用激光扫描共聚焦显微镜观察雪松花粉和花粉管

为更直观地观察和显示花粉和花粉管中细胞结构及其细胞核的状态与行为。雪松花粉和花粉管经卡诺液固定,分别以埃氏苏木精、曙红、Hoechst 33243单染和曙红-Hoechst 33342双染后,用冬青油整体透明,在激光扫描共聚焦显微镜下观察。4种染色法观察效果不同;以曙红-Hoechst 33342双染的样品观察效果最佳,在紫外光激发下清晰地显示出细胞核,在488 nm激光激发下不仅能清晰看到花粉和花粉管壁结构,且能分辨管细胞、柄细胞及体细胞的结构特点和空间位置关系。建立了一种快速简便的适于在激光扫描共聚焦显微镜下观察花粉和花粉管中成员细胞结构及其细胞核的状态、行为的制片技术;激光扫描共聚焦显微镜具有独特的共轭成像装置、连续光学扫描、图像三维重组和多通道检测等功能,极好地展示了雪松花粉和花粉管的结构特点,相比于传统的光学显微镜和荧光显微镜,其观察到的图像更清晰、更直观、更具立体感。     

激光扫描共聚焦显微镜（CLSM）法观察宁夏枸杞的胚珠发育

宁夏枸杞胚珠孚尔根染色后经透明用激光扫描共聚焦显微镜直接观察各发育时期胚珠内部结构。结果显示,用孚尔根染色后,枸杞大孢子发生和雌配子体发育的各个阶段都可在激光共聚焦显微镜下清楚呈现。此种方法克服了胚囊因深埋在胚珠体细胞组织中而难以观察的问题。与经典的切片方法相比,该法可对胚珠整体进行观察,操作简单、可在较短时间内大规模地检测胚囊发育状况。     

同源四倍体水稻受精与胚胎形成过程的观察

激光扫描共聚焦显微术具有“组织与细胞CT”的功能,可以对整体组织进行扫描并构建三维结构。在水稻胚囊发育研究上建立的整体染色透明激光扫描共聚焦显微术辅助D IC法,对同源四倍体水稻广陆矮4号-4x和L202-4x受精和胚胎发育过程进行了研究,描述授粉后不同时段胚囊发育的特点,发现同源四倍体水稻受精、胚胎和胚乳发育过程及特点与正常的二倍体水稻的基本一致,但在不同发育时段中存在无胚、无胚乳胚囊、胚乳吞噬胚、胚胎发育停滞、胚囊退化等异常。2份材料的异常情况存在差异。这些异常均可能导致结实率降低。     

共聚焦荧光镜检术揭示大蒜鳞片细胞间期核中的F肌动蛋白网络

采用免疫荧光和荧光分子探针技术与共聚焦激光扫描显微镜观察相结合,对大蒜（Ａｌｌｉｕｍ ｓａｔｉｖｕｍ Ｌ．）鳞片细胞间期核中是否存在Ｆ肌动蛋白进行了研究。结果表明,以兔抗肌动蛋折抗体为一抗、ＦＴＴＧ－羊抗兔ＩｇＧ抗体为二抗进行免疫荧光标记实验,在荧光镜下观察到蒜瓣薄壁组织的细胞核及表皮细胞核均发出明亮的黄绿色荧光经共聚焦激光扫描显微镜进一步检查,整个细胞核呈黄绿色荧光,说明其中含有肌动蛋白。经ＴＲ     

活体染色显微技术和绿色荧光蛋白在本科实验教学中的应用

激光扫描共聚焦显微镜的原理和使用是本科生细胞生物学实验教学中的重要内容。目前,在细胞生物学实验教学中常使用绿色新鲜的植物叶片作为实验材料,在激光扫描共聚焦显微镜下对叶绿体的自发荧光进行观察。叶绿体的自发荧光信号强而且范围广,使学生难以清晰地理解特异性的荧光信号。该文通过对转p35S::Naa10-GFP基因拟南芥幼苗的根尖进行活体染色[碘化丙啶(propidium iodide,PI)和4′,6-二脒基-2-苯基吲哚(4′,6-diamidino-2-phenylindole,DAPI)染色],在不同的激发光下,收集相应的荧光信号,通过计算机辅助成像,获得不同颜色叠加的特异荧光信号图像。该实验设计简单可行,获得的图像清晰且便于观察,能够使初学者直观并且深刻理解激光扫描共聚焦显微镜的原理和使用方法,适合在高校细胞生物学实验教学中推广,同时也为研究其他蛋白质亚细胞定位提供技术参考。     

水稻双胚苗无融合生殖胚胎学研究初报

将子房整体染色透明观察后,通过筛选材料石蜡切片的方法,研究发现水稻双胚苗品系APⅣ中,存在低频率的无融合生殖。开花前珠心细胞特化并分裂发育形成不定胚。随着珠心组织的退化,不定胚长八胚囊腔中,以球形胚形式存在。开花后4天,球形胚开始分化。球形胚在胚囊中可以和合子胚并存,也可以单独存在。但双胚主要来自受精的助细胞或合子胚纵裂。开花后3—4天,在胚乳腔中着色深的球状结构是胚乳部份脱落形成的,不是不定胚。珠孔端反足细胞团不能形成胚。     

组织透明技术在植物解剖学和植物发育生物学实验教学中的应用

整体组织透明和组织切片技术是研究植物组织和器官的结构及其发育过程的常用实验手段。该文针对本科生植物学课程的侧根、胚珠(特别是胚囊)以及胚胎发育内容设计了相应的实验教学课程。该实验以拟南芥幼苗、不同发育时期的花蕾和种子为材料,经固定、脱色和组织透明,利用正置显微镜观察侧根、胚珠以及胚胎的发育过程。根组织经透明后,在显微镜下可以清晰地观察到从侧根原基的建成到侧根发生的八个发育阶段。各个发育时期的胚珠经组织透明后,在显微镜下可以清晰地观察到大孢子母细胞、功能性大孢子(FG1期)以及FG2~FG7期的胚囊。各个发育时期的种子经透明后,在显微镜下可以清晰地观察到胚胎发育的1细胞期、8细胞期、球形期、心形期、鱼雷期、拐杖期和成熟期。这些实验结果可以使学生对拟南芥等双子叶植物的侧根、胚珠以及胚胎发育过程有较为系统的了解。该实验方法在其他较小的双子叶植物中也适用。     

共聚焦激光扫描对呼吸窘迫综合症大鼠肺组织的观察

目的：为了更直观地观察和显示呼吸窘迫综合症(acute respiratory distress syndrom,ARDS)典型的病理变化(肺泡内形成一层蛋白质透明膜)。方法：利用百草枯(Paraqual)染毒SD大鼠复制ARDS实验动物模型,取肺病理组织,切片,试剂Goat—Anti-Rat—FITC IgM IgG染色,共聚焦激光扫描显微镜(confocal laser scarming microscope,CLSM)观察。结果：CLSM能清晰到样品内不同层面的病理变化。结论：共聚焦激光扫描显微镜能清晰观察样品内不同层面的结构,相比于传统的光学显微镜,其观察到的图像更直观、更具立体感,能更好表达ARDS的病理变化特征。     

用共聚焦扫描显微镜检术观察水稻胚囊发育

介绍了一种快速简便观察分析水稻胚囊发育程序的方法。水稻子房经固定和脱水,用冬青油整体透明及丁香油封片,在共聚焦扫描显微镜检术下,发育中的胚囊产生自发荧光、可分辨出胚囊内部结构。ＦＡＡ和４％戊二醛两种固定液效果不同,后者效果较佳。     

激光共聚焦显微技术在植物学中的应用

激光扫描共聚焦显微镜（Ｌａ－ｓｅｒ　Ｓｃａｎｎｉｎｇ　Ｃｏｎｆｏｃａｌ　Ｍｉｃｒｏｓｃｏｐｅ,ＬＳＣＭ）是近年来发展起来的一种新型高精度显微镜,它在荧光显微镜成像基础上加装了激光扫描装置,使用可激发的荧光探针对样品进行标记,利用计算机进行图像采集处理,从而可得到样品内部细微结构的荧光图像。目前此种显微技术不仅用于观察经固定的各种细胞和组织结构,而且还可对活细胞的形态、结构,离子实时动态等进行观察和定量荧光测定,以及定量图像分析。另外,该仪器还具备样品断层扫描,三维图像重建的独特功能。因此,共聚焦…     

雾灵山草地早熟禾多胚囊和多胚现象的研究

无融合生殖是指未经精卵融合而产生后代的特殊生殖方式,它可以分为单倍体无融合生殖和二倍体无融合生殖;对于作物改良意义更大的是二倍体无融合生殖。多胚囊和多胚现象SHI是无融合生殖的表现形式。本文运用石蜡切片法、子房整体透明法研究了雾灵山草地早熟禾〖WTBX〗（Poa pratensis〖WTBZ〗 L.）多胚囊和多胚现象。结果表明,（1）草地早熟禾多胚囊来源有两种：一是来自大孢子母细胞,二是来自珠心细胞;（2）草地早熟禾多胚来源有四个：其一是有性生殖胚,其二是孤雌生殖胚,其三是无配子生殖胚,其四是珠心胚。     

The kinetics of cytological events during double fertilization in Zea mays L.

By using a clearing method, the process of double fertilization in Zea mays L. (line A 188) was analysed and the precise sequence of events was determined. The period from pollen tube arrival to gamete fusion was relatively short, possibly less than 1 h. The karyogamy was of premitotic type, and the time from the contact of male and female nuclei to the fusion of male and female nucleoli was about 5 h in the egg cell and 3 h in the central cell. In the central cell, the sperm nucleus fused with either one of the polar nuclei or the secondary nucleus, the latter being observed for the first time in maize. The zygote was in the resting period for 13–16 h before division commenced, changing the cell polarity during karyogamy and the resting period. The primary endosperm nucleus divided immediately after karyogamy was completed in the central cell. The embryo sacs with two-celled proembryos contained four to eight endosperm nuclei. The timetable of fertilization events could be a standard for further studies on in vitro fertilization at the cytological and molecular levels.     

Invvestigations on Early Embryogenesis of Actinidia chinensis Planch var. chinensis

This paper deals with early embryogenesis of Actinidia chinensis var. chinensis. 1. Ovary superior consists of 34—45 carpels. Each carpel contains 11–45 ovules. The ovule is uni-integument and tenuinucellar. The ovule is anatropous. The archesporium is formed by a single cell, and directly develops into megaspore mother cell. Sometimes the archesporium consists of 2–3 cells, but only one of them develops into megaspore mother cell and the others are degenerated. 2. The mature pollen grain is two-celled and the embryo sac belongs to olygonum type. In most embryo sacs two polar nuclei are fused before fertilization. One of the synergids was destroyed as the pollen tube penetrated into embryo sac the other one disappeared after fertilization. In most cases the antipodal cells became degenerated in fertilization process, only some remained until the first division of primary endosperm nucleus. 3. In Beijing area the double fertilization of Actinidia chinensis occurred 30–72 hours after pollination. In the fertilization one sperm fused with egg nucleus and the other sperm fused with the secondary nucleus as usual. The fusion of the secondary nucleus with sperm was in advance of the fusion of the egg nudeus. 4. The endosperm is cellular type.     

An embryological study ofPlatanthera bifolia (Orchidaceae)

Flowers ofPlatanthera bifolia were hand-pollinated and fixed in FPA₅₀ after 2, 5, 7, 14, and 21 days. Ovules, made transparent in Herr's clearing fluid, were investigated using confocal scanning laser microscopy. Pollination initiates the megasporogenesis. Two days after pollination dyads are frequent. Three days later most embryo sacs contain two nuclei. Seven days after pollination the embryo sacs are 4–8-nucleate and some are organized, and a week later all embryo sacs are organized and fertilization takes place. The embryo sac development follows thePolygonum type. Twenty-one days after pollination the egg nuclei have been fertilized and the embryo sacs contain 2- to many-celled embryos. A suspensor is formed during early stages of embryo development but degenerates later. Fertilization of the central nucleus does not lead to endosperm development.     

Isolation of embryo sacs from Dianthus ovules by enzymatic treatments and microdissection

 Mature ovules of Dianthus (Caryophyllaceae) were histologically observed by clearing and serial sectioning to characterize the cells of the embryo sac. The results show that the mature embryo sac was located deep inside the hemitropous ovule due to thick nucellar tissue at the micropylar region. For the isolation of the embryo sacs, ovules were collected from ovaries of flowers 1 day after anthesis, and treated with an enzyme solution for digesting cell walls on a gyratory shaker. After 12 h of enzyme treatment, these ovules were dissected using a glass needle under an inverted microscope to release the embryo sacs. The embryo sacs, characterized by their specific size, were successfully released by these successive treatments. The viability of the embryo sacs was more than 80% as assessed with fluorescein diacetate staining. Fluorescent staining with 4,6-diamidino-2-phenylindole revealed the nuclei of the egg apparatus in the isolated embryo sacs. The procedure for isolating embryo sacs established in this study will offer a new approach to further in vitro studies on fertilization in Dianthus. Received: 20 January 1999 / Revision received: 12 July 1999 / Accepted: 17 August 1999     

The Development of Gynoecium after Anthesis and Fertilization in Eleutherococcus senticosus (Araliaceae)

The development status of gynoecia in Eleutherococcus senticosus flowers is different from that in ordinary plants. Female gametophytes of E. senticosus have not become mature until the 6th day after anthesis. On the 6th day, 82.25% of embryo sacs in female plants, and 67.25％ of those in hermaphroditic plants become mature, while the rest are sterile, immature or degenerated with no fertilized embryo sacs observed. At the same time, all embryo sacs degenerated and flowers withered in male plants. On the 7th day, a few embryo sacs in female and hermaphroditic plants start being fertilized. Accompanying the differentiation of embryo sacs, styles of female and hermaphroditic flowers start to expand and their nectaries become mature gradually. After the 4th or 6th day of anthesis, stigmatic papillae become conspicious and stigmata become white and open. In the meantime, the stigmata become receptive and the nectaries get active or reactive. By the 9th or 10th day, 40～65 ％ of embryo sacs in female plants and 25～41% of those in hermaphroditic plants have been fertilized. The whole process of fertilization in E. senticosus was observed. About 2 or 3 days after pollination, the two sperm nuclei start to fuse with the egg and the secondary nucleus. The fertilization of E. senticosus belongs to the premitotic type of syngamy. The essential process of the fusion of male and female nuclei during syngamy may be generalized as follows: (1) the contacting of male nucleus with the female one; (2) the fusion of nuclear membranes between the male and female nuclei; (3) the despiralization of male spireme and the appearance of male nucleolus inside the fertilized female nucleus; (4) the dispersion of male chromatin and the mergence with the female chromatin, which is the sign of completion of the fusion of the two nuclei. In addition, degeneration types of mature embryo sacs were observed. And typical polyspermy and a series of cases in which extra sperms enter the em-bryo sac are recorded.     

Polar distribution dynamics of Con A binding sites in embryo sacs is temporally coupled by the fertilization process

The binding site distribution of concanavalin agglutinin (Con A) and wheat germ agglutinin (WGA) on embryo sacs at various developmental stages of Torenia fournieri L was studied by using a cooled Charge Coupled Device (CCD) and fluorescent Con A and WGA probes. The distribution patterns of Con A and WGA binding sites on embryo sacs changed during the fertilization process. The fluorescent signal indicating Con A binding sites was distributed evenly on the surface of the embryo sac wall before anthesis, was much denser on the micropylar end of the embryo sac wall and looked like a corona on the day of anthesis. After pollination, stronger fluorescence was present on the micropylar end of the embryo sac wall and the filiform apparatus (FA), showing an obvious polar distribution. When the pollen tube entered the embryo sac and reached a synergid, the fluorescence was still concentrated on the micropylar end and FA, and started to appear on the synergid. After fertilization, the polar distribution of the fluorescence gradually disappeared and an even distribution pattern was observed again on the embryo sac wall. These results revealed that the dynamic distribution of Con A binding sites was temporally coupled with the process of fertilization. WGA binding site distribution on the embryo sac was also investigated and showed a simple pattern but also regularly changed during the process of fertilization. The variation of these lectin binding sites during the fertilization process suggests that lectin binding site interactions may play a role in the process.     

四种显微技术观测大鼠颌下腺细胞与丝素-壳聚糖体外共培养的形态学特点

目的采用倒置显微镜、扫描电镜（scanning electron microscopy,SEM）、荧光显微镜和激光共聚焦显微镜（（laser scanning confocal microscopy,LSCM））技术对大鼠颌下腺细胞（rat submandibular gland cells,RSMGs）与丝素-壳聚糖（silk fibroin-chitosan,SFCs）的体外复合培养进行形态学观察。为观测、评估种子细胞在三维支架的内部生长情况提供技术支持。方法取0～8 d龄SD大鼠的颌下腺,对大鼠颌下腺细胞进行原代培养、分离纯化并传代;用抗细胞角蛋白单克隆抗体（CK8）及淀粉酶抗体的免疫细胞化学染色鉴定细胞来源。选取传至第二代的对数生长期的RSMGs作为种子细胞,选取SFCs共混膜（5×5×2）mm作为支架材料构建组织工程化涎腺样结构。将种子细胞与支架材料复合培养并分别于倒置显微镜、SEM、荧光显微镜和LSCM下观察二者复合生长情况。结果倒置显微镜可以直接观察活细胞与支架复合生长情况,方法简单易行。SEM可以较精确的展示细胞支架复合生长的表面超微结构。经过荧光染料的着色,荧光显微镜和LSCM都可以观察到支架上锚定的种子细胞。荧光显微镜可见细胞核的荧光信号均匀的分布在支架孔隙内。LSCM通过层扫描及三维重建技术对较厚的标本获取图像;并可以通过旋转图像,从不同角度观察细胞支架复合物的三维剖面或整体结构,得到更为准确的定位信息。结论四种显微技术均可应用于RSMGs与SFCs体外共培养的形态学观测。LSCM的三维重建技术结合荧光染料标记可以较好地获得RSMGs与SFCs复合生长的情况,有着较广泛的应用价值。     

Cytological Studies on the Embryogenesis of Hybrids between Oryza sativa L.(Pennisetum sp.

(1) The pollen grains of Pennisetum can germinate normally on the stigma of rice and the pollen tubes can grow into the style and enter the embryo sacs. However, the process of double fertilization is slow and more or less abnormal and phenomenon of simple fertilization often occurs. (2) It has been found that in the majority of cases the development of the embryos is slow and stays long in the stage of globular embryos, thus, the differentiation of the embryos is very difficult and degeneration of the embryos appears many times. Simple differentiation was observed only in some embryos during 16–24 days after pollination. Normal differenting and developing embryos were not observed. The cause of the degeneration of the embryos is related to the state of endosperm development and also to the non-coordination of the genomes of both parents. (3) The development of the endosperm is abnormal. The change from the free nuclei into the cells in the endosperm is delayed as late as the 8th day after pollination. The whole endosperm tissue is composed of the cell masses which are quite different both in shape and function, a part of these endospemn cells lacks the ability to synthesize starch. The disintegration of the endosperm could be frequently observed during their development. (4) A lots of starch are accumulated in the nucellar cells near the antipodals, It is shown that there was some metabolic confusion resulted from the crossing in the embryo sacs. Based on the above mentioued results the authers consider that the failure of producing seeds by crossing is at least related to the nutrient condition which are essential for the development of embryos. If embryo culture technique is employed at the early stage of the embryo development the hybrid seeds could be obtained.