Biochemical Alternations in Bacillus megaterium as Produced by Aflatoxin B1

Bacillus megaterium NRRL B-1368 cells and spores were produced on Trypticase Soy Broth (TSB) and Agar (TSA) containing 3.8 μg of aflatoxin B₁ per ml, analyzed for selected chemical constituents, and compared to cells and spores of B. megaterium produced on nontoxic Trypticase Soy Media. There was an initial 30% kill of cells after inoculation into toxic TSB and during the first 3.5 hr of incubation followed by a logarithmic growth phase in which the generation time was 75 min as compared to 20 min for the control culture. Chemical analyses revealed an increase in protein, deoxyribonucleic acid (DNA), and ribonucleic acid (RNA) on both a per cell basis and a per cent dry weight basis when B. megaterium was grown in toxic TSB. There was a concurrent decrease in the total amounts of cellular protein, DNA, and RNA synthesized in toxic TSB. Amino acid analyses of control and test cell walls showed little, if any, difference in cell wall composition. About 97% sporulation of B. megaterium occurred after 3 days on nontoxic TSA although 6 days were required to attain 65% sporulation on toxic TSA. Germination of spores was not inhibited by 4.0 μg of aflatoxin per ml but outgrowth was. No significant differences were observed in the heat resistance, protein, DNA, RNA, or dipicolinic acid content of spores formed on toxic TSA and nontoxic TSA.     

Conditions for induction of bacteriophage from lysogenic Bacillus megaterium with aflatoxin B1.

The present study was conducted to determine whether or not aflatoxin B1 was an effective inducing agent for lysogenic bacteria and to characterize some of the parameters involved in induction. A lysogenic strain of Bacillus megaterium (NRRL-B-3695) and an indicator strain of this species (NRRL-B-3694) were used. Cultures of the lysogenic strain were incubated for various periods of time in the presence of aflatoxin B1. Plaque-forming units as well as colony-forming units were then determined. Results of the present study indicated that bacteriophage lysogenizing B. megaterium could be induced with aflatoxin B1. The optimum concentration for induction was 25 micrograms of toxin per ml of early-log-phase culture. Evidence suggested that: (i) higher concentrations of aflatoxin B1 formed hydrophobic complexes which would not efficiently induce B. megaterium; (ii) the toxic effect of aflatoxin B1 severely limited the number of cells which could be induced prior to killing action of the toxin; and (iii) concentrations less than 25 micrograms of aflatoxin B1 per ml were not efficient inducers of bacteriophage production nor did they demonstrate the toxic effect observed at higher concentrations.     

Occurrence and Thermoresistance of Spores of Psychrophilic and Psychrotrophic Aerobic Sporeformers in Soil and Foods

Spores of psychrotrophic (able to grow at 5°C) aerobic sporeformers occurred in soil in high numbers (2 × 10³-5 × 10⁶/g), whereas psychrophilic (able to grow at 0°C) spores were present at significantly lower levels (500–10⁵/g). Psychrotrophic spores were absent in herbs and spices: in pasteurized meals prepared industrially their numbers varied from <10 to 1000/g. For spores harvested from Trypticase Soy Agar (TSA), the heat resistance of the cold-tolerant sporeformers was low with D _90°C-values from 1–11 min. The recovery of heated psychrophilic spores on this medium at 5°C was equal to their recovery at 20°C. However, the recovery of heated psychrotrophic spores was lower at 5°C than at 20°C, whereas unheated spores gave the same counts at both temperatures. The heat resistance of naturally occurring spores of cold-tolerant sporeformers washed from soil was comparable with the resistance of spores formed on TSA.     

Conditions for induction of bacteriophage from lysogenic Bacillus megaterium with aflatoxin B1.

The present study was conducted to determine whether or not aflatoxin B1 was an effective inducing agent for lysogenic bacteria and to characterize some of the parameters involved in induction. A lysogenic strain of Bacillus megaterium (NRRL-B-3695) and an indicator strain of this species (NRRL-B-3694) were used. Cultures of the lysogenic strain were incubated for various periods of time in the presence of aflatoxin B1. Plaque-forming units as well as colony-forming units were then determined. Results of the present study indicated that bacteriophage lysogenizing B. megaterium could be induced with aflatoxin B1. The optimum concentration for induction was 25 micrograms of toxin per ml of early-log-phase culture. Evidence suggested that: (i) higher concentrations of aflatoxin B1 formed hydrophobic complexes which would not efficiently induce B. megaterium; (ii) the toxic effect of aflatoxin B1 severely limited the number of cells which could be induced prior to killing action of the toxin; and (iii) concentrations less than 25 micrograms of aflatoxin B1 per ml were not efficient inducers of bacteriophage production nor did they demonstrate the toxic effect observed at higher concentrations.     

Mechanism of action of aflatoxin B1 in Bacillus megaterium

Bacillus megaterium cells from various growth phases were equally susceptible to the lethal effects of aflatoxin B1. Known surfactants (EDTA and Tween-80) accentuated the effects of aflatoxin B1. Viability and inulin uptake in aflatoxin B1-exposed cells decreased considerably. The effect was concentration dependent. A straight-line relationship observed in the death curve indicated a single target for aflatoxin B1 action in B. megaterium. Leakage of intracellular constituents in B. megaterium was also concentration dependent, and this can be related to the extent of cell membrane damage.     

Mechanism of action of aflatoxin B1 in Bacillus megaterium.

Bacillus megaterium cells from various growth phases were equally susceptible to the lethal effects of aflatoxin B1. Known surfactants (EDTA and Tween-80) accentuated the effects of aflatoxin B1. Viability and inulin uptake in aflatoxin B1-exposed cells decreased considerably. The effect was concentration dependent. A straight-line relationship observed in the death curve indicated a single target for aflatoxin B1 action in B. megaterium. Leakage of intracellular constituents in B. megaterium was also concentration dependent, and this can be related to the extent of cell membrane damage.     

The vitamin requirements of Staphylococcus cohnii

In heat-resistance studies with spores of Clostridium sporogenes BC-2, an improved recovery medium was needed for severely heat-damaged spores as the used previously--Wynne medium in Miller-Prickett tubes--did not allow accurate counts of spores because of gas formation and disruption of agar. Initial test with pour plates of Viande-Leyure medium containing egg-yolk gave much increased counts for spores previously heated for 50 min at 112 degrees C; this increase was attributed to the presence of egg-yolk. Addition of egg-yolk to Reinforced Clostridial Agar, All-Culture Medium and Trypticase Soy Agar showed that Trypticase Soy Agar with egg-yolk was the best recovery medium. For the final formulation, the value of supplementation with cysteine-HCl and methylene blue was also shown. The resultant Egg-yolk Trypticase Soy Agar is conveniently prepared from BBL Trypticase Soy Agar (40 g) with the addition of 0.4 g/l cysteine-HCl, 4 mg/l of methylene blue and 2% Oxoid egg-yolk emulsion aseptically to the melted basal medium. For optimal spore counts, pour plates are incubated anaerobically for 5--7 d at 30 degrees C.     

Growth of Desulfovibrio on the Surface of Agar Media

Growth of Desulfovibrio desulfuricans (API strain) was found to take place in an atmosphere of hydrogen on the agar surface of complex media, including yeast extract (Difco), and Trypticase Soy Agar (BBL) without any added reducing agents. For growth on a 2% yeast extract-agar surface in the absence of hydrogen (nitrogen atmosphere), sodium lactate was required in the medium. Growth on the surface of Trypticase Soy Agar (TSA) under nitrogen took place readily in the absence of an added hydrogen donor. A medium (TSA plus salts) is described based upon the addition of sodium lactate (4 ml per liter), magnesium sulfate (2 g per liter), and ferrous ammonium sulfate (0.05%) to TSA, which appears suitable for the isolation and growth of Desulfovibrio on the surface of agar plates in an atmosphere of hydrogen. Sodium lactate does not appear to be essential in this medium for good growth and sulfate reduction in a hydrogen atmosphere, but is essential in a nitrogen atmosphere. Growth of Desulfovibrio (hydrogen atmosphere) on the agar surface of media commonly used for its cultivation as well as on an inorganic medium containing bicarbonate as a source of carbon is poor and erratic unless inoculated (Desulfovibrio) plates of TSA plus salts are incubated in the same container with plates of these media. This stimulatory effect of incubation with inoculated plates of TSA plus salts medium appears to be due to as yet unidentified volatile material produced by D. desulfuricans when growing on this medium. Another volatile material, or possibly the identical material, appears to act similarly to a hydrogen donor.     

Natural incidence of endophytic bacteria in pea cultivars under field conditions

Pea plants grown in the field were used to study the natural incidence of endophytic bacteria in the stem. Eleven pea cultivars at the flowering stage were screened for the presence of endophytic bacteria using a printing technique with surface disinfested stem cross-sections on 5% Trypticase Soy Agar (TSA). Five cultivars showed colonization. Cultivar Twiggy showed the highest and most consistent colonization and was further investigated. Stems of cv. Twiggy at the pod stage were analyzed for endophytic bacterial types and populations. Cross-sections of surface disinfested stems were printed on 5% TSA. Endophytic bacterial populations decreased from the lower to the upper part of the stem. One section from the third and the fourth internode was surface disinfested, homogenized, and spiral plated on the media 5% TSA, R2A, and SC (Davis et al. 1980). Over a series of 30 samples, 5% TSA gave significantly better recovery of bacterial endophytes compared with R2A and SC media. For most stems, populations ranged from 10(4) to 10(5) CFU/g except in one of the field blocks in which endophyte populations were uniformly higher. Comparison of colony counts by spiral plating and printing showed a positive correlation. The most frequently recovered bacterial types were Pantoea agglomerans and Pseudomonas fluorescens. Less frequently isolated were Pseudomonas viridiflava and Bacillus megaterium.     

Development of a selective plating technique for the recovery of Escherichia coli O157: H7 after heat stress

The use of Sorbitol MacConkey Agar supplemented with 4-methylumbelliferyl β-D-glucuronide (MSMA), which is commonly used in the isolation of Escherichia coli O157: H7, has been shown to perform poorly when stressed cells of the pathogen are present. The incorporation of a resuscitation period (2 h at 25°C) on Trypticase Soy Agar (TSA) before overlay with MSMA was found to significantly ( P 0·01) improve recovery of heat-stressed (52°C/60 min) cells. Maximal recovery was, however, obtained by adding catalase (1000 U) to the TSA before overlaying with MSMA. This recovery protocol was shown not to result in the loss of the major known virulence factors of E. coli O157: H7 (genes encoding eae , VT1 and VT2).     

Microbial detoxification of aflatoxin

Yeasts, molds, bacteria, actinomycetes, algae, and fungal spores were screened for their ability to degrade aflatoxin. Some molds and mold spores partially transformed aflatoxin B(1) to new fluorescing compounds. Only one of the bacteria, Flavobacterium (aurantiacum?) NRRL B-184, removed aflatoxin from solution. Both growing and resting cells of B-184 took up toxin irreversibly. Toxin-contaminated milk, oil, peanut butter, peanuts, and corn were completely detoxified, and contaminated soybean was partially detoxified by addition of B-184. Duckling assays showed that detoxification of aflatoxin solutions by B-184 was complete, with no new toxic products being formed.     

Radiation resistance and injury of Yersinia enterocolitica

The D values of Yersinia enterocolitica strains IP134, IP107, and WA, irradiated at 25 degrees C in Trypticase soy broth, ranged from 9.7 to 11.8 krad. When irradiated in ground beef at 25 and -30 degrees C, the D value of strain IP107 was 19.5 and 38.8 krad, respectively. Cells suspended in Trypticase soy broth were more sensitive to storage at -20 degrees C than those mixed in ground beef. The percentages of inactivation and of injury (inability to form colonies in the presence of 3.0% NaCl) of cells stored in ground beef for 10 days at -20 degrees C were 70 and 23%, respectively. Prior irradiation did not alter the cell's sensitivity to storage at -20 degrees C, nor did storage at -20 degrees C alter the cell's resistance to irradiation at 25 degrees C. Added NaCl concentrations of up to 4.0% in Trypticase soy agar (TSA) (which contains 0.5% NaCl) had little effect on colony formation at 36 degrees C of unirradiated Y. enterocolitica. With added 4.0% NaCl, 79% of the cells formed colonies at 36 degrees C; with 5.0% NaCl added, no colonies were formed. Although 2.5% NaCl added to ground beef did not sensitize Y. enterocolitica cells to irradiation, when added to TSA it reduced the number of apparent radiation survivors. Cells uninjured by irradiation formed colonies on TSA when incubated at either 36 or 5 degrees C. More survivors of an exposure to 60 krad were capable of recovery and forming colonies on TSA when incubated at 36 degrees C for 1 day than at 5 degrees C for 14 days. This difference in count was considered a manifestation of injury to certain survivors of irradiation.     

Interaction between Streptococcus lactis and Aspergillus flavus on production of aflatoxin.

The inoculation of Aspergillus flavus spores into a culture of Streptococcus lactis in Lablemco tryptone broth medium resulted in little or no aflatoxin accumulation even though the growth of the fungus was not hindered. The drop in pH and reduced nutrient levels in the medium as a result of the S. lactis growth were not the cause of the observed inhibition. The inhibition was not eliminated by the addition of carbohydrate equal to the amount used by the bacterium before the inoculation with the fungus. Aflatoxin levels were also markedly reduced when S. lactis was inoculated into a growing A. flavus culture. In addition to inhibiting the synthesis of aflatoxin, S. lactis also degraded preformed toxin. A. flavus, on the other hand, not only reduced the growth of S. lactis but also affected the morphology of the bacterial cell; the cells became elongated and formed long chains. S. lactis produced and excreted the inhibitor into the medium late in its growth phase. The inhibitor was a heat-stable low-molecular-weight compound. Chloroform extracts of A. flavus grown in the presence of S. lactis were toxic to Bacillus megaterium but did not exhibit mutagenic or carcinogenic activity in the Salmonella/mammalian microsome mutagenicity test.     

Interaction between Streptococcus lactis and Aspergillus flavus on production of aflatoxin

The inoculation of Aspergillus flavus spores into a culture of Streptococcus lactis in Lablemco tryptone broth medium resulted in little or no aflatoxin accumulation even though the growth of the fungus was not hindered. The drop in pH and reduced nutrient levels in the medium as a result of the S. lactis growth were not the cause of the observed inhibition. The inhibition was not eliminated by the addition of carbohydrate equal to the amount used by the bacterium before the inoculation with the fungus. Aflatoxin levels were also markedly reduced when S. lactis was inoculated into a growing A. flavus culture. In addition to inhibiting the synthesis of aflatoxin, S. lactis also degraded preformed toxin. A. flavus, on the other hand, not only reduced the growth of S. lactis but also affected the morphology of the bacterial cell; the cells became elongated and formed long chains. S. lactis produced and excreted the inhibitor into the medium late in its growth phase. The inhibitor was a heat-stable low-molecular-weight compound. Chloroform extracts of A. flavus grown in the presence of S. lactis were toxic to Bacillus megaterium but did not exhibit mutagenic or carcinogenic activity in the Salmonella/mammalian microsome mutagenicity test.     

Spore pool glutamic acid as a metabolite in germination

Spore glutamic acid pools were examined in dormant and germinating spores using colorimetric and (14)C analytical procedures. Germination of spores of Bacillus megaterium (parent strain), initiated by d-glucose, was accompanied by a rapid drop in the level of spore pool glutamate, from 12.0 mug/mg of dry spores to 7.7 mug/mg of dry spores after 30 sec of germination. Similar decreases in extractable spore pool glutamate were observed with l-alanine-initiated germination of B. licheniformis spores. On the other hand, glutamate pools of mutant spores of B. megaterium, with a requirement of gamma-aminobutyric acid for spore germination, remained unchanged for 9 min of germination, at which time more than 50% of the spore population had germinated. Evidence for conversion of spore pool glutamate to gamma-aminobutyric acid during germination of spores of B. megaterium (parent strain) was obtained.     

Reverszal of grwoth inhibition of Bacillus megaterium dut to aflatoxin by coffee and tea extracts

Growth inhibition of Bacillus megaterium by aflatoxin B₁ is employed in semi-quntitative assay of the toxin,. Aqueous extracts of tea and coffee were found in interfere with this assay, which indicated that tea and coffee contain factors(s) which can reverse the aflatoxin toxicity on B. megaterium     

Recovery of Spores of Bacillus stearothermophilus from Thermal Injury

Bacillus stearothermophilus grown in nutrient broth produced a product which promoted recovery from thermal injury of its spores. This phenomenon was observed with nutrient agar as the plating medium but not with a medium composed of Trypticase, Phytone, dextrose and phosphate (TPDP). Recovery of injured spores was greatest in such a medium if it contained starch or charcoal. Trypticase soy agar and dextrose tryptone agar were markedly inferior to TPDP medium.     

Regression Curve Analysis of Cephalosporin Activity

Regression lines were calculated for cephalothin, cephalexin, and cephaloridine by relating zone diameters of inhibition to minimal inhibitory concentrations (MIC) obtained in Mueller-Hinton agar and in Trypticase Soy Agar. A regression line was calculated for cephaloglycin by obtaining MIC values in Trypticase Soy Agar at pH 6.6. Regression lines calculated from MIC values in Mueller-Hinton agar were practically superimposable on those based on MIC values in Trypticase Soy Agar. Organisms susceptible by disc testing to cephalothin were usually susceptible to cephalexin and cephaloridine.     

Liquid Nitrogen Preservation of Saccharomyces carlsbergensis and its Use in a Rapid Biological Assay of Vitamin B6 (Pyridoxine)

Growth medium as well as freezing menstruum greatly influenced the recovery of Saccharomyces carlsbergensis when it was quickly frozen in liquid nitrogen at - 196 C and quickly thawed at 40 C. Nearly 90% recovery in viability was obtained when S. carlsbergensis was grown in Trypticase Soy Broth and frozen in vitamin B(6) basal assay medium. The growth phase of S. carlsbergensis also influenced recovery after freezing. When S. carlsbergensis was grown in Trypticase Soy Broth and frozen in the broth at the logarithmic-growth phase, only 7% viability was retained; the recovery rate increased to 81% when the culture was frozen in the maximal stationary phase. To have the least possible lag period of growth after thawing, a technique called growth-phase conditioning was introduced. After 1 hr of growth-phase conditioning, S. carlsbergensis was clearly out of lag phase, and budding was observed. A vitamin B(6) microbiological assay with a 6-hr incubation period and with the use of liquid nitrogen-frozen S. carlsbergensis is described.     

Uptake of aflatoxin B1 and T-2 toxin by two mycotoxin bioassay microorganisms: Kluyveromyces marxianus and Bacillus megaterium

Uptake of aflatoxin B1 (AFB1) and trichothecene T-2 toxin from growth medium by mycotoxin bioassay strains of Klutyveomyces marxianus and Bacillus megaterium was assessed by incubating, washing, and sonicating the cells, extracting samples with chloroform, and analysing the extracts by a combination of high-performance thin-layer chromatography (HPTLC) and fluorescence densitometry. Using cultures of K. marxianus, the entire AFB1 dose was recovered and no AFB1 metabolites were detected. Less than 1% of the AFB1 was recovered from the cells, and AFB1 did not inhibit growth. Methanol in the incubation medium had no significant effect on the levels of AFB1 associated with K. marxianus cells. The entire dose of T-2 toxin was also recovered from K. marxianus cultures, and no metabolites were detected; again, less than 1% of T-2 toxin was cell-associated, but growth was completely inhibited. AFB1 partially inhibited the growth of B. megaterium; approximately 12% of the dose could not be recovered, and no AFB1-related metabolites were detected. Methanol increased the levels of recoverable AFB1 associated with B. megaterium cells. In the case of T-2 toxin, around 8% of the dose was not recovered, and no metabolites were detected; growth of B. megaterium was stimulated. These results suggest irreversible binding of both toxins, or derivatives of them, to the cells of B. megaterium.