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。     

华山新麦草胚和胚乳的发育研究

采用常规石蜡切片法,观察了华山新麦草胚和胚乳的发育过程,结果表明,华山新麦草胚和胚乳的发育过程与一般禾本科植物基本相同,胚胎发生属紫宛型,顶细胞和基都参与胚体的形成,胚胎发育经过二细胞原胚,多细胞原胚,球形原胚,梨形原胚,分化胚和成熟胚阶段,成熟胚具有胚根,胚芽,盾片,胚牙鞘,胚根鞘,外胚叶等典型禾本科植物成熟胚的结构,胚乳发育类型为核型,包括游离核阶段,细胞化阶段和生长成熟阶段,待大量游离核形成之后才形成细胞壁,紧贴胚囊的一层胚乳细胞最后形成种子的糊粉层,其余的胚乳细胞最后充满淀粉粒,其特点为：（1）有双球形原胚的现象;（2）反足细胞解体较早;（3）胚乳游离核时期和细胞时期胚乳细胞核的核仁多样。     

兴安落叶松胚性愈伤组织诱导影响因子的研究

以成熟和未成熟合子胚为外植体,研究影响兴安落叶松（Larix gmelinii）胚性愈伤组织诱导的几种主要因子。结果表明兴安落叶松合子胚带胚乳培养有利于胚性愈伤组织的诱导;内蒙沙地种源成熟合子胚的诱导率显著（p<0.05）高于加格达奇山地种源;冷藏处理可以提高成熟合子胚胚性愈伤组织的诱导率;不同发育时期的未成熟合子胚的诱导率存在显著差别（p<0.05）,其中以子叶初期合子胚（7月5日）诱导率最高;2,4-D对胚性愈伤组织诱导的影响较大,且与BA、KT存在一定的协同作用;S培养基比DCR和MS培养基更有利于胚性愈伤组织的诱导;培养基中琼脂含量为4 g·L^-1时,诱导率较高。     

刺梨胚及胚乳的发育

本研究对单瓣刺梨胚及胚乳的发育过程进行了观察,获得如下主要结果:1.刺梨胚的发育属于紫菀型的一种变异类型。原胚发育早期,在胚体顶端具有明显的胚芽原细胞。成熟胚为典型的双子叶植物胚的形态,在子叶中贮藏大量的蛋白质粒。2.刺梨的胚乳属核型。经游离核时期以后形成胚乳细胞。紧邻胚囊周界壁的表层胚乳细胞可以进行平周分裂,产生层叠状的胚乳周缘层。此种后形成的胚乳,我们称之为次生胚乳。当次生胚乳形成时,其余的胚乳细胞逐渐解体,最后几乎完全消失。次生胚乳只在合点处解体,其余保留至种子成熟。3.发现了开花后一些胚珠中无胚或胚和胚乳在发育早期退化的现象,可认为是刺梨种子不育的一个重要原因。     

黑藻早期个体发育的研究

对黑藻（Hydrilla verticillata）个体发育中的胚胎发育（从合子到种子胚）和种苗发育（从种子到种苗）进行了研究。发现沉水植物黑藻与挺水植物泽泻（Alisma orientale）在胚柄只有1～2个细胞、种子胚苗端发达根端未分化、萌发后根端始分化、分生区之上产生根环与下胚轴毛、初生根短命等特点上基本相同,并对这些特点进行了讨论。     

罗汉果胚,胚乳及胚乳有器的发育

本文采用石蜡切片与酶解分离法对罗汉果Ｓｉｒａｉｔｉａ ｇｒｏｓｖｅｎｏｒｉ胚、胚乳及胚乳吸器发育过程进行观察。ａ）罗汉果胚的发育是按Ｇｅｕｍ ｕｒｂａｎｕｍ的分裂程序进行的,属紫菀型。但在合子分裂成球胚过程中,胚芽原细胞分化明显,故属紫菀型的变异型。ｂ）胚乳发育属核型,在球形胚阶段,在合点端和珠孔端有发育的胚乳吸器形成并进行旺盛生长,最大长度达１４２０μｍ,心形胚期,吸器活动开始减退,合点端核型胚     

谷子胚和胚乳的发育

合子的第一次分裂为斜的横分裂,胚发育至棒状原胚后,胚顶端一侧的细胞加速分裂形成一团分生组织细胞,由这团分生组织分化盾片、胚芽鞘、胚芽生长点和胚根。胚体的其它部分参与部分盾片和胚根鞘的构成。胚柄不参与胚的组成,胚无外胚叶,胚胎发育属禾本型。核型胚乳。从胚囊壁产生的自由生长壁把胚乳游离核隔开形成一层胚乳细胞。然后这层细胞平周分裂使胚乳细胞变成二层,以后的胚乳细胞增殖以细胞有丝分裂方式进行。胚乳的最外层     

陕西蕨类植物新记录

报道了陕西分布新记录的11种蕨类植物,即峨眉盾蕨（Neolepisorus emeiensis）、边缘鳞盖蕨（Microlepia marginata）、肾羽铁角蕨（Asplenium humistratum）、城口铁角蕨（A. chengkouense）、蚀盖耳蕨（Polystichum erosum）、伴藓耳蕨（P. muscicola）、尾叶耳蕨（P. thomsonii）、尖齿耳蕨（P. acutidens）、康定耳蕨（P. kangdingense）、石韦（Pyrrosia lingua）和绒紫萁（Osmunda claytoniana）,凭证标本均保存于西北农林科技大学植物标本馆（原西北植物研究所标本馆）（WUK）。至此,陕西现有蕨类植物已有258种（不包括变种和变型）。     

湖南蕨类植物区系新资料

报道了湖南蕨类植物区系新记录17种（隶属7科,11属）,它们是桫椤（Alsophila spinulosa）、长尾铁线蕨（Adiantunm diaphanum）半月形铁线蕨（A. philippense）、新月蕨（Pronephrium gymnopteridifrons）、密毛紫柄蕨（Pseudophegopteris hirtirachis）、禾秆紫柄蕨（P. microstegia）、金佛山溪边蕨（Stegnogramma jinfoshanensis）、假大羽铁角蕨（Asplenium pseudolaserpitiifolium）、都匀铁角蕨（A. toramanum）、长镰羽耳蕨（Polystichum falcatilobum）、瓦鳞耳蕨（P. fimbriatum）、棕鳞耳蕨（P. polyblepharum）、倒鳞耳蕨（P. retroso-paleaceum）、膜边肋毛蕨（Ctenitis clarkei）、三叉蕨（Tecaria subtriphylla）、指叶假瘤蕨（Phymatopteris dactylina）、掌叶线蕨（Colysis digitata）。     

湖南蕨类植物区系新资料（Ⅱ）

报道了湖南蕨类植物区系新记录20种（隶属5科7属）;它们是毛足铁线蕨 (Adiantum bonatianum)、多芒复叶耳蕨（Arachniodes aristatissima）、狭长复叶耳蕨（A. attenuata）、粗裂复叶耳蕨(A. grossa)、南川复叶耳蕨(A. nanchuanensis)、黑鳞复叶耳蕨（A. ningrospinosa）、缩羽复叶耳蕨(A. reducta)、长刺复叶耳蕨（A. setifera）、节肢蕨（Arthromeris lehmannii）、多羽节肢蕨（A. mairei）、上斜刀羽耳蕨（Polystichum assurgentipinnum）、深裂耳蕨（P. incisopinnulum）、前原耳蕨（P. mayebarae）、假线鳞耳蕨（P. pseudosetosum）、边果耳蕨（P. shimurae）、钻鳞耳蕨（P. subulatum）、等基贯众（Cyrtomium aequibasis）、尖齿肋毛蕨（Ctenitis dentisora）、梵净肋毛蕨（C. wantsingshanica）、琼崖舌蕨（Elaphoglossum mcclurei）。     

Campynemanthe (Campynemaceae): Morphology, microsporogenesis, early ovule ontogeny and relationships

Campynemanthe Baill. consists of three species endemic to New Caledonia. Two species are studied and compared. The tapetum is secretory with 2-nucleate tapetal cells. Microsprogenesis is successive, microspore tetrads are isobilateral and the pollen grains are free and inaperturate or have a weakly defined aperture. Placentation is axile with 3–4 ovules in each of the three locules. Ovules are anatropous and crassinucellate with the micropyle formed by the inner integument alone. The archesporial cell cuts off a parietal cell, which divides to form a parietal tissue. The nucellar epidermis divides periclinally at the nucellar apex to become 2-layered. The megaspore tetrad is T-shaped, in which the micropylar megaspore cells are separated by an oblique wall. The chalazal megaspore enlarges and apparently developes into a Polygonum-type embryo sac, but a mature embryo sac has not been seen. The ripe seeds are pale and non-phytomelaniferous. They have copious endosperm rich in fatty oils. The embryo is minute. These characters and gross morphological similarities support relationship with Campynema Labill., but there are also conspicuous differences. The two genera are considered related. They also closely approach genera of the variable family Melanthiaceae and there are reasons to include them in this family.     

大麦胚和胚乳发育的相关性及贮藏营养物质的积累

大麦(Hordeum vulgare L.)开花后1d,见合子及退化助细胞,游离核胚乳尚未形成;开花后2～3d,胚为5及10个细胞,胚乳为游离核期;开花后4及5、6d,胚为梨形及长梨形,胚乳达细胞化期;开花后8d,胚为胚芽鞘期,糊粉层原始细胞产生;开花后10d,胚具1叶,糊粉层1～2层;开花后13d胚为2叶胚,亚糊粉层发生;开花后17d,3叶胚形成,糊粉层多为3层并停止分裂,菱柱形及不规则胚乳细胞分化;开花后21～29d,胚为4叶胚,胚乳进一步分化;开花后33d,胚为5叶成熟胚,胚乳亦成熟。淀粉、蛋白质在胚中积累始于开花后13d。在盾片中由基向顶发生,在胚芽鞘及叶原基中,首先在顶端出现。成熟盾片顶端的淀粉消失。开花后6d,胚乳开始积累淀粉;开花后10d,糊粉层及胚乳细胞积累蛋白质。开花17d后胚乳的蛋白质体多聚集,29d后蛋白质体显著减少。开花后17d,在盾片及糊粉层细胞中检测到油脂。果长或果长与稃片长之比和盾片长可作为不同发育期胚和胚乳的形态指标。     

Embryological Studies on Sagittaria guayanensis H. B. K. Subsp. lappula (D. Don) Bojin (Alismataceae)

This paper deals with the embryological characteristics of Sagittaria guayanensis H. B.K. subsp. lappula (D. Don) Bojin. The anther wall development follows the Monocotyledonous type. The cytokinesis of microspore mother cell in meiosis is of the Successive type. The tetrads of microspores show an isobilateral arrangement, and the mature pollen grains are 3-celled. The ovule is bitegminous, pseudo-crassinucellate and anatropous. The megaspore mother cell originates directly from a single archesporial cell. The mature embryo sac consists of 7 cells including 8 nuclei and conforms to the Allium type. The two polar nuclei do not fuse into a secondary nucleus before fertilization. Instead, one sperm fuses with the micropylar end polar nucleus first , and the fertilized polar nucleus then migrates to the chalazal end, where it fuses with the second polar nucleus, forming the primary endosperm nucleus. The embryo development conforms to the Caryophyllad type. The mature embryo is U-shaped and forms the embryonic shoot apex accompanied by two leaves. The endosperm development corresponds to the Helobial type. The primary endosperm nucleus (invariably lying in the chalazal part of the embryo sac) divides and forms two chambers:large micropylar one and small chalazal one. The chalazal endosperm chamber remains binucleate, while, in the micropylar chamber free nuclear divisions occur and then cellnlarization takes place. During the embryo formation the endosperm gradually degrades and can not be found in the mature seed. The subgenus Lophotocarpus is different from the subgenus Sagittaria in some embryological aspects, especially in the structure of mature embryo sac and the double fertilization process.     

Zygotic embryogenesis in Anthurium (Araceae)

Morphological, anatomical, and histochemical aspects of zygotic embryogenesis by Anthurium andraeanum Lind. were investigated from 4 to 24 wk postpollination. Anatomical features were correlated with morphology of the spadix and capacity of embryos to germinate in vitro. Development from a single-cell zygote to fully mature seed takes 24 wk. The suspensor was two ranked and obvious during the early stages of embryogeny. It was apparent by week 8, substantial until week 14, and diminished rapidly until its absence by week 22. Differentiation of the shoot apex, cotyledon, and protoderm occurs at 14 wk. The embryo starts to derive nutrition from the endosperm at this time, and germination of cultured ovules reached 56%. By 20 wk the shoot apex had visible leaf primordia and the root apex was clearly defined. The cotyledon was well developed and surrounded the shoot tip. The storage of protein and starch was at its greatest in the endosperm and embryo. Furthermore, 100% germination of cultured ovules and embryos occurred at 20 wk and thereafter. Fully mature embryos at 24 wk are green and contain protoxylem elements.     

冠果草的胚胎学研究

冠果草花药壁的发育为单子口十型,绒毡层为周原质团型。小孢子母细胞减数分裂为连续型,四分体呈左右对称式排列,成熟花粉为三细胞型。双珠被,假厚珠心,倒生胚珠。胚囊发育为葱型,成熟胚囊的特点是两个极核分别位于中央细胞两端,不融合成次生核。受精过程中,一个精于与卵核融合形成合子,另一精子先与珠孔端极核融合,之后受精极核再移动到合点端与另一极核融合,形成初生胚乳核。胚的发育为石竹型。成熟胚呈马蹄形,具有2片真叶。胚乳发育为沼生目型。随着胚的发育,胚乳细胞逐渐解体,成熟种子中无胚乳。     

Thioredoxin and germinating barley: targets and protein redox changes

The endosperm and embryo of barley ( Hordeum vulgare L.) grain were investigated to relate thioredoxin h and disulfide changes to germination and seedling development. The disulfide proteins of both tissues were found to undergo reduction following imbibition. Reduction reached a peak 1 day earlier in the embryo than in the endosperm, day 1 vs. day 2. The profile in both cases resembled those observed with wheat and rice, i.e., the reduction of the storage proteins increased initially and then declined during the period of seedling growth. The extent of the increase in reduction observed with barley endosperm was, however, less pronounced than with the other cereals. Also, unlike wheat and rice, the storage proteins of the endosperm were highly reduced in the dry seed and the sulfhydryl content of glutelins showed no appreciable change during this period. The relative abundance of thioredoxin h during germination and early seedling growth differed in the embryo and endosperm: a progressive decrease in the endosperm (as seen with wheat) vs. an increase in the embryo. Thioredoxin h was found in the major seed tissues in characteristic forms. Three forms were found in the scutellum and aleurone, whereas two, which may represent isoforms, were identified in the root and the shoot. Using a recently developed strategy based on two-dimensional gel electrophoresis, several proteins were identified as specific targets for thioredoxin in the embryo following oxidation with H(2)O(2), among them barley embryo globulin 1, peroxiredoxin and acidic ribosomal protein P(3). The results confirm earlier findings with the endosperm of other cereals and extend the importance of thioredoxin-linked redox change to the germinating embryo for functions that potentially include dormancy, protection against reactive oxygen species, translation and the mobilization of storage proteins.     

Embryo sac, endosperm, and seed of Nemophila (Boraginaceae) relative to taxonomy, with a remark on embryogeny in Pholistoma

Studies on embryology and seed morphology are complementary to molecular phylogenetics and of special value at the genus level. This paper discusses the delimitation and evolutionary relationships of genera within the tribe Hydrophylleae of the Boraginaceae. The seven Nemophila species characterized by a conspicuous seed appendage are similar in embryology and seed structure. The ovule is tenuinucellate and unitegmic with a meristematic tapetum. The embryo sac penetrating the nucellar apex is of the Polygonum type, has short-lived antipodal cells, and an embryo sac haustorium. The endosperm is cellular, producing two terminal endosperm haustoria, of which the chalazal has a lateral branch. Embryogeny is of the Chenopodiad type (as in Pholistoma). The seed coat is formed from the small-celled inner epidermis of the integument. The large-celled outer epidermis of the integument disintegrates into scattered cells. Seed pits evolve from irregularly placed inner epidermal cells of the integument. The chalazal part of the ovule produces a cucullus, that functions as an ant-attracting elaiosome. Those species of Nemophila with a conspicuous cucullus form a natural genus. Nemophila is most closely related to Pholistoma. The integumentary seed pits of Nemophila might have evolved from ovular seed pits similar to those in Pholistoma.     

HISTOCHEMISTRY AND ULTRASTRUCTURE OF RICE (ORYZA SATIVA) ZYGOTIC EMBRYOGENESIS

Rice embryo development was examined, histochemically and ultrastructurally, from the time of fertilization to embryo maturity. At the time of fertilization, the megagametophyte consists of an antipodal mass of 10–15 cells, parietally positioned along the placental side of the central cell, and, at the micropylar end, two partly fused polar nuclei and the egg apparatus. Hydrolysis of adjacent nucellar tissue suggests the secretion of hydrolytic enzymes by the antipodal mass. The antipodal cells stain intensely for RNA and protein, indicating that they are metabolically active. The egg, supported by two overarching synergids, occupies a small, wall ingrowth-lined pocket of the central cell that quickly fills with cellular endosperm after fertilization. The endosperm cells, initially supplied with nutrients from wall ingrowth-derived vesicles, are digested and utilized by the embryo as a nutritive source. The developing embryo is also supplied with assimilates via the nucellus at the base of the embryo until about 8 days after fertilization. After 8 days, the embryo is no longer connected to the nucellus, and the nucellar cells at the base of the embryo are crushed. The zygote is not structurally polarized and contains a central nucleus, amyloplasts, lipid bodies, dictyosomes and extensive dilated ER. The first division of the zygote is transverse and unequal and occurs about 4 hours after fertilization. Embryo development is rapid, and within 24 hr, the embryo consists of 5–8 cells. Organ development begins with scutellum emergence in the 3-day-old embryo. The shoot apex organizes and the coleoptile develops from scutellum tissue at 4 days postfertilization, the epiblast emerges at 5 days, and the vascular bundle and root apex differentiate by 6 days after fertilization. Starch begins to accumulate in the basal cells of the 3-day-old embryo and deposition proceeds acropetally over the next 9–10 days. Lipid accumulation begins in the basal scutellum in the 6-day-old embryo and also proceeds acropetally. Storage protein synthesis is first detected in 6-day-old embryos and accumulation again proceeds acropetally, reaching the apex of the scutellum of the 25-day-old embryo. The ultrastructure of the 24-hr-old embryo is distinctive. The cells are characterized by numerous vesicles, heterochromatin and extensive nuclear evaginations.