Effect of glucose concentration on the biosynthesis of prodigiosin by serratia marcescens (author's transl)]

Serratia marcescens is an enterobacteria which produces a characteristic red pigment denominated prodigiosin. To study the effect of glucose on the kinetics of this secondary metabolite, cultures of Serratia marcescens S10 were incubated at 30 degrees C in the mineral medium GL, with glucose (2 g/l) as the carbon source. Prodigiosin production in relation to glucose consumption is studied, and parallel-wise, the effect of various concentrations of glucose on prodigiosin production. The kinetics data show the close correlation between glucose consumption and the synthesis of prodigiosin. This substrate inhibits the synthesis of pigment in cultures grown on solid medium GL with concentrations of glucose up to 15 g/l.     

Degradation of Uric Acid by Certain Aerobic Bacteria

We have isolated and identified nine cultures of aerobic bacteria capable of growing on an elective medium containing uric acid as the only source of carbon, nitrogen, and energy. Four of these cultures were identified as Aerobacter aerogenes, two as Klebsiella pneumoniae, and the remainder as Serratia killiensis, Pseudomonas aeruginosa, and Bacillus species. Another culture identified as P. fluorescens required both glucose and uric acid for growth. When 23 laboratory stock cultures were inoculated into the uric acid medium, A. aerogenes, B. subtilis, Mycobacterium phlei, P. aeruginosa, and S. marcescens were able to grow. These five cultures also grew when the uric acid was replaced with adenine, guanine, hypoxanthine, xanthine, or allantoin, but growth was poor. In all of these media, including the uric acid medium, addition of glucose along with the nitrogenous compounds yielded good growth. Induction experiments demonstrated that the ability of A. aerogenes, K. pneumoniae, P. aeruginosa, P. fluorescens, S. kiliensis, S. marcescens, B. subtilis, and Bacillus sp. to degrade uric acid is an induced property. Of these organisms, only Bacillus sp. accumulated a small amount of intracellular uric acid.     

有机碳化合物对湛江等鞭金藻生长的影响

为了探讨有机碳化合物对湛江等鞭金藻的营养效应,实验设置了在f/2培养基中添加葡萄糖、乙酸钠、半乳糖、甘油、乙醇、柠檬酸钠和甘氨酸等7种有机碳化合物的处理,测定了湛江等鞭金藻(Isochrysis zhanjiangensis)的生长情况。结果表明,参试的7种有机碳化合物中,甘氨酸对湛江等鞭金藻细胞生长的促进作用最明显,而乙醇对藻细胞生长的促进效果不明显,其他5种均有不同程度的促进作用。7种有机碳对湛江等鞭金藻胞内蛋白质含量和总脂的积累量具有一定差异性影响。0.5～10g·L^-1的葡萄糖、乙酸钠均可提高胞内蛋白质和总脂的含量。半乳糖对总脂积累量的影响不明显。     

Biosynthesis of Prodigiosin, a Secondary Metabolite of Serratia marcescens

Prodigiosenes (prodigiosin and prodigiosin-like pigments) are known to be synthesized by only one genus of Eubacteriales and by two genera of Actinomycetales. Biosynthesis by Serratia marcescens occurs over a relatively narrow range of temperatures, although the bacteria grow over a broad range. When cultures of S. marcescens were incubated at 27 C in 1.0% casein hydrolysate, viable count and protein attained maximal values within 24 to 48 h, whereas prodigiosin did not reach a maximum until 96 h. The greatest amount of pigment was synthesized when cultures were in the senescent phase of growth. Suspensions of nonproliferating bacteria incubated at 27 C in only L-alanine also synthesized prodigiosin, although at a slower rate than growing cultures. Kinetics of growth for the wild-type, red S. marcescens and a white mutant were identical when incubated at 27 C, but the wild type produced abundant pigment. These results plus other data obtained from the literature suggest that prodigiosin is a secondary metabolite. The importance of this proposal to understanding the function of prodigiosin in S. marcescens is discussed.     

Changes in redox potentials during transitional processes in pure and mixed cultures of Escherichia coli and Serratia marcescens

There were studied transitional processes accompanying the beginning of growth under glucose addition and stopping of growth under glucose exhaustion in pure and mixed aerobic cultures of Escherichia coli and Serratia marcescens. Continued record of Eh, pH, and CO2 showed that these processes sharply differ from each other in their character in pure and mixed cultures, it is particularly related to the changes of the redox potential. There is no characteristic change in the redox potential in pure culture of E. coli at growth termination in the case when S. marcescens cells are present in the culture.     

Carboxymethylcellulase produced by facultative bacteria from the hind-gut of the termite Reticulitermes hesperus.

Bacillus cereus RW1 and Serratia marcescens RW3, isolated from the hind-gut of the termite Reticulitermes hesperus, both grew well on mesquite wood and produced moderate amounts of carboxymethylcellulase. Carboxymethylcellulose (CMC) gels were depolymerized rapidly by B. cereus RW1 and slowly by S. marcescens RW3. The depolymerization of CMC was pH and temperature sensitive. Depolymerization of gels by growing cultures of B. cereus RW1 and the action of cell-free extracts of B. cereus RW1 on CMC sols were optimum at pH 6.0 and 5.5, respectively. Glucose and cellobiose increased the rate of CMC gel depolymerization. Enzyme synthesis rather than growth was stimulated by the addition of glucose to a culture of RW1 growing on a non-cellulosic substrate. Bacillus cereus RW1 produced both cell-free and cell-bound carboxymethylcellulase.     

Removal of inhibitors of bacterial growth by dialysis culture.

Dialysis culture was used to investigate the extent to which growth inhibition in bacterial cultures may be caused by accumulation of metabolites. Escherichia coli B was grown in a glucose/salts medium. A concentrated nutrient solution was pumped at a constant rate into the growing culture to ensure that growth was not limited by exhaustion of nutrients. In this way the only difference between growth conditions in dialysis and non-dialysis cultures was the transfer of dialysable metabolites from the culture vessel to the reservoir in the dialysis culture system. By adjusting the glucose concentration in the feed and maintaining a constant rate of feeding, glucose-limited growth could be achieved. Under these conditions, with oxygen in excess, bacterial yields of 140 to 150 g dry wt l-1 were obtained in dialysis culture compared with 30 to 40 g l-1 in non-dialysis culture. The high yields in dialysis culture depended on the removal of end-products of glucose metabolism. Growth inhibition was demonstrated to be the result of the combined influence of acetate, lactate, pyruvate, succinate, propionate and isobutyrate in concentrations found at the end of growth in non-dialysis cultures of Escherichia coli B.     

The kinetics and physiology of stipitatic acid and gluconate production by carbon sufficient cultures of Penicillium stipitatum growing in continuous culture

The yield from glucose of ammonia-grown carbon-limited continuous cultures of Penicillium stipitatum was ca. 20% higher than that of nitrate-grown cultures at all growth rates examined. However, the yield from oxygen was similar during growth on both nitrogen sources. Under phosphate limitation the specific rate of gluconic acid and stipitatic acid production increased with growth rate, but the former product accounted for virtually 100% of the excreted carbon. Stipitatic acid was not produced under nitrogen limitation, and glucose supplied to the culture in excess of that required for growth was virtually quantatively converted into gluconic acid. Productivities of 11.4 g gluconic acid/L/h were stably maintained in continuous culture. Under conditions of glucose excess the enzyme glucose oxidase was excreted into the culture. The specific activity of this extracellular enzyme increased when the input glucose concentration to the culture was progressively increased. The excretion of a protein under nitrogen limitation suggests that this enzyme plays an important role under these conditions. Indeed, it was demonstrated that nitrogen-limited cultures did not overmetabolize gluconate at either pH 6.5 or 3.5, although up to 29 g/L gluconate was present in the culture. The Y(gluconate) and YO(2) of C- and N-limited gluconate-grown cultures were similar indicating that the rapid conversion of glucose to gluconate probably affords a means of regulating carbon flow in this organism. Nitrogen-limited cultures of P. stipitatum overmetabolized glucose to a much greater extent than acetate, fructose, or gluconate.     

Kinetic control of ethanol production by Zymomonas mobilis

Summary Zymomonas mobilis UQM 2716 was grown anaerobically in continuous culture (D = 0.1/h; 30° C) 3nder glucose or nitrogen limitation at pH 6.5 or 4.0. The rates of glucose consumption and ethanol production were lowest during glucose-limited growth at pH 6.5, but increased during growth at pH 4.0 or under nitrogen limitation, and were highest during nitrogen-limited growth at pH 4.0. The uncoupling agent CCCP substantially increased the rate of glucose consumption by glucose-limited cultures at pH 6.5, but had much less effect at pH 4.0. Washed cells also metabolised glucose rapidly, irrespective of the conditions under which the original cultures were grown, and the rates were variably increased by low pH and CCCP. Broken cells exhibited substantial ATPase activity, which was increased by growth at low pH. It was concluded that the fermentation rates of cultures growing under glucose or nitrogen limitation at pH 6.5, or under glucose limitation at pH 4.0, are determined by the rate at which energy is dissipated by various cellular activities (including growth, ATP-dependent proton extrusion for maintenance of the protonmotive force and the intracellular pH, and an essentially constitutive ATP-wasting reaction that only operates in the presence of excess glucose). During growth under nitrogen limitation at pH 4.0 the rate of energy dissipation is sufficiently high for the fermentation rate to be determined by the inherent catalytic activity of the catabolic pathway.Abbreviations CCCP carbonyl cyanide p-trifluoromethoxyphenylhydrazone - qG rate of glucose consumption (g glucose/g dry wt cells/h) - qE rate of ethanol production (g ethanol/g dry wt cells/h) - Y growth yield (g dry wt cells/g glucose) - D dilution rate Offprint requests to: C. W. Jones     

Role of growth phase and ethanol in freeze-thaw stress resistance of Saccharomyces cerevisiae.

The freeze-thaw tolerance of Saccharomyces cerevisiae was examined throughout growth in aerobic batch culture. Minimum tolerance to rapid freezing (immersion in liquid nitrogen; cooling rate, approximately 200 degrees C min-1) was associated with respirofermentative (exponential) growth on glucose. However, maximum tolerance occurred not during the stationary phase but during active respiratory growth on ethanol accumulated during respirofermentative growth on glucose. The peak in tolerance occurred several hours after entry into the respiratory growth phase and did not correspond to a transient accumulation of trehalose which occurred at the point of glucose exhaustion. Substitution of ethanol with other carbon sources which permit high levels of respiration (acetate and galactose) also induced high freeze-thaw tolerance, and the peak did not occur in cells shifted directly from fermentative growth to starvation conditions or in two respiratorily incompetent mutants. These results imply a direct link with respiration, rather than exhaustion of glucose. The role of ethanol as a cryoprotectant per se was also investigated, and under conditions of rapid freezing (cooling rate, approximately 200 degrees C min-1), ethanol demonstrated a significant cryoprotective effect. Under the same freezing conditions, glycerol had little effect at high concentrations and acted as a cryosensitizer at low concentrations. Conversely, under slow-freezing conditions (step freezing at -20, -70, and then -196 degrees C; initial cooling rate, approximately 3 degrees C min-1), glycerol acted as a cryoprotectant while ethanol lost this ability. Ethanol may thus have two effects on the cryotolerance of baker's yeast, as a respirable carbon source and as a cryoprotectant under rapid-freezing conditions.     

Regulatory factors affecting alpha-amylase production in bacillus licheniformis.

Possible factors regulating alpha-mylase synthesis in wild-type Bacillus licheniformis and in mutants producing elevated levels of the enzyme were studied in terms of catabolite repression, apparent temperature-sensitive repression, induction, and culture age. The synthesis of alpha-amylase in the parent strain occurred long after the culture reached the stationary phase of growth as a result of de novo protein synthesis, occurred only at high temperature around 50 C and not below 45 C, appeared to be induced in the presence of oligosaccharides with some linkage of alpha-1,4-, beta-1,4, beta-1,6-glucosyl glucose, or alpha-1,6-galactosyl glucose, and was repressed by the addition of exogenous glucose or low-molecular-weight metabolites. The addition of cyclic adenosine 3',5'-monophosphate stimulated alpha-amylase accumulation in growing cultures of the parent strain, but neither shortened the long lap period prior to the start of alpha-amylase synthesis nor mitigated the repressive effect of glucose. Mutant strains derived from the parent strain showed variation in the pattern of alpha-amylase synthesis, and some of them such as F-12s and F-14 produced alpha-amylase constitutively and without sensitivity to catabolite repression or transient repression from the moment of cell growth. These results are discussed in relation to possible regulatory mechanisms that might account for the observed characteristics of alpha-amylase synthesis in this facultative thermophilic microorganism.     

Metabolic flux analysis of the mixotrophic metabolisms in the green sulfur bacterium Chlorobaculum tepidum

The photosynthetic green sulfur bacterium Chlorobaculum tepidum assimilates CO(2) and organic carbon sources (acetate or pyruvate) during mixotrophic growth conditions through a unique carbon and energy metabolism. Using a (13)C-labeling approach, this study examined biosynthetic pathways and flux distributions in the central metabolism of C. tepidum. The isotopomer patterns of proteinogenic amino acids revealed an alternate pathway for isoleucine synthesis (via citramalate synthase, CimA, CT0612). A (13)C-assisted flux analysis indicated that carbons in biomass were mostly derived from CO(2) fixation via three key routes: the reductive tricarboxylic acid (RTCA) cycle, the pyruvate synthesis pathway via pyruvate:ferredoxin oxidoreductase, and the CO(2)-anaplerotic pathway via phosphoenolpyruvate carboxylase. During mixotrophic growth with acetate or pyruvate as carbon sources, acetyl-CoA was mainly produced from acetate (via acetyl-CoA synthetase) or citrate (via ATP citrate lyase). Pyruvate:ferredoxin oxidoreductase converted acetyl-CoA and CO(2) to pyruvate, and this growth-rate control reaction is driven by reduced ferredoxin generated during phototrophic growth. Most reactions in the RTCA cycle were reversible. The relative fluxes through the RTCA cycle were 80～100 units for mixotrophic cultures grown on acetate and 200～230 units for cultures grown on pyruvate. Under the same light conditions, the flux results suggested a trade-off between energy-demanding CO(2) fixation and biomass growth rate; C. tepidum fixed more CO(2) and had a higher biomass yield (Y(X/S), mole carbon in biomass/mole substrate) in pyruvate culture (Y(X/S) = 9.2) than in acetate culture (Y(X/S) = 6.4), but the biomass growth rate was slower in pyruvate culture than in acetate culture.     

Induction of Prodigiosin Biosynthesis after Shift-Down in Temperature of Nonproliferating Cells of Serratia marcescens

Nonpigmented bacteria obtained by growth of Serratia marcescens at 38 C synthesized prodigiosin at 25 C if certain individual amino acids were added to cultures of nonproliferating cells. In order of effectiveness, the amino acids were: DL-histidine, L-proline, L-hydroxyproline, DL-alanine, L-alanine, DL-aspartic acid, D-alanine, DL-proline, L-serine, L-ornithine, L-glutamic acid, and D-proline. DL-Histidine at its optimal concentration (20 mg/ml) induced formation of prodigiosin (198 mug of prodigiosin per mg of bacterial protein) after incubation of cultures for 54 hr. Lower concentrations (10 mg/ml) of the other amino acids usually were optimum but less prodigiosin was synthesized, and the maximal amount of pigment occurred between 36 and 48 hr. DL-Methionine was not effective alone but at a low concentration (40 mug/ml) enhanced and accelerated biosynthesis of prodigiosin in the presence of other suitable amino acids. Addition of 2 mg of L-proline per ml at 0 hr induced formation of only 30 mug of prodigiosin after incubation for 42 hr, but addition at 36 hr of 5 mg more of L-proline per ml increased synthesis to 120 mug at 42 hr. Again, DL-methionine markedly augmented prodigiosin biosynthesis in these cultures. Synthesis of prodigiosin ceased if cultures were shifted from 25 to 38 C. Prodigiosin biosynthesis by the nonproliferating cells was maximum when cultures were aerated, the amount of bacterial protein was about 2.0 mg/ml, and amino acids were added at 0 hr. Bacteria synthesized prodigiosin most efficiently when they were harvested from aerated cultures grown at 38 C for 24 hr in a complete medium in a fermentor.     

The enzymic interconversion of acetate and acetyl-coenzyme A in Escherichia coli.

Mutants of Escherichia coli K12 have been isolated that grow on media containing pyruvate of proline as sole carbon sources despite the presence of 10 or 50 mM-sodium fluoroacetate. Such mutants lack either acetate kinase [ATP: acetate phosphotransferase; EC 2.7.2.1] or phosphotransacetylase [acetyl-CoA: orthophosphate acetyltransferase; EC 2.3.1.8] activity. Unlike wild-type E. coli, phosphotransacetylase mutants do not excrete acetate when growing aerobically or anaerobically on glucose; their anaerobic growth on this sugar is slow. The genes that specify acetate kinase (ack) and phosphotransacetylase (pta) activities are cotransducible with each other and with purF and are thus located at about min 50 on the E. coli linkage map. Although Pta- and Ack- mutants are greatly impaired in their growth on acetate, they incorporate [2-14C]acetate added to cultures growing on glycerol, but not on glucose. An inducible acetyl-CoA synthetase [acetate: CoA ligase (AMP-forming); EC 6.2.1.1] effects this uptake of acetate.     

Growth and Cellulase Formation by Cellvibrio fulvus

S ummary : The aerobic cellulolytic bacterium Cellvibrio fulvus grew on several sugars and polysaccharides, but not on highly substituted cellulose derivatives, organic acids and alcohols. Whereas no growth was obtained on long cotton fibres, it occurred on such fibres cut into small pieces, and on filter paper and chromatography powders derived from cotton. Lignin free wood pulp was rapidly degraded. The organism grew best at pH 7–8 and utilized nitrate, ammonium and some amino acids as nitrogen sources. The bacteria have cell-bound cellulase but enzyme was also found in the culture medium. Glucose repressed cellulase formation and the enzyme activity of cultures grown on cellulose was much higher than on sugars. Reducing sugar was not detected in cellulose cultures. The pH optimum for hydrolysis of carboxymethylcellulose (CMC) was 7 and the enzyme was inhibited by mercuric acetate but not by p -chloromercuribenzoate or EDTA. Fractionation of cellulase preparations from cultures grown on partially hydrolysed filter paper gave many components of different molecular weights. The activities of these components against carboxymethylcellulose and microcrystalline cellulose differed.     

Impact of carbon sources on growth and oxalate synthesis by the phytopathogenic fungus <Emphasis Type="Italic">Sclerotinia sclerotiorum</Emphasis>

The impact of various supplemental carbon sources (oxalate, glyoxylate, glycolate, pyruvate, formate, malate, acetate, and succinate) on growth and oxalate formation (i.e., oxalogenesis) by Sclerotinia sclerotiorum was studied. With isolates D-E7, 105, W-B10, and Arg-L of S. sclerotiorum, growth in an undefined broth medium (0.1% soytone; pH 5) with 25 mM glucose and 25 mM supplemental carbon source was increased by the addition of malate and succinate. Oxalate accumulation occurred in the presence of glucose and a supplemental carbon source, with malate, acetate, and succinate supporting the most oxalate synthesis. With S. sclerotiorum Arg-L, oxalate-to-biomass ratios, an indicator of oxalogenic potential, were dissimilar when the organism was grown in the presence of different carbon sources. The highest oxalate-to-biomass ratios were observed with pyruvate, formate, malate, acetate, and succinate. Time-course studies with acetate-supplemented cultures revealed that acetate and glucose consumption by S. sclerotiorum D-E7 coincided with oxalogenesis and culture acidification. By day 5 of incubation, oxalogenesis was halted when cultures reached a pH of 3 and were devoid of acetate. In succinate-supplemented cultures, oxalogenesis essentially paralleled glucose and succinate utilization over the 9-day incubation period; during this time period, culture pH declined but never fell below 4. Overall, these results indicate that carbon sources can regulate the accumulation of oxalate, a key pathogenicity determinant for S. sclerotiorum.     

Studies on the Production of Pink Pigment in Pseudomonas extorquens NClB 9399 Growing in Continuous Culture

S ummary . The pink pigment of Pseudomonas extorquens was identified tentatively as an oxo-carotenoid similar to rhodoxanthin. The production of the pigment increased at the end of the logarithmic phase of growth of Ps. extorquens in batch cultures. It was produced during growth on a wide variety of carbon and nitrogen sources, with the exception of ethanol, but not in the presence of diphenylamine, an observation which was consistent with the identification of the pigment as a carotenoid. The organism was grown in continuous culture under conditions of oxygen and magnesium limitation which might be expected to restrict the oxidation of γ-carotenes to pink pigments. However, such limitations caused an increase in pigmentation over that of methanol-limited cultures. Non-pink mutants of Ps. extorquens , obtained after the use of the mutagen, ethyl methyl sulphonate, did not have growth-rates lower than those of the parent strain. The pigment would seem to have no central metabolic role in actively growing cells but carbon is diverted to pigment production when growth is restricted by other than carbon limitation.     

Causes of conductance change in yeast cultures

The conductance change due to growth of Saccharomyces cerevisiae Y112, Zygosaccharomyces bailii M and Rhodotorula rabra NCYC 63 in culture media containing glucose, tartrate pH buffer and ammonium ions as sole nitrogen source was compared with that in a medium containing L-asparagine as sole nitrogen source. Decreases in conductance were observed in glucose-ammonium cultures of all three yeasts while little change occurred in cultures with L-asparagine as sole nitrogen source. This supports the hypothesis that the metabolic activity primarily responsible for conductance change in yeast cultures is the uptake of charged ammonium ions as nitrogen source and the reaction of protons with pH buffer compounds.
Rhodotorula rubra cultures with L-asparagine as sole carbon source caused large increases in conductance with growth. Chemical analyses of culture filtrates showed that this increase in conductance was due to use of L-asparagine as carbon source and the excretion of nitrogen surplus to biosynthetic needs as ammonium. In addition, the production of aspartate, acetate and bicarbonate contributed to the increase in conductance.     

Causes of conductance change in yeast cultures.

The conductance change due to growth of Saccharomyces cerevisiae Y112, Zygosaccharomyces bailii M and Rhodotorula rubra NCYC 63 in culture media containing glucose, tartrate pH buffer and ammonium ions as sole nitrogen source was compared with that in a medium containing L-asparagine as sole nitrogen source. Decreases in conductance were observed in glucose-ammonium cultures of all three yeasts while little change occurred in cultures with L-asparagine as sole nitrogen source. This supports the hypothesis that the metabolic activity primarily responsible for conductance change in yeast cultures is the uptake of charged ammonium ions as nitrogen source and the reaction of protons with pH buffer compounds. Rhodotorula rubra cultures with L-asparagine as sole carbon source caused large increases in conductance with growth. Chemical analyses of culture filtrates showed that this increase in conductance was due to use of L-asparagine as carbon source and the excretion of nitrogen surplus to biosynthetic needs as ammonium. In addition, the production of aspartate, acetate and bicarbonate contributed to the increase in conductance.