中水技术污水处理工艺去除病毒的效果

中水技术开发既可缓解水资源的紧缺,又能改善城市环境。本文报道用石英粉吸附/洗脱和浓缩棒脱水的二步浓集水病毒技术(回收率为25.4～37.3％),研究中水技术不同处理工艺去除病毒的效果。结果,二级处理可去除掺入病毒的98.9％,结合三级处理的混凝沉淀和过滤,可去除99.976％,再加活性炭吸附或加氯消毒,所得中水分别去除掺入病毒的99.986％和99.991％。经首都机场中水道试验厂水样检测表明,中水中未检测到病毒(<0.23PFU/L)。     

环境介质中病毒生态的研究

病毒是许多人及重要经济动、植物病患的病原。一些病毒在环境中可因条件不同而生存数小时到数月, 并在水、气、士中迁移达若干公里。现有的污水处理方法对病毒, 特别是肠道病毒效果欠佳, 土地处置原污泥以及污水灌溉的水果和蔬菜能传播人肠道病毒。即使小至一个组织培养的感染剂量(病毒)也可引起人的疾病, 因此对环境介质中, 特别是饮水和食物中的少量病毒的去除也是重要的。现有的指示物不能确切地指示粪便污染, 更不能充分反映人肠道病毒的污染。大肠菌噬菌体在地表水、地下水和污水中比人肠道病毒更呈持久性, 还有许多适于选择分析技术特有性能, 因此很可能在一定条件下用它作人肠道病毒的指示物。作者对我国今后需要开展的研究提出了建议。     

超滤过结合密度梯度离心纯化鲍曼不动杆菌噬菌体方法的建立

目的 探讨获得低浓度内毒素和高滴度鲍曼不动杆菌噬菌体的方法,为制备安全的噬菌体生物制剂提供参考.方法 用可截留100 kD以上分子量的超滤离心管浓缩噬菌体裂解液并滤出分子量约为10 kD的内毒素,然后用蔗糖密度梯度离心纯化噬菌体浓缩液;分别测定超滤前、超滤后和纯化后的噬菌体滴度,采用鲎试验测定超滤前后内毒素的浓度,通过SDS-PAGE分析超滤前后和纯化后噬菌体蛋白的纯度.结果 经超滤离心法噬菌体滴度从3.9×1010 PFU/mL提高至1.68×1012PFU/mL,并可去除99.2％的内毒素;超滤过结合密度梯度离心后的SDS-PAGE可清晰呈现7种蛋白,分子量为29～100 kD.结论 超滤过结合密度梯度离心是一种简便、快速浓缩和纯化噬菌体的方法,并可有效地去除裂解液中的内毒素.     

噬菌体对黏质沙雷菌感染 BA LB／c小鼠的保护作用

本文旨在观察噬菌体对黏质沙雷菌感染小鼠的治疗作用,为噬菌体疗法应用于细菌性感染提供依据。以黏质沙雷菌为宿主菌,采用双层琼脂噬斑法从污水中分离和纯化裂解性噬菌体。将最小致死量的黏质沙雷菌经腹腔感染BALB／c小鼠后,立即腹腔注射不同剂量的噬菌体,观察动物的生存率并确定噬菌体的保护剂量。在动物感染后的不同时间（0、20、40、60和180 min ）观察噬菌体疗法对动物存活率的影响。将噬菌体和细菌同时或分别注射动物后,分析噬菌体在动物体内的药代动力学。结果显示,经噬斑法从污水中分离出1株裂解性噬菌体（命名为φSM9‐3Y ）,电镜观察发现该噬菌体属有尾噬菌体目肌尾噬菌体科。动物腹腔感染黏质沙雷菌并立即给予噬菌体后发现,当噬菌体的保护剂量为108 PFU／ml时,动物的存活率为100％。动物感染后40和60 min给予噬菌体（1010 PFU／ml）治疗,动物的存活率为60％。药代动力学表明,将噬菌体和细菌同时注入动物体内,在6 h内噬菌体的滴度维持在1010 PFU／ml。结果提示,噬菌体对黏质沙雷菌所致动物腹腔内感染的治疗是有效的,提示针对细菌性感染的噬菌体疗法具有潜在的应用价值。     

路德维希肠杆菌噬菌体的分离及生物学特性

【背景】噬菌体能够特异性杀死宿主细菌,特别是耐药性细菌,可以作为新型杀菌剂,而关于路德维希肠杆菌噬菌体的研究尚属空白。【目的】分离路德维希肠杆菌噬菌体,并对其生物学特性进行研究。【方法】通过双层平板法分离、纯化、鉴定噬菌体;通过SDS-PAGE电泳分析结构蛋白;通过透射电子显微镜分析噬菌体的形态;通过结晶紫染色法和刚果红平板法分析生物被膜。【结果】以路德维希肠杆菌X20为指示菌从环境样品中分离获得了噬菌体GM20,噬菌斑透明且有较小晕环,直径大小平均为0.47 mm。透射电镜观察显示,噬菌体GM20具有可伸缩尾部,属于肌尾噬菌体科(Myoviridae)。GM20的滴度为7.65×10~9PFU/mL,为烈性噬菌体。一步生长曲线结果显示,噬菌体的潜伏期约为15 min,释放量约为164.3 PFU/infection center。进一步分析显示,GM20具有较好的抑菌效果,耐噬菌体菌株突变株平均突变率为1.06×10~(-5)。【结论】烈性噬菌体GM20能够杀死路德维希肠杆菌X20,有可能应用于路德维希肠杆菌感染的预防与控制。     

武汉东湖针簇多肢轮虫的种群变动和生产量

针簇多肢轮虫(Polyarthra trigla)是武汉东湖的优势轮虫,1983,5—1984,4在Ⅰ,Ⅱ站分别测定了这种轮虫卵和种群密度。Ⅰ站卵的密度在0—245个/升之间,平均为27个/升,种群密度为0—6600个/升,平均为362个/升;Ⅱ站卵的密度为0—321个/升,平均为22个/升,种群密度为0—2770个/升,平均为159个/升。在5—30℃的培养温度下,卵的发育时间随温度升高而缩短,它们间的关系可用下列回归方程表示: lnD=0.4627 1.2929lnT-0.4995(lnT)~2 用直接称重法测定该种轮虫平均干重为0.07微克。计算了针簇多肢轮虫的瞬时出生率,增长率和死亡率。用二种不同的方法测定了这种轮虫的生产量。Ⅰ站的平均日生产量,用世代时间法测得10.19微克/升,用卵比率法测得5.98微克;Ⅱ站分别为3.59和3.01微克/升。     

毛蚶中肠道病毒检测方法的建立

本文建立了检测毛蚶中肠道病毒的方法。病毒在pH4.5时吸附于毛蚶组织,离心后用pH9.5甘氨酸盐水将病毒从毛蚶组织中洗脱出来,并用0.0005mol/L三氯化铝代替Johnson法中的Cat—Floc,达到去除细胞毒性物质的目的。经过再一次离心,利用牛肉浸膏在pH3.5—4.0时凝聚并吸附病毒的特性使洗脱液中的病毒得到浓缩。离心后沉淀溶解于0.1mol/L磷酸氢二钠溶液。用本法提取毛蚶中脊髓灰质炎病毒,当病毒含量为每克组织3.5×10~5至35PFU时,平均回收率为71.2％。     

肠出血性大肠埃希菌O157:H7噬菌体FEC14和FEC19特性及污染牛肉杀菌潜在应用探究

【背景】肠出血性大肠埃希菌O157:H7是重要的食源性致病菌之一,并且其耐药性越来越严重,寻找裂解性强噬菌体用于防治大肠埃希菌感染具有广阔的应用前景。【目的】从环境中分离鉴定能特异裂解大肠埃希菌O157:H7的噬菌体,通过对生物学特性及裂解细菌功效的探究,为其在食品安全防控中提供理论依据和研究基础。【方法】通过双层平板法分离并纯化噬菌体,透射电镜观察噬菌体形态,测定最佳感染复数、一步生长曲线、pH稳定性、温度稳定性,对噬菌体进行全基因组测序及噬菌体裂解细菌功效。【结果】2株大肠埃希菌O157:H7噬菌体FEC14和FEC19的头部皆呈二十面体立体对称,FEC14头部直径约80nm,尾丝呈星形,FEC19头部直径约58 nm,尾丝呈针形;噬菌体FEC14的最佳感染复数为0.001,潜伏期为15 min,裂解期为65 min,平均暴发量为156 PFU/cell,FEC19的最佳感染复数为0.1,潜伏期为10 min,裂解期为80 min,平均暴发量为800 PFU/cell;噬菌体FEC14能在60℃、pH 4.0-11.0条件下存活,噬菌体FEC19在70℃、pH5.0-9.0条件下存...     

噬菌体作为指示病毒的应用研究进展北大核心

噬菌体是一类专性侵染细菌的病毒,在形态大小、结构组成等生物特性上与高等生物病毒具有相似性,同时噬菌体实验室操作技术简单,安全性高,在培养、计数、稳定性和灵敏度等方面具有非常大的优势。因此,将噬菌体作为指示生物模拟或替代高等生物病毒的研究和应用已开始受到国内外研究人员的关注,并取得一定进展。本文论述了噬菌体作为指示病毒的优势,并对噬菌体在病毒过滤去除效果评价、消毒效果评价、病毒传播规律研究、环境及水质监测等领域的研究和应用进行了总结分析,综述了噬菌体在各领域应用的可行性证据、应用案例及难点问题,并结合噬菌体作为指示病毒的不足之处,对进一步以噬菌体作为指示病毒的研究和应用提出建议和展望。     

高碑店污水系统病毒污染情况的检测

本文报道用石英粉吸附——洗脱法浓集污水病毒,其回收率为51～90％。对1985年3～7月采集的不同水样进行病毒分离和蚀斑滴定,结果表明,高碑店污水系统中的病毒大部分为肠道病毒。春季以脊髓灰质炎病毒为主,夏季以柯赛奇B3及非肠道病毒为主。不同类型污水中的病毒浓度依次为:原污水58PFU/1;二级污水<19,约为9PFU/1;医用污水<16,约为1PFU/1,地下水<1.7PFU/1,未检出病毒。夏季水样内病毒浓度较春季低。     

Water Absorbency and Water Retention of the Natural Seed Coat of Seriphidium transiliense

The natural seed coat of Seriphidium transiliense Poljak could indirectly absorb water to almost saturation in 1 to 3 h at different temperatures and different relative humidities (RH). At lower humidifies, temperature almost did not affect the water absorbing rate, but at higher humidities, water absorbency escalated with temperature rise. In drought condition with a RH of 21%, it could still retain 10% of water. The direct water absorbing rate of the natural seed was about 1 500%, while that of the seed without film was only 170%. The natural seed coat made up 11% of the total seed weight. The direct absorbing rate was 12 400%. The water absorbency belonged to monomolecular layer absorption at RH < 70%. The ability of water absorbency was stronger at RH > 70%, and the water absorbency belonged to multimolecular layer absorption. There was a linear correlation between the reciprocal of the water absorbing rate and that of the water absorbing time. According to the classifying analysis and the determination of the seed coat substances using IR, it was initially maintained that the main composition of the seed coat of Seriphidium transiliense Poljak was neither protein, pectine, cellulose, nor starch, but some other polysaccharide composed of aldoses. It also contained a kind of acid-base indicating substance.     

Water and the cytoskeleton.

The diffusion of intracellular fluid and solutes is mainly limited by the density and the geometry of crossbridges between cytoskeletal polymers mediating the formation of an integrated cytoplasmic scaffold. Evidence for specific relationships between water and cytoskeletal polymers arises from the effect of heavy water on their polymerization process in vitro and on the cytoskeleton of living cells. The hydration of cytoskeletal subunits is modified through polymerization, a mechanism which may be involved in the direct contribution of the cytoskeleton to the osmotic properties of cells together with changes of hydration of polymers within networks. The dynamic properties of the hydration layer of cytoskeletal polymers may reflect the repetitive distribution of the surface charges of subunits within the polymer lattice, thus inducing a local and long range ordering of the diffusion flows of water and solutes inside polymer networks. The interactions between subunits in protofilaments and between protofilaments determine the specific viscoelastic properties of each type of polymer, regulated by associated proteins, and the mechanical properties of the cell through the formation of bundles and gels. Individual polymers are interconnected into dynamic networks through crossbridging by structural associated proteins and molecular motors, the activity of which involves cooperative interactions with the polymer lattice and likely the occurence of coordinated modifications of the hydration layer of the polymer surface. The cytoskeletal polymers are polyelectrolytes which constitute a large intracellular surface of condensed anionic charges and form a buffering structure for the sequestration of cations involved in the regulation of intracellular events. This property allows also the association of cytoplasmic enzymes and multimolecular complexes with the cytoskeleton, facilitating metabolic channelling and the localization of these complexes in specific subdomains of the cytoplasm. The consequences of interactions between membranes and the cytoskeleton in all cellular compartments range from the local immobilization and clustering of lipids and membrane proteins to the regulation of water and ion flows by the association of cytoskeletal subunits or polymers with transmembrane channels. The possibility that the polyelectrolyte properties of the cytoskeletal polymers contribute to the modulation of membrane potentials supports the hypothesis of a direct involvement of the cytoskeleton in intercellular communications.     

Distribution and Interannual Changes of the Zooplankton of the Durgun Water Basin and Adjoining Water Objects (the Western Mongolia)

The article describes quantitative and structural characteristics of zooplankton of polytypic sites of a water system including a lake, canal, and a water reservoir. It is shown that in the littoral zone of lakes and water reservoirs, the number of species and communities is higher, and biomass, lower. However, in the littoral zone of shallow lake zooplankton in number, took priority due to Rotifera, in the deep part of the water body – Rotifera and Cladocera; in the center of the lake zooplankton dominated by biomass due to Cladocera and Copepoda, in the water reservoir—due to the Copepoda. The dam area of the water reservoir had the highest species richness of zooplankton among all studied sites. The greatest number and biomass of zooplankton within a waterbody are noted in upper part, where a sedimentation zone had formed, and as a whole for the system of the investigated waterbodies, the maximum quantity indices are typical of lake communities. It is revealed that the starkest interannual changes in zooplankton were observed in the shallow lake: the number of species decreased—in the littoral zone at the expense of Rotifera, and in the center, the biomass increased at the expense of Cladocera; in deep-water area of the dam area of the reservoir, conversely, the number of species, as well as the number and biomass of the community, increased due to Copepoda.     

Effects of Water Stress and Hardening on the Internal Water Relations and Osmotic Constituents of Cotton Leaves

Experiments were designed to test the hypothesis that the internal water relations of leaves are altered when cotton plants (Gossypium hirsutum L.‘Acala SJ-2′) are conditioned by several cycles of water stress. Preliminary experiments suggested that plants so conditioned are less sensitive to water deficits and that the change might be partly explained by an accumulation of solutes or by structural alterations attendant on development under conditions of water stress. Leaves of preconditioned plants maintained turgor to lower values of water potential than did leaves of well-watered plants. Accompanying this change was a lower osmotic potential at any given leaf water content in preconditioned plants. Tissue analysis of several osmotically active solutes indicated that soluble sugars and malate accumulate to about the same levels (dry-weight basis) in both conditioned and unconditioned plants exposed to stress. These accumulations could not account for the turgor change. Analysis of the data on relative water content indicated that the leaves of conditioned plants had less water per unit dry weight than did leaves of controls. This change accounts for a substantial fraction of the difference between the osmotic potential of conditioned and control plants. The results of a simple model suggest that structural changes may play a significant role in explaining differences in the responses of conditioned and control plants to water stress.