'过山香'香蕉胚性悬浮细胞原生质体分离的方法研究

目的:研究不同的方法对‘过山香'胚性悬浮细胞原生质体分离的影响,筛选最适合用于‘过山香'香蕉胚性悬浮细胞原生质体分离的方案.方法:用不同浓度、不同组合的酶液对‘过山香'原生质体进行分离,并对酶液的甘露醇含量、pH值进行调节.结果:3.0%纤维素酶R-10+0.2%果胶酶Y-23的是最佳酶组合;酶解8 h、酶液中含0.41 M甘露醇、酶液pH值为5.3时,获得原生质体产量最高.结论:合适的酶组合、酶解时间、酶液的渗透压和pH值对‘过山香'香蕉胚性悬浮细胞原生质体的分离有明显的促进作用.     

‘过山香’香蕉胚性悬浮细胞原生质体分离的方法研究

目的：研究不同的方法对‘过山香’胚性悬浮细胞原生质体分离的影响,筛选最适合用于‘过山香’香蕉胚性悬浮细胞原生质体分离的方案。方法：用不同浓度、不同组合的酶液对‘过山香’原生质体进行分离,并对酶液的甘露醇含量、pH值进行调节。结果：3．0％纤维素酶R-10＋0．2％果胶酶Y-23的是最佳酶组合;酶解8h、酶液中含0．41M甘露醇、酶液pH值为5．3时,获得原生质体产量最高。结论：合适的酶组合、酶解时间、酶液的渗透压和pH值对‘过山香’香蕉胚性悬浮细胞原生质体的分离有明显的促进作用。     

石牌广藿香原生质体的分离及培养研究

以石牌广藿香悬浮细胞为材料,对影响其原生质体分离和培养的酶浓度、作用时间、溶液渗透压和材料的生理状态等因素进行了研究。结果表明:以0.5%的果胶酶、0.2%离析酶和0.8%的纤维素酶组合处理继代培养3～11d的悬浮细胞8h,渗透压调节剂为9%甘露醇,原生质体产量达1.65×106 protoplasts·mL-1 PCV,活力超过86%。在原生质体的液体浅层培养中,细胞分裂频率为13.5%。     

火炬松胚性悬浮细胞原生质体的分离和培养

以火炬松成熟合子胚的胚性悬浮细胞为材料分离原生质体,研究了酶液组成,渗透压稳定剂和悬浮细胞生长对原生质体产量和原生质体活力的影响。     

‘陇东’紫花苜蓿原生质体最佳分离条件

以‘陇东’紫花苜蓿（Medicago sativa L.cv.‘Longdong’）下胚轴愈伤组织为材料,研究酶液组合、酶解时间、酶液渗透压、愈伤组织继代培养时间及预处理措施对原生质体分离效果的影响。结果表明：获得产量最高（8.8×105个·g-1）、活力最高（88.55%）的原生质体最佳酶液组合为2%纤维素酶＋0.5%果胶酶＋0.3%崩溃酶、酶解时间为10h、酶液渗透压即甘露醇浓度为0.55mol·L-1,愈伤继代培养天数为12d、预处理措施为4℃、黑暗条件下放置24h。     

丹参悬浮培养细胞原生质体的制备和活力检测

对丹参悬浮培养细胞原生质体制备条件进行了研究,并利用FDA染色和钙离子荧光探针Fluo-3/AM装载对制备得到的原生质体的活力和功能进行了检测。丹参悬浮培养细胞原生质体的制备条件为:悬浮培养细胞酶解的适宜酶液组合为纤维素酶1.5%、果胶酶0.3%和离析酶0.5%;适宜的甘露醇浓度为0.4 mol/L;酶解时间为12 h;在600 r/min转速下离心5 min收集,纯化得到原生质体,其产量为1.1×106/g FW,FDA检测显示其活力为95%以上,荧光探针Fluo-3/AM可成功装载到原生质体中。     

玉米、小麦、水稻原生质体制备条件优化

玉米Zea mays L.、小麦Triticum aestivum L.、水稻Oryza sativaL.是三大重要粮食作物,对其原生质体制备条件的优化具有重要意义.以玉米(综3)、小麦(中国春)、水稻(日本晴)10日龄幼苗为材料,研究了叶肉细胞原生质体分离过程中的酶浓度、酶解时间和离心力大小等因素对产量和活力的影响.结果表明:酶浓度和酶解时间对原生质体产量影响显著,随着酶解液浓度和酶解时间的提高,原生质体产量增加,但细胞碎片同时增多.水稻经真空处理后,原生质体产量大幅度提高.通过正交实验设计得出如下结果:玉米叶肉细胞原生质体分离的最佳条件为:纤维素酶1.5％,离析酶0.5％,50 r/min酶解7h,100×g离心2 min收集,原生质体产量为7×106/g FW;小麦叶肉细胞原生质体分离的最佳条件为:纤维素酶1.5％,离析酶0.5％,50 r/min酶解5h,100×g离心2 min收集,原生质体产量为6×106/g FW;水稻叶肉细胞原生质体分离的最佳条件为:纤维素酶2.0％,离析酶0.7％,50 r/min酶解7h,1 000×g离心2 min收集,得到的原生质体产量为6×106/g FW.通过二乙酸荧光素染色发现原生质体活力均在90％以上.用PEG-Ca2+介导法将含有绿色荧光蛋白的质粒转化入原生质体,转化率可达50％ ～80％.     

基于亚细胞定位的大豆和鹰嘴豆原生质体分离体系的建立与优化

以湘豆3号大豆和Kabuli型鹰嘴豆幼嫩叶片为材料,研究了酶解种类及配比、酶解液中甘露醇浓度、酶解液p H和酶解时间对两种豆科植物幼嫩叶片原生质体产量和存活率的影响。结果表明,湘豆3号大豆叶片在含有0.5%纤维素酶Onozuka R-10、0.8%半纤维素酶Hemicellulase、0.8%离析酶Macerozyme R-10、0.4%果胶酶Pectolyase Y-23、0.1%2-(N-吗啡啉)乙磺酸(MES)和10%甘露醇的酶解液中(pH 6.0),27℃黑暗条件下恒温水浴振荡(45 r/min)酶解6 h,分离得到的原生质体产量和存活率最高;Kabuli型鹰嘴豆叶片在含有0.5%纤维素酶Onozuka R-10、0.8%半纤维素酶Hemicellulase、0.8%离析酶Macerozyme R-10、0.1%MES和10%甘露醇酶解液中(pH 4.8),27℃黑暗条件下恒温振荡水浴(45 r/min)7–8 h,分离得到的原生质体产量和存活率最高。通过上述件分离到的湘豆3号大豆和Kabuli型鹰嘴豆幼嫩叶片原生质体用于亚细胞定位的效果最好。     

野大麦幼穗原生质体的分离和培养

以野大麦(Hordeum brevisubulatum)的幼穗诱导愈伤组织,建立悬浮细胞系,利用胚性悬浮细胞系在不同的酶解条件和不同的酶解液中分离原生质体并进行培养,获得了细胞分裂,形成细胞团。     

疣粒野生稻胚性悬浮细胞系的建立及其原生质体的培养和植株再生

云南疣粒野生稻的成熟种子经55℃温度处理3d打破休眠后,在诱导培养基上诱导出愈伤组织。挑选胚性愈伤组织置于液体培养基中振荡培养,经3个月的继代培养,建立胚性细胞悬浮系。悬浮细胞经酶解、去壁后获得大量原生质体,固体包埋后添加液体培养基进行原生质体培养。在培养过程中调节培养体系的渗透压,获得小愈伤组织;经增殖后在分化培养基上诱导产生胚状体,成功得到疣粒野生稻的原生质体再生植株。     

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