名词解释

菌落在固体培养基上,一个单细胞(孢子)经过一定时间培养后,在一局限的地方繁殖成为肉眼可见的细胞群体,称为菌落。因之,可用菌落数来代表活菌(孢子)的数目。不同成分的培养基上,菌落呈现的特征不同;不同的菌在相同成分的培养基上,菌落呈现的特征也各不相同;又由于各种菌在固定的培养基上菌     

氧化压力下沙门氏菌可培养性检测及其活的非可培养状态形成情况

【背景】氧化压力会导致细菌进入活的非可培养(viable but non-culturable,VBNC)状态,菌落形成能力可能受到亚致死损伤的影响。目前对于VBNC态细菌的定量检测是基于活菌数与可培养数的差值,因此可培养数的检测对于VBNC态定量研究很关键,培养基组成不合适可能会造成漏检。【目的】分析培养基组成对氧化压力下亚致死损伤细菌检测的重要影响;探究常见食源性致病菌肠炎沙门氏菌在氧化压力下形成VBNC态的情况。【方法】分别采用Luria-Bertani (LB)、beef peptone yeast (BPY)和Salmonella Shigella (SS)培养基检测并比较肠炎沙门氏菌的可培养数;采用RT-qPCR、荧光染色-激光共聚焦显微镜观测氧化压力下肠炎沙门氏菌形成VBNC态的情况。【结果】非选择性培养基LB和BPY能检出亚致死细菌,SS培养基中牛胆盐导致可培养数减少;肠炎沙门氏菌经53°C过氧化氢处理1.5 h后进入VBNC态的比例显著高于53°C过氧化氢+亚铁离子和过氧化氢+柠檬酸处理(P<0.05)。【结论】在对VBNC态的检测中应选择合适的固体培养基检测可...     

易致污染的支原体在固体培养基上的形态特征

目的研究不同条件下、不同生长期易致污染的支原体在固体培养基中的形态特征。方法通过改变支原体菌体浓度、培养时间及培养基组成,观察支原体在固体培养基中的形态变化。结果支原体菌体浓度小于103cfu/m L时,培养至2~3天后可在固体培养基中形成典型的"油煎蛋"状形态,以蔗糖作为碳源培养支原体会导致葡萄糖发酵型支原体(肺炎支原体)不能在固体培养基中形成典型菌落,当使用牛血清代替马血清为支原体提供外源胆固醇时,猪鼻支原体在固体培养基中不能形成典型菌落。结论支原体的不同生长期、菌体浓度、培养基的组成都会使易致污染的支原体在固体培养基上的形态发生变化。     

真菌的L型

随着广谱抗生素、免疫抑制剂的广泛应用及恶性肿瘤、AIDS 发病率的升高,真菌对人类的感染日益增多。尽管真菌细胞壁坚硬而复杂,但也因受到体内外某些因素的影响发生细胞壁缺损变为 L型。真菌 L 型的形成自发形成:真菌能自发形成 L 型,将念珠菌接种在营养缺乏的培养基上,使其处于饥饿状态,长出的菌30～50%缺乏细胞壁。若在培养基中加入人血,反而不利于 L 型的生长,若将此 L 型继续培养,菌落周边长出假菌丝,2周后又逐渐回复成典型的     

非高渗透压培养基培养细菌L型的研究

本文用青霉素在高渗透压的L型培养基上,诱导金黄色葡萄球菌和白喉杆菌形成L型后,直接种入无血清亦无渗透压保护剂的非高渗透压培养基中,传代培养和观察其形态、培养及代谢特性。结果表明,金黄色葡萄球菌L型和白喉杆菌L型在非高渗透压培养基中,传代培养后,不能在高渗透压的L型培养基上生长形成菌落。和丧失了对多种糖发酵的能力。     

三种绒泡菌属原质团的培养和孢子果的诱导发生

在黏菌个体发育研究的培养过程中,经常发生原质团不能转变为孢子果的情况,使个体发育停留在营养生长阶段,利用液体发酵和有饲培养相结合的方法获得的绒泡菌属黏菌原质团进行了孢子果的诱导。在饥饿条件下,通过对光照和温度的调节,获得了绒泡菌属黏菌在不同培养条件下形成孢子果和菌核的最佳条件。在固体培养基和液体培养基中获得全白绒泡菌孢子果的最佳培养条件分别为：24℃、6,000lx光照和20℃、6,000lx光照;获得扁绒泡菌孢子果的最佳培养条件分别为：26℃、6,000lx光照和20℃、6,000lx光照。淡黄绒泡菌Physarum melleum在固体培养基上既可以获得孢子果也可以获得菌核,最佳培养条件分别为：26℃、6,000lx光照和22℃、3,000lx光照;在液体培养基中只能形成菌核,条件为：22℃、6,000lx光照。     

7种甲真菌病致病菌的侵袭力比较

目的观察红色毛癣菌、白念珠菌、红酵母、短帚霉、串珠镰刀菌、烟曲霉、绳状青霉是否具有侵犯离体甲板的能力,并比较其侵袭能力的强弱。方法将无菌甲板接种于红色毛癣菌、白念珠菌、红酵母、短帚霉、串珠镰刀菌、烟曲霉、绳状青霉7种真菌的3种不同培养基(固体沙氏培养皿、液体沙氏试管及生理盐水试管)中,定期用NaOH溶甲法分析甲板受侵程度。结果某些非皮肤癣菌性丝状真菌侵犯体外甲板的能力与红色毛癣菌基本相同,但丝状真菌比酵母菌强,酵母菌中白念珠菌比红酵母强。同一种真菌在固体培养基上对甲板的侵袭力远比在液体培养基中或生理盐水中强。结论一定条件下,某些非皮肤癣菌也能直接侵犯甲板。真菌侵犯甲的能力与其形成菌丝的能力及其与甲板接触的稳定性成正比。     

高产吲哚乙酸及高泌氨巴西固氨螺菌的筛选与鉴定

目的：从玉米根际和土壤中分离具有高产吲哚乙酸较强的泌氨能力的巴西固氮螺菌。方法：分别通过半固体NFb培养基、CR培养基、LB培养基分离培养固氮菌株,并经过一系列菌落菌体形态特征、生理生化特性和16S rDNA序列测定等试验对其进行鉴定。结果：经分离纯化获得10株固氮菌,并鉴定均为巴西固氮螺菌（Azospirillum brasilense）,其中菌株R7在甘油半固体培养基上能分泌约14mmol/L的氨,在添加了色氨酸的培养基中能够合成58.8μg/ml的吲哚-3-乙酸（IAA）。结论：成功筛选得到一株既高产吲哚乙酸又有较强的泌氨能力的巴西固氮螺菌。     

低温寡营养条件下副溶血弧菌形成活的非可培养状态及其复苏研究

为研究在低温寡营养条件下副溶血弧菌(Vibrio parahaemolyticus)能否进入活的非可培养状态(VBNC),将浓度为1×1010CFU/mL的副溶血弧菌HW799在陈海水中4℃保存,每隔5天取样分别用吖啶橙染色荧光显微镜直接计数法(AODC)、活菌直接计数法(DVC)和涂布平板法(PC)测定细菌总数、活细菌数和可培养细菌数.在第30天时总细菌数基本不变,仍保持在109CFU/mL,活菌数为106CFU/mL,比总菌数低了约三个数量级,可培养细菌数为零,表明绝大部分副溶血弧菌HW799进入了VBNC状态;用扫描电镜、流式细胞仪对副溶血弧菌HW799活的非可培养状态、正常状态以及复苏后的细胞形态的研究表明进入VBNC状态后副溶血弧菌HW799形状变为球状,体积比正常状态明显变小,活细胞数也略有减少;采用在培养液中添加营养物质升温培养的方法,使VBNC状态的副溶血弧菌细胞在48h内复苏为可培养状态,复苏后的副溶血弧菌HW799与正常状态的细菌形态相似.     

食品微生物检验中菌落总数测定的注意事项

1菌落总数及测定菌落是指细菌在固体培养基上生长繁殖而形成的能被肉眼识别的生长物,它是由数以万计相同的细菌集合而成。当样品被稀释到一定程度,与培养基混合,在一定培养条件下,每个能够生长繁殖的细菌细胞都可以在平板上形成一个可见的菌落。菌落总数就是指食品检样经过处理     

Hungry bacteria – definition and properties of a nutritional state

Bacteria are sometimes neither starving nor under nutrient-excess conditions. When growing with suboptimal levels of nutrients, hungry bacteria express appropriate cellular responses. This review discusses approaches to defining the hunger response in both molecular and growth kinetic terms. The gene expression changes unique to hunger conditions are described, using Escherichia coli as the primary example. Metabolite changes with hunger and starvation and the differing role of the stationary phase regulator RpoS also lead to the hypothesis proposed in this review that bacteria undertake distinct approaches to hunger and starvation. Indeed, an understanding of the difference between hunger and starvation and the incompatibility between hunger and starvation responses explains some of the paradoxical mutational adaptations, such as rpoS inactivation, found in natural populations.     

Adhesion to medical device materials and biofilm formation capability of some species of enterococci in different physiological states

Enterococci may survive in adverse environments including the human body where bacteriocins, antibiotics, iron-limitation and immune response represent stressing conditions for bacteria that cause division block. In those conditions, bacteria present in the human body would hardly be in an exponentially growing phase but would mostly be in physiological states such as starvation or the viable but nonculturable (VBNC) state. The possibility that the starved and VBNC bacteria can maintain their ability to adhere to living and inanimate substrates is the first mandatory step for them potentially to cause an infection process. In this study it is shown that starved and stationary enterococcal cells are able to form biofilms on plastic material albeit with reduced efficiency as compared to growing cells. Moreover, although VBNC enterococcal forms are not capable of forming biofilms, Enterococcus faecalis and other enterococcal species of medical interest maintain their ability to synthesize the polymeric matrix for a limited period of time under adverse environmental conditions. The data presented, together with those regarding the maintenance of the division recovery potential already proved in nonculturable bacteria, further support the possibility for the VBNC and other nondividing bacterial forms to have a role as infectious agents and to constitute a risk to human health.     

Role of dissolution rate and solubility in biodegradation of aromatic compounds.

Strains of Moraxella sp., Pseudomonas sp., and Flavobacterium sp. able to grow on biphenyl were isolated from sewage. The bacteria produced 2.3 to 4.5 g of protein per mol of biphenyl carbon, and similar protein yields were obtained when the isolates were grown on succinate. Mineralization of biphenyl was exponential during the phase of exponential growth of Moraxella sp. and Pseudomonas sp. In biphenyl-supplemented media, Flavobacterium sp. had one exponential phase of growth apparently at the expense of contaminating dissolved carbon in the solution and a second exponential phase during which it mineralized the hydrocarbon. Phase-contrast microscopy did not show significant numbers of cells of these three species on the surface of the solid substrate as it underwent decomposition. Pseudomonas sp. did not form products that affected the solubility of biphenyl, although its excretions did increase the dissolution rate. It was calculated that Pseudomonas sp. consumed 29 nmol of biphenyl per ml in the 1 h after the end of the exponential phase of growth, but 32 nmol of substrate per ml went into solution in that period when the growth rate had declined. In a medium with anthracene as the sole added carbon source, Flavobacterium sp. converted 90% of the substrate to water-soluble products, and a slow mineralization was detected when the cell numbers were not increasing. Flavobacterium sp. and Beijerinckia sp. initially grew exponentially and then arithmetically in media with phenanthrene as the sole carbon source. Calculations based on the growth rates of these bacteria and the rates of dissolution of phenanthrene suggest that the dissolution rate of the hydrocarbon may limit the rate of its biodegradation.     

Effect of Interfaces on Small, Starved Marine Bacteria

The copiotrophic marine Vibrio sp. strain DW1, shown previously in batch culture to increase in numbers at the onset of starvation and then to form viable small cells with low endogenous respiration, appears to have a survival advantage at interfaces. Vibrio sp. strain DW1 behaved differently at interfaces compared with the aqueous phase under starvation conditions: (i) small cells were observed at an air-water interface without nutrients, (ii) nutrients added to the air-water interface quickly produced larger cells at the surface, (iii) motility persisted many hours longer at the solid-water interface of a dialysis membrane in a microchamber at the onset of starvation, and (iv) regrowth and division at the solid-liquid interface occurred quickly and at nutrient concentrations too low to permit growth in the aqueous phase. It was concluded that, if small starved cells from copiotrophic bacteria can reach an interface, additional survival mechanisms become available to them: (i) interfaces constitute areas of favorable nutrient conditions, and (ii) interfaces lacking a sufficient amount of nutrient, nevertheless, trigger cells to become smaller, thus increasing their surface/volume ratio and the packing density.     

Role of dissolution rate and solubility in biodegradation of aromatic compounds

Strains of Moraxella sp., Pseudomonas sp., and Flavobacterium sp. able to grow on biphenyl were isolated from sewage. The bacteria produced 2.3 to 4.5 g of protein per mol of biphenyl carbon, and similar protein yields were obtained when the isolates were grown on succinate. Mineralization of biphenyl was exponential during the phase of exponential growth of Moraxella sp. and Pseudomonas sp. In biphenyl-supplemented media, Flavobacterium sp. had one exponential phase of growth apparently at the expense of contaminating dissolved carbon in the solution and a second exponential phase during which it mineralized the hydrocarbon. Phase-contrast microscopy did not show significant numbers of cells of these three species on the surface of the solid substrate as it underwent decomposition. Pseudomonas sp. did not form products that affected the solubility of biphenyl, although its excretions did increase the dissolution rate. It was calculated that Pseudomonas sp. consumed 29 nmol of biphenyl per ml in the 1 h after the end of the exponential phase of growth, but 32 nmol of substrate per ml went into solution in that period when the growth rate had declined. In a medium with anthracene as the sole added carbon source, Flavobacterium sp. converted 90% of the substrate to water-soluble products, and a slow mineralization was detected when the cell numbers were not increasing. Flavobacterium sp. and Beijerinckia sp. initially grew exponentially and then arithmetically in media with phenanthrene as the sole carbon source. Calculations based on the growth rates of these bacteria and the rates of dissolution of phenanthrene suggest that the dissolution rate of the hydrocarbon may limit the rate of its biodegradation.     

渗透剂对酿酒酵母生长的影响及其模型分析

考察了Saccharomyces cerevisiae FL1酵母菌株在固体平板上的生长动力学过程及2种渗透剂对不同生理阶段的酵母细胞增殖行为的影响．建立了一个数学模型,该模型可以预测固体培养过程中生物量随时间的变化情况,结果表明,模型预测值与实际值能够很好符合,将该模型应用于考察氯化钠和甘油对细胞增殖行为的影响,结果揭示,氯化钠显著抑制指数生长期和平衡期细胞分裂,降低酵母比生长速率和生物量;甘油对平衡期细胞增殖有促进作用,提高比生长速率和生物量;甘油与氯化钠之间存在协同作用,0．15M甘油不能减弱高盐的应激作用。     

Cyclic growth of lactobacilli in beer

J.L. FERNANDEZ AND W.J. SIMPSON 1994. Beer-spoilage lactic acid bacteria displayed unusual growth characteristics in beer. Cycles of growth and death occurred, as assessed by the ability of the organisms to form colonies on a range of solid growth media, or grow in liquid media, including beer and modified de Man, Rogosa and Sharpe medium. During the death phase, the viable cell count fell by more than 99.9%. The cells were dead rather than nonculturable. Staining with acridine orange showed that they remained physically intact during the death phase. It seems that cycles of 'cryptic growth' occur in beer. Cells isolated from different stages of the growth cycle produced similar growth curves when re-inoculated into beer, showing that selection of adapted cells does not occur.     

Recovery from nutrient starvation by a marine Vibrio sp.

A marine psychrophilic Vibrio sp., Ant-300, recovered from starvation after the addition of 1 volume of complete nutrient medium to 9 volumes of starvation menstruum. Turbidity (measured by optical density), viable cell counts, cell size (measured from electron micrographs), and cellular concentrations of protein, DNA, and RNA were monitored with recovery time. The usual growth curve of bacterial cultures was observed. On a per viable cell basis, protein, DNA, and RNA increased to maximum values just before cell division and then returned to close to the initial starved-cell value during the stationary phase. Cells under complete starvation conditions or missing only one nutrient in the stationary phase responded with cell division resulting in many smaller cells. The length of the lag phase during recovery was directly proportional to the length of the prior starvation period, even when identical numbers of cells were used for recovery. Cells appeared to pass more deeply into dormancy with starvation time.     

Recovery from nutrient starvation by a marine Vibrio sp

A marine psychrophilic Vibrio sp., Ant-300, recovered from starvation after the addition of 1 volume of complete nutrient medium to 9 volumes of starvation menstruum. Turbidity (measured by optical density), viable cell counts, cell size (measured from electron micrographs), and cellular concentrations of protein, DNA, and RNA were monitored with recovery time. The usual growth curve of bacterial cultures was observed. On a per viable cell basis, protein, DNA, and RNA increased to maximum values just before cell division and then returned to close to the initial starved-cell value during the stationary phase. Cells under complete starvation conditions or missing only one nutrient in the stationary phase responded with cell division resulting in many smaller cells. The length of the lag phase during recovery was directly proportional to the length of the prior starvation period, even when identical numbers of cells were used for recovery. Cells appeared to pass more deeply into dormancy with starvation time.