食品工业废渣以发酵技术生产菌体蛋白饲料的研究

为了将食品工业废渣中可被微生物利用的营养物质构成蛋白质的微生物菌体,采用以固态发酵法生产蛋白饲料。试验结果表明,通过组合菌株,在2t规模的发酵池里进行连续培养,较佳的控制工艺条件是：培养温度30℃,培养基初始水份65％,培养时间80h,产品的菌体蛋白达到了30％以上,粗纤维含量下降60％以下,废渣中灰分降低了30％以上,钙和磷分别提高了70％和205倍,并含有丰富的纤维素酶,提高了食品工业废渣的利用价值。     

Human-derived cell lines to study xenobiotic metabolism

In vitro systems make for rapid identification of xenobiotic effects and can be used to study cellular and subcellular toxicity mechanisms. In this report the metabolic competence of two human-derived cell lines, a hepatic (Hep G2) and a pulmonary one (A549) was tested. In the two cell systems the capability to activate Benzo[a]Pyrene through the cytochrome P450 enzyme system and to form reactive metabolites was analysed. ³H-BaP and the scintillation counting analysis were used to show the differences of the metabolic activity in Hep G2 and A549. A similar time course of ³H-BaP uptake was observed in the cell systems. Nevertheless, in the two cell lines the distribution of radioactive metabolites seemed to reflect a specific tissue response to toxicity.     

全氟辛酸对斜生栅藻细胞膜特性影响研究(Effect of Perfluorooctane Acid on Cell Membrane Properties of Scenedesmus obliquus)

斜生栅藻暴露于全氟辛酸(PFOA)中,其细胞膜特性可通过不同荧光染料染色的荧光信号变化来反映.应用流式细胞仪检测荧光信号,研究了PFOA对斜生栅藻细胞膜的完整性、选择透过性和膜电位指标的影响效应.实验结果显示,全氟辛酸对表征细胞膜完整性的碘化丙啶(PI)染料荧光强度起到显著刺激作用,栅藻细胞膜受损几率随暴露浓度升高呈现上升趋势;低暴露浓度下栅藻细胞膜选择透过性增强,但在高浓度暴露下这一细胞膜特性受到明显抑制,具体表现为表征酯酶活性的二乙酸荧光素(FDA)荧光强度出现先升后降的变化;与FDA荧光强度变化趋势相反,反映膜电位的碘代3,3’-二己氧基羰花青(DIOC6(3))荧光强度则先降后升,预示高浓度PFOA暴露将导致细胞膜处于异常的生理状态.     

微囊藻毒素-LR通过线粒体途径诱导人支气管上皮细胞凋亡

探讨线粒体Caspase依赖性途径是否参与微囊藻毒素-LR(microcystin-LR,MC-LR)诱导人支气管上皮细胞(human bronchial epithelial cells,16HBE)凋亡过程。将处于对数生长期的16HBE分别暴露于终浓度为0(对照组)、2.5、5、10μg·m L-1的微囊藻毒素-LR和10μg·m L-1MC-LR+50μmol·L-1Caspase广谱抑制剂Z-VAD-FMK,持续24 h和48 h。检测细胞凋亡率,线粒体跨膜电位(ΔΨm),Caspase-3和Caspase-9相对表达量。结果显示,与对照组相比,各浓度染毒组细胞凋亡率和Caspase-3、Caspase-9相对表达量均升高,10μg·m L-1MC-LR染毒组线粒体膜电位降低;与10μg·m L-1MC-LR组相比,10μg·m L-1MCLR+50μmol·L-1Z-VAD-FMK组细胞凋亡率明显降低,Caspase-3和Caspase-9相对表达量降低,差异均有统计学意义(P0.05)。且随着MC-LR染毒浓度的升高或染毒时间的延长,16HBE细胞凋亡率和Caspase-3、Caspase-9相对表达量呈升高趋势。研究表明,MC-LR可以通过线粒体Caspase依赖性途径诱导16HBE细胞凋亡。     

Pesticide wastewater treatment using the combination of the microbial electrolysis desalination and chemical-production cell and Fenton process

• MEDCC combined with Fenton process was developed to treat real pesticide wastewater. • Pesticide removal was attributable to desalination in the MEDCC. • High COD removal was attributable to organic distributions in different chambers. The combination of the microbial electrolysis desalination and chemical-production cell (MEDCC) and Fenton process for the pesticide wastewater treatment was investigate in this study. Real wastewater with several toxic pesticides, 1633 mg/L COD, and 200 in chromaticity was used for the investigation. Results showed that desalination in the desalination chamber of MEDCC reached 78%. Organics with low molecular weights in the desalination chamber could be removed from the desalination chamber, resulting in 28% and 23% of the total COD in the acid-production and cathode chambers, respectively. The desalination in the desalination chamber and organic transfer contributed to removal of pesticides (e.g., triadimefon), which could not be removed with other methods, and of the organics with low molecular weights. The COD in the effluent of the MEDCC combined the Fenton process was much lower than that in the perixo-coagulaiton process (<150 vs. 555 mg/L). The combined method consumed much less energy and acid for the pH adjustment than that the Fenton.     

Transmembrane transport of polycyclic aromatic hydrocarbons by bacteria and functional regulation of membrane proteins

• Explaintheadsorption, uptake and transmembrane transport of PAHs by bacteria. • Analyze functional regulation of membrane proteins inthe transmembrane transport. • Proteomics technology such as iTRAQ labeling was used to access expressed proteins. • Single cell analysis technology wereused to study the morphological structure. In recent years, increasing research has been conducted on transmembrane transport processes and the mechanisms behind the microbial breakdown of polycyclic aromatic hydrocarbons (PAHs), including the role of membrane proteins in transmembrane transport and the mode of transmission. This article explains the adsorption, uptake and transmembrane transport of PAHs by bacteria, the regulation of membrane protein function during the transmembrane transport. There are three different regulation mechanisms for uptake, depending on the state and size of the oil droplets relative to the size of the microbial cells, which are (i) direct adhesion, (ii) emulsification and pseudosolubilization, and (iii) interfacial uptake. Furthermore, two main transmembrane transport modes are introduced, which are (i) active transport and (ii) passive uptake and active efflux mechanism. Meanwhile, introduce the proteomics and single cell analysis technology used to address these areas of research, such as Isobaric tags for relative and absolute quantitation (iTRAQ) technology and Nano Secondary ion mass spectrometry (Nano-SIMS). Additionally, analyze the changes in morphology and structure and the characteristics of microbial cell membranes in the process of transmembrane transport. Finally, recognize the microscopic mechanism of PAHs biodegradation in terms of cell and membrane proteins are of great theoretical and practical significance for understanding the factors that influence the efficient degradation of PAHs contaminants in soil and for remediating the PAHs contamination in this area with biotechnology.     

0,0-二甲基-(2,2,2-三氯-1-羟基乙基)磷酸酯对4种藻类生长的影响

0,0-二甲基-(2,2,2-三氯~(-1)-羟基乙基)磷酸酯(敌百虫)为广谱杀虫剂,用途广泛,但对藻类的毒理学效应研究还有待完善。采用4种受试藻样,设置5个敌百虫浓度组(1、5、10、50和100 mg·L~(-1))和对照组,实验周期40 d,藻细胞的初始接种密度106cells·m L~(-1),光暗比12 h/12 h,24 h曝气,24 h磁力搅拌,实验温度25℃,p H 6.8,每隔24 h取样。结果表明:5 mg·L~(-1)、10 mg·L~(-1)、50 mg·L~(-1)浓度的敌百虫对铜绿微囊藻和小球藻的生长有促进作用,其中以50 mg·L~(-1)浓度组的促进作用最为显著,促进作用主要表现在生长峰值的延后以及生长对数期的延长,而高剂量(100 mg·L~(-1))的敌百虫则有抑制藻生长的作用。取50 mg·L~(-1)敌百虫浓度组以及铜绿微囊藻和小球藻作进一步深入研究,结果表明:50 mg·L~(-1)敌百虫浓度组的叶绿素a含量峰值比对照组高30%,细胞体内的SOD、ATP含量都高于对照组。敌百虫的使用浓度通常在0.1~1.0 mg·L~(-1),低于本实验最佳浓度。本实验中1 mg·L~(-1)敌百虫对藻生长影响效果不明显。     

ZnO纳米粒子抑制体外小鼠光感受器细胞MnSOD的表达及活性

随着纳米技术的发展,纳米材料在生物医药以及化工中已得到广泛应用。作为一类新型材料,其安全性也日益受到人们的高度关注。为探索氧化锌(ZnO)纳米粒子对小鼠视网膜光感受器细胞的毒性作用,本文通过MTT、荧光染色、流式细胞术、实时荧光定量PCR和酶联免疫吸附试验(ELISA)等技术,分别对经不同浓度ZnO纳米粒子处理的小鼠光感受器细胞活性、活性氧水平、锰超氧化物歧化酶(Mn SOD)的基因和蛋白表达及活性进行了检测。结果表明,ZnO纳米粒子可通过诱导细胞线粒体产生过多的活性氧,降低线粒体膜电位,导致小鼠视网膜光感受器细胞损伤;ZnO纳米粒子能显著减少Mn SOD在mRNA和蛋白质水平的表达,降低Mn SOD活性,加剧氧化应激介导的细胞损伤。因此,氧化应激水平的提高导致了过量的活性氧产生及Mn SOD表达和活性的下降,与ZnO纳米粒子引起的细胞毒性作用有关。     

微生物燃料电池处理含硫废水的研究进展

随着工业的快速发展及化石能源的大量消耗,迫切地需要寻找一种可持续发展的绿色节能技术来替代不可再生能源.微生物燃料电池(microbial fuel cell,MFC)以其处理难降解废水的同时产生电能的优势引起了人们的广泛关注,成为近几年的研究热点,而含硫废水一直以来是废水处理的难点.本文回顾了MFC生物除硫的发展历程,...     

藻细胞膜电信号对重金属的快速反应研究

为探讨藻细胞膜电信号对重金属离子的响应特征,运用细胞外表面技术和电化学方法研究了淡水藻——大型轮藻(Nitellaflexilis)藻细胞膜电位和膜电阻对汞、镉、铅的快速反应.结果表明,细胞膜电位和膜电阻对汞、镉响应灵敏且快速,30min内即对1μmol·L-1Hg2+、Cd2+表现出超极化和膜电阻增大反应,而5、10μmol·L-1Hg2+、Cd2+则在15min内引起细胞去极化、膜电阻减小,且剂量效应显著.细胞膜电信号对Pb2+的响应浓度为100μmol·L-1,30min内细胞先去极化后超极化,膜电阻持续增大.重金属作用前后相比,高浓度Hg2+、Cd2+(5、10μmol·L-1)导致藻细胞不可逆损伤,而其低浓度所致的损伤可恢复.Pb2+致藻细胞不可逆损伤的最低浓度为500μmol·L-1.对比膜电信号对3种离子的响应特点,发现藻细胞膜电位和膜电阻对Hg2+和Cd2+的响应灵敏度大于Pb2+.