甘蓝型油菜小孢子胚状体发生的细胞学观察

应用甘蓝型油菜ＤＨ系保６０４为材料研究小孢子胚发生过程,结果表明,在小孢子离体培养１～５ｄ内,随培养天数增加,小孢子的存活率迅速下降,部分小孢子培养后出现细胞膨大和分裂,并沿２－细胞。“ｆ”形３细胞,多细胞原体,胚柄球形胚,心形胚最终发育成鱼雷形胚,一般在心形胚阶段,胚柄脱离胚主体部分游离到培养基中,大多数膨大的细胞不能分裂或分裂后停止发育或发育异常。     

短柄五加胚和胚乳发育的研究

短柄五加胚发育属茄型,棒形胚后期胚柄最为发达,球形胚胚柄开始退化,心形胚期胚柄解体。胚乳发育属核型,当胚乳游离核为２００￣３００个时,以自由生长细胞壁的方式进行胚乳细胞化。胚乳细胞进一步增殖以有丝分裂方式进行,球形胚时,胚乳细胞最外层细胞特化为分泌层,胚乳细胞贮藏蛋白质和脂类物质。在胚乳游离核为３２￣６４个时,单珠被的内表皮层分化为珠被绒毡层。合子分裂后,珠被绒毡层发育最为充分;棒形胚后期,珠被绒     

茌梨的胚胎发育和开花结实的相关性研究

茌梨的花药以造孢组织越冬。第二年春,花芽萌动时形成小孢子母细胞。小孢子的发生为同时型。成熟花粉粒为2细胞型。4月初,珠心顶端第三层细胞中的造孢细胞发育为大孢子母细胞,属厚珠心型。胚囊发育属蓼型。胚发育始于4月下旬,受精卵进行横分裂,后经棒状原胚、球形原胚、心形胚和鱼雷形胚,至7月中旬幼胚逐渐成熟。胚的发育属藜型。胚乳发生为核型。茌梨大小孢子的发生和雌雄配子体的形成与花芽、花外形标志之间,有较稳定的相关性。胚和胚乳的发育与果实的生长有一定的相关性。     

辣椒花药培养胚状体发生的组织学和细胞学研究

采用荧光显微镜、扫描电镜和透射电镜技术．系统研究了辣椒花药培养胚状体发生的组织学和细胞学变化特征。辣椒单个花药中花粉发育具有强烈的不同步性。随着培养时期的变化．不同时期花粉的百分率也发生变化。处于单核靠边期的小孢子培养以后按两种发育途径之一进行发育。在多数情况下,孢子体不对称分裂,产生典型双核花粉。胚性花粉粒是由营养核的重复分裂形成的。当小孢子从四分体中释放出来．特殊类型的外壁已经形成。在随后的花粉发育过程中．小孢子体积增大,外壁继续加厚。培养24h后,小孢子体积增大。胚性发生的小孢子表现出两种不同的形态变化。当胚状体发育到心形胚时．胚状体的表皮细胞排列规则。用光学和电子显微镜分析了小孢子胚状体形态形成过程．及胚状体诱导后细胞组织发生的一系列结构变化的时序性特征,这些变化主要影响质体、液泡室、细胞壁和细胞核,进一步分化的程序模拟合子胚的发育。     

茴香组织培养中体细胞胚胎发生的组织细胞学研究

将茴香幼茎或叶柄的愈伤组织转入附加6-BA和低浓度2,4-D的MS培养基以后,愈伤组织逐步由松软状转变成为颗粒状的胚性愈伤组织,胚状体起源于胚性愈伤组织中的单个细胞或胚性细胞团。在含NAA和6-BA的培养基中,胚状体发育成熟,并再生小植株。茴香的胚状体主要以单细胞内起源方式发生。首先由胚状体单个原始细胞分裂形成2-细胞原胚,2-细胞原胚以三种方式进行分裂:1.T- 形分裂;2.直线形分裂;3.田字形分裂。不同的分裂方式决定了胚柄的有无。茴香胚状体的发育过程与合子胚基本相同。由原胚发育成为球形胚,依次经过心形胚和鱼雷胚阶段,形成成熟的子叶胚。在胚状体发育的每一个阶段,都有其分生组织的活动中心。球形胚期,两团分生组织位于胚体中部对应的两点;心形胚期,位于两侧和中部;鱼雷胚期,分生组织的分布在子叶形成区域呈倒“U”形,在下胚轴部位呈中空的梭形。到子叶期,分生组织从两片子叶伸向胚根,呈“Y”形分布。两子叶间产生茎生长点,由生长点分化出叶原基。胚状体最终发育成为完整植株。     

白杄体细胞胚胎发生的细胞组织学和淀粉积累动态的研究

以白木千（ＰｉｃｅａｍｅｙｅｒｉＲｅｈｄ．ｅｔＷｉｌｓ．）的成熟种胚为外植体,诱导体细胞胚胎发生。整体染色封片和组织切片的观察结果表明,白木千体细胞胚起源于胚性愈伤组织的单个细胞。胚性细胞经过一次不均等分裂产生两个细胞,即胚细胞和胚柄细胞。然后依次经过胚性胚柄团、球形胚、心形胚及鱼雷形胚阶段,最后发育成具有子叶的成熟胚。通过ＰＡＳ反应研究后发现,在体细胞胚发育过程中,淀粉粒在胚性胚柄团时期开始积累,至心形胚时期达到积累高峰,且淀粉粒的分布主要集中于胚柄细胞、分裂旺盛的胚细胞、器官原基及其附近细胞。据此结果推测淀粉的消长与体细胞胚发生的能量供应有关。     

柽柳胚和胚乳发育的观察

利用常规石蜡制片技术,对柽柳（Tamarix chinensis Lour.）胚和胚乳的发育过程进行了观察。结果表明,胚发育属茄型,其基细胞先行纵裂。胚柄基部发育迅速,具吸器作用,球形胚期胚柄最为发达,其细胞质丰富,贮藏淀粉类物质,至晚心形胚期胚柄依然存在。助细胞被受精产生多胚现象。胚乳发育属核型,初生胚乳核常常晚于合子分裂,胚乳核的分裂速度慢于胚体细胞的分裂速度。当胚乳游离核为 32个时,以自由生长细胞壁的方式进行胚乳细胞化。胚乳细胞进一步增殖极少。珠心细胞只有两层,细胞核大,胞质丰富,内含贮藏物质,至心形胚期逐渐解体。     

白Qian体细胞胚胎发生的细胞组织学和淀粉积累动态的研究

以白Ｑｉａｎ的成熟种胚为外植体,诱导体细胞胚胎发生。整体染色封片和组织切片的观察结果表明,白Ｑｉａｎ体细胞胚起源于胚性愈伤组织的单个细胞。胚性细胞经过一次不均等分裂产生两个细胞,即胚细胞和胚柄细胞。然后依次经过胚性胚柄团、球形胚、心形胚及鱼雷形胚阶段,最后发育成具有子叶的成熟胚。通过ＰＡＳ反应研究后发现,在体细胞胚发育过程中,淀粉粒在胚性胚柄团时期开始积累,至心形胚时期达到积累高峰,且淀粉粒的分布     

初始培养条件对定兴芥小孢子胚胎发生的影响

本文探索了油菜花药培养中小孢子胚早期发育的适宜条件。花药分步悬浮法第一培养基的简化实验表明,小孢子胚在仅含有20%蔗糖的空白培养基上的诱导率(212%)与对照的(202%)无显著差异。这样,第一培养基便从原Keller培养基简化为不含大量、微量和有机元素而仅含有20%蔗糖的水溶液,并且,花药第一阶段的培养时间从原来的3—5天减少到1.5—2天。此外,研究了花药在蔗糖水溶液上的滞留时间对小孢子胚胎早期发育的影响。滞留36～48小时,小孢子胚的诱导率(135%)最佳。考察小孢子胚胎早期发育的状况与不同滞留时间的关系则发现,36—48小时内每100个活细胞里,膨大细胞约占70%。这表明,早期培养时,花粉只要膨大而不需分裂即可转入第二阶段培养,便可获得较高产率的胚状体。     

问题解答

问:“原胚”是指植物胚胎发育过程中的哪个时期? 答:在植物胚胎发育过程中,合子先横裂一次形成顶端细胞和基细胞。一般基细胞发育成胚柄,在胚胎发育成熟时已经退化消失;由顶端细胞发育成胚的本体。顶端细胞经多次分裂形成一团细胞,随后由于平周分裂有了表皮原和基本分生组织的分化,此时胚体呈圆球形,称为球形胚时期。后来由于胚体上半部两侧的细胞分裂较快,形成两个小突起,为子叶原基,使胚体呈心脏形,称为心形胚时期(指双子叶植物)。随着胚器官发育的完成,形成成熟的胚。在子叶原基出现以前,从顶端细胞分裂到球形胚时期都可称为胚胎发育的“原胚”阶段。     

Evidence for microspore embryogenesis in wheat anther culture

Summary In wheat, plants may be regenerated from microspores via direct embryogenesis or organogenesis or embryogenesis from callus. Light and scanning electron microscopy were used to carefully study morphogenesis of microspore-derived plants from anther culture on modified 85D12 starch medium and to determine whether the plants were formed via organogenesis or embryogenesis. Our results indicate that plants are formed via embryogenesis from microspores. Evidence for embryogenesis included the formation of the epidermis and a suspensorlike structure (21 days after culture), followed by initiation of an apical meristem, differentiation of the scutellum, and embryo elongation. At 28 days in culture, the embryo possessed a well-developed scutellum and axis with suspensor. Embryogenesis was further confirmed by coleoptile and radicle elongation during germination when the embryos were cultured on medium supplemented with kinetin with or without coconut water. In this system, an average 67 microspores per responsive anther began cell division but only 3.69 embryos were formed per responsive anther after 6 wk. Adventitious embryos could be induced if the embryos, once formed, remained on initiation medium for 10 wk instead of being transferred to regeneration medium. Developmental stages which may be amenable to changes that could enhance plant production were identified. The potential to use this information to enhance plant production is discussed.     

结球甘蓝游离小孢子胚胎发生

以结球甘蓝品种“强夏”为材料进行游离小孢子培养,对与胚胎发生关系密切的因子进行探讨。研究结果表明,在盛花前期取材最适宜;单核晚期至双核期的小孢子才能发育成胚状体;含17%蔗糖的培养液在培养初期有利于小孢子存活;培养3d后胚胎诱导则以14％蔗糖浓度为最好;高浓度（17％）蔗糖培养3d后添加低浓度（11％）蔗糖培养液能大大提高胚胎发生能力,比一直在14％蔗糖培养液培养的提高282．4％,比更新培养液培养的提高126．1％。     

Production of embryoids and calli from isolated microspores of tomato (Lycopersicon esculentum Mill.) in liquid media

Isolated uninucleate microspores of tomato,Lycopersicon esculentum Mill, were cultured in defined, liquid nutritive media. The microspores developed to haploid embryoids with or without an attached suspensor or into calli with compactly or loosely arranged cells.     

Microspore embryogenesis in anther cultures of two Indian cultivars of Brassica juncea (L.) Czern.

Direct microspore-derived embryo formation in anther cultures of two cultivars of Brassica juncea was obtained. Preliminary culture of anthers at 35°C for 1–5 days prior to maintenance at 25°C stimulated embryogenesis. Embryogenesis was also stimulated by an initial culture at 5°C for 3 days. Analysis of squashed anthers revealed that approximately 10% of the microspores began dividing, but less than 1% developed into macroscopic embryos. All embryos transferred to embryo culture medium survived, but only 30% of these developed directly into normal plantlets. The androgenic plants were haploid (2n=18).     

Effects of culture density,conditioned medium and feeder cultures on microspore embryogenesis in Brassica napus L. cv. Topas

Summary In microspore cultures of Brassica napus L. cv. Topas, embryo yield increases with culture density up to about 40,000 microspores per ml. A much higher density (100,000 per ml) appears inhibitory to embryogenesis. A relatively high culture density (30,000 or 40,000 per ml) for the first 2–4 days of culture is crucial for embryogenesis, after which cultures may be diluted to allow better embryo growth.Medium conditioned by culturing microspores at 30,000 or 40,000 per ml for 1 day improved microspore-embryo yield in low density cultures (3,000 or 4,000 per ml) more than 3-fold. In contrast, media conditioned with microspores from 1–4 days or 0–4 days of culture were inhibitory.Use of feeder cultures resulted in up to 10-fold increase of embryo yield in low density microspore cultures, depending on the method used. Filter papers and other membranes placed on top of feeders greatly inhibited embryogenesis in the feeder layer as well as microspores cultured on the feeder, possibly due to poorer gaseous exchange.     

Characterization of polarity development through 2- and 3-D imaging during the initial phase of microspore embryogenesis in Brassica napus L

Isolated microspores of B. napus in culture change their developmental pathway from gametophytic to sporophytic and form embryo-like structures (ELS) upon prolonged heat shock treatment (5 days at 32 °C). ELS express polarity during the initial days of endosporic development. In this study, we focussed on the analysis of polarity development of ELS without suspensor. Fluorescence microscopy and 3-D confocal laser scanning microscopy (CLSM) without tissue interfering enabled us to get a good insight in the distribution of nuclei, mitochondria and endoplasmic reticulum (ER), the architecture of microtubular (MT) cytoskeleton and the places of 5-bromo-2′-deoxy-uridine (BrdU) incorporation in successive stages of microspore embryogenesis. Scanning electron microscopy (SEM) analysis revealed, for the first time, the appearance of a fibrillar extracellular matrix-like structure (ECM-like structure) in androgenic embryos without suspensor. Two types of endosporic development were distinguished based upon the initial location of the microspore nucleus. The polarity of dividing and growing cells was recognized by the differential distributions of organelles, by the organization of the MT cytoskeleton and by the visualization of DNA synthesis in the cell cycle. The directional location of nuclei, ER, mitochondria and starch grains in relation to the MTs configurations were early polarity indicators. Both exine rupture and ECM-like structure on the outer surfaces of ELS are supposed to stabilize ELS's morphological polarity. As the role of cell polarity during early endosporic microspore embryogenesis in apical–basal cell fate determination remains unclear, microspore culture system provides a powerful in vitro tool for studying the developmental processes that take place during the earliest stages of plant embryogenesis.     

Induction of Haploid Callus from Isolated Microspores of Peony in vitro

The in vitro culture of isolated microspores of two cultivarsof Paeonia, P. lactiflora cv. "Kumoinotsuru" (2n=10) and cv."Toyonoakari" (2n = 10), was attempted. With both cultivars,some cultured microspores (3–6%) began to divide afterfive to seven days of culture. Those of "Kumoinotsuru" grewinto calli, whereas the others degenerated. Cytological examinationof the callus developed from a microspore revealed haploids,diploids or a mixture of both. No direct embryo formation frommicrospores was observed in this experiment. (Received December 1, 1980; Accepted January 16, 1981)     

Impact of genotype,plant growth regulators and activated charcoal on embryogenesis induction in microspore culture of pepper (Capsicum annuum L.)

The production of double haploids through androgenesis is used by breeders to produce homozygous lines in a single generation. Androgenesis can be achieved by isolated microspore culture, which, however, allows the production of embryogenesis with a very low efficiency. In order to improve the overall embryogenesis in pepper, we study the differences of microspore embryogenesis in different genotypes of pepper, and also document the effect of growth regulators in pretreatment media, and activated charcoal (AC) on embryogenesis induction. Fifty different pepper genotypes were evaluated, and the swollen rate of microspores from different genotypes varied from 3.11% to 29.56% with the mean value of 13.13%. Microspores from genotype ‘36’ had the highest swollen rate, and the lowest swollen rate of microspores was observed in genotype ‘26’. It was concluded from the statistical results of L₉ (3³) orthogonal test that changes in the level of BA influenced the swollen rate of microspores more significantly, and the combination of 0 mg∙l^− 1 6-benzyladenine (BA), 0.2 mg∙l^− 1 α-naphthaleneacetic acid (NAA) and 0.5 mg∙l^− 1 kinetinin (Kin) was best. AC at a concentration of 0.05% could act as a promoter of embryogenesis in the microspore culture of different pepper genotypes, while the more significant effect was observed with the low responsive genotypes.     

Effects of High Temperature on the Cultures of Isolated Microspores in Brassica campestris ssp. pekinensis

The influence of high temperature (33℃) on embryogenesis in isolated microspore culture of Chinese cabbage (Brassica campestris spp. pekinensis ) was investigated by microscpopy of FDA and DAPI. The microspores cultured at constant temperature of 25 ℃ lost their viability quickly and only few viable microspores were found after 7 days of culture. The morphology of the cultured microspores became as turgescent as the "rugby" which was similar to the mature pollen of the Chinese cabbage. The first nuclear division of the microspores was asymmetric. The microspores lost their capacity of embryogenesis under such condition. In contrast, when the microspores were cultured at 33℃ for 24 h before they were transfered to the culture condition of 25 ℃, their developmental pattern was changed. Some of the microspores could remain viable even for 7 days in culture, they became rounded off. The symmetric nuclear division pattern was induced. The frequency of such division was about 40%. Of the several new cell division types observed, the symmetric type was more frequent (55%) than others. The microspores treated under 33℃ were able to form embryoids via embryogenesis. The critical period of high temperature treatment on microspore culture of Chinese cabbage was about the initial 12 h, if the cell division index of microspore was concerned, but the period was the initial 24 h if the frequency of embryogenesis was considered.     

Tobacco zygotic embryogenesis in vitro: the original cell wall of the zygote is essential for maintenance of cell polarity, the apical-basal axis and typical suspensor formation

We have developed a reliable in vitro zygotic embryogenesis system in tobacco. A single zygote of a dicotyledonous plant was able to develop into a fertile plant via direct embryogenesis with the aid of a co-culture system in which fertilized ovules were employed as feeders. The results confirmed that a tobacco zygote could divide in vitro following the basic embryogenic pattern of the Solanad type. The zygote cell wall and directional expansion are two critical points in maintaining apical-basal polarity and determining the developmental fate of the zygote. Only those isolated zygotes with an almost intact original cell wall could continue limited directional expansion in vitro, and only these directionally expanded zygotes could divide into typical apical and basal cells and finally develop into a typical embryo with a suspensor. In contrast, isolated zygote protoplasts deprived of cell walls could enlarge but could not directionally elongate, as in vivo zygotes do before cell division, even when the cell wall was regenerated during in vitro culture. The zygote protoplasts could also undergo asymmetrical division to form one smaller and one larger daughter cell, which could develop into an embryonic callus or a globular embryo without a suspensor. Even cell walls that hung loosely around the protoplasts appeared to function, and were closely correlated with the orientation of the first zygotic division and the apical-basal axis, further indicating the essential role of the original zygotic cell wall in maintaining apical-basal polarity and cell-division orientation, as well as subsequent cell differentiation during early embryo development in vitro.