Mechanisms of heat inactivation in Salmonella serotype Typhimurium as affected by low water activity at different temperatures

AIMS: To determine the effect of reduced water activity (a(w)) on thermal inactivation of Salmonella serotype Typhimurium at different temperatures and its mechanism. METHODS AND RESULTS: D-value determinations at a range of different temperatures showed that heating at reduced a(w) (0.94, produced by addition of glucose or sodium chloride to nutrient broth) was protective at temperatures above 53-55 degrees C but sensitizing below this temperature. Using selective enumeration media to determine injury, it was shown that at lower heating temperatures cells survived at high a(w) with cytoplasmic injury whereas at low a(w) these cells were killed. At higher temperatures ribosome degradation was a more important cause of death and was inhibited by low a(w) heating media thereby providing greater heat resistance. CONCLUSIONS: The observed change in behaviour reflects the different reactions responsible for thermal death at different temperatures and their different response to reduced a(w). SIGNIFICANCE AND IMPACT OF THE STUDY: This work qualifies the previous assumption that reduced a(w) is protective and suggests that the efficacy of low temperature pasteurization regimes may be increased by reduced a(w).     

Bacterial community dynamics in aerated cow manure slurry at different aeration intensities

Aims: This study aimed to characterize microbial community dynamics in aerated cow manure slurry at different aeration intensities. Methods and Results: Batch aerobic treatments were set up in 5‐l jar fermentor, each containing 3 l of manure slurry; the slurries were subjected to low, medium and high (50, 150 and 250 ml min^?1, respectively) aeration for 9 days. Microbial community composition was determined using terminal restriction fragment length polymorphism and a clone library targeting 16S rRNA genes. High and medium aeration accelerated organic carbon degradation in parallel with the degree of aeration intensity; however, 90% of the initial total organic carbon was retained during low‐aeration treatment. During the active stages of organic carbon decomposition, clones belonging to the class Bacilli accumulated. Moreover, Bacilli accumulation occurred earlier under high aeration than under medium aeration. Conclusions: Organic matter degradation was mainly governed by a common microbial assemblage consisting of many lineages belonging to the class Bacilli. The timing of community development differed depending on aeration intensity. Significance and Impact of the Study: This study reports on changes in several environmentally important parameters and the principal microbial assemblage during the pollution‐reducing phase of cattle manure aeration treatment.     

UGA can be decoded as tryptophan at low efficiency in Bacillus subtilis.

Replacement of cat-86 codon 7 or 144 with the UGA codon permitted the gene to confer chloramphenicol resistance in wild-type Bacillus subtilis. UAA replacements of the same codons resulted in a chloramphenicol-sensitive phenotype in wild-type B. subtilis and a chloramphenicol-resistant phenotype in suppressor-positive strains. N-terminal sequencing showed that UGA at codon 7 was decoded as tryptophan in wild-type cells, at an efficiency of about 6%.     

Ribosomal protein L20 can replace the assembly-initiator protein L24 at low temperatures

The assembly of the 50S subunit from Escherichia coli ribosomes is initiated by two ribosomal proteins, L24 and L3. A mutant lacking the assembly-initiator protein L24 shows distinct phenotypic features (temperature sensitivity, growth rate reduced by a factor of 6 at permissive temperatures below 34 degrees C, underproduction of 50S subunits), which could be traced back to assembly effects caused by lack of L24 [Herold, M., Nowotny, V., Dabbs, E. R., & Nierhaus, K. H. (1986) Mol. Gen. Genet. 203, 281-287]. As expected, only one assembly protein was effective during in vitro assembly at nonpermissive temperatures, whereas surprisingly the restoration of active particle formation at permissive temperatures was paralleled by the reappearance of two initiator proteins. Here we analyze the initiation of assembly at permissive temperatures in the absence of L24. We demonstrate in a series of reconstitution experiments with purified proteins that the two initiator proteins are L20 and L3. Thus, L20 can replace L24 for the initiation of assembly at permissive temperatures.     

Oil degradation by basidiomycetes in soil and peat at low temperatures

A total of 17 basidiomycete strains causing white rot and growing on oil-contaminated substrates have been screened. Three strains with high (Steccherinum murashkinskyi), average (Trametes maxima), and low (Pleurotus ostreatus) capacities for the colonization of oil-contaminated substrates have been selected. The potential for degrading crude oil hydrocarbons has been assessed with the use of fungi grown on nonsterile soil and peat at low temperatures. Candida sp. and Rhodococcus sp. commercial strains have been used as reference organisms with oil-degrading ability. All microorganisms introduced in oil-contaminated soil have proved to be ineffective, whereas the inoculation of peat with basidiomycetes and oil-degrading microorganisms accelerated the destruction of oil hydrocarbons. The greatest degradation potential of oil-aliphatic hydrocarbons has been found in S. murashlinskyi. T. maxima turned out to be the most successful in degrading aromatic hydrocarbons. It has been suggested that aboriginal microflora contributes importantly to the effectiveness of oil-destructing microorganisms. T. maxima and S. murashkinskyi strains are promising for further study as oil-oxidizing agents during bioremediation of oil-contaminated peat soil under conditions of low temperatures.     

Bacterial gene expression at low temperatures

Under suboptimal environmental conditions such as low temperatures, many bacteria have an extended lag phase, altered cell structures, and composition such as a less fluid (more rigid) and leaky cytoplasmic membrane. As a result, cells may die, enter into a starvation mode of metabolism or a physiologically viable but non-culturable (VBNC) state. In the latter state, the amount of gene expression per cell is virtually undetectable. In this article, gene expression under (suboptimal) low temperature conditions in non-psychrophilic environmental bacteria is examined. The pros and cons of some of the molecular methodologies for gene expression analysis are also discussed.     

Methanogenesis at low temperatures by microflora of tundra wetland soil

Active methanogenesis from organic matter contained in soil samples from tundra wetland occurred even at 6 °C. Methane was the only end product in balanced microbial community with H₂/CO₂ as a substrate, besides acetate was produced as an intermediate at temperatures below 10°C. The activity of different microbial groups of methanogenic community in the temperature range of 6–28 °C was investigated using 5% of tundra soil as inoculum. Anaerobic microflora of tundra wetland fermented different organic compounds with formation of hydrogen, volatile fatty acids (VFA) and alcohols. Methane was produced at the second step. Homoacetogenic and methanogenic bacteria competed for such substrates as hydrogen, formate, carbon monoxide and methanol. Acetogens out competed methanogens in an excess of substrate and low density of microbial population. Kinetic analysis of the results confirmed the prevalence of hydrogen acetogenesis on methanogenesis. Pure culture of acetogenic bacteria was isolated at 6 °C. Dilution of tundra soil and supply with the excess of substrate disbalanced the methanoigenic microbial community. It resulted in accumulation of acetate and other VFA. In balanced microbial community obviously autotrophic methanogens keep hydrogen concentration below a threshold for syntrophic degradation of VFA. Accumulation of acetate- and H₂/CO₂-utilising methanogens should be very important in methanogenic microbial community operating at low temperatures.     

A mutated bovine prochymosin zymogen can be activated without proteolytic processing at low pH

As a first step towards understanding how the zymogen structure of prochymosin contributes to the process by which active enzyme is produced, we altered the nucleotide sequence which encodes the amino-terminal (or propeptide) region of the protein. Of the two sites for autoproteolysis of prochymosin, one where pseudochymosin is formed at a pH of 2 and the other where chymosin is formed at pH 4-5, we changed the former by removing one codon and changing two other codons. This genetically modified prochymosin was proteolytically processed and activated normally at pH 4.5. However, at pH 2.0 we observed only partial activation of the zymogen and found no evidence of proteolytic processing. The properties of this engineered prochymosin suggest that zymogen activation does not require proteolysis and that the two different zymogen processing sites can function independently from one another.     

Chronic irradiation with low doses can be characterized by significant biological efficacy

Chromosomal aberrations (ChA) level was analyzed in the onion root meristem after the chronic irradiation with different dose capacities. It was shown that after the chronic irradiation with doses of 0.87 cGy, 2.61 cGy and 4.35 cGy the level of chromosomal aberrations depended on the dose capacity. Its value may also correspond to those which have been induced with accute irradiation. Biological efficacy of chronic irradiation may be from 20 to 1000 time folder in order to compare it with accute irradiation and this value depends on the irradiation regime.     

Toxin production by Bacillus cereus dairy isolates in milk at low temperatures

A total of 136 strains of Bacillus cereus isolated from milk and cream were evaluated for toxin production based on HeLa S3, Vero, and human embryonic lung (HEL) cell cytotoxicity in vitro. HEL cell monolayers were more susceptible than the other two cell lines. The percentage of isolates exhibiting HEL cytotoxicity was similar (43.0 and 48.4%) when the strains were grown in brain heart infusion broth containing 0.1% glucose (BHIG) at 7 and 24 h, respectively, at 30 degrees C. In milk, only 21.8% of isolates showed HEL cytotoxicity at 7 h, and the number increased significantly to 73.2% at 24 h at 30 degrees C. Further, 102 toxin-positive isolates were acclimatized to grow at 8 degrees C in milk. Ninety-four (92.2%) of the strains produced HEL cytotoxicity of various degrees with no strict correlation to bacterial cell numbers and also elicited vascular permeability reaction in rabbit skin. Under aerated growth conditions (agitation, 200 rpm) B. cereus elicited cytotoxicity in BHIG and in milk at temperatures of 30, 15, and 8 degrees C. However, in nonaerated (stagnant) cultures toxin production was diminished (BHIG) or completely lost (milk) at all temperatures. Toxin production at 8 degrees C was evaluated in two different types of commercial cardboard milk packages by inoculation with a potent toxigenic dairy isolate. No detectable HEL cytotoxicity was observed in milk in any of the packages either at stagnant conditions or during mechanical shaking. However, the same strain produced cytotoxin in whipped cream at 8 degrees C.     

The feeling of dampness at low temperatures

The widely held view that in cold weather one feels colder when the atmosphere is damp than when it is dry was investigated on clothed subjects. Subjective coldness and dampness, determined by a panel of six people who walked about half a mile in the open in winter, were compared with measurements of temperature, relative humidity, and other meteorological variables. The panellists comments showed that when the weather is cold, people think it is damp when the sky is overcast, irrespective of relative humidity. However, when this factor has been allowed for there still appears to be some correlation between subjective dampness and relative humidity. Relative humidity does appear to have an effect on how cold one feels at low temperatures, but only to a limited extent, and in the opposite direction to popular belief.     

Injury to human granulocytes at low temperatures

Granulocytes differ from other blood cells in that they are more sensitive to injury on freezing and thawing. Previous studies suggest that the difficulty in preserving them is related to their sensitivity to osmotic stress. A miniaturized system both for freezing granulocytes and testing their function in the same Terasaki plates has been developed. This allowed study of several factors simultaneously including concentration of protective additive, different cooling conditions, and dilution conditions on rewarming.We observed two types of injury to granulocytes frozen to higher subzero temperatures and thawed directly. The first type was initially severe but decreased with time in the frozen state under some conditions and appears not to have been reported in other cell systems. The second type of injury consists of conventional loss of function with longer holding times after freezing. Cells surviving these two classes of injury could be protected against the further stress of rapid cooling into liquid nitrogen, but this protection required a longer time during cooling in the frozen state than with other cell types.We have studied the interactions between several variables, e.g., time in DMSO before freezing and dilution rate after thawing in an attempt to characterize the unusual injurious mechanism at high subzero temperatures that, we believe, is the real cause of the difficulty of preserving these cells.     

Protein structure and function at low temperatures

Proteins represent the major components in the living cell that provide the whole repertoire of constituents of cellular organization and metabolism. In the process of evolution, adaptation to extreme conditions mainly referred to temperature, pH and low water activity. With respect to life at low temperatures, effects on protein structure, protein stability and protein folding need consideration. The sequences and topologies of proteins from psychrophilic, mesophilic and thermophilic organisms are found to be highly homologous. Commonly, adaptive changes refer to multiple alterations of the amino acid sequence, which presently cannot be correlated with specific changes of structure and stability; so far it has not been possible to attribute specific increments in the free energy of stabilization to well-defined amino-acid exchanges in an unambiguous way. The stability of proteins is limited at high and low temperatures. Their expression and self-organization may be accomplished under conditions strongly deviating from optimum growth conditions. Molecular adaptation to extremes of temperature seems to be accompanied by a flattening of the temperature profile of the free energy of stabilization. In principle, the free energy of stabilization of proteins is small compared to the total molecular energy. As a consequence, molecular adaptation to extremes of physical conditions only requires marginal alterations of the intermolecular interactions and packing density. Careful statistical and structural analyses indicate that altering the number of ion pairs and hydrophobic interactions allows the flexibility of proteins to be adjusted so that full catalytic function is maintained at varying temperatures.