青阳参的大孢子发生与雌配子体发育

利用常规石蜡制片技术、荧光显微技术、光镜细胞化学技术、电子显微镜技术对青阳参大孢子发生、雌配子体形成过程进行了详细观察。结果显示,青阳参为边缘胎座,胚珠倒生、短珠柄,单珠被,薄珠心型,珠心细胞含有大量的淀粉粒、线粒体和内质网等;大孢子孢原细胞起源于下表皮并直接行使大孢子母细胞的功能;合点端的大孢子分裂形成8-核胚囊;蓼型胚囊;成熟胚囊中有大量淀粉粒;珠孔受精;胚乳在早期发育阶段以游离核形式存在,约在16~32核的阶段细胞壁形成,通常情况下胚乳核的分裂比合子的分裂早,成熟胚乳细胞单核、形状不规则,没有胚乳吸器;胚的发育经过原胚、球型胚和心型胚阶段,茄型;成熟的种子具有种毛,位于珠孔端的珠被表皮细胞是种毛长出的区域,种子中含有大量的脂肪。     

高山红景天胚胎学研究

高山红景天(Rhodiola sachalinensis A.Bor.)具8个雄蕊,每个雄蕊有4个花粉囊。小孢子母细胞减数分裂时,胞质分裂为同时型。形成的四分体为四面体形。花药壁由表皮、药室内壁、二层中层和绒毡层五层细胞组成,其发育方式为基本型。腺质型绒毡层,有些绒毡层细胞分裂形成不规则双层,少数细胞双核。二细胞型花粉。雌蕊由4心皮组成。边缘胎座,倒生胚珠,双珠被,厚珠心,胚珠发育中形成珠心喙。大孢子四分体线形或T -形,合点大孢子具功能。胚囊发育为蓼型。成熟胚囊中,卵细胞核、助细胞核均位于细胞的合点端,珠孔端具液泡;极核融合为次生核,并位于卵细胞合点端附近; 3个反足细胞退化。双受精属于有丝分裂前配子融合类型。胚的发育为石竹型;基细胞侵入珠孔端,形成囊状吸器。细胞型胚乳;初生胚乳核分裂形成两个细胞,其珠孔端的细胞发育成胚乳本体,合点端的细胞直接发育成具一单核的合点吸器。     

小蓬草的胚胎学研究

对小蓬草（Conyzacanadensis）大小孢子发生、雌雄配子体形成、受精、胚及胚乳发育过程进行了研究,主要结果如下：花药四室,药壁由表皮、药室内壁、中层和绒毡层组成。表皮退化;药室内壁宿存,细胞柱状伸长,纤维状加厚;中层细胞退化较早,在小孢子母细胞减数分裂开始时仅存残迹;绒毡层于小孢子母细胞减数第一次分裂前期开始原位变形退化,属于腺质型绒毡层;小孢子母细胞减数分裂为同时型,四分体的排列方式主要为四面体形和左右对称形;成熟花粉粒多为3-细胞花粉粒,偶见2-细胞花粉粒。子房下位,2心皮,1室,单胚珠,基生胎座;单珠被,薄珠心,倒生胚珠,具发达的珠被绒毡层。珠心表皮下分化出大孢子孢原细胞,孢原细胞直接发育为大孢子母细胞,大孢子母细胞减数分裂形成4个大孢子直线形排列,仅合点端的大孢子发育成功能大孢子母细胞,胚囊发育为蓼型。两个极核在受精前融合为次生核,珠孔受精。胚乳发育属于核型,胚胎发育为紫菀型;具胚乳吸器。     

小蓬草的胚胎学研究

对小蓬草(Conyza canadensis)大小孢子发生、雌雄配子体形成、受精、胚及胚乳发育过程进行了研究,主要结果如下:花药四室,药壁由表皮、药室内壁、中层和绒毡层组成.表皮退化;药室内壁宿存,细胞柱状伸长,纤维状加厚;中层细胞退化较早,在小孢子母细胞减数分裂开始时仅存残迹;绒毡层于小孢子母细胞减数第一次分裂前期开始原位变形退化,属于腺质型绒毡层;小孢子母细胞减数分裂为同时型,四分体的排列方式主要为四面体形和左右对称形;成熟花粉粒多为3细-胞花粉粒,偶见2细-胞花粉粒.子房下位,2心皮,1室,单胚珠,基生胎座;单珠被,薄珠心,倒生胚珠,具发达的珠被绒毡层.珠心表皮下分化出大孢子孢原细胞,孢原细胞直接发育为大孢子母细胞,大孢子母细胞减数分裂形成4个大孢子直线形排列,仅合点端的大孢子发育成功能大孢子母细胞,胚囊发育为蓼型.两个极核在受精前融合为次生核,珠孔受精.胚乳发育属于核型,胚胎发育为紫菀型;具胚乳吸器.     

獐牙菜的胚胎发生

对獐牙菜大孢子发生、雌配子体形成、受精、胚及胚乳发育过程进行了研究。主要结果如下：子房2心皮,1室,4列胚珠,侧膜胎座;薄珠心,单珠被,倒弯生胚珠。大孢子母细胞减数分裂形成4个大孢子直线形排列,合点端的大孢子具功能,胚囊发育为蓼型。3个反足细胞宿存,每个细胞均多核和异常膨大,反足吸器明显,并在胚乳之外形成染色较深的类似“外胚乳”的结构。珠孔受精,受精作用属于有丝分裂前类型。胚乳发育为核型;胚胎发育为茄型。果实成熟时,种子发育至球形胚阶段。反足细胞在龙胆科一些短命植物中的宿存与分裂具有重要的生殖适应与进化意义。     

粉叶小檗大孢子发生和雌配子体形成

采用石蜡切片方法对粉叶小檗（Berberis pruinosa Franch.)的大孢子发生和雌配子体形成过程进行了研究。主要结果如下：雌蕊1枚,子房单心皮,边缘胎座,2枚胚珠倒生,具双珠被,厚珠心,珠孔由内外两层珠被共同形成,呈“Z”字形;单孢原,位于珠心表皮下;直线形大孢子四分体,合点端的1个大孢子发育为功能大孢子,胚囊发育类型为蓼型;成熟胚囊中,2个极核在受精前融合为次生核;3个反足细胞不发达,较早退化;"品"字形卵器,其中助细胞发达且具丝状器。     

兰花蕉的胚胎学研究

兰花蕉（Orchidantha chinensis T.L.Wu）的胚珠倒生,具厚珠心和双珠被。内外珠被形成珠孔。假种皮从外珠被的项端发生。造孢时期,胚珠具有一层周缘细胞。造孢细胞发育成大孢子母细胞,大孢子母细胞减数分裂形成大孢子的线形四分体,少数三分体。合点大孢子具功能。胚囊发育属蓼型。成熟胚囊的合点端狭长,胚珠具有珠心冠原和承珠盘。反足细胞寿命长,胚珠维管束属于合点后多维管束类型。胚乳发育属核型。种子脱落时,胚尚未分化出胚芽和胚根。     

一年蓬的胚胎学研究

对一年蓬大小孢子、雌雄配子体、受精、胚乳和胚的发育过程进行了观察研究。结果显示:花药4室;药壁发育属于双子叶型,由表皮、药室内壁、1层中层和1层绒毡层组成;花药成熟时表皮退化,药室内壁宿存,其细胞柱状伸长,纤维状加厚;中层形成不久随即退化;绒毡层于小孢子母细胞减数第一次分裂前期开始原位退化,小孢子时期完全退化,属腺质绒毡层。小孢子母细胞减数分裂为同时型,小孢子四分体主要为四面体型,兼有十字型和左右对称型;成熟花粉粒为3-细胞粒。子房下位,两心皮一室,单胚珠,基生胎座,单珠被,薄珠心,倒生胚珠,具发达的珠被绒毡层;珠心表皮下分化出大孢子孢原,孢原细胞直接发育为大孢子母细胞;直线形四分体,合点端为功能大孢子,胚囊发育类型为蓼型,存在二倍体孢子生殖的胚囊;两极核在受精前融合为次生核,珠孔受精;胚乳发育属核型,具胚乳吸器,胚胎发育为紫菀型。并对一年蓬胚胎发育中的无融合生殖现象进行了讨论。     

八角莲大孢子发生和雌配子体形成

首次报道了八角莲(Dysosma versipellis (Hance)M.cheng)大孢子发生和雌配子体形成的过程.结果:双珠被,多为厚珠心胚珠,少数为假厚珠心,胚珠多为横生,少数为弯生;边缘胎座,子房一室,多胚珠,珠孔由两层珠被共同形成,呈"之"字形;多为单孢原,位于珠心表皮下:偶见2～3个孢原细胞位于珠心表皮下;大孢子母细胞有两种发生方式;直线形大孢子四分体,合点端的大孢子发育为功能大孢子,蓼型胚囊;成熟胚囊中,二个极核在受精前合并为次生核;三个反足细胞不发达,较早退化;"品"字形卵器极性明显,其中卵细胞与助细胞极性相反;助细胞发达,其丝状器在不同发育时期形态及大小不同,且具吸器功能.     

石香薷（唇形科）的胚胎学研究

石香薷(Mosla chinensis Buch.-Ham.ex Maxim.)花药壁发育属双子叶型。花药具4个小孢子囊;腺质绒毡层,细胞具2～4核,有3至数个核仁;初生造孢细胞直接行小孢子母细胞的功能,在小孢子囊中成单列。花粉母细胞减数分裂后胞质分裂为同时型;小孢子四分体呈四面体形,也有左右对称形,成熟花粉具2细胞。胚珠倒生,单珠被,薄珠心,大孢子四分体线形排列,功能性大孢子位于合点端,少数为合点端第二个细胞。胚囊发育属蓼型,珠孔区近卵圆形,比合点区稍短,合点区较狭窄。胚胎发生属柳叶菜型。细胞型胚乳,珠孔吸器为单孢3核,合点吸器为单孢2核。种子无胚乳,种皮由珠被发育。石香薷雌雄配子体的发育、胚胎发生及胚乳形成,与紫苏属的Perilla ocimoides几乎完全一致。不同点仅在于石香薷在2-细胞花粉时,药室内壁细胞切向伸长,壁尚未发生纤维状加厚(P.ocimoides药室内壁细胞径向伸长,胞壁纤维状加厚),珠孔吸器为单孢3核(P.ocimoides为单孢4核)。胚胎学显示石荠苎属与紫苏属有密切的亲缘关系。     

北柴胡大小孢子发生和雌雄配子体发育的研究

用石蜡切片法对北柴胡的大、小孢子发生和雌、雄配子体发育过程进行观察研究.结果显示,北柴胡的胚珠为倒生型,单珠被,薄珠心.孢原细胞不经分裂直接发育成大孢子母细胞;四分体线性,多数情况下合点端的大孢子为功能大孢子,少数情况下亚合点端的大孢子也可发育为功能大孢子,蓼型胚囊;八核胚囊时期,珠心基部和两侧的一些珠心细胞保持自己的细胞质和形状,留存较久,成为珠心座细胞,珠被内表皮细胞发育为珠被绒毡层;花药壁发育类型为基本型,绒毡层为腺质绒毡层.小孢子母细胞减数分裂的胞质分裂为同时型,产生正四面体型四分体.成熟花粉为3细胞型.     

Embryological Studies of Codonopsis pilosula Nannf.

This paper reports the studies of megasporogenesis and microsporogenesis, development of female and male gametophytes, fertilization, and development of embryo and endosperm, The anther wall consists of four layers, i.e. epidermis, endothecium, middle layer and tapetum. Part of the tapetum cells originates from the primary parietal cells, and the other part comes from the basic tissue of the anther partition. Tapeta? cells are uninucleate or binucleate, and belong to the secretory type. Microsporocyte originates directly from the primary sporogenous cell, Cytokinesis is of the simultaneous type. Arrangement of microspores in tetrad is isobilateral. Mature pollen grain is of the 2-celled type. The ovary is tricarpellum, trilocular with many ovules. The ovule is mono-integinous, tenui-nucellar and anatropous. The embryo sac originates from the single-archesporial cell. The one chalazal megaspore in linear tetrad is the functional megaspore. The development of embryo sac is of the Polygonum type. Before fertilization, two polar nuclei fuse in to a secondary nucleus and the antipodal cells degenerate. Fertilization is porogamy, fusion of one sperm with secondary nucleus is faster than that of one sperm with egg nucleus. The development of endosperm is of the cellular type. The first three divisions of endosperm ceils are regular. Two endosperm cells near the ends of chalaza and the micropyle develop into haustorium without division. The haustoria gradually degenerate at the late stage of globular embryo. The mature seeds contain abundant endosperm. The development of embryo is of the Solanad type. The suspensor consists of 12–20 cells. The optimum development of the suspensor is at the early stage of the globular embryo. It begins to degenerate after late globular stage. The embryo develops from proembryo, heartshaped embryo, dicotyledenous- to mature embryo.     

苦瓜胚胎学研究

以石蜡制片法对苦瓜(Momordi cacharantia L.)进行了胚胎学研究。小孢子母细胞减数分裂时,胞质分裂为同时型,形成四面体型四分体和左右对称型四分体。成熟花粉为二细胞型。子房三室,双珠被,厚珠心,倒生胚珠。大孢子四分体为线形,合点端功能大孢子发育成为蓼型胚囊。中央细胞细胞质中有大量贮藏物质存在。极核在受精时融合。双受精过程属有丝分裂前配子融合类型。3个反足细胞随受精过程进行而退化。胚胎发生为柳叶菜型。核型胚乳,合点端具胚乳吸器。     

Embryological Studies in Glycyrrhiza uralensis Fisch.

This paper reports the studies of overall embryology of Glycyrrhiza uralensis Fisch. Development of the anther wall follows the dicotyledonous type. The cytokinesis of the microspore mother cell in meiosis is of simultaneous type. The arrangement of microspores in tetrad is tetrahedral, isobilateral and decussate. Microspores have various types of abortive to development. Mature pollen grain is of the 2-celled type. The ovule is bitegminous, crassinucellate and campylotropous. The megaspore mother cell gives rise to unequal dyad and then linear tetrad. The chalazal megaspore, the second or the third megaspore towards the micropylar end are functional megaspore. The development of the embryo sac conforms to the Polygonum type. Mature embryo sac has various types of variation. The fertilization belongs to the premitotic type of syngamy. The development of most embryoes belongs to the Onagrad type. The development of the endosperm belongs to the nuclear type and the endosperm near the chalazal end develops into haustorium.     

A study on the development of stigma and megagametophyte,and embryogeny in Cimicifuga simplex Wormsk

This is one of a series of studies on the reproductive features in Cimicifuga nanchuanensis Hsiao, an endangered plant endemic to China, and C. simplex Wormsk, a closely related and widely spread species as a control. The present paper deals with the results of cyto-morphological observations on the megasporogenesis, the development of female gametophytes, and the embryogeny in C. simplex. Its anatropous ovules are bitegminous and crassinucellate. A megaspore mother cell undergoes meiosis to form a linear or T-shaped megaspore tetrad. The embryo sac is of Polygonum type. The three antipodal cells persist up to the globular stage of embryo development.Two polar nuclei fuse to form a secondary nucleus close to the chalazal end of the embryo sac and connect with antipodal cells before fertilization. The development of endosperm is of Nuclear type. Cellularization of nuclear endosperm initiates since early globular stage of the embryo development. Development of the embryo in C. simplex is of Onagrad type. C. simplex is dichogamous. Stigmatic papillae emerge on the 1st∽2nd day and they elongate into stigmatic hairs on the 3rd∽5th day after stamens withering. The great impact of the differences of the receptible period of stigmas and pollen viabilitybetween the two species on effective pollination and seed-setting rate is discussed.     

Studies on the Development of Gametophytes in Cornus officinalis (Cornaceae)

The floral bud of Cornus officinalis Sieb. et Zucc. began to differentiate at the end of April. In the beginning of November, female and male gametophytes reached their maturation. The flowers fell off in the following March. The wall of the microsporangium comprised epidermis, endothecium, two or three middle layers and a single layer of amoeboid tapetum with two nuclei. The extra-tapetal membrane was formed during the later stage of the development of anther. Meiosis of microspore mother-cell was normal and cytokinesis was of the simultaneous type. The tetrad was tetrahedral in shape. The mature pollen grains were 2-celled and 3-colporate. The ovule was unitegminous and tenuinucellate. During the development of the ovule, some special structures were formed, e. g. hypostase and obturator which originated from the integument. A single archesporium differentiated immediately below the nucellar epidermis. It functioned directly as the megaspore mother-celL This cell under went meiosis to form a linear tetrad. The chalazal megaspore was functional. The development of the embryo sac was conformed as the polygonum type. Two polar nuclei fused into the secondary nucleus and 'three antipodal cells degenerated soon after the embryo sac reached its maturation, at that time the female gametophyte had become an embryo sac which consisted of only four cells each with a nucleus just before two months of blooming. The nuclei of some synergids located in the chalazal part of the cells. Contrarily, the micropylar past of the synergids were occupied by a large vacuole. The secondary nucleus was usually located in the chalazal part of the embryo sac.     

苦瓜胚胎学研究

以石蜡制片法对苦瓜(Momordica charantia L.)进行了胚胎学研究。小孢子母细胞减数分裂时,胞质分裂为同时型,形成四面体型四分体和左右对称型四分体。成熟花粉为二细胞型。子房三室,双珠被,厚珠心,倒生胚珠。大孢子四分体为线形,合点端功能大孢子发育成为蓼型胚囊。中央细胞细胞质中有大量贮藏物质存在。极核在受精时融合。双受精过程属有丝分裂前配子融合类型。3个反足细胞随受精过程进行而退化。胚胎发生为柳叶菜型。核型胚乳,合点端具胚乳吸器。     

Studies on the Development of Male and Female Gametophytes in Sinojakia xylocarpa

Observed in this paper was the development of the microspore and megaspore, male and female gametophytes in Sinojakia xylocarpa, which is endemic to China. The anther comprises four microsporangia. Microspore wall forms simultaneously after meiotic division in PMCs. The arrangment of microspore in a tetrad is tetrahedral. Bicel lular pollen grains appear at the shedding stage. ‘They are 3-colporate, with irregular min ute-faveolate exine sculpture. The anther wall development is of the dicotyledonous type, and its endothecitum develops slight fibrous thickenings, which also form on some epidermal cells. The tapetum is glandular. The pistil with hollow style is composed of three carpels, and its ovary contains several anatropous ovules. The ovule is unitegmic, tenuinucellar, but no obturator was observed. The archesporial cell functions directly as the megaspore mother cell which forms a linear tetrad, but T-shaped tetrad was found in a few ovules. A Polygonum type embryo sac forms from the functional chalazal megaspore. In the mature embryo sac, the synergids are elongate with a large vacuole at the chalazal end, but the distrihution of vacuoles in the egg cell appears random. Two polar nuclei remain in contact with each other for a spell before the fertilization and the 3 antipodal cells may persist into early postfertilzation stages. Numerous starch gra ins occur in the embryo sac. According to the present embryological studies on Sinojakia xylocarpa and the works on embryogenesis by some early embryologist, authors consider that Styracaceae, Symplocaceae, Sapotaceae and Ebenaceae are rather closely related, and we alsoconsider it reasonable to put the 4 families mentioned above in Ebenales.