed batch process was studied. Saccharomycopsis fibuliger was used as the amylolytic microorganism and Rhodosporidium toruloides, which does not grow on starch, as the lipid producer. The concentration of nitrogen can be used as an external regulator of growth and competition in this process. The total biomass concentration decreased and the relative amount of Rh. toruloides increased with decreasing initial concentration of nitrogen in the medium. The highest lipid concentration (9.7 g·l^-1), highest overall lipid production rate (0.15 g·l^-1·h^-1) and highest concentration of lipid in biomass (36.5%) were obtained in cultures with an initial nitrogen concentration of 0.5 g·l^-1. Compared to monocultures of Lipomyces starkeyi and Aspergillus oryzae on starch, the mixed culture showed slightly lower conversion of starch to lipid but was superior in the final lipid concentration and the overall lipid production rate.     

Continuous culture of Candida utilis: influence of medium nitrogen concentration

When Candida utilis was grown in continuous culture, decreasing the concentration of N in the medium affected cell composition, biomass yield, biomass productivity, maximal growth rate and cell morphology. When the dilution rate was low (0.1 h^-1), reducing N from 1100 to 100 mg/l led to a 40% decrease in RNA content of the cells. Nitrogen-limited growth, which occurred when N<420 mg/l, was associated with significant changes in cell-wall carbohydrates and a significant reduction in the glycogen content of the cells. A set of culture conditions was established which permitted maximal consumption of the main nutrients in the medium and the production of yeast biomass suitable as a source of single-cell protein.     

Enzyme production by the nematode-trapping fungus,Duddingtonia flagrans

Duddingtonia flagrans degrades peptides, proteins, starch, pectin, lipase, lecithin and oils when grown on agar medium. Serine proteases with optimal activity at pH 8.5 to 10.5 were produced when it was grown in submerged culture. It also produced phospholipase C with optimal activity at pH 8.5, lipases with high activity at pH 3.5 and at 7.5 to 8.5 and pectin-degrading enzymes with pH optima of 3 and 8. The pH of the culture medium affected the types of lipases and pectin degrading enzymes produced but not the proteases or phospholipase C.     

A New Pectolytic Enzyme in Erwinia aroideae Formed in the Presence of Nalidixic Acid

Pectolytic enzyme formation by whole cells of Erwinia aroideae was markedly stimulated when nalidixic acid was added to a culture medium. The activity of pectolytic enzyme was markedly stimulated by nalidixic acid when the activity was measured by the decrease of viscosity of pectin, while activities of both polygalacturonic acid trans-eliminase and polygalacturonase which were measured respectively by the increase of optical density at 230 nm and the liberation of aldehyde groups, were not stimulated. The analysis of pectolytic enzyme by carboxymethyl cellulose column chromatography indicated that there was a significant difference in the elution profiles between the pectolytic enzyme induced by nalidixic acid and that synthesized under normal conditions. Therefore, we conclude that two enzymes are distinct protein species.     

Effect of tannins on growth and amylase production by Calvatia gigantea

The effect of tannins was investigated on growth and α-amylase (α-1,4-glucan 4-glucanohydrolase, EC 3.2.1.1) production by the edible fungal species Calvatia gigantea, grown in a laboratory-scale fermenter on acorn starch media containing up to 2 g tannins l⁻¹. No inhibition of both growth and amylase excretion was observed when the fungus was cultivated on media containing 40 to 100 times higher tannin concentration than that reported to inhibit microbial growth. Amylase excretion was enhanced when starch was dry sterilized but specific growth rate was higher when starch was wet sterilized. Biomass and amylase production increased with increasing substrate concentration and specific growth rate reached its maximum value at 20 g l⁻¹ starch concentration. The optimum pH of biomass and amylase productionwas 5.0–5.5 and 6.0−6.5 respectively and that of temperature was 29–32 and 29–30°C respectively. Maximum yields of 68 250 U amylase and 0.58–0.60 g biomass g⁻¹ acorn were obtained at optimum growth conditions. A plot of reciprocal growth rate vs. reciprocal starch concentration made it possible to calculate K_s = 0.84 g acorn starch l⁻¹ and μ_max = 0.249 h⁻¹.     

Novel lignocellulolytic ability of Candida utilis during solid-substrate cultivation on apple pomace

Lignocellulolytic enzymes from conventional and non-conventional yeasts are not commonly studied, and they have never been described for Candida utilis species. After solid-substrate cultivation of C. utilis (CCT 3469) on apple pomace, degradation of cellulose, pectin and lignin fragments was observed. Production of the main lignocellulolytic enzymes by C. utilis was investigated and high activity for pectinase (239 U ml^–1) as well as a significant manganese-dependent peroxidase (19.1 U ml^–1) activity was found. Low cellulase (3.0 U ml^–1) and xylanase (1.2 U ml^–1) activities were also observed suggesting that C. utilis may have lignocellulose degradation ability.