噬藻体PP对野生宿主——丝状蓝藻的吸附率、裂解周期及释放量的影响

研究在日光光照条件下,以自然水体中存在的丝状蓝藻作为噬藻体PP的野生宿主,用离心法测定了噬藻体PP对野生宿主藻的吸附率,用一步生长曲线法获得了噬藻体PP对野生宿主藻的裂解周期及释放量。结果表明:噬藻体PP对野生宿主藻在60min时能够达到的吸附率为1.79‰,吸附系数为8.09%,噬藻体PP感染野生宿主藻的潜伏期介于45～75min之间,平均释放量为34.32PFU·Cell-1。上述结果一方面说明,噬藻体PP感染野生宿主藻的吸附系数、潜伏期及释放量均远小于以实验室培养的鲍氏织线藻作为宿主所得到的数据;另一方面也说明,噬藻体PP具有较强的吸附和裂解野生宿主的能力,这将有助于解释噬藻体PP在淡水富营养化水体中具有广泛分布的现象。     

营养条件对噬藻体PP感染席藻动力学的影响

本试验设计了从正常的AA培养基(CK组)到N和P含量只有正常AA培养基1/600的6种培养基.在25 ℃、2000 lx条件下将宿主席藻在6种培养基中培养8个月后,用显微直接计数法测定了席藻的生长曲线以及噬藻体PP感染宿主席藻的裂解周期与致死率,用离心法测定了噬藻体PP对宿主席藻的吸附率,用一步生长曲线法测定了噬藻体PP的释放量和裂解周期.结果表明: 提高N和P含量会促进宿主席藻的生长,统计分析也显示,在对数中期(第6天),高营养盐浓度中细胞密度显著高于低营养盐浓度中的密度;提高营养盐浓度噬藻体PP的吸附率会显著增高,主要表现为在AA中噬藻体PP的吸附率极显著高于其他组;同时6种培养基条件下噬藻体PP对席藻的致死率变化不大;随着营养水平的升高,噬藻体PP的潜伏期和裂解周期明显缩短,平均释放量显著增加,但裂解宿主的效率却没有显著变化.上述结果说明噬藻体PP对宿主藻的感染力会随着营养水平的提高而明显增强,并可能在水体富营养化进程中发挥着调控藻类种群更替的作用.     

气候变化对海藻龙须菜生长与光合作用耐热特性的影响

为探讨大气CO2升高和温室效应对龙须菜生长及生理生化特性的影响,在4种条件下培养龙须菜:1)对照组(390μL/L CO2+20℃),2)CO2升高组(700μL/L CO2+20℃),3)温度升高组(390μL/L CO2+24℃),4)温室效应组(700μL/L CO2+24℃),测定藻体生长和生化组分以及高温胁迫下的最大光化学量子产量(Fv/Fm)和光能利用效率(α)、光合速率(Pn)和呼吸速率(Rd)。结果表明,CO2升高、温度升高以及温室效应均促进龙须菜的生长,温室效应下的促进作用更明显。温室效应使龙须菜具较高的Pn和Rd以及较低的可溶性蛋白(SP)和可溶性碳水化合物(SC)含量。高浓度CO2对叶绿素(Chl a)和类胡萝卜素(Car)含量没有显著影响,而高温使其上升;藻红蛋白(PE)和藻蓝蛋白(PC)含量不受CO2浓度和温度的影响。龙须菜Fv/Fm、α、Pn和Rd值,在32℃处理3 h后略有上升,在36℃处理3 h后下降,而在40℃处理20 min后降到极低水平。正常温度(20℃)生长的龙须菜最高耐受温度在32—36℃之间,而较高温(24℃)生长的龙须菜在36—40℃之间;生长温度对光合作用和呼吸作用耐热性能的影响比CO2浓度的影响更大;而温室效应生长条件下的龙须菜光合作用表现出更突出的耐热性能。     

水华蓝藻噬藻体对不同条件培养的宿主细胞感染性分析

在从武汉东湖水样中培养分离水华蓝藻噬藻体(Planktothrix agardhii Virus from Lake Donghu,PaV-LD)的基础上,对在不同条件培养的宿主蓝藻细胞中,PaV-LD增殖效率及裂解作用进行了测定分析。分别将PaV-LD接种到生长期、半连续培养更新率或光照不同的宿主蓝藻液中,并采用稀释培养计数(Mostprobable number,MPN)方法与电镜观察,测定子代PaV-LD释放量及宿主细胞的裂解作用。结果显示:对数生长期宿主蓝藻单个细胞中子代PaV-LD的平均释放量为350感染单位(Infectious Units,IU/cell),显著高于稳定生长期的平均释放量110 IU/cell。在用新鲜培养基更新率为0%、35%、50%和65%的半连续培养宿主蓝藻中,接种PaV-LD 5d之后,噬藻体的释放量分别约为50 IU/cell、70 IU/cell、220 IU/cell或310 IU/cell,表明子代PaV-LD释放率随培养基更新率的增加而显著提高。在光照条件下感染3—4d后,宿主蓝藻细胞充分裂解,并释放大量子代PaV-LD,滴度可由初始7.00×103IU/mL快速增加到8.56×107IU/mL;但在遮光条件下,同样感染的蓝藻细胞未见裂解,也检测不到释放的子代噬藻体。电镜观察显示,在光照条件下感染的蓝藻细胞类囊体膜结构消失,而大量子代PaV-LD颗粒主要分布在原有类囊体的部位。显然,宿主蓝藻细胞的培养条件和状态可能对获得噬藻体纯培养有决定性影响。     

温度与CO2浓度升高对集胞藻PCC 6803修复UV损伤的关键基因转录量的影响

通过Taqman探针绝对定量法研究了集胞藻PCC 6803在5种不同的环境条件下:(1)25℃+400μmol/mol CO₂,(2)29℃+400μmol/mol CO₂,(3)25℃+800μmol/mol CO₂,(4)29℃+800μmol/mol CO₂,(5)25℃+1200μmol/mol CO₂,其phrA/psbA1/psbA2/psbA3等UV修复基因和16S rRNA基因的转录本拷贝数的变化情况。结果表明:温度与CO₂浓度的升高可以导致集胞藻PCC 6803的psbA2/psbA3基因和16S rRNA转录本拷贝数的大幅减少,说明温室效应将有可能导致蓝藻的UV损伤修复能力与核糖体合成能力的下降;温度升高和CO₂浓度升高对psbA2/psbA3基因和16S rRNA转录本拷贝数的联合作用表现为互相抵消,说明温度升高与CO₂浓度升高的联合作用的机制较复杂,值得深入研究。     

感染丝状蓝藻的噬藻体的裂解周期和释放量的测定

近年来,随着浮游病毒的认识的深入,人们认识到浮游病毒对水体中初级生产力的影响是巨大的[1],其主要证据就是发现噬藻体在海洋蓝藻的种群控制上发挥着重要作用[2]. 噬藻体的释放量和裂解周期是衡量噬藻体感染力的重要指标,很多重要的生态指标如病毒在生态系统中对宿主的致死率、病毒种群得以维持的阈浓度等都需要使用病毒的释放量和裂解周期来加以推算[3,4], 因此准确地测定这两个基本参数是十分重要的.在自然界,很多丝状蓝藻,如颤藻、鱼腥藻、螺旋藻、席藻等是能够形成水华的,其中有些还具有产毒的功能[5].丝状蓝藻的形态特征有别于单细胞蓝藻, 在被噬藻体感染时,丝状蓝藻的感染周期和光合生理也与单细胞蓝藻有较大的差异[6],因此研究裂解丝状蓝藻的噬藻体的方法可能不同于感染单细胞的噬藻体.本次试验以一种感染丝状宿主的噬藻体为材料,探讨了确定其裂解周期和释放量的研究方法.     

不同光、温条件下野生宿主对噬藻体PP的光修复率

研究了1株野生宿主藻对UV-B损伤的噬藻体PP的光修复率,结果显示该野生宿主的光修复率显著高于实验室培养的坑形席藻(Phormidium foveolarumIU427)和鲍氏织线藻(Plectonema boryanum IU594)。不同理化条件(光质、光强、水温)下该野生宿主对经UV-B损伤的噬藻体PP光修复情况,结果表明:野生宿主的光修复率与UV-A强度、可见光强度、水温之间均呈显著正相关(P0.05);可见光所驱动的光修复能力明显高于UV-A所驱动的光修复,且修复率会在可见光强达到160μE.m-.2s-1时接近饱和。说明,自然条件下浅水湖泊中可见光介导的宿主光修复作用占主导地位,由于受水温和透明度的双重影响,野生宿主在秋季的修复能力最强,而在冬季的修复能力最弱。     

感染丝状蓝藻的噬藻体的裂解周期和释放量的测定

近年来 ,随着浮游病毒的认识的深入 ,人们认识到浮游病毒对水体中初级生产力的影响是巨大的[1] ,其主要证据就是发现噬藻体在海洋蓝藻的种群控制上发挥着重要作用[2 ] 。噬藻体的释放量和裂解周期是衡量噬藻体感染力的重要指标 ,很多重要的生态指标如病毒在生态系统中对宿主的致死率、病毒种群得以维持的阈浓度等都需要使用病毒的释放量和裂解周期来加以推算[3,4 ] ,因此准确地测定这两个基本参数是十分重要的。在自然界 ,很多丝状蓝藻 ,如颤藻、鱼腥藻、螺旋藻、席藻等是能够形成水华的 ,其中有些还具有产毒的功能[5] 。丝状蓝藻的形态特征…     

模拟生态系统中噬藻体裂解蓝藻宿主的生态学效应

实验采用模拟生态系统,研究了噬藻体裂解蓝藻宿主后营养物质循环变化的过程,以及细菌和漂浮植物对这个过程的影响。结果表明噬藻体裂解宿主所释放的营养元素在细菌的作用下迅速进入新的循环并形成新的水华,而加入浮萍则可以有效吸收水体营养,防止新的水华发生。因此推测单纯地利用包括噬藻体在内的微生物裂解藻类的方法,并非治理水华的有效方法,但如果能够结合漂浮植物等其它治理手段,则有可能同时实现水华的控制和水质的改善。     

噬藻体感染相关基因的研究进展

噬藻体是感染蓝细菌(蓝藻)的病毒,能调控蓝细菌种群的丰度和多样性,在许多水生生态系统的食物网动态变化和生物地球化学循环中起关键作用。噬藻体与宿主细胞发生各种相互作用,包括吸附、入侵和复制,参与感染过程,从而完成噬藻体的生命周期。本文在综述噬藻体生命周期与基因组结构相互关联的基础上,重点介绍噬藻体与宿主蓝细菌相互作用的蛋白,如噬藻体吸附蛋白、内肽酶、穿孔素、DNA聚合酶、藻胆体降解蛋白A(NblA)、毒力因子、抗CRISPR蛋白(Acr)和小分子热休克蛋白等,分析它们的分子特性,阐述它们在噬藻体感染蓝细菌以及噬藻体-蓝细菌相互作用的分子机制。为了更好地认识驱动不同噬藻体与宿主及水生环境相互作用的策略、感染效率及生态学影响,本文不仅对这些与噬藻体感染相关的重要基因研究动态进行综述与讨论,还在了解噬藻体丰富的多样性和复杂性的基础上,提出应用新技术对噬藻体感染相关基因的功能进行广泛研究,以期扩展全球水生病毒数据库,进一步认识噬藻体与宿主的相互作用机理。     

Gelatin degradation at elevated temperature

Four gelatin types (A, B, C and AB), two different samples of each, were subjected to temperature treatments with the incubation temperature, incubation time, gelatin concentration and solvent (type and concentration of salt ions and pH) as variables. Degradation was studied by means of fast protein liquid chromatography and sodium dodecylsulphate polyacrylamide gel electrophoresis. All the variables tested seemed to be critical.

Addition of a protease inhibitor cocktail confirmed that the observed degradation was not due to the action of proteases.

Fluorescence measurements indicated that during the temperature treatment pentosidine and pyridinoline cross-links can be broken, while the cleavage of peptide bonds was verified by ninhydrin tests and N-terminal amino-acid analyses with phenyl isothiocyanate.     

Fatigue microcracks that initiate fracture are located near elevated intracortical porosity but not elevated mineralization

In vivo microcracks in cortical bone are typically observed within more highly mineralized interstitial tissue, but postmortem investigations are inherently limited to cracks that did not lead to fracture which may be misleading with respect to understanding fracture mechanisms. We hypothesized that the one fatigue microcrack which initiates fracture is located spatially adjacent to elevated intracortical porosity but not elevated mineralization. Therefore, the spatial correlation between intracortical porosity, elevated mineralization, and fatigue microdamage was investigated by combining, for the first time, sequential, nondestructive, three-dimensional micro-computed tomography (micro-CT) measurements of each in cortical bone specimens subjected to compressive fatigue loading followed by a tensile overload to fracture. Fatigue loading resulted in significant microdamage accumulation and compromised mechanical properties upon tensile overload compared to control specimens. The microdamage that initiated fracture upon tensile overload was able to be identified in all fatigue-loaded specimens using contrast-enhanced micro-CT and registered images. Two-point (or pair) correlation functions revealed a spatial correlation between microdamage at the fracture initiation site and intracortical porosity, but not highly mineralized tissue, confirming the hypothesis. This difference was unique to the fracture initiation site. Intracortical porosity and highly mineralized tissue exhibited a significantly lower and higher probability, respectively, of being located spatially adjacent to all sites of microdamage compared to the fracture initiation site. Therefore, the results of this study suggest that human cortical bone is tolerant of most microcracks, which are generally compartmentalized within the more highly mineralized interstitial tissue, but a single microcrack of sufficient size located in spatial proximity to intracortical porosity can compromise fracture resistance.     

Reversible inhibition of EcoRI with elevated pressure

The endonuclease activity of EcoRI is completely inhibited at 200 MPa, 37 degrees C using the plasmid pBR 322 as a substrate. When assayed at 133 MPa approximately half the activity at atmospheric pressure was observed; from these data the standard molar volume change is estimated to be -80 cm3mol-1. Upon return to atmospheric pressure the enzyme reacted in a standard manner with its restriction site in pBR 322. Pressurization did not decrease the specificity of the endonuclease activity of the enzyme for its canonical site. These results are discussed in terms of the role of ionic interactions in protein-DNA interactions.     

Prevention of elevated cholesterolemia in monkeys.

Alfalfa root saponins prevented the expected increase in plasma cholesterol associated with the Ingestion of a semipurified high-butter, high-cholesterol diet in monkeys. Experiments in rats indicate that alfalfa root saponins decrease cholesterol intestinal absorption.     

Sensitivity of Norway spruce physiology and terpenoid emission dynamics to elevated ozone and elevated temperature under open-field exposure

Volatile organic compounds (VOCs) emitted from vegetation to the atmosphere contribute to global climate change, but climate change factors also affect VOC emission from vegetation. Soil-grown Norway spruce seedlings were exposed to elevated ozone (1.4 × ambient ozone concentration) and elevated temperature (ambient + 1.3 °C) alone and in combination as well as to ambient ozone and temperature treatments under open-field conditions. VOC emissions (mainly terpenoids), genes involved in early steps of plastidial monoterpene and isoprene synthesis, photosynthetic parameters and growth were measured. In July, when daytime elevated ozone concentrations had been over 40 ppb, ozone doubled the total terpenoid emissions by increasing the emissions of many monoterpenes and sesquiterpenes. Elevated temperature changed the terpenoid profile by increasing the emissions of oxygenated monoterpenes, but did not influence total emissions. Terpenoid emission profiles also differed between elevated ozone alone and elevated ozone in combination with elevated temperature. In August, when daytime elevated ozone concentrations had been ca. 30 ppb, significant treatment effects were not found. Ozone and temperature reduced the expression of DXS2B (1-deoxy-d-xylulose 5-phosphate synthase type II), and ozone that of DXR (1-deoxy-d-xylulose 5-phosphate reductoisomerase) in August. Elevated temperature reduced the stem diameter growth, net photosynthesis and stomatal conductance, but elevated ozone did not have effects on these parameters. Results suggest that elevated temperature may not modify the ozone responses, or vice versa, in terms of gas exchange, growth or total terpenoid emission rates of young Norway spruces in a near-future climate. However, observed changes in terpenoid emission profiles may be important in the future climate, as reactivity in the troposphere differs between individual terpenoids.     

Rice production in a changing climate: a meta-analysis of responses to elevated carbon dioxide and elevated ozone concentration

Rice is arguably the most important food source on the planet and is consumed by over half of the world's population. Considerable increases in yield are required over this century to continue feeding the world's growing population. This meta-analysis synthesizes the research to date on rice responses to two elements of global change, rising atmospheric carbon dioxide concentration ([CO₂]) and rising tropospheric ozone concentration ([O₃]). On an average, elevated [CO₂] (627 ppm) increased rice yields by 23%. Modest increases in grain mass and larger increases in panicle and grain number contributed to this response. The response of rice to elevated [CO₂] varied with fumigation technique. The more closely the fumigation conditions mimicked field conditions, the smaller was the stimulation of yield by elevated [CO₂]. Free air concentration enrichment (FACE) experiments showed only a 12% increase in rice yield. The rise in atmospheric [CO₂] will be accompanied by increases in tropospheric O₃ and temperature. When compared with rice grown in charcoal-filtered air, rice exposed to 62 ppb O₃ showed a 14% decrease in yield. Many determinants of yield, including photosynthesis, biomass, leaf area index, grain number and grain mass, were reduced by elevated [O₃]. While there have been too few studies of the interaction of CO₂ and O₃ for meta-analysis, the interaction of temperature and CO₂ has been studied more widely. Elevated temperature treatments negated any enhancement in rice yield at elevated [CO₂], which suggests that identifying high temperature tolerant germplasm will be key to realizing yield benefits in the future.