环境因子对转基因鱼腥藻培养的影响

摇瓶中对转TNF-α基因鱼腥藻7120（Anabaenasp.PCC7120,pDC-TNF)混合培养条件进行了研究,在含蔗糖9g/L,NaNO32.25g/L的BG-11培养基混合培养时,得到最适培养条件接种量5%,光照强度为1000Lux,光/暗周期（光照时间/黑暗时间）12h/12h,温度25-30℃,自然初始pH值,100mL摇瓶装液量40mL,转基因鱼腥藻15d生物量可达到3g/L以上,可溶性蛋白含量接近30%,TNF表达水平大于22%,与自养相比,生物量增加82.06%,表达水平提高38.79%,证明混合营养型培养是转rhTNF-α基因鱼腥藻7120实现高密度,高表达培养的途径。     

不同补料发酵方式对发夫酵母产虾青素的影响

对发夫酵母的不同补料发酵方式进行了研究,期望提高发酵产率,以便对工业化生产提供一定的指导作用。实验结果表明：采用恒pH葡萄糖-氨水流加培养,色素量和生物量均具有最大值,分别为54.3μg/ml和49.5μg/ml;其次是指数流加培养,色素量和生物量分别为49.9μg/ml和47.4mg/ml;恒pO2流加方式下色素量和生物量分别为34.04ug/ml和35.4mg/ml;恒pH葡萄糖流加方式所得的色素量和生物量最小,分别为32.3μg/ml和31.5mg/ml。不同的补料发酵方式对发夫酵母生长和色素形成的影响很大。     

pH及流加葡萄糖对酵母分批发酵生产谷胱甘肽的影响

在5 L的发酵罐中研究了pH及流加葡萄糖对酵母分批发酵生产谷胱甘肽(GSH)的影响。实验考察了不同浓度的流加葡萄糖和不同的恒pH值的分批发酵对于酵母生产GSH产量的变化。实验结果表明,当pH值控制为5.0,流加葡萄糖流速为5g.L-1.h-1,连续流加30 h,可使GSH产量最高,与之前未流加葡萄糖和控制pH相比,其产量提高了6倍。     

粗甘油优化污泥脱水液培养小球藻过程的研究

污泥脱水液为污泥压缩过程产生的污水,因其含有N、P等营养物,可用于微藻的培养。但污泥脱水液碳氮比低,可利用碳源有限,影响微藻生长。本研究考察外加不同浓度(1 g/L,2 g/L,4 g/L,6 g/L)生物柴油副产物-粗甘油对污泥脱水液培养小球藻过程的影响。结果表明:1 g/L、2 g/L粗甘油浓度能促进小球藻生长,藻生物量为1.29 g/L、1.45 g/L;2 g/L粗甘油浓度下氨氮、总氮去除率达99.32%和97.52%。粗甘油被分解后易使培养体系pH降至7以下,使总磷去除率比对照组略低。外加1 g/L、2 g/L粗甘油组的COD去除量分别为553.00 mg/L和405.00 mg/L。藻细胞元素和傅里叶红外光谱分析表明补加粗甘油后藻细胞中C元素和H元素相对含量均明显增加,C元素含量约为对照组的1.5倍;2 g/L粗甘油组的蛋白质与脂类物质含量均高于对照组。MPBR半连续培养小球藻过程中,HRT为5 d时藻生物量维持在1.99~2.21 g/L,大约为批次生物量的1.50倍;氨氮、总氮、总磷、COD的去除率分别在96.26%~99.20%、92.44%~94.04%、53.63%~58.58%、59.44%~65.57%。     

重组大肠杆菌高密度发酵生产RGD-TRAIL的条件优化

本文以一株产RGD-TRAIL的重组大肠杆菌为研究对象,在10L发酵罐中考查了诱导温度、pH值、溶氧、流加葡萄糖对重组大肠杆菌生长和RGD-TRAIL蛋白表达的影响。结果表明:诱导温度25℃,pH值控制7.0,溶氧控制30%,以5g·L~(-1)·h~(-1)流速流加葡萄糖最有利于菌体生长和蛋白表达,菌体收率和RGD-TRAIL产量分别达到45.99g·L~(-1)和160.2mg·L~(-1)。     

HCMV pp65截短蛋白原核表达条件优化

为了提高HCMVpp65蛋白片段在大肠杆菌中表达量,研究了不同发酵条件对其表达的影响,包括培养基、接种量、温度、摇床转速、pH、诱导时间以及诱导剂IPTG使用浓度等。结果表明,以LB培养基为发酵液,按5%接种量,37℃培养3h后IPTG诱导5h,重组菌菌体生物量为0.6g/L,目的蛋白表达量达18mg/L。用3.7L发酵罐进行放大培养,菌体生物量达0.85g/L,最高目的蛋白表达量达到25mg/L。     

氮源对雨生红球藻绿色生长期细胞生长的影响

【背景】雨生红球藻(Haematococcus pluvialis)细胞能合成积累具有超强抗氧化活性的虾青素,是生产高值天然虾青素的优异藻种。【目的】解析不同氮源对雨生红球藻生长的效应,以期建立优化氮素营养提高雨生红球藻生物量和虾青素产量的技术体系。【方法】选用Na NO3和NH_4Cl为氮源、辅以pH缓冲液Hepes,培养雨生红球藻藻株797,测试2种不同氮源对雨生红球藻藻液pH、营养生长期(绿色生长期)藻细胞生长、叶绿素含量和生物量等的影响。【结果】以Na NO3为氮源培养的雨生红球藻细胞的比生长速率、生物量、叶绿素a和叶绿素b含量均高于以NH_4Cl为氮源培养的藻细胞。不同氮源对雨生红球藻培养液的pH值有显著影响,NH_4Cl氮源导致培养液pH值降低,然而Na NO3氮源则导致培养液pH值上升。添加pH缓冲液Hepes能有效稳定培养液的pH值,并促进雨生红球藻的生长,尤以NH_4Cl为氮源添加Hepes的效果更显著。不同氮源导致雨生红球藻营养生长阶段细胞的生长和生物量等差异主要源于不同氮源引起藻液pH的变化。【结论】添加pH缓冲液Hepes可有效控制藻液pH,进而显著促进以Na NO3和NH_4Cl为氮源的雨生红球藻营养生长阶段细胞的生长和生物量积累。     

扁藻培养条件初探

在250 mL三角瓶中对扁藻的生长条件作了初步探索。在f/2培养基的基础上,通过正交实验确定主要营养盐的浓度分别为:NaNO30.08 g/L,KH2PO40.006 g/L,NaHCO30.8 g/L,可以使扁藻的倍增时间由原来的1.34 d缩短为0.64 d,并得出了主要营养盐含量与扁藻生物量的关系。研究表明,人尿对扁藻的生长有良好的促进作用,流加营养盐和人尿可使藻液浓度达4.25×106个/mL,比对照提高了36%。     

氨水流加用于粪产碱杆菌热凝胶发酵

热凝胶是粪产碱杆菌(Alcaligenes faecalis)在氮源限制条件下生成的水不溶性胞外多糖,分泌到胞外后就附着在菌体外壁,因此在细胞生长期提高生物量对促进热凝胶合成有重要意义。热凝胶分批发酵时, 起始NH4Cl浓度提高到3.6 g/L时能促进菌体生长和热凝胶合成,但是过量NH4Cl会抑制热凝胶合成,且生物量提高不是很明显。为了进一步提高菌体浓度, 在菌体生长期, 氨水取代NaOH溶液进行流加控制pH为7.0, 随后又用2 mol/L NaOH控制pH 5.6。实验表明, 氨水流加使菌体浓度大大提高,流加24 h使菌体浓度达到18.8 g/L。但是菌体浓度过高也会抑制热凝胶的合成,在氨水流加14 h时,菌体浓度在11.9 g/L左右, 热凝胶产量最高（72 g/L）。     

氨水流加用于粪产碱杆菌热凝胶发酵

热凝胶是粪产碱杆菌(Alcaligenes faecalis)在氮源限制条件下生成的水不溶性胞外多糖,分泌到胞外后就附着在菌体外壁,因此在细胞生长期提高生物量对促进热凝胶合成有重要意义。热凝胶分批发酵时, 起始NH4Cl浓度提高到3.6 g/L时能促进菌体生长和热凝胶合成,但是过量NH4Cl会抑制热凝胶合成,且生物量提高不是很明显。为了进一步提高菌体浓度, 在菌体生长期, 氨水取代NaOH溶液进行流加控制pH为7.0, 随后又用2 mol/L NaOH控制pH 5.6。实验表明, 氨水流加使菌体浓度大大提高,流加24 h使菌体浓度达到18.8 g/L。但是菌体浓度过高也会抑制热凝胶的合成,在氨水流加14 h时,菌体浓度在11.9 g/L左右, 热凝胶产量最高（72 g/L）。     

Investigation of the mechanism of temperature sensitivity of the electroreceptors of ampullae of lorenzini

In experiments on Black Sea skates (Raja clavata), the potential of the receptor epithelium of the ampullae of Lorenzini and spike activity of single nerve fibers connected to them were investigated during electrical and temperature stimulation. Usually the potential within the canal was between 0 and –2 mV, and the input resistance of the ampulla 250–400 k. Heating of the region of the receptor epithelium was accompanied by a negative wave of potential, an increase in input resistance, and inhibition of spike activity. With worsening of the animal's condition the transepithelial potential became positive (up to +10 mV) but the input resistance of the ampulla during stimulation with a positive current was nonlinear in some cases: a regenerative spike of positive polarity appeared in the channel. During heating, the spike response was sometimes reversed in sign. It is suggested that fluctuations of the transepithelial potential and spike responses to temperature stimulation reflect changes in the potential difference on the basal membrane of the receptor cells, which is described by a relationship of the Nernst's or Goldman's equation type.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. I. M. Sechenov, Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Pacific Institute of Oceanology, Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Neirofiziologiya, Vol. 12, No. 1, pp. 67–74, January–February, 1980.     

Principles of organization and evolution of systems of regulation of functions

Evolution of living organisms is closely connected with evolution of structure of the system of regulations and its mechanisms. The functional ground of regulations is chemical signalization. As early as in unicellular organisms there is a set of signal mechanisms providing their life activity and orientation in space and time. Subsequent evolution of ways of chemical signalization followed the way of development of delivery pathways of chemical signal and development of mechanisms of its regulation. The mechanism of chemical regulation of the signal interaction is discussed by the example of the specialized system of transduction of signal from neuron to neuron, of effect of hormone on the epithelial cell and modulation of this effect. These mechanisms are considered as the most important ways of the fine and precise adaptation of chemical signalization underlying functioning of physiological systems and organs of the living organism