法夫酵母PLX-ll发酵纤维素酶水解物合成虾青素

法夫酵母（Phaffiarhodozyma)PLX朅ll菌株能够发酵纤维素酶水解物进行虾青素的生物合成。纤维素的酶解物主要为纤维二糖和葡萄糖,在另外添加适量其它营养物后可被法夫酵母发酵用于生长及合成虾青素。摇瓶试验结果表明,培养108h,法夫酵母的生物量可达2.3g／L,虾青素的产率达913.4g／g干细胞,虾青素体积产率为2.1mg／L。在2L罐的发酵试验中,法夫酵母的生物量可达3.23g／L（第96h）,虾青素的产率达581.4g／g干细胞,虾青素体积产率达1.88mg／L。     

法夫酵母PLX-All发酵纤维素酶水解物合成虾青素

法夫酵母（Phaffia rhodozyma)PLX-All菌株能够发酵纤维素酶水解物进行虾青素的生物合成。纤维素的酶解物主要为纤维二糖和葡萄糖,在另外添加适量其它营养物后可被法夫酵母发酵用于生长及合成虾青素。摇瓶试验结果表明,培养108h,法夫酵母的生物量可达2.3g／L,虾青素的产率达913.4g／g干细胞,虾青素体积产率为2.1mg／L。在2L罐的发酵试验中,法夫酵母的生物量可达3.23g／L（第96h）,虾青素的产率达581.4g／g干细胞,虾青素体积产率达1.88mg／L。     

法夫酵母PLX-All发酵纤维素酶水解物合成虾青素*

法夫酵母（Phaffia rhodozyma)PLX-All菌株能够发酵纤维素酶水解物进行虾青素的生物合成。纤维素的酶解物主要为纤维二糖和葡萄糖,在另外添加适量其它营养物后可被法夫酵母发酵用于生长及合成虾青素。摇瓶试验结果表明,培养108h,法夫酵母的生物量可达2.3g／L,虾青素的产率达913.4g／g干细胞,虾青素体积产率为2.1mg／L。在2L罐的发酵试验中,法夫酵母的生物量可达3.23g／L（第96h）,虾青素的产率达581.4g／g干细胞,虾青素体积产率达1.88mg／L。     

法夫酵母产虾青素的反复分批及反复分批补料发酵

以生物量和虾青素产量为指标,考察法夫酵母多批次半连续培养产虾青素的稳定性。实验结果显示,在摇瓶上分别以4 d和5 d为周期反复分批培养法夫酵母,虾青素产量呈现先增加再下降的趋势,但第2代至第7代虾青素产量仍高于第1代,并且4 d为周期的虾青素平均产量略高于5 d的。在5 L罐法夫酵母进行反复分批补料发酵中,不管是补加30％的葡萄糖还是补加30％的淀粉水解糖,第2个批次发酵的生物量和虾青素产量均达到第1个批次的水平,表明菌种稳定性较好。     

法夫酵母PLX—A11发酵纤维素酶水解物合成虾青素

法夫酵母（Ｐｈａｆｆｉａ ｒｈｏｄｏｚｙｍａ）ＰＬＸ－Ａ１１菌株能够发酵纤维素酶水解物进行虾青素的生物合成。纤维素的酶解物主要为纤维二糖和葡萄糖,在另外添加适量其它营养物后可被法夫酵母发酵用于生长及俣成虾青素。摇瓶试验结果表明,培养１０８ｈ,法夫酵母的生物量可达２．３ｇ／Ｌ,虾青素的产率达９１３．４μｇ／ｇ干细胞,虾青素体积产率为２．１ｍｇ／Ｌ。在２Ｌ罐的发酵试验中,法夫酵母的生物量可达３．２３ｇ     

虾青素对db/db小鼠糖尿病肾病的保护作用

目的：采用2型糖尿病模型db/db小鼠,观察虾青素对糖尿病肾病的保护作用。方法：db/db小鼠糖尿病肾病模型成模后随机分为：模型对照组、氯沙坦组、虾青素低剂量组、虾青素高剂量组进行干预。同窝db/m小鼠作为正常对照。其中,氯沙坦组、虾青素低剂量组、虾青素高剂量组分别采用氯沙坦10 mg/（kg·d）BW、虾青素30 mg/（kg·d）BW、虾青素60 mg/（kg·d）BW进行灌胃,氯沙坦与虾青素均用橄榄油溶解,正常对照组与模型对照组灌胃等量橄榄油。干预8w后,检测其空腹血糖、OGTT、24 h尿白蛋白、尿ACR、肌酐、尿素氮等指标。结果：低剂量虾青素对糖耐量无不良影响,并能显著降低血清尿素氮、尿蛋白、尿ACR水平。结论：低剂量虾青素具有肾脏保护作用,但不具有剂量依赖性。     

虾青素高产菌株的选育

采用激光（Laser）、紫外线（UV）、亚硝基胍（NTG）及其复合诱变法夫酵母菌,再用高浓度葡萄糖培养基选育经复合诱变的法夫酵母菌。结果表明：与原始出发菌相比,菌株经诱变后其虾青素产量有显著提高,其中复合诱变的是青素产量可达7.26μm/ml。诱变高产菌株遗传稳定性好。     

海洋红酵母产虾青素培养基优化的初步研究

为了提高海洋红酵母发酵虾青素的产量水平,对海洋红酵母的培养基成分进行了初步研究。试验结果表明,海洋红酵母能利用葡萄糖、淀粉水解糖、糖蜜等多种碳源,用淀粉水解糖为碳源培养海洋红酵母所获得的虾青素体积产率最大;用牛肉膏为氮源有利于提高海洋红酵母的生物量,以(NH4)2SO4、NH4Cl和蛋白胨为氮源有利于提高海洋红酵母的虾青素体积产率,用KNO3、草酸铵、蛋白胨、尿素有利于提高海洋红酵母的虾青素细胞产率;在海洋红酵母的培养基中添加Mn2 、Cd2 、Zn2 、Fe2 能增加生物量,添加Zn2 、Fe3 、Mn2 能增加海洋红酵母的虾青素体积产率,添加Fe3 能提高海洋红酵母的虾青素细胞产率。     

非水介质大孔树脂分离纯化虾壳中虾青素

通过7种大孔树脂对虾青素的静态吸附容量和解析率等指标的考察,筛选出AB-8大孔吸附树脂,用于分离虾壳中虾青素,同时利用高效液相色谱（HPLC）法测量虾青素的含量。结果表明,AB-8树脂对虾青素的吸附量为（24．17±0．5）mg／g,解吸率为95．2％,最大上样量（每g干树脂）以虾青素计为（23．07±0．2）mg,并确定用8倍量柱床体积的乙酸乙酯为洗脱剂,纯化所得虾青素的纯度为14．73％。     

超临界C02萃取雨生红球藻中虾青素工艺的研究

本工艺以雨生红球藻粉为原料,采用超临界COz萃取技术,萃取雨生红球藻浸膏,可有效地将雨生红球藻颗粒中的虾青素萃取出来,使萃余物（残渣）中总虾青素含量的平均值为0．224％;提取物得率（以油浸膏的总量计）可达28．5％;虾青素的提取率可达66．69％;雨生红球藻油浸膏中虾青素含量为5．710％。     

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