The effect of citric acid, lactic acid, sodium citrate and sodium lactate, alone and in combination with nisin, on the growth of Arcobacter butzleri

The importance of Arcobacter spp. as a cause of human foodborne illness is unresolved. Organic acids and their sodium salts, and nisin are preservatives commonly used in the type of foods from which the organism is recovered. In this study their effect on the growth of A. butzleri in culture, alone and in combination, was investigated. At 0.5%, 1.0% and 2.0% lactic and citric acids inhibited A. butzleri growth; 2% sodium lactate was effective in inhibiting growth over 8 h incubation but not over longer periods. Sodium citrate was more effective than sodium lactate. Nisin alone inhibited A. butzleri growth at 500 IU ml-1 over 5 h. It did not enhance the effect of sodium citrate inhibition but it did augment the effect of sodium lactate alone over 8 h.     

Role of sodium in the growth of a ruminal selenomonad.

The ruminal selenomonad strain H18 grew rapidly (mu = 0.50 h-1) in a defined medium containing glucose, ammonia, purified amino acids, and sodium (95 mM); little if any ammonia was utilized as a nitrogen source. When the sodium salts were replaced by potassium salts (0.13 mM sodium), there was a small reduction in growth rate (mu = 0.34 h-1), and under these conditions greater than 95% of the cell nitrogen was derived from ammonia. No growth was observed when the medium lacked sodium (less than 0.35 mM) and amino acids were the only nitrogen source. At least six amino acid transport systems (aspartate, glutamine, lysine, phenylalanine, serine, and valine) were sodium dependent, and these systems could be driven by an electrical potential (delta psi) or a chemical gradient of sodium. H18 utilized lactate as an energy source for growth, but only when sodium and aspartate were added to the medium. Malate or fumarate was able to replace aspartate, and when these acids were added, sodium was no longer required. Glucose-grown cells accumulated large amounts of polysaccharide (64% of dry weight), and when the exogenous glucose was depleted, this material was converted to acetate and propionate as long as sodium was present. When the cells were incubated in buffers lacking sodium, succinate accumulated and exogenous succinate could not be decarboxylated. Because sodium had little effect on the transmembrane pH gradient at pH 6.7 to 4.5, it did not appear that sodium was required for intracellular pH regulation.     

Role of sodium in the growth of a ruminal selenomonad

The ruminal selenomonad strain H18 grew rapidly (mu = 0.50 h-1) in a defined medium containing glucose, ammonia, purified amino acids, and sodium (95 mM); little if any ammonia was utilized as a nitrogen source. When the sodium salts were replaced by potassium salts (0.13 mM sodium), there was a small reduction in growth rate (mu = 0.34 h-1), and under these conditions greater than 95% of the cell nitrogen was derived from ammonia. No growth was observed when the medium lacked sodium (less than 0.35 mM) and amino acids were the only nitrogen source. At least six amino acid transport systems (aspartate, glutamine, lysine, phenylalanine, serine, and valine) were sodium dependent, and these systems could be driven by an electrical potential (delta psi) or a chemical gradient of sodium. H18 utilized lactate as an energy source for growth, but only when sodium and aspartate were added to the medium. Malate or fumarate was able to replace aspartate, and when these acids were added, sodium was no longer required. Glucose-grown cells accumulated large amounts of polysaccharide (64% of dry weight), and when the exogenous glucose was depleted, this material was converted to acetate and propionate as long as sodium was present. When the cells were incubated in buffers lacking sodium, succinate accumulated and exogenous succinate could not be decarboxylated. Because sodium had little effect on the transmembrane pH gradient at pH 6.7 to 4.5, it did not appear that sodium was required for intracellular pH regulation.     

Influence of various bile salts on ββ-glucuronidase activity of intestinal bacteria

While the decrease of the β-glucuronidase activity of sonicated cells of Clostridium perfringens and Escherichia coli was obvious for sodium deoxycholate (DC), it was not so obvious for other bile salts (sodium glycocholate and sodium cholate). The enzyme activity of intact cells of these bacteria was significantly enhanced by the presence of DC, but not by the other bile salts in the buffer. These results suggest that the permeability of the bacterial cells is increased more by the presence of DC than by other bile salts.     

Elucidation of Growth Inhibition and Acetic Acid Production by Clostridium thermoaceticum

The production of acetic acid by Clostridium thermoaceticum was studied by using batch fermentations. In a pH-controlled fermentation with sodium hydroxide (pH 6.9), this organism was able to produce 56 g of acetic acid per liter. On the other hand, when the pH was not controlled and was decreased during fermentation to 5.4, the maximum attainable acetic acid concentration was only 15.3 g/liter. To obtain a better understanding of the end product inhibition, various salts were tested to determine their effect on the growth rate of C. thermoaceticum. An inverse linear relationship between the growth rate and the final cell concentration to the sodium acetate concentration was found. By using different concentrations of externally added sodium salts, the relative growth inhibition caused by the anion was found to be in the order of acetate > chloride > sulfate. Various externally added cations of acetate were also examined with respect to their inhibitory effects on growth. The relative magnitude of inhibition on the growth rate was found to be ammonium > potassium > sodium. The combined results have shown that the undissociated acetic acid was much more inhibitory than the ionized acetate ion. Complete growth inhibition resulted when the undissociated acetic acid concentration was between 0.04 and 0.05 M and when the ionized acetate concentration was 0.8 M. Therefore, at low pH (below 6.0), undissociated acetic acid is responsible for growth inhibition, and at high pH (above 6.0), ionized acetate ion is responsible for growth inhibition.     

Effect of lithium salts on lactate dehydrogenase,adenylate kinase,and 1-phosphofructokinase activities

Inhibitions of 30?nM rabbit muscle 1-phosphofructokinase (PFK-1) by lithium, potassium, and sodium salts showed inhibition or not depending upon the anion present. Generally, potassium salts were more potent inhibitors than sodium salts; the extent of inhibition by lithium salts also varied with the anion. Li₂CO₃ was a relatively potent inhibitor of PFK-1 but LiCl and lithium acetate were not. Our results suggest that extents of inhibition by monovalent salts were due to both cations and anions, and the latter needs to be considered before inhibition can be credited to the cation. An explanation for monovalent salt inhibitions is proffered involving interactions of both cations and anions at negative and positive sites of PFK-1 that affect enzyme activity. Our studies suggest that lithium cations per se are not inhibitors: the inhibitors are the lithium salts, and we suggest that in vitro studies involving the effects of monovalent salts on enzymes should involve more than one anion.     

BANANA GEL

The conditions for the formation of gels from banana extracts were studied. Gels were obtained with extracts more alkaline than pH 7.0 with very small quantities of calcium, strontium, and barium salts, the gel formation with these salts decreasing in the indicated order. In solutions more acid than pH 6.0, no gels were obtained with these salts. Magnesium, lithium, and sodium salts did not cause gel formation either in acid or alkaline solutions. Pancreatine gave a gel on incubation with banana extract at pH 5.0. The gel-forming property of banana extracts was destroyed on boiling.     

Sensitivity of Streptococcus thermophilus to Chemical Permeabilization

Streptococcus thermophilus cultures were treated with conjugated and unconjugated bile salts and tested for β-galactosidase activity. Na-deoxycholate and chenodeoxycholate were more efficient permeabilizing agents than cholate, and all three bile salts were superior to their corresponding glyco- and tauro-conjugates. Treatment with sodium dodecyl sulfate resulted in the highest measurable β-galactosidase levels in permeabilized cells, whereas response to Triton X-100 was variable and strain dependent. Na-deoxycholate, chenodeoxycholate, and sodium dodecyl sulfate caused cell injury and arrested culture growth for 4 h or longer. The nongrowing permeabilized biomass of S. thermophilus was used to hydrolyze lactose in aqueous solutions and milk.     

Evaluation of Inhibitory Effect of Organic and Inorganic Salts Against Ilyonectria liriodendri,The Causal Agent of Root Rot Disease of Kiwifruit

This study evaluated efficacy of 42 organic and inorganic salts as possible alternatives to synthetic fungicides for the control of Ilyonectria root rot of kiwifruit. Preliminary in vitro tests showed that ammonium bicarbonate, ammonium carbonate, potassium benzoate, potassium sorbate, sodium benzoate and sodium metabisulphite at 2% completely inhibited mycelial growth of the fungus. No significant differences were observed among these salts and disodium EDTA (P ≤ 0.05). However, the ED₅₀, minimum inhibition concentration (MIC), and minimum fungicidal concentration (MFC) values indicated that sodium metabisulphite was more toxic to Ilyonectria liriodendri than these other six salts. Soil bioassays showed that sodium metabisulphite, sodium benzoate and potassium sorbate at 0.25% completely inhibited mycelial growth of the fungus, whereas potassium benzoate reduced the mycelial growth of fungus by 90.30%; however, the differences in inhibitory effects were statistically insignificant (P ≤ 0.05). Moreover, there was no significant difference between 0.1% sodium metabisulphite and 0.5% ammonium carbonate, 0.75% ammonium bicarbonate and 1.5–2.0% disodium EDTA (P ≤ 0.05). Unlike disodium EDTA, complete inhibitory was observed with ammonium carbonate and ammonium bicarbonate at higher concentrations. However, in root bioassays, applications of 2% ammonium bicarbonate, 1.5% ammonium carbonate and 2% disodium EDTA were phytotoxic to kiwifruit seedlings, but 0.25% four other salts were neither phytotoxic to kiwifruit seedlings nor did it adversely affect root length, root fresh weight and root dry weight of seedling. This study also showed I. liriodendri to be capable of growth in both acidic and basic environments. However, while the fungus showed uninhibited growth at pH values of 5–11, growth decreased significantly at both higher and lower pH values (P ≤ 0.05) and was completely inhibited at pH 12.     

Quantitation of metal cations bound to membranes and extracted lipopolysaccharide of Escherichia coli

Inductively coupled plasma emission spectroscopy was used to quantitate the metal cations bound to outer and cytoplasmic membranes and to extracted lipopolysaccharide from several Escherichia coli K12 strains. The outer membrane was found to be enriched in both calcium and magnesium relative to the cytoplasmic membrane. Both membranes contained significant levels of iron, aluminum, and zinc. The multivalent cation content of the lipopolysaccharide resembled that of the intact outer membrane. Lipopolysaccharide extracted from wild-type k12 strains contained higher levels of Mg than Ca regardless of the growth medium, but the medium used for growth did affect the relative amounts of bound Mg as well as the levels of the minor cations iron, aluminum, and zinc. In contrast, lipopolysaccharide isolated from a deep rough mutant strain, D21f2, contained more Ca than Mg. Electrodialysis of lipopolysaccharide from wild-type k12 strains removed 1 mol of Mg per mol of lipopolysaccharide but did not significantly affect the level of other bound metal ions. Dialysis of lipopolysaccharide against sodium (ethylenedinitrilo)tetraacetate removed most of the Mg and Ca, resulting in a sodium salt. The equimolar replacement of divalent cations with sodium in the sodium salt resulted in a net loss of counterion change. The sodium salt was dialyzed against either tris(hydroxymethyl)aminomethane hydrochloride, CaCl2, MgCl2, or TbCl3, and the resulting lipopolysaccharide salts were analyzed for their ionic composition. It was shown that tris(hydroxymethyl)aminomethane and Ca can replace some but not all of the Na bound to the sodium salt, but all of the other multivalent cations tested replaced Na, resulting in uniform lipopolysaccharide salts. Lipopolysaccharide isolated from the deep rough mutant strain D21f2 was also converted into a sodium salt. Relative to the wild-type lipopolysaccharide, Na was able to neutralize the anionic charge to a greater extent in the mutant lipopolysaccharide. Our results suggest that the loss of specific groups in the core region of the lipopolysaccharide from the mutant strain results in a more open structure that allows the binding of larger cations and of more monovalent cations.     

An active type IV secretion system encoded by the F plasmid sensitizes Escherichia coli to bile salts

F(+) strains of Escherichia coli infected with donor-specific bacteriophage such as M13 are sensitive to bile salts. We show here that this sensitivity has two components. The first derives from secretion of bacteriophage particles through the cell envelope, but the second can be attributed to expression of the F genes required for the formation of conjugative (F) pili. The latter component was manifested as reduced or no growth of an F(+) strain in liquid medium containing bile salts at concentrations that had little or no effect on the isogenic F(-) strain or as a reduced plating efficiency of the F(+) strain on solid media; at 2% bile salts, plating efficiency was reduced 10(4)-fold. Strains with F or F-like R factors were consistently more sensitive to bile salts than isogenic, plasmid-free strains, but the quantitative effect of bile salts depended on both the plasmid and the strain. Sensitivity also depended on the bile salt, with conjugated bile salts (glycocholate and taurocholate) being less active than unconjugated bile salts (deoxycholate and cholate). F(+) cells were also more sensitive to sodium dodecyl sulfate than otherwise isogenic F(-) cells, suggesting a selectivity for amphipathic anions. A mutation in any but one F tra gene required for the assembly of F pili, including the traA gene encoding F pilin, substantially restored bile salt resistance, suggesting that bile salt sensitivity requires an active system for F pilin secretion. The exception was traW. A traW mutant was 100-fold more sensitive to cholate than the tra(+) strain but only marginally more sensitive to taurocholate or glycocholate. Bile salt sensitivity could not be attributed to a generalized change in the surface permeability of F(+) cells, as judged by the effects of hydrophilic and hydrophobic antibiotics and by leakage of periplasmic beta-lactamase into the medium.     

Preparation of inositol phosphates from sodium phytate by enzymatic and nonenzymatic hydrolysis

Procedures for preparing myo-inositol bis-, tris-, tetrakis-, and pentakisphosphates from sodium phytate were established. Hydrolysis was achieved by autoclaving or enzymatic treatment; the inositol phosphates were separated by anion-exchange chromatography and were identified by fast atom bombardment-mass spectrometry. Enzymatic hydrolysis was more specific than autoclaving for isomer formation, whereas autoclaving was more efficient for producing the bis- and trisphosphates, which did not accumulate in significant amounts under the conditions of enzymatic hydrolysis. Sodium salts of the inositol phosphates were more powdery and less hygroscopic than the potassium salts. The procedures were satisfactory for producing gram quantities of each inositol phosphate, amounts adequate for animal studies of effects on mineral bioavailability.     

Phospholipid fatty acid and lipopolysaccharide fatty acid signature lipids in methane-utilizing bacteria

The effect of human bile juice and bile salts (sodium cholate, sodium taurocholate, sodium glycochenodeoxycholate and sodium chenodeoxycholate) on growth, sporulation and enterotoxin production by enterotoxin-positive and enterotoxin-negative strains of Clostridium perfringens was determined. Each bile salt inhibited growth to a different degree. A mixture of bile salts completely inhibited the growth of enterotoxin-positive strains of this organism. Human bile juice completely inhibited the growth of all the strains at a dilution of 1:320. A distinct stimulatory effect of the bile salts on sporulation was observed in the case of C. perfringens strains NCTC 8239 and NCTC 8679. The salts also increased enterotoxin concentrations in the cell extracts of the enterotoxin-positive strains tested. No effect on enterotoxin production was detected when an enterotoxin-negative strain was examined.     

Release of proteinase from mycelium of Mucor hiemalis

When Mucor hiemalis NRRL 3103 was grown in soybean medium, only a small fraction of the proteinase produced by the organism appeared in the culture filtrate, whereas the bulk of the enzyme was bound to the mycelial surface. Optimal pH of the proteinase ranged from 3.0 to 3.5. Inclusion of sodium chloride or other ionizable salts in the growth medium, however, resulted in the liberation from the mycelium of the loosely bound enzyme as it was formed. Maximal release of proteinase was achieved at a sodium chloride concentration of 0.5 m. The loosely bound proteinase was eluted also from intact resting mycelium by ionizable salts but not by water or by nonionizable substances. The amount of enzyme eluted from the mycelium depended upon the concentration of sodium chloride up to 0.3 m. Since liberation took place rapidly even at 0 C, a loose ionic linkage must exist rather than a biochemical binding of the enzyme to the mycelium. The recovery of proteolytic activity from repeated salt extractions was greater than that originally detected in the intact mycelium, possibly owing to unmasking of more active enzymes or functional groups. Further proteinase activity was released when salt-extracted mycelium was ruptured. Part of the proteinase thus observed was firmly attached to the cell fraction, and part of it appeared in the supernatant fluid. These conditions implied the presence of intracellular or firmly attached proteinase which could be partially released.     

Bile salt dependent bile flow in the rabbit: evidence for the importance of an amiloride inhibitable pathway

Bile salt dependent flow and electrolyte secretion in response to two bile salts were studied in awake rabbits. It was found that sodium glycodeoxycholate had a much greater choleretic and cholioneretic efficiency than sodium taurocholate. The effect of the bile salts on flow and electrolyte secretion was not linear across the range of bile salt secretion rates studied. When amiloride was administered significant decreases in choleretic and cholioneretic efficiencies occurred, but furosemide had no effect. It is concluded that bile salts stimulate electrolyte transport via amiloride inhibitable cellular processes, and that this electrolyte transport is in part responsible for bile salt dependent bile flow.     

Effect of salts on the lytic activity of gramicidin S and its derivatives

Potassium and sodium chlorides, sulfates, acetates and phosphates activated the lytic action of gramicidin S and its derivatives on protoplasts of M. lysodeikticus. The derivatives used were positively charged and neutral by the free amino groups in the ornithine moieties. The salts had no effect on lysis of the bacillar protoplasts by gramicidin S and its positively charged derivatives. The lytic effect of the neutral derivative on the bacillar protoplasts markedly increased in the presence of the salts, activation of the lysis by the phosphates being more pronounced than that by the other salts. Increased membrane activity of gramicidin S in the presence of the salts was not connected with association of the substance molecules in solution. Probably it was due to increased destruction of the membranes at the account of activated detergent effect of the antibiotic and its derivatives.     

Effect of various salts on the growth and development of Geotrichum candidum,the causal agent of carrot sour rot

This study evaluated the efficacy of ammonium, calcium, potassium and sodium salts as possible alternatives to synthetic fungicides in the control of Geotrichum candidum, the causal agent of sour rot on carrots. In vitro mycelial growth of G. candidum was completely halted by ammonium bicarbonate and carbonate; calcium oxide; potassium benzoate, carbonate and sorbate; sodium benzoate, carbonate and fluoride (2% w/v). Potassium and sodium bicarbonate also reduced mycelial growth by 77.78% and 90.60%, respectively, and the difference between the effects of sodium bicarbonate and the first group of salts was not statistically significant (p < 0.05). With the exception of potassium and sodium bicarbonate, the above‐mentioned salts also halted or strongly reduced arthrospore germination. Potassium bicarbonate, and sodium bicarbonate, acetate and propionate significantly increased conidiation (p < 0.05). Of all the salts tested in vitro, only ammonium bicarbonate and carbonate, calcium oxide and sodium fluoride were toxic to G. candidum. In in vivo studies, all the calcium salts tested (acetate, chloride, citrate, formate, lactate, oxide, propionate and silicate), several of the sodium salts (acetate, bicarbonate, chloride and fluoride) and potassium bicarbonate exhibited both protective and curative activity against G. candidum, significantly reducing the severity of sour rot in comparison to pathogen‐inoculated controls (p < 0.05). Although no curative was observed with ammonium bicarbonate, ammonium carbonate, potassium carbonate, potassium chloride, sodium carbonate or sodium citrate, these salts also demonstrated significant protective activity against sour rot when compared to controls (p < 0.05). In sum, the study findings show that all of the selected salts may be used to control carrot sour rot, except for sodium fluoride, which exhibited phytotoxicity to carrots.     

Combined effect of betaine and trehalose on osmotic tolerance of <Emphasis Type="Italic">Escherichia coli</Emphasis> in mineral salts medium

In mineral salts medium, supplementing with betaine in combination with increased production of endogenous osmoprotectant from a second copy of the trehalose biosynthetic genes (otsBA) improved growth of E. coli and increased the MIC for xylose, glucose, sodium lactate and NaCl. With these compounds, this combination was more effective than either betaine or trehalose alone. With succinate, this combination was no more effective than betaine alone. Neither approach improved tolerance to ethanol. A combination of betaine and increased trehalose may improve strain productivity for many bioproducts by promoting growth in the presence of high sugar concentrations.     

Alkalotolerance of Yersinia enterocolitica as a basis for selective isolation from food enrichments.

Alkalotolerance of Yersinia enterocolitica measured in solutions of potassium hydroxide with 0.5% sodium chloride was influenced by the cell suspension medium, temperature, and growth phase. The rate of cell destruction (delta log N per minute) was five times greater at 30 degrees C than at 20 degrees C. Differences in the degree of cell destruction at various concentrations of potassium hydroxide were related to pH and not to osmolarity. The addition of peptones to potassium hydroxide provided a protective effect that was greater for cells suspended in Trypticase soy broth than for those suspended in phosphate-buffered sorbitol-bile salts broth. Log-phase cells were less alkalotolerant than cells in the stationary phase of growth. A modified procedure for alkali treatment, using peptone-supplemented 0.5% potassium hydroxide-0.5% sodium chloride and the addition of a pH 6.6 buffer after treatment to prevent further cell destruction, was used to observe a marked difference in alkalotolerance between Y. enterocolitica and other gram-negative bacteria. Despite this difference, alkali treatment was not highly successful for recovery of Y. enterocolitica from enrichments of seeded foods in comparison with selective enrichment in bile-oxalate-sorbose broth.     

Factors Affecting Selectivity of Brilliant Green-Phenol Red Agar for Salmonellae

Commercial brilliant green (BG)-sulfa agar was found to be nonselective toward a test series of Enterobacteriaceae. Various formulations of BG were prepared by using Trypticase soy agar (BBL) as a base. Results were more reproducible when BG dye was added after sterilization than before. Sulfonamides improved selectivity as compared with brilliant green alone. Sulfanilamide (SN) was slightly more selective for salmonellae than other sulfonamides tested. Bile salts and sodium dodecyl sulfate markedly reduced the toxicity of BG to all the test bacteria. Enterobacter strains were most difficult to inhibit. A combination of 5 mg of BG and 1 g of SN/liter prevented growth of Proteus mirabilis and Escherichia coli and retarded growth of Enterobacter strains. The BG-SN agars were superior in selectivity to a series of commercial agars tested, and numbers of salmonellae recovered on BG-SN agar and Trypticase soy agar (BBL) were the same. Brilliant green agars with various degrees of selectivity are described.