上海市细胞生物学学会1986年年会召开

上海市细胞生物学学会于1986年12月26日至27日在上海召开了年会。26日上午举行了年会开幕式,会上由庄孝僡理事长致开幕词,胡兆庆秘书长作了学会的工作报告。大会并邀请了细胞生物学研究所王亚辉所长作了细胞生物学的趋向和发展战略的报告。有150余人参加了会议。26日下午和27日上午进行了分组论文报告,共报告了64篇论文,年会显示了近年来上海市细胞生物学研究取得的成就。会议期间还邀请了下述同志作了小组专题报告。庄孝僡:关于中胚层的决定和分化的问题;顾国彦:胞质分裂时蛙卵表面运动;鲍璿:体外培养神     

邻体干扰模型的改进及其在营林中的应用

本文研究了植物群落中优势种个体间的相互干扰问题。在前人工作基础上提出了邻体干扰指数的改进模型及野外资料搜集方法。保证了数学模型的逻辑一致性,增加了生态学的解释意义。本文还讨论了邻体干扰效应模型的选择问题,进而得出了约束条件下的材积增长的数学优化模型。以四川省重庆市缙云山马尾松林为例,进行了实例研究。     

中国微生物学会召开在京常务理事扩大会

中国微生物学会于1984年5月4日召开了在京常务理事扩大会。出席会议的有在京常务理事、各工作委员会和专业委员会的负责人等17人。秘书长王大耜同志主持了会议,就以下内容作了汇报,经会议讨论,大家取得了一致意见。1.传达了1984年中国科协工作要点;关于编写《当代中国的科技群众团体及其活动》的通知。2.讨论通过了1984年学术活动经费预分配方案。3.汇报了1984年科普和编辑出版工作安排。4.汇报了1984年的有关国际交流活动。5.研究了中国微生物学史料的收集工作。6.讨论了今年的常务理事扩大会议采用通讯方式召开和研究1985年召开学会理事会的初步打算等。     

原生质体在分离和鉴定植物生化突变体中的应用

本文就植物原生质体在生化突变体的分离与鉴定中的应用进行了述评。对一些从原生质体培养系统中选出的生化突变体进行了归类。讨论了原生质体在分离生化突变体中的优点。分析了原生质体在选择方案中的特殊性。评价了原生质体在鉴定和应用突变体中的作用。此外,还指出了原生质体应用中存在的一些问题。     

《分子光子学原理及应用》简介

本书绪论回顾了分子光子学的发展历程,并概述了相关的研究领域。第一章根据光学原理、分子学理论、辐射理论和分子场与辐射场的相互作用,介绍了分子光子学的基本原理。第二章总结了光化学反应的特性。第三章讨论了受激发能量转移和光诱导电子跃迁等典型物理化学过程。第四章展示了在电场、磁场或声学场的作用下,光的散射现象和材料诱发变性。第五章介绍了由光辐射引起的光变性,并讨论了非线性光学现象和相干光谱学。     

邻体干扰模型的改进及其在营林中的应用

 本文研究了植物群落中优势种个体间的相互干扰问题。在前人工作基础上提出了邻体干扰指数的改进模型及野外资料搜集方法。保证了数学模型的逻辑一致性,增加了生态学的解释意义。本文还讨论了邻体干扰效应模型的选择问题,进而提出了约束条件下的材积增长的数学优化模型。以四川省重庆市缙云山马尾松林为例,进行了实例研究。     

大豆转基因的研究进展

近年来利用基因工程技术,大豆的遗传转化取得了较大的进展。该文介绍了几种主要的大豆遗传转化系统的优点和缺点。探讨了影响农杆菌介导大豆遗传转化的因素。分析了大豆遗传转化中存在的一些问题及其解决办法,评价了转基因大豆的生物安全性,展望了未来大豆遗传转化的发展前景。     

《分子光子学--原理及应用》简介

本书绪论回顾了分子光子学的发展历程,并概述了相关的研究领域。第一章根据光学原理、分子学理论、辐射理论和分子场与辐射场的相互作用,介绍了分子光子学的基本原理。第二章总结了光化学反应的特性。第三章讨论了受激发能量转移和光诱导电子跃迁等典型物理化学过程。第四章展示了在电场、磁场或声学场的作用下,光的散射现象和材料诱发变性。第五章介绍了由光辐射引起的光变性,并讨论了非线性光学现象和相干光谱学。     

植物体细胞杂种及其选择

没有细胞壁的球形原生质体给体细胞杂交提供了有利体系,为克服远缘植物间有性过程中(包括授粉、授精)的不亲和性开辟了途径。同时也为携带外源遗传信息的大分子渗入列细胞创造了机会。从而打破了只依靠有性重组的界线,扩大了遗传重组的范围。近十年来已建立了体细胞杂交的一系列程序和方法,获得了许多体细胞杂种和胞质杂种。     

蛋白质折叠机理的理论研究

简要综述了近年来蛋白质折叠机理的理论研究。首先回顾了蛋白质折叠理论的发展历程,然后对折叠中间体的研究现状作了较详细的介绍。同时,对折叠机理理论研究中的几种理论模型和模拟算法作了细致评述,分析了其现状和存在的问题。最后,总结和讨论了折叠机理理论研究的现存问题及研究热点,并展望了该领域研究的发展趋势。     

天竺葵雌性生殖单位的超微结构

应用透射电镜研究了临近受精时天竺葵(Pelargonium hortorum Bailey)胚囊中的卵细胞、助细胞和中央细胞的结构。证明了卵细胞与助细胞以及助细胞与助细胞之间从合点端至珠孔端有很大的面积以质膜分界,仅珠孔端少部分以壁分隔。卵细胞与中央细胞之间同样缺乏细胞壁。在卵细胞的合点端,两质膜不同程度地分离形成宽窄相间的间隙。在间隙的絮状基质中存在小泡,这些小泡的产生似与卵和中央细胞中周质内质网的活动有关。推测小泡为多糖性质,可能为合子新壁的建造提供物质。卵细胞质中含巨大线粒体,质体和内质网也较丰富。基于超微结构的特征,可认为卵细胞具高度的生理合成活动的潜能。中央细胞极核位于珠孔端与卵器细胞毗邻,有利于在双受精作用中同时发生精细胞与卵细胞和精细胞与中央细胞核的融合。中央细胞的侧壁在珠孔端形成内突,具传递细胞的特点,表明这是雌配子体向孢子体摄取营养的重要部位。助细胞的细胞质含丰富的细胞器,这与多数植物中的相似,但具几个明显的特征,即核中存在微核仁,内质网形成圆球体或脂体,线粒体富集在丝状器的附近。传粉后花粉管进入胚囊之前,两个助细胞中一个退化。     

水稻胚囊超微结构的研究

水稻(Oryza sativa L.)胚囊成熟时,卵细胞的合点端无细胞壁,核居细胞中部,细胞器集中在核周围,液泡分散于细胞周边区域。助细胞珠孔端有丝状器,合点端无壁,核位于细胞中部贴壁处,细胞器主要分布在珠孔端,液泡主要分布在合点端。开花前不久,一个助细胞退化。中央细胞为大液泡所占,两个极核靠近卵器而部分融合,细胞器集中在极核周围和靠近卵器处,与珠心相接的胚囊壁上有发达的内突。反足细胞多个形成群体,其增殖主要依靠无丝分裂与壁的自由生长,反足细胞含丰富活跃的细胞器,与珠心相接的壁上有发达的内突。开花后6小时双受精已完成,合子和两个助细胞合点端均形成完整壁。合子中开始形成多聚核糖体、液泡减小。退化助细胞含花粉管释放的物质,其合点端迴抱合子。极核已分裂成数个胚乳游离核,中央细胞中细胞器呈活化状态。反足细胞仍在继续增殖。讨论了卵细胞的极性、助细胞的退化、卵器与中央细胞间界壁的变化、反足细胞的分裂特点等问题。     

Ultrastructure of the Developing and Fertilized Embryo Sac of Amaranthus hypochondriacus L.

Amaranthus hypochondriacus embryo sac development was investigatedbefore and after fertilization. During the early stages of development,the young embryo sac displays three antipodal cells at the chalazalpole that degenerate very early in the maturation process, beforethe synergids and egg cell are completely differentiated. Themature embryo sac is composed only of the female germ unit.The synergid cells organize a filiform apparatus accompaniedby the presence of mitochondria and dictyosomes with numerousvesicles. The involvement of the synergids in transport andsecretory functions related to pollen tube attraction and guidance,are discussed. The egg cell is located at the micropylar polenear the synergids and displays exposed plasma membranes atthe chalazal pole. The fertilized egg cell does not exhibitmarked changes after fertilization except for the closure ofthe cell wall. The central cell is the largest cell of thisvery long embryo sac. The fused nucleus is close to the eggapparatus before fertilization and displays a remarkable chalazalmigration after gamete delivery. The ultrastructure of the centralcell cytoplasm and the numerous wall ingrowths around this cellsuggest an important role in nutrient transportation. Aftergamete delivery, the embryo sac displays electron dense bodiesthat aggregate within the intercellular space between the synergids,egg cell and central cell. These bodies, that appear in theembryo sac of several plants, are probably involved in gametedelivery for double fertilization. The possibility of biparentalinheritance of mitochondria in this plant is also discussed.Copyright 1999 Annals of Botany Company Amaranthus hypochondriacus, grain amaranth, embryo sac, fertilization.     

Structure of Embryo Sac Before and After Fertilization and Distribution of Transfer Cells in Ovules of Green Gram

The structure of embryo sac before and after fertilization, embryo and endosperm development and transfer cell distribution in Phaseolus radiatus were investigated using light and transmission electron microscopy. The synergids with distinct filiform apparatus have a chalazal vacuole, numerous mitochondria and ribosomes. A cell wall exists only around the micropylar half of the synergids. The egg cell has a chalazally located nucleus, a large micropylar vacuole and several small vacuoles. Mitochondria and plasrids with starch grains are abundant. No cell wall is present at its chalazal end. There are no plasma membranes between the egg and central cell in several places. The zygote has a complete cell wall, abundant mitochondria and plastids containing starch grains. Both degenerated and persistent synergids migh.t serve as a nutrient supplement to proembryo. The wall ingrowths occur in the central cell, basal cell, inner integumentary cells, suspensor cells and endosperm cells. These transfer cells may contribute to embryo nutrition at different developmental stages of embryo.     

Ultrastructures of the Egg Apparatus and the Central Cell of Calystegia hederacea (Convolvulaceae) Before and After Fertilizati on

Ultrastructures of the mature embryo sac of Calystegia hederacea Wall. and its changes after fertilization are described. The positional organization of the egg cell, the two synergids and the central cell, as well as their interrelationships were studied. Some regions of the cell boundaries between the egg cell and the central cell, as well as between the egg cell and the synergids were devoid of typical cell wall before fertilization, displayed a feature quite similar to the characteristic absence of the cell wall in the fertilization target zone occurred in most angiosperms. Besides the genera ultrastructural characteristics of the egg apparatus and the central cell, there were several unusual aspects in C. hederacea, such as the egg nucleus located above the large vacuole near the chalazal end of the cell, many polyribosomes in the cytoplasm of the egg cell and wall ingrowths on both sides of the hooks of the central cell. All these unusual characteristics seemed to be closely associated with the short duration of the fertilization and the absence of antipodal cells in the mature embryo sac. It is concluded that the female germ unit of C. hecleracea is considered to be a topographical and physiological unit to realize their functions for successful double fertilization.     

FERTILIZATION IN BARLEY

The mature embryo sac of barley consists of an egg, two synergids, a central cell, and up to 100 antipodal cells. At shedding the male gametophyte is 3-celled, consisting of a vegetative cell with a large amount of starch and two sperms having PAS+ boundaries. Before pollination the nucleus and cytoplasm of each synergid appear normal. After pollination the nucleus and cytoplasm of one synergid undergo degeneration. The pollen tube grows along the surface of the integument of the ovule, passes through the micropyle, and enters the degenerate synergid through the filiform apparatus. The pollen tube discharges the vegetative nucleus, two cellular sperms, and a variable amount of starch into the degenerate synergid. Soon after deposition the sperms migrate by an unknown mechanism to the chalazal end of the degenerate synergid. Sperm nuclei then enter the cytoplasm of the egg and central cell, ultimately resulting in the formation of the zygote and primary endosperm nucleus, respectively. Sperm boundaries do not enter egg or central cell, but it was not possible to determine the fate of other sperm components. Degenerate vegetative and synergid nuclei remain in the synergid after fertilization, constituting what are considered to be X-bodies in barley. The second synergid degenerates during early embryogeny.     

东北地区野豌豆属VICIAL．物种生物学研究Ⅷ．幼苗形体结构动态和种间界限

在野外居群调查的启示下,本文以组件观点对柳叶野豌豆复合种和歪头菜幼苗亚单位的时序变化与开花关系进行了分析。结果发现在柳叶野豌豆复合种栽培居群中存在打破物种间形体结构特征的个体,即在复叶由一对小叶组成的植株就已开花而进入生殖时期。另外,在歪头菜的野生居群中发现由三或四枚小叶组成复叶的个体,因此,我们推测这种形体结构的变化可能暗示着柳叶野豌豆复合种和歪头菜有着共同的祖先。     

Fertilization and Histochemical Investigation on Pulsatilla chinensis (Bung) Regel

Fertilization and variation of protein and starch grains in Pulsatilla chinensis (Bung) Regel have been studied at light microscopic level with histochemical test. Based upon the observations, the main conclusions are summarized as follows: The mature pollen grains are two-celled in which the generative cell shows the stronger protein staining than the vegetative cell. And vegetative cells are full of starch garins. When the pollen tube enters into the embryo sac, one synergid is destroyed, or in a few cases synergids are intact. Occasionally two synergids are disorganized as pollen tube penetrates. However, most of the remaining syuergids break down during fertilization, only in a few cases it remains till early stage of embryo development. The contents discharged by the pollen tube consist of two sperms, which stain intensely blue with protein dyes, a great amount of protein and starch grains. Mature female gametophyte (embryo sac) consists of an egg apparatus, central cell, which has a huge secondary nucleus, and antipodal apparatus which retain in course of fertilization. A few of embryo sac contain two sets of egg apparatus, a central cell with two huge secondary nuclei and two sets of antipodal apparatus. In some nucleoli of the central cell the comb-like structure pattern may be detected clearly. There are 1–2 small nucleoli in some egg cells and central cells. All the cells in embryo sac show protein positive reaction. According to the different shades of the color in cells, its may be arranged in the following order: antipodal cells, synergids, central cell and egg cell. Only a few small starch grains are present near nuclei of central cell and egg cell before fertilization, but no starch grains remain in most of the central cell, the synergids and antipodal cells. The fertilization is of the premitotic type. The fusion of the sexual nuclei progresses in the following order: 1, sperms approach and lie on the egg nucleus and secondary nucleus; 2, sperm chromatin sinks themselves into female nucleus, and male nucleolus emerges with the sperm chromosome; and 3, male nucleoli fuse with the nucleoli of egg nucleus and central cell nucleus, and finally forming the zygote and the primary endosperm cells respectively. Nevertheless, as it is well known, the fertilization completes in central cell obviously earlier than that in egg cell. Though it has been explained in cereals and cotton, in Pulsatilla chinensis the main reason is that nucleolar fusion of the male and female nucleoli in egg nucleus is slower than that in secondary nucleus. And the dormancy of the primary endosperm nucleus is shorter than that of the zygote. In the process of fertilization, histochemical changes are considerably obvious in the following three parts: 1, from the begining of fusion of male and female nuclei to form zygote and primary endosperm cell, Protein staining around female nucleus appears to increase gradually; 2, no starch grains are detected in embryo sac. Though only starch grains are carried in by pollen tube, they are completely exhausted during this period; and 3, near completion of fertilization starch grains appear again in zygote, however, not yet in primary endosperm nucleus till its dividing for the first time. The present study reveals that antipodal cells and synergids seem to play a significant role in nutrition of the embryo sac during the fertilization.     

Ovule,Female and Male Gametophyte and Fertilization of Kingdonia uniflora Balfour F. et W. W. Smith

The structure of ovule, female and male gametophyte, double fertilization and the distrubution of starch grains during the fertilization have been studied. The main results are as follows: ( 1 ) Ovule The ovule is anatropous, unitegmic and tenuinucellate. The nucetlus appears cylindric, since megaspores and embryo sac development, its internal cells of nucellus become disorganized, so that only a single layer of epidermal cells remains toward the side of the micropyle, On the other hand, the integument is not as long as nucellus, as a result micropyle is not formed. And no vascular bundle is found in the integument. (2) Female gametophyte The mature embryo sac is slender and is composed of an egg cell, two synergids, a central cell and three antipodal cells. The egg cell is situated slightly away from the tip of embryo sac. Some of them contain starch grains. Synergids occupy the tip of embryo sac. Its wall at micropylar region appears irregular in thickenes and irregular in ingrowths to form the filiform apparatus. The centrateell is very large, and strongly vacuolated Two polar nuclei come to contact closely with each other, but not fuse, or to fuse into a large secondary nucleus before fertilization. The polar nuclei or the secondary nucleus are usually situated at the middle-lower position of the central cell or nearer to the chalazal end above the antipodal cell. It is different from egg cell, no starch grains are found here. In most embryo sacs three antipodal cells are found. They are not as large as those in other plants of Ranunculaceae. But six antipodal cells or the antipodal cell with two nuclei may rarely be found. Like synergid, the wall of them appears not only irregularly thickened, but clearly with irregular ingrowths. In a few antipodal cells the starch garins are usually found near the nucleus. By the end of fertilization, antipodal cells become disintegrated. (3) Male gametophyte Most pollen grains are two-celled when shedding, and rich in starch grains. A few of them contain single nucleus or three-celled. (4) The double fertilization The fertilization of Kingdonia unifiora Balfour f. et W, W. Smith is wholly similar to some plants of Ranunculaceae studied. First, the pollen tube penetrates a degenerating synergid. And the pollen tube discharges its contents with two sperm nuclei into the degenerating synergid cell. One of the two sperms fuses with the nucleus of the egg, and the other fuses with two polar nuclei or the secondary nucleus of the central cell. If one sperm nucleus at first fuses with one of the polar nuclei, and then the fertilized polar nuclei again fuses with other polar nucleus. Secondly, the fertilization of the polar nuclei or the secondary nuclei completes earlier than that of the egg. The primary endosperm nucleus begins to divide earlier than the zygote. It seems that one of the sperm nuclei come to contact with egg nucleus, the other has already fused with polar nuclei or the secondary nucleus. The zygote with a single nucleolus appears until the endosperm with 16–20 cell. Thirdly, before and after fertilization there are one to some small nucleoli in egg nucleus and polar nuclei or secondary nucleus. However they increase in quantity from the beginning of the fusion of male nucleis. These nucleoli quite differ from male nucleoli by their small size, and most of them disappear at the end of fertilization. It may be concluded that the small nucleoli increase in quantity is related to the fusion of male and female nuclei. In the duration of fertilization, in ovule starch distribution is in the basal region of integument. But in embryo sac, onlysome egg cells, or zygotes contain starch grains, a part of which was brought in by pollen tube. Sometimes the starch grains are found in some synergids and antipodal cells. No starch grains are found in the central cell.     

CAPSELLA EMBRYOGENESIS: THE SYNERGIDS BEFORE AND AFTER FERTILIZATION

The ultrastructure and composition of the synergids of Capsella bursa-pastoris were studied before and after fertilization. The synergids in the mature embryo sac contain numerous plastids, mitochondria, dictyosomes and masses of ER and associated ribosomes. Each synergid contains a large chalazal vacuole, a nucleus with a single nucleolus and is surrounded by a wall. This wall is thickest at the micropyle end of the cell where it proliferates into the filiform apparatus. At the chalazal end of the cell the wall thins and may be absent for small distances. The pollen tube grows into one of the two synergids through the filiform apparatus and extends one-third the length of the cell before it discharges. Following discharge of the pollen tube, mitochondria and plastids of the tube can be identified in the synergid as can hundreds of 0.5 μ polysaccharide spheres liberated by the tube. The method by which the sperm or sperm nuclei enter the egg or central cell is not known although an apparent rupture was found in the wall of the egg near the tip of the pollen tube. The second synergid changes at the time the pollen tube enters the first synergid. These changes result in the disorganization of the nucleus and loss of the chalazal wall and plasma membrane. Eventually this synergid loses its identity as its cytoplasm merges with that of the central cell.