金鱼草胚囊的人工分离

用果胶酶与纤维素酶的混合液离解金鱼草的胚珠,从中分离出完整的胚囊。由固定材料分离的胚囊,经透明染色后可借助干涉差显微装置观察由受精前直至受精后具上百个胚乳细胞时期的胚囊的内部结构。由新鲜胚珠分离胚囊也已初步突破,并对其作了简易的显微化学观察。讨论了活胚囊分离的意义与胚囊离体培养的前景。     

颠茄胚囊细胞原生质体的酶法分离和观察

分离被子植物雌配子原生质体对发展植物受精工程有着重要意义。最近几年,虽然用酶法分离生活的胚囊已有一些成功的报道。但对分离组成胚囊细胞的原生质体前人还没有进行过尝试。1984年我们首次从烟草生活胚珠中分离出卵细胞、中央细胞、助细胞和反足细胞的原生质体。最近我们又用颠茄胚珠为材料,采用酶解压片技术进行分离胚囊细胞的原生质体,也取得预期的结果。获得了有活性的卵细胞、中央细胞和助细胞的原生质体。从而证明这项技术是有推广应用价值的。在观察中发现用酶法分离生活胚囊细胞的原生质体,能     

一种新型的DNA荧光染料-DAPI的光学特性及其应用

近年来,由于荧光显微镜的改进,荧光染料的不断增多以及免疫荧光技术的发展,荧光显微术已在细胞生物学的研究中广泛应用。荧光显微术用于研究细胞核和染色体已有较长的历史,不过目前除了哺乳类染色体分带荧光技术和孚尔根型荧光染色有所发展外,曾经使用过的一些核的荧光染色方法已应用不多。最近,一种新型的DNA荧光染     

水稻双受精过程的共聚焦显微镜观察

(郑州大学离子束生物工程省重点实验室,郑州450052)摘要:首次利用核特异荧光染色与整体透明技术并利用激光扫描共聚焦显微镜(LSCM)对水稻双受精过程进行了观察。激光扫描共聚焦显微镜具有"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。经荧光染色及透明处理后,在激光扫描共聚焦显微镜下经488nm激光激发,胚囊内各细胞的细胞核以及核仁发出明亮荧光,细胞核轮廓比较清晰,层次感强,并能清晰观察到胚囊内各细胞的结构特点和空间位置关系。不论是对开花前较小的成熟胚囊材料还是开花后较大的胚囊材料都取得了较好的观察效果。同传统的光学显微镜和荧光显微镜相比,其观察到的图像更清晰、更直观、更具立体感。     

一种新型的DNA荧光染料—DAPI的光学特性及其应用

近年来,由于荧光显微镜的改进,荧光染料的不断增多以及免疫荧光技术的发展,荧光显微术已在细胞生物学的研究中广泛应用。荧光显微术用于研究细胞核和染色体已有较长的历史,不过目前除了哺乳类染色体分带荧光技术和孚尔根型荧光染色有所发展外,曾经使用过的一些核的荧光染色方法已应用不多。     

用显微荧光术定量蚕豆染色体DNA

本文的目的在于探索一个简便而准确地测定单个染色体DNA含量的方法。作者选用蚕豆(Vicia faba,2n=12)根尖细胞做材料。第一步用Feulgen染色及显微吸收光度术测得该品种二倍体胞核DNA含量力36.15皮克(微微克,第二步用DNA特异性荧光染料——DAPI标记该细胞的染色体,然后在UNIVAR显微荧光计上测量各条染色体的荧光强度。经简单换算和统计学处理求得六对染色体DNA分布:9.27、5.03、4.71、4.47、4.26、3.91皮克(微微克)。     

植物病原真菌细胞核和隔膜的双重荧光染色技术

<正> 近年来的研究证实,真菌细胞核的荧光染色是一程序简便、快速而准确的染色技术。作者(1993)在应用荧光染料4,6-Diamidion-2-phemylindol(DAPI)和Hoechest 33258对植物病原真菌的染色中,虽然菌丝细胞核明显可辩,但不能观察到菌丝隔膜,因而无法统计每一菌丝细胞中的核数目。     

几种植物生活胚囊的分离与鉴定

向日葵、金鱼草和烟草的成熟胚囊以及前两种植物受精后具原胚和胚乳的胚囊均已从新鲜胚珠中分离出来。干涉差显微观察与 H33258荧光显微技术表明它们确系保持了细胞结构和含有丰富内含物的完整胚囊。荧光素二醋酸酯的显微鉴定进一步证明它们是有生活力的。     

利用激光扫描共聚焦显微术对同源四倍体水稻胚囊形成与发育的进一步观察

应用改进的整体染色透明激光扫描共聚焦显微术(WCLSM),对同源四倍体水稻PDER-2B-4x胚囊的形成与发育过程进行观察。发现其胚囊的形成发育过程与二倍体的一致,可以清楚地划分为8个发育时期,即孢原细胞形成期、大孢子母细胞形成期、大孢子母细胞减数分裂期、功能大孢子形成期、单核胚囊形成期、胚囊有丝分裂期、八核胚囊发育期和成熟胚囊期。除正常发育的过程外,大孢子发育的各个过程均出现一些异常现象,包括:细胞退化、核位置异常、核数目异常和细胞分化异常等。这些异常可能最终导致多种结构异常成熟胚囊的形成。     

洋葱卵细胞的分离

将洋葱的胚珠置于酶液中酶解50~110 min后剥去其珠被,可清楚地看到珠心中的胚囊轮廓。用解剖针将珠心从中部横切,然后挤压其珠孔部位,卵器细胞从胚珠的切口处逸出。再用显微操作仪的玻璃针将卵细胞和两个助细胞分开,达到分离洋葱卵细胞的目的。酶对分离卵细胞具有重要作用,在最佳的酶液浓度[0.02%果胶酶Y23、0.08%果胶酶(Serva)、0.05%纤维素酶和0.05%半纤维素酶]下酶解胚珠110 min后,解剖1 h可从24个胚珠中分离出10个卵细胞(41.67%)。随着胚囊的发育,两个助细胞的体积出现明显的二形性。洋葱生活卵细胞的分离为开展洋葱离体受精建立了基础,也为研究洋葱卵器细胞的发育创造了条件。     

A New Method for Embryo Sac Isolation and In Situ Fusion of Egg and Synergid Protoplasts in Nicotiana tabacurn

A new method combining enzymatic maceration with osmotic shock was developed for isolation of living embryo sac and its protoplasts in Nicotiana tabacum L. The principle of this method was that the ovules submitted to enzymatic treatment and osmotic shock could release embryo sacs along with some internal ovular cells through either the funicle cut end or the micropyle. Factors affecting embryo sac isolation were investigated, including concentration of mannitol as a shock osmoticum and in enzymesolution ,duration of enzymatic maceration,and duration of osmotic shock. As a result a procedure was established: Ovules at mature embryo sac stage were macerated for 2. S h in 1 %–1.5% cellulase R-10 and 0. 5% macerozyme R-10 (or 1% Pectinase,Serva) dissolved in 13% mannitol solution using microshaker,followed by osmotic shock for 15–30 min with enzyme free 8% mannitol solution and gentle agitation using a pipette. Using a capillary,50–70 embryo sacs could be collected manually in one hour. The embryo sacs thus isolated could be kept viable from which protoplasts of egg cell and other componcnt cells could be further isolated. An additional interesting phenomenon was that osmotic shock often caused in situ fusion the protoplasts of egg cell and synergids. The rate of fusion ranging 9%—71.9% could be controlled by modification of the procedure. This phenomenon merits further attention both from basic and practical point of view. The present method gives the advantages of faciliting isolation and promoting good harvest of viable embryo sacs/female protoplasts within a relative short time.     

Isolation and preservation of the living embryo sac ofCrinum asiaticum L. var.japonicum baker

The enzymatic maceration method was used to isolate an intact embryo sac ofCrinum asiaticum and its component cells. Best results were obtained when using enzyme solutions that contained pectinase hemicellulase, cellulase and pectolyase. Aseptic ovules were incubated in the enzyme solution for 1.5 hr at 25 C. This allowed the isolation of embryo sacs to yield up to 20% of the amount present. An isolated embryo sac usually consists of an egg cell, synergids, antipodals and a central cell. Some embryo sacs can be digested as gametophytic protoplast. The size, shape and position of the isolated embryo sac seemingly possessed similarities with those of the fixed embryo sac in the ovary. An isolated embryo sac can be in a living state when the result of the fluorochromatic reaction (FCR) and protoplasmic streaming is positive. When cultured in proper media, 68% of the isolated gametophytic protoplasts were observed to have sustained their positive FCR for more than 1 month.     

Isolation of the lily embryo sac

Summary A 5%–8% yield of isolated embryo sacs of Lilium longiflorum was obtained using an enzymatic isolation procedure. The best results were obtained with a maceration mixture containing mannitol, pectinase, pectolyase, cellulase, hemicellulase, CaCl₂ and NaOH. All developmental stages of the female gametophyte can be isolated in the living condition, although fewer than expected mature stages were observed. Moreover, only some of the more mature embryo sacs showed a positive fluorochromatic reaction (FCR) at the time of liberation. When the embryo sacs were stored in the enzyme or sugar solution after isolation, the positive reaction rapidly diminished for all stages. The isolated embryo sac and its nuclei were similar in size, shape, and position to the in situ embryo sac. Light microscopical observations of sectioned material revealed an intact cellular structure. However, the deleterious effects of the enzyme solution were sometimes observed in the form of lipid-like accumulations inside the isolated embryo sac.In collaboration with: Reconnaissance Cellulaire et Amélioration des Plantes, Université Cl. Bernard-Lyon I; INRA 879, 43, Boulevard du 11 Novembre 1918, F-69622 Villeurbanne Cedex, France     

Isolation of Viable Embryo Sacs and Their Protoplasts of Nicotiana tabacum

Isolation of fixed and fresh embryo sacs has been reported. However,the isolation of protoplasts of embryo sac elements is reported here for the first time.The protoplasts of egg cell, synergids, central cell and antipodal cells have been isolated with the retaining of their viability. Though this is a preliminary work, it indicatesthe potentiality of isolation of naked female gametes of angiosperms, which may beused in genetic manipulation and plant biotechnology. Nicotiana tabacum was grown in the greenhouse of the Department of Biology,Peking University. From opened and unpollinated flowers, the ovaries were removedand sterilized with 70% alcohol. The ovules were dissected out from those ovaries andfollowed by incubation (4–8 hrs. 28℃) in anenzyme solution containing 2% driselase, 0.65 M mannitol and 0.25% potassium dextran sulfate. Ovules from 3 4 ovariescould be incubated with 1 ml of enzyme solution in a 3 cm petri dish. All these manipulations and the following procedures were carried out under sterile conditions. Afterincubation, ovules were washed 3 times with a washing solution of 0.65 M mannitol.The isolated embryo, sacs and their protoplasts were obtained by gently squashing digested ovules in a small volume of washing solution on a slide. When the fresh ovules were incubated 3–3.5 hrs in the enzyme solution, the embryosacs may be successfully isolated in an intact manner, either for mature or immatureembryo sacs. The isolated embryo sac looked plump, viable and very distinct in itsstructure. If the isolated embryo sacs were incubated in 0.01% fluorescein diacetate(FDA) used as a test for the viability of the embryo sac, and observed under fluorescein microscope, the cytoplasm of all embryo sac elements, including egg cell, synergids,central cell and antipodal cells, showed strong fluorescence. It is proved that these iso-lated embryo sacs are still viable. When the incubation of ovules was prolonged as to 8 hrs in certain cases, theboundary wall of the embryo sac may be partially digested and the protoplasts of embryo sac elements came out from micropylar or chalazal end after squashing. The difference of the protoplasts derived from different embryo sac elements could be recognized by their relative size and other characteristics. The egg protoplast is smallerthan that of the synergid. However, the protoplasts of antipodal cells were. obviouslysmaller than that of egg. But the central cell protoplast was the largest among theseprotoplasts and possessed two polar nuclei and a very large central vacuole. All theseisolated protoplasts of embryo sac elements were also proved viable with FDA method. The importance of isolated protoplasts of embryo sac elements is discussed withrespect to genetic manipulations.     

Deleterious effect of minimal enzymatic treatments on the development of isolated maize embryo sacs in culture

The long-term viability of isolated embryo sacs was studied in maize. Fertilised embryo sacs were digested in order to remove most of the nucellus cells present on their surfaces and then transferred to culture. Experiments on 161 embryo sacs showed that isolation treatments using even minimal enzymatic digestion affected the further development of the embryo sacs. Few embryo sacs survived in culture and those produced only abnormal embryos; they produced no plants. We concluded that embryo sacs isolated through enzymatic digestion may offer limited prospects for long-term studies where normal embryogenic development is required. Alternative strategies are discussed for maize.     

Prolongation of Embryo Sac Viability in Pear (Pyrus communis) Following Pollination or Treatment with Gibberellic Acid

Embryo sac development has been investigated in unpollinated,cross pollinated and gibberellic acid (GA₂) treated flowersof Pyrus communis L. While pollination and GA₃ treatments donot alter embryo sac development, they prolong embryo sac viability.In untreated unpollinated flowers, ovules degenerate between12 and 21 d after anthesis, while in cross pollinated and GA₃treated flowers this degeneration is postponed by about 10 d.Thus, in a cross pollinated flower this extends the period overwhich a successful fertilization can take place. This increasedperiod of viability is accompanied by an elongation of the embryosac itself. Elongation takes place two weeks prior to fertilizationin cross pollinated flowers. The extension of life span of embryo sacs following pollinationand treatment with gibberellic acid indicates that a stimulusinduced by ‘pollination’ could be mediated by GA₃Whatever its mechanism of operation, the prolongation of embryosac viability by pollination represents a selective advantage,in that the period at which the ovules are receptive to fertilizationmust be significantly extended. Embryo sac, gibberellic acid, Pyrus communis, pear, pollination     

Anatomy of Watermelon Embryo Sacs Following Pollination, Non-pollination or Parthenocarpic Induction of Fruit Development

There is little information on the fate of embryo sacs in plantovules if pollination is prevented. In this study embryo sacsfrom watermelon were observed over a 13 day period followingflowering with (a) normal pollination, (b) non-pollination and(c) induction of parthenocarpic fruit development with naphthaleneacetic acid. Following pollination, and prior to fertilizationapproximately 2 days later, the embryo sacs completed developmentand consisted of two synergids with prominent filiform apparatus,an egg cell, a central cell with two polar nuclei and threeantipodal cells. Sperm nuclei were observed within the embryosac at 2 days and by 4 days the endosperm was proliferating.In the non-pollination treatment the embryo sac was still intactafter 4 days although the antipodal nuclei were becoming hardto distinguish. By 7 days only the two synergids and the eggcell were still well defined, the polar nuclei appeared in somepreparations to be fused, and the antipodals had degenerated.By 10 days the embryo sac was a structure-less watery mass.In parthenocarpic fruit the fate of the embryo sac was similarto that in non-pollinated fruit except that final breakdownwas delayed past 10 days. Maturity of the majority of embryo sacs in an ovary appearedto be contemporaneous with penetration of the pollen tube, andon the basis of the anatomical results it seems possible thatembryo sacs could be fertilized up to 2 days beyond the normaltime. Citrullus lanatus, watermelon, embryo sac, anatomy, pollination, parthenocarpy     

Isolation of Embryo Sac with the Enzyme-Squash Technique

The enzyme-squash technique is especially suited for studying the development of megaspores and embryo sacs in angiosperms. Ovulles are fixed in FPA, FAA or Carnoy's for 2–24 hrs. After passing through a series of alcohol and distilled water, they are treated in an aqueous solution of 2% Driselase. for 3-6 hrs. at 28℃. Ovules are then transferred with a drop of laeto-phenol-glycerin fluid to a slide, covered with a cover glass. By the aid of gently tapping and pressing the cover glass, as that of ordinary squash method, cells of ovules are separated and the megaspores or embryo sacs are isolated, and then examined with phase contrast optics With this technique we have successfully isolated the megaspores and embryo sacs in different developmental stages from fixed ovules of several plant species, including Atropa belladonha, Vanilla fragrans, Belamcanda chinensis, Platycodon grandifIorus and Oenothera odorata. The rosults of the experiments indicate that this technique for isolation of embryo sac has several advantages it is suitable both in tenuinucellate and crassinucellate ovules the manipulation of this technique is rather simple and the special instruments are net required the difficulties of the separation of the embryo sac from its nucellar epidermis or tissues of the chalazal end can be overcome by this method. The initial results of isolation of vital embryo sacs from living ovules has been gotten with this technique.     

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     

蓝猪耳卵细胞和合子的分离

蓝猪耳(Torenia fournieri)胚囊部分裸露出胚珠,在光学显微镜下能清楚观察到卵细胞和助细胞的形态结构.用解剖和酶解-解剖两种方法都能分离出生活卵细胞.用前种方法机械分离出的卵细胞数量较少(5%),但避免了酶对配子识别研究的干扰.在后种方法中加入0.1%纤维素酶和0.1%果胶酶既能使分离更加容易操作,又对卵细胞没有致命伤害,能在短时间内分离出较多的卵细胞(18%).用酶解-解剖方法也可分离出授粉14 h后的合子细胞.