Mechanism of action of benzoic acid on Zygosaccharomyces bailii: effects on glycolytic metabolite levels, energy production, and intracellular pH.

The effects of benzoic acid in the preservative-resistant yeast Zygosaccharomyces bailii were studied. At concentrations of benzoic acid up to 4 mM, fermentation was stimulated and only low levels of benzoate were accumulated. Near the MIC (10 mM), fermentation was inhibited, ATP levels declined, and benzoate was accumulated to relatively higher levels. Intracellular pH was reduced but not greatly. Changes in the levels of metabolites at different external benzoic acid levels showed that glycolysis was limited at pyruvate kinase and glyceraldehyde dehydrogenase-phosphoglycerate kinase steps. Inhibition of phosphofructokinase and several other glycolytic enzymes was not responsible for the inhibition of fermentation. Instead, the results suggest that the primary action of benzoic acid in Z. bailii is to cause a general energy loss, i.e., ATP depletion.

Effect of benzoic acid on glycolytic metabolite levels and intracellular pH in Saccharomyces cerevisiae.

Low concentrations of benzoic acid stimulated fermentation rates in Saccharomyces cerevisiae. At concentrations near the maximum permitting growth, there was inhibition of fermentation, lowered ATP and intracellular pH, and relatively greater accumulation of benzoate. Changes in the levels of glycolytic intermediates suggested that fermentation was inhibited as a result of high ATP usage rather than of lowered intracellular pH. Specific inhibition of phosphofructokinase or of several other glycolytic enzymes was not observed.

Relationships among Cell Size, Membrane Permeability, and Preservative Resistance in Yeast Species.

The rate of uptake of propanoic acid and the cell dimensions were measured for 23 yeasts differing in their resistance to weak-acid-type preservatives. Relationships between reciprocal uptake rate, reciprocal permeability, cell volume, cell area, volume/area, and the MICs of benzoic acid and propanoic acid for the yeasts were tested by correlation analysis on pairs of parameters. The MIC of methylparaben, which is not a weak-acid-type preservative, was included. The most significant relationships found were between both reciprocal uptake rate and reciprocal permeability and the MICs of propanoic and benzoic acids Cell volume, area, and volume/area were each individually correlated with propanoic and benzoic acid MICs, but less strongly. In multiple regression analyses, inclusion of terms for volume, area, or volume/area did not markedly increase the significance. The MIC of methylparaben was unrelated to the uptake and permeability parameters, but did show a correlation with cell volume/area. Schizosaccharomyces pombe was anomalous in having very low permeability. Exclusion of these outlying data revealed particularly strong relationships (P < 0.001) between both reciprocal uptake rate and reciprocal permeability and the benzoic acid MIC. MICs for Zygosaccharomyces bailii isolates were substantially higher than for the other species, and therefore Z. baillii isolates had a large influence on the regressions. However, the relationships observed remained significant even after removal of the Z. bailii data. In showing a correlation between the rate at which propanoic acid enters yeast cells and the ability of the cells to tolerate this and other weak-acid-type preservatives, but not methylparaben, the results suggest that the resistance mechanism, in which preservative is continuously removed from the cell, is a common and major determinant of the preservative tolerance of yeast species.

The response of Gluconobacter oxydans to sorbic and benzoic acids.

The minimal inhibitory concentrations (MIC) of sorbic and benzoic acids for Gluconobacter oxydans were 1000 mg/l and 900 mg/l respectively at pH 3.8. A reduction in the pH of the test medium to 3.3 reduced the MIC of both preservatives by about 300 mg/l. When G. oxydans was grown in the presence of sublethal concentrations of sorbic or benzoic acids before the MIC was determined, the MIC of both compounds increased substantially within 1 h. Growth of G. oxydans was modified in several ways by the presence of sorbic acid in the medium. The duration of the lag phase increased and there was a substantial decrease in the viable count during the lag phase in the presence of high concentrations. The generation time increased and the viable count at the end of the logarithmic phase was reduced. At 1 degree C, G. oxydans grew in the absence of sorbic acid but was inactivated by 400 mg sorbic acid/l. At 37 degrees C the viable count of suspensions of G. oxydans decreased in both the absence and presence of sorbic acid. Sorbic acid increased the death rate. Growth of G. oxydans was prevented by eliminating air from culture vessels, combined with the addition of ascorbate to the medium containing 400 mg sorbic acid/l.

Relationships between the resistance of yeasts to acetic, propanoic and benzoic acids and to methyl paraben and pH.

Minimum inhibitory concentrations of acetic, propanoic and benzoic acids and methyl paraben were determined at pH 3.50 for 22 isolates of 11 yeast species, differing in their resistance to preservatives. Growth in the presence of benzoic acid enhanced the resistance of yeasts to benzoic and the other weak acid preservatives, but not to methyl paraben. Resistance to acetic, propanoic and benzoic acids was strongly correlated, but was not closely related to resistance to methyl paraben. Minimum pH for growth was not related to resistance to the weak acids. The results suggest that growth in the presence of weak-acid preservatives involves a common resistance mechanism.

Effect of benzoic Acid on growth yield of yeasts differing in their resistance to preservatives.

Yeasts grown in the presence of benzoic acid tolerated 40 to 100% higher benzoic acid concentrations than did those grown in the absence of weak-acid-type preservatives. They also accumulated less benzoate in the presence of glucose. In chemostat cultures, benzoic acid reduced growth yield and the rate of cell production but increased specific fermentation rates. Benzoate contents were lower than those required for equilibrium when cells were impermeable to benzoate anion. Intracellular pHs were maintained near neutrality. Between species, stimulation of fermentation was inversely related to preservation resistance but was unrelated to the maximum rate of fermentation. The results show that a major effect of benzoic acid on yeasts in the presence of an energy source is the energy requirement for the reduction in cytoplasmic benzoate concentration and maintenance of pH. This energy source is unavailable for growth, resulting in lower growth yields and rates. Resistant species may be less permeable to undissociated benzoic acid.

Determination of dipicolinic acid in bacterial spores by derivative spectroscopy.

Dipicolinic acid was extracted from approximately 0.1 mg spores or 0.5 ml of sporulating culture with 20 mM HCl for 10 min at 100 degrees C. The suspension was diluted with 5 mM Ca2+, 100 mM Tris, pH 7.6, centrifuged, and the first derivative of the uv absorbance spectrum recorded from 275 nm to 285 nm. DPA concentration was determined from the difference between the maximum at 276.6 nm and the minimum at 280 nm. The use of the difference between two first derivative values removed possible interference from sloping baselines. Turbidity, nucleic acids, and bacteriological media did not interfere. Analysis time for four extracts was 4 min using a spectrophotometer reading at 0.1-nm intervals. Dipicolinate at 0.1 mM gave 0.184 absorbance/nm at 25 degrees C. The coefficient of variation was 1.5%, and the detection limit 1 microM.

Heat stability of Bacillus cereus enzymes within spores and in extracts.

Inactivation rates for nine enzymes extracted from Bacillus cereus spores were measured at several temperatures, and the temperature at which each enzyme had a half-life of 10 min (inactivation temperature) was determined. Inactivation temperatures ranged from 47 degrees C for glucose 6-phosphate dehydrogenase to 70 degrees C for leucine dehydrogenase, showing that spore enzymes were not unusually heat stable. Enzymes extracted from vegetative cells of B. cereus had heat stabilities similar to the respective enzymes from spores. When spores were heated and the enzymes were subsequently extracted and assayed, inactivation temperatures for enzymes within the spore ranged from 86 degrees C for glucose 6-phosphate dehydrogenase to 96 degrees C for aldolase. The internal environment of the spore raised the inactivation temperature of most enzymes by approximately 38 degrees C. Loss of dipicolinic acid from spores was initially slow compared with enzyme inactivation but increased rapidly with longer heating. Viability loss was faster than loss of most enzyme activities and faster than dipicolinic acid release.

Liquid chromatographic determination of dipicolinic Acid from bacterial spores.

Dipicolinic acid was determined by reverse-phase liquid chromatography. Elution was with 0.2 M potassium phosphate, pH 1.8, containing 1.5% tert-amyl alcohol or higher concentrations of lower alcohols or acetonitrile. The normal analytical range was 50 to 1,000 muM, which is equivalent to 0.1 to 1 mg of spores per ml with a relative standard error of 2 to 4% and a detection limit of <100 pmol. Dipicolinic acid was fully extracted from spores by heating at pH 1.8 for 10 min at 100 degrees C. Sporulating cultures may be analyzed in less than 20 min without separation of cells from media. Liquid chromatography was also used to detect dipicolinic acid in more complex substrates, e.g., guinea pig feces containing Metabacterium polyspora spores and canned food. Dipicolinic acid could be detected in unspoiled canned salmon containing <10 added Bacillus cereus spores per g.

Relationship between the heat resistance of spores and the optimum and maximum growth temperatures of Bacillus species.

Heat resistance of spores of Bacillus strains was compared with the temperature adaptation of each strain as measured by the optimum and maximum growth temperatures and the heat resistance of vegetative cells. Maximum growth temperatures ranged from 31 to 76 degrees C and were little affected by the nature of the growth medium. The temperature giving maximum growth rate was closely correlated to the maximum temperature for growth, and about 6 degrees C lower. Vetetative-cell heat resistance, determined on exponential-phase cells, was also correlated with maximum growth temperature. The temperature at which spores were inactivated with a decimal reduction time of 10 min was in the range of 75 to 121 degrees C. This temperature was 46 +/- 7 degrees C higher than the maximum growth temperature and correlated with it and the other cell parameters. Spore heat resistance can be considered to have two components, the temperature adaptation characteristic of the species and the stabilization conferred by the spore state.

Partial purification and some properties of the uridine diphospho-N-acetylglucosamine-enolpyruvate reductase from Staphylococcus epidermidis.

A method for the partial purification of the uridine diphospho-N-acetylglucosamine-enolpyruvate reductase from Staphylococcus epidermidis is presented. Some properties of the enzyme, including its dependence on monovalent cation and flavine adenine dinucleotide, are discussed.

Appearance of muramic lactam during cortex synthesis in sporulating cultures of Bacillus cereus and Bacillus megaterium.

Evidence is presented for the appearance of muramic lactam during the late stages of sporulation at about the same time dipicolinic acid synthesis occurs.

Structure of the peptidoglycan of bacterial spores: occurrence of the lactam of muramic acid.

Six major oligosaccharides were released from the peptidoglycan of spores of Bacillus subtilis by lysozyme treatment. They were isolated and characterized as a disaccharide, tetrasaccharide, and hexasaccharide composed of equal amounts of muramic acid and glucosamine and containing two, three, and four acetyl groups, respectively. Three of the compounds were substituted by a single L-alanine residue, and the other three by a single tetrapeptide substituent on the acetylmuramic acid residue at the reducing end of each compound. The other muramic acid residue in the tetrasaccharides (and two of the three in the hexasaccharides) were shown to be present as muramic lactams, a sugar not previously found in nature and, hence, a unique spore constituent. Other features of the structure of spore peptidoglycan are discussed.