表达外源谷氨酸脱羧酶基因对重组乳酸乳球菌胁迫抗性的影响

通过在乳酸乳球菌（Lactobacillus lactis）NZ9000外源添加一定浓度的γ-氨基丁酸（gamma-aminobutyric acid,GABA）和表达可以合成GABA的谷氨酸脱羧酶（glutamic acid decarboxylase,GAD）两种方式,研究L. lactis NZ9000在酸胁迫和冷冻胁迫下的表现。结果表明：外源添加GABA的手段对于L. lactis NZ9000在酸胁迫和冷冻胁迫下的生长没有明显帮助。与之相反,通过逆转录-聚合酶链式反应克隆茶树中的CsGAD,构建pNZ8148-CsGAD表达载体,可获得高效表达GAD的基因工程重组菌L.?lactis?NZ9000/pNZ8148-CsGAD。经2?ng/mL乳酸链球菌素（Nisin）诱导8?h后,高效液相色谱检测表明重组菌合成GABA能力提高5?倍以上。生长曲线测定结果表明,正常培养条件下,重组菌到达对数生长平台期的时间较对照菌延长,到达稳定期的最大生物量（OD600?nm）提高至对照菌的1.5?倍;在pH?4.0的酸性培养条件下,对照菌基本不生长,而重组菌仍保持一定的生长力。低温胁迫实验结果表明,培养至稳定期后期的乳酸菌抗冻能力和存活率均要高于对数期中期和稳定期前期2?个培养阶段,且不同培养阶段中,重组菌的存活率均高于对照菌1～2?个数量级。综上所述,重组的L.?lactis?NZ9000/pNZ8148-CsGAD能够通过食品级异源表达CsGAD产生的GABA显著提高乳酸菌抗酸和抗冷冻胁迫的能力。本研究为探索研究乳酸菌抗胁迫机理、改良乳酸菌生长状态以利于其工业化用途的扩展提供了参考。     

Genotypic diversity of stress response in Lactobacillus plantarum, Lactobacillus paraplantarum and Lactobacillus pentosus

Lactobacillus plantarum, Lactobacillus pentosus and Lactobacillus paraplantarum are three closely related species which are widespread in food and non-food environments, and are important as starter bacteria or probiotics. In order to evaluate the phenotypic diversity of stress tolerance in the L. plantarum group and the ability to mount an adaptive heat shock response, the survival of exponential and stationary phase and of heat adapted exponential phase cells of six L. plantarum subsp. plantarum, one L. plantarum subsp. argentoratensis, one L. pentosus and two L. paraplantarum strains selected in a previous work upon exposure to oxidative, heat, detergent, starvation and acid stresses was compared to that of the L. plantarum WCFS1 strain. Furthermore, to evaluate the genotypic diversity in stress response genes, ten genes (encoding for chaperones DnaK, GroES and GroEL, regulators CtsR, HrcA and CcpA, ATPases/proteases ClpL, ClpP, ClpX and protease FtsH) were amplified using primers derived from the WCFS1 genome sequence and submitted to restriction with one or two endonucleases. The results were compared by univariate and multivariate statistical methods. In addition, the amplicons for hrcA and ctsR were sequenced and compared by multiple sequence alignment and polymorphism analysis. Although there was evidence of a generalized stress response in the stationary phase, with increase of oxidative, heat, and, to a lesser extent, starvation stress tolerance, and for adaptive heat stress response, with increased tolerance to heat, acid and detergent, different growth phases and adaptation patterns were found. Principal component analysis showed that while heat, acid and detergent stresses respond similarly to growth phase and adaptation, tolerance to oxidative and starvation stresses implies completely unrelated mechanisms. A dendrogram obtained using the data from multilocus restriction typing (MLRT) of stress response genes clearly separated two groups of L. plantarum strains from the other species but there was no correlation between genotypic grouping and grouping obtained on the basis of the stress response pattern, nor with the phylograms obtained from hrcA and ctsR sequences. Differences in sequence in L. plantarum strains were mostly due to single nucleotide polymorphisms with a high frequency of synonymous nucleotide changes and, while hrcA was characterized by an excess of low frequency polymorphism, very low diversity was found in ctsR sequences. Sequence alignment of hrcA allowed a correct discrimination of the strains at the species level, thus confirming the relevance of stress response genes for taxonomy.     

Utilizing luminometry for monitoring growth of Listeria monocytogenes in its liquid or gelified monocultures and cocultures with "acid-only" Lactococcus lactis

The light output of a bioluminescent recombinant strain of Listeria monocytogenes increased parallel with its viable cell counts during the exponential phase of the growth both in aerobic monocultures and mixed cultures, but dropped significantly at the commencement of the stationary phase. Suppression of L. monocytogenes by a nisin-less strain of Lactococcus lactis occurred only as an early induction of the stationary state of the target organism. In low-salt cocultures, an inverse linear correlation was found between the logarithmic initial counts of lactic acid bacteria and the extent of growth of Listeria. Decrease of luminometric activity of the bioluminescent test organism indicate sensitively the transformation of the cells into metabolically less active stationary state as a stress-adaptive response to nutrient depletion, "metabolic crowding", or, inimical processes.     

Diversity of stress responses in dairy thermophilic streptococci

Exponential and stationary phase cells of 56 strains of the dairy Streptococcus species S. thermophilus, S. macedonicus and S. salivarius, were exposed to acid, osmotic, oxidative and heat stresses to investigate the diversity of their responses. Three strains of dairy related streptococci, Lactococcus lactis ATCC11454, Enterococcus faecium DSM20477 and Enterococcus faecalis DSM20478, were included for comparison purposes. Acid and heat adaptation and cross-protection to stress were studied in ten strains with different stress response patterns. Cell death and the changes in protein expression were evaluated by plate counts and Sodium Dodecyl Sulfate Polyacrilamide Gel Electrophoresis, respectively. All strains of all species were highly tolerant of osmotic stress. With a few exceptions, acid and oxidative treatments reduced the number of viable cells by > 5 log units but responses to heat stress were more variable. For some, but not all strains, stationary phase cells were more resistant to some or all stresses. Matrix cluster analysis was used to group strains on the basis of their pattern of stress response in seven clusters. Significant associations between the sources of strains and stress resistance were found for acid and oxidative stresses. Adaptation to stress during the exponential phase enhanced the survival of acid and heat stressed cells from 1 to 60,000-folds, but a detrimental effect of adaptation on cell viability was evident for oxidative and osmotic stresses for three strains. Adaptation and entry into the stationary phase resulted in significant changes of protein bands whose estimated molecular masses corresponded with those of proteins (DnaK, GprE, GroEL, and GroES) involved in the general stress response but no statistically significant correlation between stress response and band intensity was evident.     

Suicide through stress: a bacterial response to sub-lethal injury in the food environment

The response of bacteria to sub-lethal injury is an important aspect of food microbiology as many inimical processes to which bacteria are subjected during processing are non-lethal. For pathogens like Salmonella and Escherichia coli, the difference in injury levels of exponential phase cells compared to their stationary phase counterparts in this regard is well recognised and evident for a variety of inimical processes. The expression of a range of stress resistance genes under the control of the sigma factor RpoS provides some explanation for the greater resistance of stationary phase cells. However in 1997 the suicide response hypothesis was put forward as an explanation for the observed response of Salmonella and E. coli to sub-lethal stresses. This hypothesis arose as an explanation for the observed protection of Salmonella and E. coli strains to heat and freeze-thaw injury by the presence of a high level of competitor organisms, a protection that had been shown to be RpoS independent. The central tenet of this theory was that under sub-lethal stress bacteria produce a burst of intracellular free radicals and it is these that lead to sub-lethal injury and/or death. Exponential phase cells because of their more active metabolism are more susceptible to this effect and suffer greater damage. This paper reviews the origins of this theory, the evidence for a free radical response and explores the potential mechanisms by which competitor cells produce a protective effect.     

The importance of RpoS in the survival of bacteria through food processing

The resistance of bacteria to environmental stresses is recognised as an increasingly important area of microbiology. In particular, the alternative sigma factor RpoS has been shown to produce greater stress resistance in stationary phase cells of Salmonella and Escherichia coli compared with those in exponential phase. Our work has shown that RpoS can be induced in exponential phase in response to a number of inimical processes used in the food industry, including changes in water activity produced using a range of humectants and preservatives. The presence of high levels of competitor cells will also lead to early induction of RpoS in Salmonella by an as yet unknown mechanism. High levels of competitor cells also provide Salmonella with an increased resistance to heat and freeze-thaw injury; the mechanism for this, however, is rpoS independent and has lead to the theory of a holistic mechanism for sub-lethal injury in respiring bacteria--the bacterial suicide response. This hypothesis predicts that sub-lethal injury occurs through the production of free radical species and not by the action of the applied inimical process per se. The demonstration of the production of a free radical burst when cells are subjected to differing types of stresses has been shown by a number of methods.     

Heat and acid tolerance of Listeria monocytogenes after exposure to single and multiple sublethal stresses

The majority of published studies on the adaptive heat or acid tolerance response of Listeria monocytogenes have been performed with a single strain exposed to a single adaptation treatment; however, in food ecosystems, microorganisms commonly exist as multi-species communities and encounter multiple stresses, which may result in "stress hardening". Therefore, the present study evaluated the adaptive responses to heat (52, 57 and 63 degrees C) or lactic acid (pH 3.5) of a 10-strain composite of L. monocytogenes meat and human isolates at stationary phase, following exposure to combinations of osmotic (10% NaCl), acidic (pH 5.0 with HCl) and thermal (T; 46 degrees C) stresses, sequentially or simultaneously within 1.5h, in tryptic soy broth with 0.6% yeast extract (TSBYE). All treatments induced adaptive responses on L. monocytogenes at 57 degrees C, while no such cross-protection was observed at 52 and 63 degrees C. Survivor curves at 57 degrees C appeared convex with profound shoulders determined by a Weibull model. The highest thermotolerance was observed after combined exposure to acid and heat shock (pH-T), followed by exposure to osmotic shock, and by the combination of osmotic with heat shock (NaCl-T). Regarding acid tolerance, prior exposure to low pH, pH-T, or a combination of NaCl, pH and T resulted in a marked increase of resistance to pH 3.5, showing concave inactivation curves with tails at higher levels of survivors (log(10)CFU ml(-1)) than the control cultures. The sequence of exposure to sublethal stresses did not affect the thermotolerance of L. monocytogenes, whereas simultaneous exposure to most multiple stresses (e.g., NaCl-pH-T, NaCl-T and NaCl-pH) resulted in higher survivors of L. monocytogenes at pH 3.5 than exposure to the same stresses sequentially. The results indicate that combinations and sequences of sublethal hurdles may affect L. monocytogenes acid and heat tolerance, especially in acidic environments with mild heating or in low moisture environments.     

Identification and partial characterization of lacticin BH5, a bacteriocin produced by Lactococcus lactis BH5 isolated from Kimchi

Strain BH5 was isolated from naturally fermented Kimchi and identified as a bacteriocin producer that has bactericidal activity against Micrococcus flavus ATCC 10240. Strain BH5 was identified tentatively as Lactococcus lactis by API test. Lactococcus lactis BH5 showed a broad spectrum of activity against most of the nonpathogenic and pathogenic microorganisms tested by the modified deferred method. The activity of lacticin BH5, named tentatively as the bacteriocin produced by L. lactis BH5, was detected at the mid-log growth phase, reached its maximum during the early stationary phase, and decreased after the late stationary phase. Lacticin BH5 also showed a relatively broad spectrum of activity against nonpathogenic and pathogenic microorganisms as tested by the spot-on-lawn method. Its antimicrobial activity on sensitive indicator cells was completely destroyed by protease XIV. The inhibitory activities of lacticin BH5 were detected during treatments up to 100 degrees C for 30 min. Lacticin BH5 was very stable over a pH range of 2.0 to 9.0 and was stable with all the organic solvents examined. It demonstrated a typical bactericidal mode of inhibition against M. flavus ATCC 10240. The apparent molecular mass of lacticin BH5 was estimated to be in the region of 3 to 3.5 kDa, by the direct detection of bactericidal activity after sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

单核细胞增生李斯特菌对食品加工中的胁迫响应及其机制研究进展

单核细胞增生李斯特菌（简称单增李斯特菌）在食品加工过程中经常会遇到环境胁迫,如酸胁迫、热胁迫、冷胁迫、干燥和高渗透压胁迫以及交叉胁迫等,并产生应激反应,而经过环境胁迫的单增李斯特菌可显著增强其抵抗致死性环境胁迫的能力,给食品安全带来极大危害。单增李斯特菌的酸胁迫响应机制主要包括F0F1-ATPase系统、谷氨酸脱羧酶系统以及精氨酸脱亚胺酶系统。热休克蛋白、冷休克蛋白、相容性溶质在单增李斯特菌的热胁迫、冷胁迫和干燥及高渗透压胁迫反应中起重要作用。本文从以上几方面就单增李斯特菌对环境胁迫响应及其机制的研究现状进行了综述,并提出了今后可能的研究方向,为单增李斯特菌在食品加工过程中的胁迫响应研究及防控提供指导。     

Biosynthesis of exopolysaccharide by a Bacillus licheniformis strain isolated from ropy cider

Listeria monocytogenes accumulates low molecular weight compounds (osmolytes, or compatible solutes) in response to chill stress. This response has been shown to be responsible, in part, for the chill tolerance of the species. Among the osmolytes tested to date, glycine betaine, gamma-butyrobetaine and carnitine display the strongest cryoprotective effect. These osmolytes are not synthesized in the cell and must be transported from the medium. In this study, the compatible solute accumulation profile of the food-borne pathogen L. monocytogenes was determined in balanced growth and stationary phase cultures grown in milk whey at 7 and 30 degrees C. In balanced growth cultures at 7 degrees C, glycine betaine (720 nmol/10(10) cfu) and carnitine (130 nmol/10(10) cfu) were the major osmolytes accumulated by wild-type L. monocytogenes 10403S, whereas carnitine (490 nmol/10(10) cfu) was the dominant osmolyte and glycine betaine was present in smaller amounts (270 nmol/10(10) cfu) in a mutant (L. monocytogenes LTG59) blocked in the major glycine betaine uptake system, glycine betaine porter II. In strain 10403S, glycine betaine and carnitine were present in eightfold and twofold excess at 7 degrees C compared to 30 degrees C; the respective ratios for strain LTG59 were 6 and 8. The intracellular concentration of osmolytes in stationary phase cultures at 7 degrees C was markedly reduced compared to that during balanced growth. Furthermore, at 4 degrees C, small but highly significant differences in growth were observed between strains. Strain LTG59 grew with a lag phase that was significantly longer, a generation time that was significantly greater and reached a final cell yield that was significantly lower than that of strain 10403S. The elevated accumulation of carnitine in the absence of glycine betaine porter II was insufficient to confer the magnitude of the cryoprotective effect displayed by the wild type.     

有氧呼吸对乳酸乳球菌代谢途径的影响及其潜在应用展望

作为兼性厌氧菌,乳酸乳球菌具有双重的代谢模式,既可以在厌氧条件下进行传统的发酵代谢,也可以在添加血红素且通氧的条件下进行有氧呼吸代谢。本文综述了乳酸乳球菌有氧呼吸代谢的遗传基础的必备元件、显著的生理学变化、实际和潜在应用。乳酸乳球菌在进行有氧呼吸代谢时具有生物量显著增加、延长存活率、降低氧胁迫和酸胁迫等优势,具有巨大的应用潜力。随着乳酸乳球菌有氧呼吸代谢的深入研究,我们可以更好地挖掘乳酸乳球菌的代谢模式和开发乳酸乳球菌的全部潜力。      

Heat and pulsed electric field resistance of pigmented and non-pigmented enterotoxigenic strains of Staphylococcus aureus in exponential and stationary phase of growth

The survival of four enterotoxigenic strains of Staphylococcus aureus (with different pigment content) to heat and to pulsed electric fields (PEF) treatments, and the increase in resistance to both processing stresses associated with entrance into stationary phase was examined. Survival curves to heat (58 degrees C) and to PEF (26 kV/cm) of cells in the stationary and in the exponential phase of growth were obtained. Whereas a wide variation in resistance to heat treatments was detected amongst the four strains, with decimal reduction time values at 58 degrees C (D(58 degrees C)) ranging from 0.93 to 0.20 min, the resistance to PEF was very similar. The occurrence of a higher tolerance to heat in stationary phase was coincident with a higher content in carotenoid pigmentation in S. aureus colonies. However, cells of the most heat resistant (pigmented) and the most heat sensitive (non-pigmented) strains in the mid-exponential phase of growth showed similar resistance to heat and to PEF. Therefore the increase in thermotolerance upon entrance into stationary phase of growth was more marked for the pigmented strains. Recovery in anaerobic conditions particularly enhanced survival to heat treatments in a non-pigmented strain. Strain CECT 4630, which possess a deficient sigma B activity, showed low heat resistance, low pigmentation, and reduced increase in thermotolerance in stationary phase. These results indicate that the magnitude of the development of a higher heat resistance in S. aureus in stationary phase is positively related to the carotenoid content of the strain. The development of tolerance to pulsed electric field was less relevant and not linked to the carotenoid content.     

Survival of Vibrio parahaemolyticus under environmental stresses as influenced by growth phase and pre-adaptation treatment

In this study, the susceptibility of Vibrio parahaemolyticus in different growth phases after exposure to lethal stresses including 47 °C and 8% ethanol was first investigated. The effect of a culture's growth phase on both the heat and ethanol shock response of V. parahaemolyticus was then examined. It was found that cells of V. parahaemolyticus in the mid-exponential phase, regardless of adaptation, were most susceptible to environmental stresses, while cells in the stationary phase were least susceptible to the lethal stresses examined. Adaptation with heat shock at 42 °C for 45 min or ethanol shock with 5% ethanol for 60 min induced an increased resistance of V. parahaemolyticus to subsequent lethal stresses at 47 °C and 8% ethanol. While the adaptation treatments resulted in a reduced resistance of the test organism to pH 4.4 and 20% NaCl. Generally, the extent of changes in the resistance of V. parahaemolyticus to lethal stresses between the adapted and control cells was found to be growth phase dependent. Compared with the respective control cells, the adapted late-exponential phase cells exhibited the greatest extent of change, while the adapted stationary phase cells showed the least change in their resistance to the lethal stresses examined.     

Tolerance and starvation induced cross-protection against different stresses in Aeromonas hydrophila

Aeromonas hydrophila is sometimes considered as a controversial human pathogen and reported to be susceptible to food processing procedures and environmental stresses. In this study, we have shown that early stationary phase cells of A. hydrophila were readily killed during up shifts in temperature (in the range 50-70 degrees C), the course of drying (at relative humidity, temperature and brightness of the laboratory) and after 5 min exposure to 20%, 30% and 40% v/v ethanol. However, this bacterium was found moderately susceptible to down shift to 4 degrees C in nutrient poor water, sodium chloride stresses (1.5 and 2 M) and to 12% and 15% v/v ethanol stresses. Tolerance against 1 M NaCl and 10% v/v ethanol was observed. At ambient temperature (24.5 degrees C), this microorganism exhibited a starvation survival state, which was largely independent of the initial cell concentrations (8.82, 7.71 and 6.76 log units). The cross-protection experiments showed that cells starved for short (1 day) or prolonged (50 days) periods developed increased resistance to down shift at 4 degrees C and ethanol stress. This may be of concern to the food-processing industry from the public health perspective.     

Physiological changes in Campylobacter jejuni on entry into stationary phase

Campylobacter jejuni NCTC 11168 does not exhibit the general increase in cellular stress resistance on entry into stationary phase that is seen in most other bacteria. This is consistent with the lack of global stationary phase regulatory elements in this organism, deduced from an analysis of its genome sequence. We now show that C. jejuni NCTC 11168 does undergo certain changes in stationary phase, of a pattern not previously described. As cells entered stationary phase there was a change in membrane fatty acid composition, principally a decrease in the proportion of unsaturated fatty acids and an increase in the content of cyclopropane and short-chain fatty acids. These changes in membrane composition were accompanied by an increase in the resilience of the cell membrane towards loss of integrity caused by pressure and an increase in cellular pressure resistance. By contrast, there were no major changes in resistance to acid or heat treatment. A similar pattern of changes in stress resistance on entry into stationary phase was seen in C. jejuni NCTC 11351, the type strain. These changes appear to represent a restricted physiological response to the conditions existing in stationary phase cultures, in an organism having limited capacity for genetic regulation and adaptation to environment.     

Milk acidification by Lactococcus lactis is improved by decreasing the level of dissolved oxygen rather than decreasing redox potential in the milk prior to inoculation

Although redox potential is very rarely taken into account in food fermentation it could be as influential as pH on bacterial activities. Lactococcus lactis is already known to exhibit a powerful reducing activity in milk but its reduction activity was shown to occur prior to its acidification activity with a potential interaction between these two lactococcal activities. Therefore, acidification lag-type phase could be shortened by decreasing the redox potential of milk before inoculation. As the redox potential is highly dependent on the dissolved oxygen level, our objective was to study their separate and combined influences on acidification and growth kinetics of pure L. lactis strains in milk. Results showed that high level of dissolved oxygen is significantly more influential on growth, and even more on acidification kinetics, than initial decreased redox potential of milk. Reduction of milk was drastic and mostly due to bacterial activity. The redox potential of milk only dropped when dissolved oxygen was entirely consumed. When there was no dissolved oxygen from the beginning, L. lactis immediately decreased the redox potential of milk and acidified afterwards. When the level of dissolved oxygen was initially high, acidification and reduction of milk occurred at the same time. Acidification kinetics was then biphasic with a slower rate during the aerobic stage and a faster rate during the anaerobic stage. The seven strains tested demonstrated diversity in both their acidification kinetics and their adaptation to high level of dissolved oxygen, independent of their growth kinetics. To conclude, we have shown that the level of dissolved oxygen in milk has a dramatic influence on acidification kinetics and could be used to control acidification kinetics in dairy industries.     

Effect of nutrient starvation on the resistance of Escherichia coli O157:H7 to subsequent heat stress

The resistance of three strains of Escherichia coli O157:H7 in their stationary growth phase to starvation (24 h in water at 37 degrees C) followed by a heat treatment (56 degrees C for up to 90 min) was determined. Starvation was found to increase significantly the resistance of two strains (NCTC 12079; eae+, VT1+, VT2+, and ATCC 43889 eae+, VT2+) but not the remaining strain (ATCC 43890 eae+, VT1+). Strain NCTC 12079 (only one tested) was shown to retain all of the three virulence factors after the two stresses. De novo protein synthesis was shown to be required for heat resistance. Evidence using an rpoS mutant indicated a central role for this gene in inducing heat resistance after a starvation stress. It is hoped that this work will contribute to more accurate risk assessments in certain food processing operations.