Proceedings: Repair of injury in Salmonella anatum cells after freezing and thawing in milk

Fast freezing and slow thawing of Salmonella anatum cells in nonfat milk solids resulted in about 20% death and 50% injury of the cells surviving the treatment. Death was defined as the inability to form colonies on a nonselective plating medium [xylose-lysine-peptone agar (XLP)] after freezing and thawing. Injury was defined as the inability to form colonies on a selective plating medium (XLP with 0.2% sodium desoxycholate added). The injured cells repaired rapidly and within 2 hr at 25 °C, in the presence of 0.1% milk solids; all the injured cells regained the ability to form colonies on the selective medium. The treated cells showed a 1-hr extended lag phase of growth as compared to the unfrozen cells. Milk solids concentration in the freezing and repair menstrua influenced injury, repair of injury, and death. The repair process was affected by the pH and temperature of environment in which the injured cells were incubated. Maximum repair occurred at pH values between 6.0 and 7.4 and temperatures from 25 to 42 °C. The data suggested repair did not require the synthesis of protein, ribonucleic acid, or cell-wall mucopeptide but did require energy synthesis.     

Characterization of the Repair of Injury Induced by Freezing Salmonella anatum

Fast freezing and slow thawing of Salmonella anatum cells suspended in water resulted in injury of more than 90% of the cells that survived the treatment. The injured cells failed to form colonies on the selective medium (xyloselysine-peptone-agar with 0.2% sodium deoxycholate) but did form colonies on a nonselective (xylose-lysine-peptone-agar) plating medium. In Tryptic soy plus 0.3% yeast extract broth or minimal broth, most of the injured cells repaired within 1 to 2 hr at 25 C. Tryptic soy plus yeast extract broth supported repair to a greater extent than minimal broth. Phosphate or citrate at concentrations found in minimal broth supported repair of some cells. MgSO(4), when present with inorganic phosphate or citrate or both, increased the extent of repair. The repair process in the presence of phosphate was not prevented by actinomycin D, chloramphenicol, and D-cycloserine, but was prevented by cyanide and 2,4-dinitrophenol (only at pH 6). This suggested that the repair process might involve energy metabolism in the form of adenosine triphosphate. The freeze-injured cells were highly sensitive to lysozyme, whereas unfrozen fresh cells were not. In the presence of phosphate or minimal broth this sensitivity was greatly reduced. This suggested that, at least in some of the cells, the injury involved the lipopolysaccharide of the cell wall and adenosine triphosphate synthesis was required for repair.     

Effect of Rehydration on Recovery, Repair, and Growth of Injured Freeze-Dried Salmonella anatum

From 70 to 90% of the Salmonella anatum cells that survived freeze-drying in nonfat milk solids were injured. After rehydration, these injured survivors failed to grow on a selective plating medium containing deoxycholate but could form colonies on a nonselective medium. In a suitable environment after rehydration, injury disappeared in most of these cells. The rate of this repair at 25 C was very rapid initially and, in a medium containing milk solids, was completed within 1 hr after rehydration. The repaired cells initiated growth about 1 hr later than normal cells and grew at a slower rate. In a medium containing milk solids, initial recovery, extent of repair of injury, initiation of growth, and rate of growth were not influenced by supplementation with extra nutrients in other rehydration media. Rehydration controlled by modifying the concentrations of lactose, sucrose, or milk solids in the rehydration medium influenced the recovery of cells and the time that growth was initiated. Glycerol failed to increase recovery. Higher numbers of cells were recovered by rehydrating at 15 to 25 C, but an earlier initiation of growth and more rapid growth were observed at 35 C.     

Repair of Injury Induced by Freezing Escherichia coli as Influenced by Recovery Medium

Freezing an aqueous suspension of Escherichia coli NCSM at -78 C for 10 min, followed by thawing in water at 8 C for 30 min, resulted in the death of approximately 50% of the cells, as determined by their inability to form colonies on Trypticase soy agar containing 0.3% yeast extract (TSYA). Among the survivors, more than 90% of the cells were injured, as they failed to form colonies on TSYA containing 0.1% deoxycholate. Microscope counts and optical density determinations at 600 nm suggested that death from freezing was not due to lysis of the cells. Death and the injury were accompanied by the loss of 260- and 280-nm absorbing materials from the intracellular pool. Injury was reversible as the injured cells repaired in many suitable media. The rate of repair was rapid and maximum in a complex nutrient medium such as Trypticase soy broth supplemented with yeast extract. However, inorganic phosphate, with or without MgSO₄, was able to facilitate repair. Repair in phosphate was dependent on the pH, the temperature, and the concentration of phosphate.     

Injury and recovery of Escherichia coli after sublethal acidification.

Over 99% of the viable cells of Escherichia coli K-12 were injured after a 60-min exposure to 0.3 M sodium acetate buffer at pH 4.2. Injured cells were those able to grow on Trypticase soy agar but unable to grow on violet red bile agar. The extent of both death and injury of acid-treated cells increased with decreasing pH or increasing concentration of acid. Injured cells were able to recover their colony-forming ability on violet red bile agar by incubation in Trypticase soy broth or potassium phosphate buffer before plating on the agar media. Direct neutralization of the injury medium did not allow recovery and, in fact, was lethal to the population. The addition of metabolic inhibitors to the Trypticase soy recovery broth was used to study the repair process. It was not affected by the presence of inhibitors of protein, cell wall, deoxyribonucleic acid, or ribonucleic acid syntheses. The addition of 2,4-dinitrophenol to the recovery medium also did not inhibit recovery. Actinomycin D and N,N'-dicyclohexylcarbodiimide were lethal to a proportion of the acidified cells but allowed another fraction of the population to recover. There were no detectable amounts of 260- or 280-nm-absorbing materials leaked during the course of acid injury.     

Repair of Injury in Freeze-Dried Salmonella anatum

Repair of injury induced by freeze-drying Salmonella anatum in nonfat milk solids occurred rapidly after rehydration. Injury in surviving cells was defined as the inability to form colonies on a plating medium containing deoxycholate. Death was defined as inability to form colonies in the same medium without this selective agent. The rate of repair of injury was reduced by lowering the temperature from 35 C to 10 C and was extremely low at 1 C. Repair was independent of influence of pH between 6.0 and 7.0. Repair did not require synthesis of protein, ribonucleic acid, or cell wall mucopeptide, but did require energy in the form of adenosine triphosphate (ATP) synthesized through oxidative phosphorylation. The requirement for ATP was based on dinitrophenol or cyanide interference with repair. Dinitrophenol activity was pH-dependent; no repair occurred at pH 6.0 and some repair was observed at pH 6.5 and above. Injured cells were extremely sensitive to low concentrations of ethylenedinitrilotetraacetate. This indicated that freeze-drying injury of S. anatum may involve the lipopolysaccharide portion of the cell wall and that repair of this damage requires ATP synthesis.     

Injury and Death of Streptococcus lactis due to Freezing and Frozen Storage

Cells of Streptococcus lactis were harvested in the early stationary phase, washed, and resuspended in either skim milk (10% nonfat milk) or buffered distilled water (0.0003 m dipotassium phosphate, pH 7.2). Samples of each suspension were frozen and stored at -20 C for intervals up to 28 days. Colony counts of the frozen culture were made using lactic agar and a “restricted” lactic agar medium (Tryptone reduced to 0.5%) to determine injury and death. Death was determined by the difference in plate counts on lactic agar before and after freezing. Injured cells were determined by the difference in plate counts on the two plating media. Greatest injury of the cells occurred during early stages of frozen storage and decreased with time, and death continuously increased. Injury and death were more pronounced when cells were frozen in water than when frozen in 10% nonfat milk solids. Certain cultures survived better when frozen rapidly, whereas with others survival was greater when freezing was slow. Successive freezing, thawing, and propagation of the culture gradually eliminated cells which showed injury by freezing.     

Injury and recovery of Escherichia coli after sublethal acidification.

Over 99% of the viable cells of Escherichia coli K-12 were injured after a 60-min exposure to 0.3 M sodium acetate buffer at pH 4.2. Injured cells were those able to grow on Trypticase soy agar but unable to grow on violet red bile agar. The extent of both death and injury of acid-treated cells increased with decreasing pH or increasing concentration of acid. Injured cells were able to recover their colony-forming ability on violet red bile agar by incubation in Trypticase soy broth or potassium phosphate buffer before plating on the agar media. Direct neutralization of the injury medium did not allow recovery and, in fact, was lethal to the population. The addition of metabolic inhibitors to the Trypticase soy recovery broth was used to study the repair process. It was not affected by the presence of inhibitors of protein, cell wall, deoxyribonucleic acid, or ribonucleic acid syntheses. The addition of 2,4-dinitrophenol to the recovery medium also did not inhibit recovery. Actinomycin D and N,N'-dicyclohexylcarbodiimide were lethal to a proportion of the acidified cells but allowed another fraction of the population to recover. There were no detectable amounts of 260- or 280-nm-absorbing materials leaked during the course of acid injury.     

Enumeration of Escherichia coli in Frozen Samples After Recovery from Injury

More than 90% of the surviving cells of Escherichia coli NCSM were injured after freezing in water at -78 C. Injury was determined by the ability of cells to form colonies on Trypticase soy agar with yeast extract but not on violet red-bile agar and deoxycholate-lactose agar. Exposure of the injured cells to Brilliant Green-bile broth and lauryl sulfate broth prevented subsequent colony formation on Trypticase soy agar with yeast extract. The freeze-injury could be repaired rapidly in a medium such as Trypticase soy broth with yeast extract (TSYB). The repaired cells formed colonies on violet red-bile agar and deoxycholate-lactose agar and were not inhibited by Brilliant Green-bile broth and lauryl sulfate broth. At least 90% of the cells repaired in TSYB within 30 min at 20 to 45 C and began multiplication within 2 h at 25 C. When the cells were frozen in different foods, 60 to 90% of the survivors were injured. Repair of the injured cells occurred in foods during 1 h at 25 C, but generally repair was greater and more reproducible when the foods were incubated in TSYB. The study indicated that the repair of freeze-injured coliform bacteria should be accomplished before such cells are exposed to selective media for their enumeration.     

Factors affecting inactivation of Moraxella-Acinetobacter cells in an irradiation process.

The effect of various stages of the irradiation processing of beef on the injury and inactivation of radiation-resistant Moraxella-Acinetobactor cells was studied. Moraxella-Acinetobacter cells were more resistant to heat inactivation and injury when heated in meat with salts (0.75% NaCl and 0.375% sodium tripolyphosphate) then in meat without salts. These salts had no effect on radiation resistance. Both radiation- and heat-injured cells were unable to form colonies at 30 degrees C in plate count agar containing 0.8% NaCl. Neither unstressed nor heat-stressed cells were able to multiply in minced beef incubated at 30 degrees C for 12 h. Only after the beef was diluted 1:10 with peptone water were the heat-injured cells able to repair and eventually multiply. Heated cells were more sensitive to radiation inactivation and injury than unheated cells. After repair, the cells regained their resistance to both NaCl and irradiation. Freezing and storage at -40 degrees C for 14 days had only a slight effect on either unstressed or heat-stressed cells.     

Injury recovery of foodborne pathogens in high hydrostatic pressure treated milk during storage

Bacteria are expected to be injured or killed by high hydrostatic pressure (HHP). This depends on pressure levels, species and strain of the microorganism and subsequent storage. Injured bacteria may be repaired which could affect the microbiological quality of foodstuffs with an important safety consideration especially in low acid food products. In this study two Gram-positive (Listeria monocytogenes CA and Staphylococcus aureus 485) and two Gram-negative (Escherichia coli O157:H7 933 and Salmonella enteritidis FDA) relatively pressure resistant strains of foodborne pathogens were pressurized at 350, 450 and 550 MPa in milk (pH 6.65) and stored at 4, 22 and 30 degrees C. The results of shelf life studies indicated two types of injury, I1 and I2, for all the pathogens studied. It is obvious that I2 type injury is a major injury and after its repair (I2 to I1), the cells can form colonies on non-selective but not on selective agar. The formation of colonies on both selective and non-selective agar occurs only after full recovery of injury (I1 to AC). The results presented in this study show that even if injured cells are not detected immediately after HHP treatment, I2 type injury could be potentially present in the food system. Therefore, it is imperative that shelf life studies must be conducted over a period of time for potential repair of I2 type injury either to detectable injury (I1) or to active cells (AC) to ascertain microbiological safety of low acid food products.     

Thermal injury of Yersinia enterocolitica.

Procedures were developed to evaluate thermal injury to three strains of Yersinia enterocolitica (serotypes 0:3, 0:8, and 0:17). Serotype 0:17 (atypical strain) was more sensitive to bile salts no. 3 (BS) and to sublethal heat treatment than the typical strains, 0:3 and 0:8. When the 0:3, 0:8, and 0:17 serotypes were thermally stressed in 0.1 M PO4 buffer, pH 7.0, at 47 degrees C for 70, 60, and 12 min, respectively, greater than 99% of the total viable cell population was injured. Injury was determined by the ability of cells to form colonies on brain heart infusion (BHI) agar, but not on Trypticase soy agar (TSA) plus 0.6% BS for serotypes 0:3 and 0:8 and TSA plus 0.16% BS for 0:17. Heat injury of serotype 0:17 cells for 15 min in 0.1 M PO4 buffer caused an approximate 1,000-fold reduction in cell numbers on selective media as compared with cells heated in pork infusion (PI), BHI broth, and 10% nonfat dry milk (NFDM). The extended lag and resuscitation period in BHI broth was 2.5 times greater for 0:17 cells injured in 0.1 M PO4 than for cells injured in BHI or PI. The rate and extent of repair of Y. enterocolitica 0:17 cells in three recovery media were directly related to the heating menstruum used for injury. The use of metabolic inhibitors demonstrated that ribonucleic acid synthesis was required for repair, whereas deoxyribonucleic, cell wall, and protein synthesis were not necessary for recovery of 0:17 cells injured in 0.1 M PO4 buffer, BHI, or PI. Inhibition of respiration by 2,4-dinitrophenol slowed repair only for 0:17 cells injured in 0.1 M PO4 buffer, not for cells injured in PI or BHI.     

Thermal injury of Yersinia enterocolitica

Procedures were developed to evaluate thermal injury to three strains of Yersinia enterocolitica (serotypes 0:3, 0:8, and 0:17). Serotype 0:17 (atypical strain) was more sensitive to bile salts no. 3 (BS) and to sublethal heat treatment than the typical strains, 0:3 and 0:8. When the 0:3, 0:8, and 0:17 serotypes were thermally stressed in 0.1 M PO4 buffer, pH 7.0, at 47 degrees C for 70, 60, and 12 min, respectively, greater than 99% of the total viable cell population was injured. Injury was determined by the ability of cells to form colonies on brain heart infusion (BHI) agar, but not on Trypticase soy agar (TSA) plus 0.6% BS for serotypes 0:3 and 0:8 and TSA plus 0.16% BS for 0:17. Heat injury of serotype 0:17 cells for 15 min in 0.1 M PO4 buffer caused an approximate 1,000-fold reduction in cell numbers on selective media as compared with cells heated in pork infusion (PI), BHI broth, and 10% nonfat dry milk (NFDM). The extended lag and resuscitation period in BHI broth was 2.5 times greater for 0:17 cells injured in 0.1 M PO4 than for cells injured in BHI or PI. The rate and extent of repair of Y. enterocolitica 0:17 cells in three recovery media were directly related to the heating menstruum used for injury. The use of metabolic inhibitors demonstrated that ribonucleic acid synthesis was required for repair, whereas deoxyribonucleic, cell wall, and protein synthesis were not necessary for recovery of 0:17 cells injured in 0.1 M PO4 buffer, BHI, or PI. Inhibition of respiration by 2,4-dinitrophenol slowed repair only for 0:17 cells injured in 0.1 M PO4 buffer, not for cells injured in PI or BHI.     

Heat-induced injury inListeria monocytogenes

Summary Heating ofListeria monocytogenes (Scott A strain) in potassium phosphate buffer (0.1 M, pH 7.2) at 52°C for 1 h led to injury, with the heat-injured cells failing to produce colonies on agar medium containing 5% NaCl. The detection of injury was based on the use of differential media: plating on tryptose phosphate broth+2% agar and 1% sodium pyruvate (TPBA+P) and on tryptose phosphate broth+2% agar and 5% NaCl (TPBA+S). Only non-injuredListeria formed colonies on TPBA+S whereas both heat-injured and non-injured cells formed colonies on TPBA+P. The bacterial count on TPBA+P minus that on TPBA+S represents the extent of heat injury. A large number of selective agars were tested and compared to TPBA+P for their ability to support repair and colony formation of heat-injuredL. monocytogenes. Media containing 0.025% phenylethanol, 0.0012–0.0025% acriflavin, 0.1–0.2% potassium tellurite, 0.001% polymyxin B sulfate, 5% NaCl or a combination of these ingredients were detrimental to the recovery of heat-injuredL. monocytogenes. Media currently in use forL. monocytogenes are not satisfactory for the recovery of injured cells.     

Death Through Respiratory Failure of a Fraction of Ultraviolet-Irradiated Escherichia coli B/r Cells

Escherichia coli B/r cells grown on a glycerol-containing medium and ultraviolet (UV)-irradiated to about 0.5% survival respire for about 1 hr and then cease for several hours. The cells that have completed repair and recovery processes begin to divide about 120 min after UV treatment, but this division is completely inhibited in liquid medium by caffeine, which delays repair of the irradiated deoxyribonucleic acid (DNA). When 5-fluorouracil (FU) is used to maintain respiration, the number of cells which form colonies when plated increases about 60-fold within 1 hr after irradiation. At least part of this increase does not involve repair while the cells are in the liquid medium because when caffeine is present there is still a 20-fold increase in colony formation. We conclude that many irradiated cells, although capable of carrying out complete and accurate repair of their DNA, die of respiratory failure; only when continuance of respiration is favored by FU treatment is their colony-forming potential realized. After an early increase, the number of cells able to form colonies in medium that contains FU remains constant while the completion of repair and recovery occurs. After these processes are completed, the number of cells able to form colonies increases slowly, except in the presence of caffeine, presumably because the late increase requires that repair steps take place while the cells are in liquid medium prior to cell division.     

Destruction of Microbacterium lacticum, Escherichia coli and Staphylococcus aureus in milk by spray-drying. I. Selective count of surviving bacteria]

In this paper a method which allows the measure of microbial death rate during spray-drying by means of a streptomycin-resistant mutant that can be grown on a streptomycin-containing agar is described. Plate counts of Microbacterium lacticum, Escherichia coli, and Staphylococcus aureus recovered from skim milk powders were done on plate count agar in the presence and absence of streptomycin and on various selective media. The powders were produced from evaporated milk previously inoculated with those organisms. Our results showed that the proposed method allows the recovery of 78% of M. lacticum, 61% of E. coli, and 100% of S. aureus that survived spray-drying. Recoveries of surviving E. coli on violet bile agar and brilliant green bile 2% were 34% and 29% respectively. Baird-Parker and mannitol salt agar media allow the recovery of all surviving S. aureus, thus showing that S. aureus cells did not lose their ability to grow in media containig 7.5% NaCl. Our results show that physiological injury of the cells during spray-drying differs from injury due to heating only.     

Normal mouse serum contains peptides which induce fibroblasts to grow in soft agar

The untransformed mouse fibroblast cells NIH/3T3, C3H/10T1/2, and rat NRK cells do not grow in soft agar in medium supplemented with 10% fetal calf serum. When fetal calf serum in the growth medium was supplemented with less than 1% of sera from mice or other vertebrates, however, these cells responded, forming large colonies. The morphology of soft agar colonies was a function of the treated cell type. In the presence of 10% serum from C57BL/6 mice, NRK cells grew to smooth-surfaced spherical colonies, while NIH/3T3 colonies showed individual round cells on their surface and C3H/10T1/2 cells grew as extended cells forming columns of end to end connected fibroblasts. Mus Musculus Castaneus-Epithelial (MMC- E) cells were not stimulated to grow in soft agar under these conditions. The major fibroblast colony-inducing factor (F-CIF) was partially purified from mouse serum by acid/ethanol-extraction, gel permeation chromatography, and reverse-phase high-pressure liquid chromatography. F-CIF is a polypeptide, which does not compete for binding to epidermal growth factor (EGF) receptors, but stimulates normal fibroblasts to form small colonies in semisolid medium and very large colonies in the presence of added EGF (2 ng/ml). In contrast to unfractionated mouse serum, purified F-CIF did not induce C3H/10T1/2 cells to grow in soft agar, suggesting that serum contains additional cell type-specific agar growth-stimulating activities.     

Suppression by the ColV,I-K94 plasmid of a growth lesion in ompA mutants of Escherichia coli

Organisms of three independently isolated ompA mutants of Escherichia coli failed to form colonies on glucose minimal agar (glucose MA) at 44 degrees C after growth in glucose minimal salts medium at 37 degrees C, although all three strains formed colonies on nutrient agar at 44 degrees C. Supplementation of the glucose MA with individual amino acids including L-methionine and/or L-cysteine did not allow colony formation at 44 degrees C, although addition of 0.1% Casamino acids was effective; replacement of glucose with other energy sources or ammonium ions with glutamate also did not allow growth at 44 degrees C. The failure to form colonies at 44 degrees C was not due to killing of the organisms, because colonies were formed if plates of the ompA mutant initially incubated at 44 degrees C were shifted to 30 degrees C after 16 h. Introduction of the ColV, I-K94 plasmid into P678-54 ompA, 1131 ompA or an ompC ompA mutant suppressed the 44 degrees C growth lesion, but other plasmids (F lac, R483ColIa, RI, ColB-K98, R124) tested in P678-54 ompA did not. Growth of the ColV, I-K94+ derivative at 44 degrees C was due to a suppressing effect of the plasmid rather than to introduction of the plasmid into a variant with normal or altered OmpA protein. An attempt was made to ascertain which component(s) encoded by ColV, I-K94 was (were) responsible for allowing growth at 44 degrees C. Transfer components appeared unlikely to be involved and plasmids which conferred individual colicins (plus the corresponding immunity component) did not suppress.(ABSTRACT TRUNCATED AT 250 WORDS)     

Injury and recovery of Bacillus megaterium from mild chlorhexidine treatment

Treatment of Bacillus megaterium cell suspensions with 12 /μmol/1 chlorhexidine diacetate for 5 min led to an approximate 50%, reduction in viability when plated onto tryptone soya agar (TSA). Fifty percent of the surviving fraction were unable to form colonies on TSA containing 5.5% w/v KCI. Such loss of KCl tolerance is indicative of membrane damage, and was recovered within 30 min of incubation in tryptone soya broth (TSB). Multiplication of the damaged organisms did not recommence in this medium until after 60 min. Inclusion of inhibitors of respiration, and of protein, RNA and DNA synthesis in the TSB recovery medium did not significantly affect either the rate or extent of the recovery of KCl tolerance by damaged organisms.     

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.