Properties ofAzotobacter vinelandii in phosphate-limited batch cultures

Batch cultures ofA. vinelandii in ammonium phosphate-limited and N-free phosphate-limited media were compared with control cultures (N-free phosphate-sufficient media). The effects of phosphate limitation on growth were determined by viable cells counts. Under phosphate-limitation conditions, growth inhibition and decreased viability were observed. Intracellular levels of RNA, poly-3-hydroxybutyrate, phosphate and oxygen uptake were significantly affected by phosphate limitation. When phosphate-limited cultures were examined microscopically, pleomorphism was more marked than in control cultures. Also phosphate-limited cells showed an increase in resistance to UV irradiation, mechanical disruption, desiceation and the combined action of ethylenediaminetetraacetie acid and lysozyme.     

Phosphate-limited culture of Azotobacter vinelandii.

Batch cultures of Azotobacter vinelandii grown in phosphate-deficient media were compared with control cultures grown in phosphate-sufficient media. Phosphate limitation was assessed by total cell yield and by growth kinetics. Although cell protein, nucleic acids, and early growth rate were unaffected by phosphate deficiency, cell wall structure, oxygen uptake, and cell viability were significantly affected. Also, phosphate-limited cells contained much larger amounts of poly-beta-hydroxybutyric acid but lower adenylate nucleotide energy charge than did control cells. The ratio of adenosine 5'-triphosphate to adenosine 5'-diphosphate was much lower in phosphate-deficient cells. The data indicate a substrate saving choice of three metabolic pathways available to this organism under different growth conditions.     

Influence of phosphate supply on teichoic acid and teichuronic acid content of Bacillus subtilis cell walls

Bacillus subtilis 168 was grown in chemostat culture in fully defined media containing a constant concentration of magnesium and concentrations of phosphate that varied from those giving phosphate-limited growth to those in which phosphate was present in excess and magnesium was limiting. Phosphate-limited bacteria were deficient in wall teichoic acid and contained less than half as much cellular phosphate as did bacteria grown in excess of phosphate. Approximately 70% of the additional phosphate in the latter bacteria was present as wall teichoic acid, indicating that the ability of the bacteria to discontinue teichoic acid synthesis when grown under phosphate limitation permits a substantial increase in their growth yield. Since not all of the additional phosphate is present as wall teichoic acid other cellular phosphates may also be present in reduced amounts in the phosphate-limited bacteria. The content of phosphate groups in walls of magnesium-limited bacteria was similar to the content of uronic acid groups in walls of phosphate-limited bacteria, and walls of bacteria grown in media of intermediate composition contained intermediate proportions of the two anionic polymers. Phage SP50, used as a marker for the presence of teichoic acid, bound densely to nearly all of the bacteria in samples containing down to 22% of the maximum content of teichoic acid. Apparently, therefore, nearly all of these bacteria contain teichoic acid, and the population does not consist of a mixture of individuals having exclusively one kind of anionic polymer. Bacteria containing less than 22% of the maximum content of teichoic bound in a nonuniform manner, and possible explanations for this are discussed.     

Total and cell wall phosphorus content inBacillus megaterium in phosphate-limited media

A comparative study of the amount of total and cell wall phosphorus inBacillus megaterium ATCC 33085, grown in media with or without phosphate limitation was carried out. The phosphorus levels were investigated during six successive subcultures. A progressive decrease in total phosphorus was found in cells cultivated in a phosphate-limited medium. A decline in the cell wall phosphorus level was observed starting only from the third subculture in phosphate-limited medium, and no phosphorus was detected in the walls of cells in the fifth subculture.     

Cyclic-2,3-diphosphoglycerate levels in Methanobacterium thermoautotrophicum reflect inorganic phosphate availability

Methanobacterium thermoautotrophicum was grown in phosphate-limited chemostat cultures at a dilution rate corresponding to a doubling time of 13.2 h. The cyclic-2,3-diphospho-D-glycerate content of these cells was 8 to 10-fold lower than that of cells grown in batch cultures having a doubling time of 11.5 h. This metabolite accounted for 5% of cell dry weight during batch growth on 2 mM phosphate. In the chemostat the steady-state concentration of phosphate was 4 microM, showing that this methanogen is adapted to highly efficient growth at low phosphate concentrations. Since growth rates were similar in both cultures, the growth rate clearly does not depend on intracellular levels of cyclic-2,3-diphosphoglycerate.     

Microcalorimetry studies of energy changes during the growth of Klebsiella aerogenes in simple salts/glucose media: growth in phosphate-limited medium

The power-time traces for cells of Klebsiella aerogenes grown in phosphate-limited media were unlike those for cells grown in phosphate-sufficient media. At a phosphate concentration of 18 mumol dm-3 three phases of growth were recognized: the exponential growth phase during which phosphate became exhausted; a slower growth phase to the exhaustion of glucose, and a period of minimal growth when acetate, formed as secondary metabolite, was metabolized. At a concentration of 40 mumol dm-3 only two phases were identified. From the measured values of biomass, carbon dioxide output, glucose and acetate, mass and energy balances were established for each phase of growth and for overall growth. The results are discussed in terms of the energy stored as biomass, that wasted as heat and that required for maintenance and biosynthetic processes when the cells are grown under normal and stressful conditions.     

Control of teichoicand teichuronic acid biosynthesis in Bacillus subitlis 168trp−: Evidence for repression of enzyme synthesis and inhibition of enzyme activity

Phosphate starvatiion induced teichuronic acid synthesis in cells of Bacillus subtilis 168trp^? which had previously been grown with excess phophate. This induction was prevented when protein synthesis was inhibited immediately prior to phosphate starvation and under these conditions cells continued to form teichoic acid. The converse was true when phosphate was added to cells previously grown in phosphate-limited chemostat. The increase in teichoic acid synthesis normally following phosphate addition was prevented by chlorampehnicol or amino acid starvation and cells continued to make teichuronic acid. The suggestion that repression of enzyme synthesis is involved in controlling the type of wall polymer made was supported by the low levels of UDP-glucose dehydrogenase found in cells grown with excess phosphate and of CDP-glycerol pyrophosphorylase in phophate-limited cells. The greater amounts of teichoic acid made under phosphate limitation and of teichuronic acid with excess phosphate when protein synthesis was also inhibited indicated that modulation of enzyme activity occurs. Glycerol starvation of a glycerol-requiring mutant did not derepress teichuronic acid synthesis, indicating that glycerol-containing intermediates do not act as repressors.     

Bioenergetics and end-product regulation of Clostridium thermosaccharolyticum in response to nutrient limitation

Fermentation of xylose by Clostridium thermosaccharolyticum was studied in batch and continuous culture in which the limiting nutrient was either xylose, phosphate, or ammonia. Transient results obtained in continuous cultures with batch grown inoculum and progressively higher feed substrate concentrations exhibited ethanol selectivities (moles ethanol/moles other products) in excess of 11. The hypothesis that this high ethanol selectivity was a general response to mineral nutrient limitation was tested but could not be supported. Growth and substrate consumption were related by the equation q(s)(1 - Y(x) (c))G(ATP) = (mu/Y(ATP) (max)) + m, with q(s) the specific rate of xylose consumption (moles xylose/hour . g cells), Y(x) (c) the carbon based cell yield (g cell carbon/g substrate carbon), G(ATP) the ATP gain (moles ATP produces/mol substrate catabolized), mu the specific growth rate (1/h), Y(ATP) (max) the ATP-based cell yield (g cells/mol ATP), and m the maintenance coefficient (moles ATP/hour . g cells). Y(ATP) (max) was found to be 11.6 g cells/mol ATP, and m 9.3 mol ATP/hour . g cells for growth on defined medium. Different responses to nutrient limitation were observed depending on the mode of cultivation. Batch and immobilized cell continuous cultures decreased G(ATP) by initiating production of the secondary metabolites, propanediol, and in some cases, D-lactate; in addition, batch cultures increased the fractional allocation of ATP to maintenance and/or wastage. Nitrogen-limited continuous free-cell cultures maintained a constant cell yield, whereas phosphate-limited continuous free-cell cultures did not. In the case of phosphate limitation, the decreased ATP demand associated with the lowered cell yield was accompanied by an increased rate of ATP consumption for maintenance and/or wastage. Neither nitrogen or phosphorus-limited continuous free-cell cultures exhibited an altered G(ATP) in response to mineral nutrient limitation, and neither produced secondary metabolites. (c) 1993 John Wiley & Sons, Inc.     

Nitrogenase activity and regeneration of the cellular ATP pool in Azotobacter vinelandii adapted to different oxygen concentrations.

The in vivo activity of nitrogenase under aerobiosis was studied with diazotrophic chemostat cultures of Azotobacter vinelandii grown under glucose- or phosphate-limited conditions at different dilution rates (Ds, representing the growth rate mu) and different dissolved oxygen concentrations. Under steady-state conditions, the concentration as well as the cellular level of ATP increased in glucose-limited cultures when D was increased. Irrespective of the type of growth limitation or the dissolved oxygen concentration, the steady-state concentrations of ATP and of dinitrogen fixed by nitrogenase increased in direct proportion to each other. Specific rates of dinitrogen fixation as well as of the regeneration of the cellular ATP pool were compared with specific rates of cellular respiration. With glucose-limited cultures, the rate of regeneration of the ATP pool and the rate of respiration varied in direct proportion to each other. This relationship, however, was dependent on the dissolved oxygen concentration. As compared to the phosphate-sufficient control, phosphate-limited cultures exhibited the same nitrogenase activity but significantly increased respiratory activities. Rates of ATP regeneration and of cellular respiration of phosphate-limited cultures did not fit into the relationship characteristic of glucose-limited cultures. However, a linear relationship between the rates of dinitrogen fixation and ATP regeneration was identified irrespective of the type of growth limitation and the dissolved oxygen concentration. The results suggest that the ATP supply rather than cellular oxygen consumption is of primary importance in keeping nitrogenase activity in aerobic cultures of A. vinelandii.     

Plant cells selected for resistance to phosphate starvation show enhanced P use efficiency

Summary In many organisms, phosphate starvation induces multigene systems that act to increase the availability and uptake of exogenous phosphates. Tissue-cultured tomato cells were plated onto solid media containing starvation levels of phosphate. While most cells died, we identified isolated clumps of callus capable of near-normal rates of growth. Starvation-resistant cells were used to start suspension cultures that were kept under phosphate starvation conditions. A selected cell line showed constitutively enhanced secretion of acid phosphatase and greatly increased rates of phosphate uptake. These pleiotropic effects suggest modification of a regulatory apparatus that controls coordinated changes in the expression of a multigene system. The somaclonal variant cell line grew normally under phosphate-sufficient conditions, but did significantly better than unselected cells under phosphate-limited conditions. In vitro selection may be a useful system for developing phosphate ultraefficient crop plants.     

Cell wall metabolism in Bacillus subtilis subsp. niger: accumulation of wall polymers in the supernatant of chemostat cultures

Cell wall polymers were measured both in the cells and in the cell-free medium of samples from steady-state chemostat cultures of Bacillus subtilis, growing at various rates under magnesium or phosphate limitation. The presence of both peptidoglycan and anionic wall polymers in the culture supernatant showed the occurrence of wall turnover in these cultures. Variable proportions of the total peptidoglycan present in the culture samples were found outside the cells in duplicate cultures, indicating that the rate of peptidoglycan turnover is variable in B. subtilis. Besides peptidoglycan, anionic wall polymers were detected in the culture supernatant: teichoic acid in magnesium-limited cultures and teichuronic acid in phosphate-limited cultures. In several samples, the ratio between the peptidoglycan and the anionic polymer concentrations was significantly lower in the extracellular fluid than in the walls. This divergency was attributed to the occurrence of direct secretion of anionic polymers after their synthesis.     

ACCUMULATION AND REDUCTION OF ARSENATE BY THE FRESHWATER GREEN ALGA CHLORELLA SP. (CHLOROPHYTA)

Arsenate accumulation and reduction kinetics at both high and low phosphate concentrations were investigated in the green alga Chlorella sp, isolated from the arsenic-contaminated Upper Mystic Lake near Boston, MA. Growth rate, accumulated cellular arsenic, and release of As(III) were determined over a range of arsenate concentrations. Arsenate inhibited growth and reduced final cell yield at high phosphate concentration. However, growth rate, final cell yield, and cellular arsenic content were all enhanced by higher arsenate concentrations in cultures grown at a low concentration of phosphate. The traditional view that phosphate-limited cells are necessarily more sensitive to As(V) toxicity may not be correct. The reduction rates of As(V) by Chlorella sp. obtained in our laboratory were similar to net reduction rates measured in epilimnetic water from the Upper Mystic Lake, demonstrating the importance of phytoplankton in arsenic reduction in freshwater.     

Effects of carbon source and growth rate on cell wall composition of Bacillus subtilis subsp. niger.

A study was made to determine whether factors other than the availability of phosphorus were involved in the regulation of synthesis of teichoic and teichuronic acids in Bacillus subtilis subsp. niger WM. First, the nature of the carbon source was varied while the dilution rate was maintained at about 0.3 h-1. Irrespective of whether the carbon source was glucose, glycerol, galactose, or malate, teichoic acid was the main anionic wall polymer whenever phosphorus was present in excess of the growth requirement, and teichuronic acid predominated in the walls of phosphate-limited cells. The effect of growth rate was studied by varying the dilution rate. However, only under phosphate limitation did the wall composition change with the growth rate: walls prepared from cells grown at dilution rates above 0.5 h-1 contained teichoic as well as teichuronic acid, despite the culture still being phosphate limited. The wall content of the cells did not vary with the nature of the growth limitation, but a correlation was observed between the growth rate and wall content. No indications were obtained that the composition of the peptidoglycan of B. subtilis subsp. niger WM was phenotypically variable.     

Effects of growth environment on recombinant plasmid stability in Saccharomyces cerevisiae grown in continuous culture

A recombinant strain of Saccharomyces cerevisiae, containing a 2-m-fragment-based plasmid (pYEa4) was grown under non-selective conditions in continuous culture. The decrease in the population carrying the plasmid-encoded auxotrophic marker, LEU2, was examined under different physiological conditions. The difference in growth rate (µ) between plasmid-free and plasmid-containing cells and the rate of plasmid segregation (R) were determined using a non-linear regression technique. Loss rates were greater in defined glucose-limited cultures than in complex glucose-limited cultures. Plasmid loss was µ-dominated in cultures grown on defined media whereas µ and R were co-dominant in cultures grown on complex medium. Loss rates increased with increasing dilution rate in complex glucose-limited cultures. The reverse was found in defined glucose-limited cultures. Plasmid retention and loss kinetics determined from defined magnesium-limited cultures were not significantly different from those observed in defined glucose-limited cultures. Although plasmid retention in defined phosphate-limited culture was not significantly different from that in defined glucose-limited culture, reduced R and increased µ indicated an alternative physiological effect of phosphate limitation on plasmid stability.     

PHYSIOLOGICAL RESPONSES TO PHOSPHORUS LIMITATION IN BATCH AND STEADY-STATE CULTURES OF DUNALIELLA TERTIOLECTA (CHLOROPHYTA): A UNIQUE STRESS PROTEIN AS AN INDICATOR OF PHOSPHATE DEFICIENCY1

A protein unique to phosphorus stress observed in Dunaliella tertiolecta Butcher was studied in the context of phosphate-limited cell physiology and is a potential diagnostic indicator of phosphate deficiency in this alga. Cells were grown over a range of limited, steady-state growth rates and at maximum (replete) and zero (phosphate-starved) growth rates. The stress protein, absent in nutrient-replete cells, was produced under all steady-state phosphate-limited conditions and increased in abundance with increasing limitation (decreasing growth rate). Cellular carbon: phosphorus ratios and the maximum uptake rate of phosphate (V_m) increased with increasing limitation, whereas the ratio of chlorophyll a: carbon decreased. Alkaline phosphatase activity did not respond to limitation but was measurable in starved, stationary-phase cells. F_v/F_m, a measure of photochemical efficiency, was a nonlinear, saturating function of p, as commonly observed under N limitation. The maximum F_v/F_m of 0.64 was measured in nutrient-replete cells growing at μ_max, and a value of zero was measured in stationary-phase starved cells. When physiological parameters were compared, the P-stress protein abundance and F_v/F_m were the most sensitive indicators of the level of deficiency. The stress protein was not produced under N- or Fe-limited conditions. It is of high molecular weight (>200) and is associated with internal cell membranes. The stress protein has several characteristics that make it a potential diagnostic indicator: it is 1) unique to phosphorus limitation (i.e. absent under all other conditions), 2) present under limiting as well as starved conditions, 3) sensitive to the level of limitation, and 4) observable without time-course incubation of live samples.     

Morphology and anionic polymer content in the cell wall of a glycerol-requiring mutant ofBacillus subtilis

A glycerol-requiring mutant ofBacillus subtilis formed irregular spheres and showed disturbed septum formation, when subjected to growth limitation by the supply of glycerol. Under phosphate limitation the cells were also round and developed asymmetric septa. In magnesium-limited cultures the cells contained a thickened wall, as compared with that of the parent strain grown under the same conditions. Chemical analysis revealed the presence of teichoic acid as the major anionic polymer in the wall of the glycerol-, as well as the magnesium-limited cells of the glycerol-requiringB. subtilis mutant.Under phosphate limitation teichuronic acid was the only anionic polymer present in the wall. Thus, in this respect, there were no apparent differences between mutant organisms and the parent strain when grown under magnesium and phosphate limitation, respectively and the observed morphological deviations could not be correlated with an altered anionic polymer content of the wall.     

Regulation of Phosphate Accumulation in the Unicellular Cyanobacterium Synechococcus

The phosphorus contents of acid-soluble pools, lipid, ribonucleic acid, and acid-insoluble polyphosphate were lowered in Synechococcus in proportion to the reduction in growth rate in phosphate-limited but not in nitrate-limited continuous culture. Phosphorus in these cell fractions was lost proportionately during progressive phosphate starvation of batch cultures. Acid-insoluble polyphosphate was always present in all cultural conditions to about 10% of total cell phosphorus and did not turn over during balanced exponential growth. Extensive polyphosphate formation occurred transiently when phosphate was given to cells which had been phosphate limited. This material was broken down after 8 h even in the presence of excess external orthophosphate, and its phosphorus was transferred into other cell fractions, notably ribonucleic acid. Phosphate uptake kinetics indicated an invariant apparent K(m) of about 0.5 muM, but V(max) was 40 to 50 times greater in cells from phosphate-limited cultures than in cells from nitrate-limited or balanced batch cultures. Over 90% of the phosphate taken up within the first 30 s at 15 degrees C was recovered as orthophosphate. The uptake process is highly specific, since neither phosphate entry nor growth was affected by a 100-fold excess of arsenate. The activity of polyphosphate synthetase in cell extracts increased at least 20-fold during phosphate starvation or in phosphate-restricted growth, but polyphosphatase activity was little changed by different growth conditions. The findings suggest that derepression of the phosphate transport and polyphosphate-synthesizing systems as well as alkaline phosphatase occurs in phosphate shortage, but that the breakdown of polyphosphate in this organism is regulated by modulation of existing enzyme activity.     

Coupling of saxitoxin biosynthesis to the G1 phase of the cell cycle in the dinoflagellate Alexandrin fundyense: temperature and nutrient effects

The correlation between changes in length of the different cell cycle stages and the toxicity of Alexandrium fundyense Balech was studied in semi-continuous cultures. Growth rates ranging from 0.031 d(-1) to 0.36 d(-1) were established at different temperatures or levels of phosphate limitation. In all treatments, G1 was the phase with the longest duration. Decrease in growth rate was associated with an increase in duration of the different cell cycle stages. Toxin content was always directly correlated to the duration of the G1 phase. In both the temperature treatments and the phosphate limitation experiments, toxin production rates remained constant for the respective range of conditions, implying that the variations in toxin content observed were a result of increasing periods of biosynthetic activity. Toxin accumulation was directly correlated to protein biosynthesis in all temperature treatments. In contrast, toxin content showed little correlation with protein content as phosphate limitation increased. Significant differences in toxin composition were observed between the temperature and phosphate treatments. Total concentrations of GTX II and III and C I and II were significantly higher in the phosphate-limited cultures, while the levels of STX, NEO and gonyautoxins I and IV remained virtually unchanged. We conclude that toxin biosynthesis in A. fundyense is coupled to the G1 phase of the cell cycle, that toxin synthesis is not down-regulated by phosphate deprivation and that interconversions among saxitoxin derivatives are influenced by the availability of phosphate.     

Insufficient uracil supply in fully aerobic chemostat cultures of Saccharomyces cerevisiae leads to respiro-fermentative metabolism and double nutrient-limitation

A combination of chemostat cultivation and a defined medium was used to demonstrate that uracil limitation leads to a drastic alteration in the physiology of auxotrophic cells of Saccharomyces cerevisiae. Under this condition, the carbon source is dissimilated mainly to ethanol and acetate, even in fully aerobic cultures grown at 0.1 h^?1, which is far below the critical dilution rate. Differently from nitrogen-, sulphur-, or phosphate-limited cultures, uracil limitation leads to residual sugar (either glucose or sucrose) concentrations below 2 mM, which characterizes a situation of double-limitation: by the carbon source and by uracil. Furthermore, the specific rates of CO₂ production and O₂ consumption are increased when compared to the corresponding prototrophic strain. We conclude that when auxotrophic strains are to be used for quantitative physiological studies, special attention must be paid to the cultivation conditions, mainly regarding medium formulation, in order to avoid limitation of growth by the auxotrophic nutrient.