陇东野生紫花苜蓿的核型分析

采用0.15%秋水仙素和0.002mol/L 8-羟基喹啉的混合液对陇东野生紫花苜蓿萌发种子的根尖预处理3h,室温条件下用1%果胶酶和1%纤维素酶酶解1.5h,得到清晰染色体制片.核型分析结果显示,陇东野生紫花苜蓿染色体数目为32条,具有1对随体,为2B核型,染色体核型组成公式为2n=32=30m(2SAT)+2sm,染色体长度组成公式为2n=2L+18M2+8M1+4S.     

中华蚊母树染色体制片及核型分析

以中华蚊母树根尖为材料,采用常规压片法制片,比较材料的不同采集时间、预处理方法、固定剂、解离方法、解离时间及染色方法对中华蚊母树根尖染色体制片的影响.结果表明最佳的制片技术为:取材时间为上午9:00~11:00或下午13:00~15:00,以饱和对二氯苯预处理3 h,用1 mol?L-1盐酸60℃下解离8 min,卡诺固定剂固定,以改良石碳酸品红染色10 min.以该最佳制片方案对中华蚊母树进行体细胞染色体核型分析,首次揭示了中国特有植物———中华蚊母树体细胞染色体数目为2n=2x=24,染色体基数x=12,染色体核型公式为2n=2x=24=12m(2SAT)+10sm+2st,主要由中部和近中部着丝点染色体组成;染色体相对长度组成为2n=24=2L+8M2+12M1+2S,核型不对称指数为64.29%,属于2A型.结果显示中华蚊母树核型对称程度较高,在进化中属于比较原始的类型.     

高山榕染色体制片优化及核型分析

以高山榕种子的根尖为材料进行染色体常规压片,比较不同预处理方法和解离方法对高山榕染色体制片的影响,以选择最优的压片方法制片并进行核型分析。结果显示,预处理24 h的总体效果优于12 h;3种预处理液的总体作用效果为0.05%秋水仙素>混合液>0.002 mol.L-18-羟基喹啉,综合比较后认为混合液低温4℃处理24 h为最佳预处理方法。解离方法选择1 mol.L-1HCl中60℃水浴2~3 min较为适宜。首次报道了高山榕核型公式为2n=2x=30=22m(2SAT)+6sm+2T,核型不对称系数为61.54%,核型属于Stebbins核型分类中的2C类型。     

黄果龙葵和龙葵染色体制片优化及核型分析

该实验以黄果龙葵和龙葵的根尖为实验材料,进行不同的预处理、固定和解离,确定出各种材料适合于核型分析的制片方法。结果表明:龙葵于15℃条件下经0.05%秋水仙素预处理2.5h,固定后用1mol/L HCl酸解后,染色观察,得到的染色体分散,易于染色体计数和形态观察。用此方法对黄果龙葵和龙葵进行核型分析,结果发现:黄果龙葵和龙葵都属于小型染色体,黄果龙葵为四倍体,核型公式为K(4n)=48=4sm+44m,核型不对称系数为56.22%,属于2B核型。龙葵为六倍体,核型公式为K(6n)=72=72m,核型不对称系数为55.89%,属于1B核型。     

贵州产蜘蛛抱蛋属植物的细胞分类学研究

报道了6种贵州产蜘蛛抱蛋属植物的染色体数目和核型,并与其相应近缘种对比,联系植物的外部形态特征,探讨核型结构与形态特征的相关性.发现1个种的染色体数目为2n =36,5个种的染色体数目为2n =38,核型公式分别为:平塘蜘蛛抱蛋(Aspidistra pingtangensis),2n =38 =20m +4sm(2sat) +14st;荔波蜘蛛抱蛋(A.liboensis),2n =38 =22m(2sat)+4sm+ 12st;赤水蜘蛛抱蛋(A.chishuiensis),2n =38 =22m(2sat)+8sm +8st;伞柱蜘蛛抱蛋(A.fungilliformis),2n =36=18m (2sat) +4sm+ 14st;四川蜘蛛抱蛋(A.sichuanensis),2n =38 =22m (2sat) +4sm +12st;丛生蜘蛛抱蛋(A caespitosa),2n =38 =20m +6sm(2sat) +12st.核型类型都为2C型.其中平塘蜘蛛抱蛋、荔波蜘蛛抱蛋和赤水蜘蛛抱蛋的染色体数目和核型均为首次报道.研究结果表明,该属植物的核型结构与外部形态特征具有一定的相关性,细胞分类学研究可以为该属植物起源进化研究以及自然分类鉴定提供一定的依据.     

小水榕染色体数目及核型分析

以小水榕根尖为材料,通过取材时间,8-羟基喹啉、饱和对二氯苯2种药剂预处理,并以细胞中有丝分裂相的数目、染色体的清晰度、分散程度为指标,探索出适于小水榕染色体分析的方法.结果表明:小水榕有丝分裂中期在一天的16:00达到高峰期,取样时间确定在16:00.饱和对二氯苯水溶液预处理2 h,卡诺氏固定液固定2 h,1 mol/L盐酸60 ℃水浴中解离3 min～4 min,并以醋酸洋红染色效果较好.小水榕核型为2 n=2 x=30=12 m+14 sm+4 st,属于"2B"类型.     

野牡丹科6种植物染色体数目及核型分析

研究了野牡丹科国产野牡丹属(Melastoma L.)4种植物和从国外引种的蒂牡花属(Tibouchina Aubl.)2种植物的染色体数目,并对4种野牡丹属植物的核型进行分析。结果表明, 野牡丹属植物的染色体数目为2n=24,为二倍体植物,蒂牡花属的蒂牡花(T. urvillean)和银毛野牡丹(T. heteromall)的染色体数目为2n=36。核型公式为：野牡丹(M. malabathricum) 2n=10m(2SAT)+14sm;毛稔(M. sanguineurn) 2n=10m+12sm+2st;地稔(M. dodecandrum) 2n=12m+12sm;细叶野牡丹(M. intermedium) 2n=12m＋10sm+2st。核型分析表明国产野牡丹属植物染色体为小染色体,绝对长度为0.43~1.79 µm;核型不对称系数为59.47~62.91,均属2B型。野牡丹属植物的核型为首次报道。     

基于荧光原位杂交技术的紫薇属植物核型分析

以紫薇(Lagerstroemia indica)、尾叶紫薇(L.caudata)、屋久岛紫薇(L.fauriei)和福建紫薇(L.limii)4种紫薇属植物为材料,利用染色体荧光原位杂交技术(FISH)获得了4种紫薇属植物的有丝分裂中期染色体FISH图及核型参数,分析了45SrDNA在紫薇属植物染色体上的数量和分布特点。结果表明,4种紫薇属植物染色体上均具有1对45SrDNA杂交位点,位于较长染色体短臂的近端部,紫薇、尾叶紫薇、屋久岛紫薇和福建紫薇的核型公式分别为2n=48=2M+24m+22sm、2n=48=30m+18sm、2n=48=2M+20m+26sm和2n=48=2M+32m+14sm,均为2A型。该研究首次获得了紫薇属植物45SrDNA荧光原位杂交核型,为紫薇属植物亲缘关系研究和细胞生物学研究提供了分子细胞学依据。     

珍珠菜属三种植物的核型研究

对国产三种珍珠菜属 (Lysimachia)植物进行了核型研究 ,其中点腺过路黄 (LysimachiahemsleyanaMaxim .)染色体核型 2n =2 2 =2m +4sm +8st+8t,聚花过路黄 (L .congestifloraHesmsl.)核型 2n =2 4=2m +2sm +1 0st+1 0t及山萝过路黄 (L .melampyroidesR .Knuth)染色体数目 2n =2 2 ,核型 2n =2 2 =4m +6sm +4st+8t,为首次报道。本文还分析了黄连花亚属 (subgen.Lysimachia) 2组 8种植物的核型 ,结果表明黄连花组(sect.Lysimachia)核型类型 1A ,过路黄组 (sect.Nummularia)核型类型 3A或 3B。     

崇明水仙根尖体细胞染色体的观察和核型分析

以崇明水仙(Narcissus tazetta L.var.chinensis Roem.)根尖体细胞为实验材料,对适宜于崇明水仙细胞学研究的前处理液和前处理时间进行了筛选,在此基础上,应用根尖压片法对重瓣花型和单瓣花型崇明水仙体细胞染色体数、核型及倍性进行了比较分析.结果显示:适宜的前处理液是对二氯苯饱和溶液,适宜的前处理时间为12 h.重瓣花型和单瓣花型崇明水仙的染色体核型差异较小,相同点为:不对称二型核型,染色体基数x=10,三倍体,体细胞染色体数2n=3x=30,第7号染色体的短臂具随体,核型均属于"3B"型,臂比大于2的染色体比率为90%.不同点为:重瓣花型的第7号和第8号染色体分别为sm和st型,单瓣花型的第7号和第8号染色体分别为st和sm型;前者的核型不对称系数(76.48%)略小于后者(76.71%);前者的相对长度系数为12L+6M2+12S,后者的相对长度系数为12L+3M1+3M2+12S;前者的最长染色体与最短染色体长度的比值(3.10)略小于后者(3.19).重瓣花型的核型公式为2n=3x=30=15st+15sm(3SAT),单瓣花型的核型公式为2n=3x=30=15st(3SAT)+15sm,崇明水仙根尖体细胞染色体的平均核型公式为2n=3x=30=15st(3SAT)+15sm.根据研究结果初步推测崇明水仙为节段异源三倍体.     

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