DEVELOPMENT OF THE OVULE AND MEGAGAMETOPHYTE IN SAXIFRAGA HIERACIFOLIA

Wiggins , Ira L. (Stanford U., Stanford, Calif.) Development of the ovule and megagametophyte in Saxifraga hieracifolia. Amer. Jour. Bot. 46(10): 692–697. Illus. 1059.—Buds of Saxifraga hieracifolia collected in the vicinity of Point Barrow, Alaska, fixed, sectioned, and stained by standard methods, revealed that the archesporial cell in the ovule of this species is hypodermal and gives rise to the megaspore mother cell and a small number of parietal cells. Occasionally 2 megaspore mother cells occur within an ovule. Meiosis in the megaspore mother cell produces a linear tetrad of megaspores, the chalazal one of which normally gives rise to a monosporic, Polygonum-type megagametophyte. The polar nuclei fuse near the chalazal end of the megagametophyte and the antipodal cells disintegrate prior to fertilization. A distinct filiform apparatus and a marked lateral “spur” develop on each synergid. Vacuolation in the egg cell and in the synergids follows the usual pattern. Only a single integument surrounds the nucellus.     

A contribution to the embryology of Desmodium motorium (Houtt.) Merr. (= D. gyrans (L.f.) DC.) (Fabaceae)

Abstract

The anthers are tetrasporangiate. The anther wall comprises epidermis, fibrous endothecium, middle layer and tapetal layer. The tapetum is of the Glandular type and its cells remain uninucleate. Meiosis in pollen mother cells is normal and simultaneous cytokinesis leads to the formation of tetrahedral and decussate microspore tetrads. The pollen grains are shed at 2-celled stage. The ovule is campylotropous, bitegmic and crassinucellate. Meiosis in megaspore mother cell results in the formation of linear or occasionally T-shaped megaspore tetrad. The chalazal megaspore develops into Monosporic Polygonum type of embryo sac. Endosperm development is of the Nuclear type.     

罗汉果大孢子发生及雌配子体发育与花部形态、胚珠变化的关系

为弄清罗汉果(Siraitia grosvenorii)大孢子发生、雌配子体发育过程与花部形态特征、胚珠的关系,运用石蜡切片法对罗汉果子房进行了显微观察。结果表明,罗汉果的胚珠倒生,双珠被,厚珠心,大孢子四分体呈线型排列,合点端一个大孢子分化为功能大孢子,成熟胚囊为蓼型。花蕾形态、胚珠变化与大孢子发生、雌配子体的发育时期具有一定相关性,当子房长度为7.0 mm≤L<9.0 mm,珠心呈椭圆形时,约有45.83%的大孢子母细胞处于减数分裂时期。因此,依据罗汉果花部形态可有效确定大孢子发生与雌配子体发育的时期。     

MORPHOLOGICAL STUDIES IN ALETRIS. I. DEVELOPMENT OF THE OVULE,MEGASPORES AND MEGAGAMETOPHYTE OF A. AUREA AND THEIR CONNECTION WITH THE SYSTEMATICS OF THE GENUS

Browne , Edward T., Jr . (U. of Kentucky, Lexington.) Morphological studies in Aletris. I. Development of the ovule, megaspores and megagametophyte of A. aurea and their connection with the systematics of the genus. Amer. Jour. Bot. 48(2): 143–147. Illus. 1961.—Development in a North American species of this variously classified genus has shown great similarity with the development in several genera of Hutchinson's Liliaceae-Narthecieae: Pleea, Tofieldia, Nanhecium and ∗∗∗Metaparthecium. The ovules are anatropous, bitegmic, crassinucellate and arranged in 4 rows in each locule of the tricarpellate pistil. There is a hypostase and an obturator. The primary archesporial cell is hypodermal. This undergoes a division to form a wall cell and the megaspore parent cell (MPC). The megaspores usually have a linear arrangement although occasionally a T-shaped tetrad may be formed. Most frequently the chalazal megaspore functions, but rarely the one adjacent to it may enlarge instead. Megagametophyte development is of the Polygonum type. A characteristic narrowed chalazal constriction is formed during the development of the megagametophyte. It is recommended on the basis of this information that Aletris be classified with the genera of the Liliaceae-Narthecieae.     

OVULE ONTOGENY,MEGASPOROGENESIS, AND EARLY GAMETOGENESIS IN TRIFOLIUM REPENS (PAPILIONACEAE)

To aid in understanding of the early events in seed development, surface topography observations with the scanning electron microscope can be coupled with new methods of clearing tissues for light microscopy study. These techniques reveal that two to four ovules begin development along the placental ridge as conduplication of the carpel proceeds in Trifolium repens L. A multicellular archesporium may develop giving rise to several sporogenous cells and ultimately to more than one megasporocyte. However, meiosis is completed in only one megasporocyte to give rise to a single linear tetrad of megaspores. The chalazal megaspore functions in megagametogenesis. Megasporogenesis and megagametogenesis progress as ovule ontogeny proceeds. The outer integument develops more rapidly than the inner and contributes to the final form of the campylotropous ovule. The most dramatic change in ovule form occurs as the tetrad develops and the functional spore enlarges and divides mitotically to produce the two-nucleate megagametophyte. It can be demonstrated that this early gametophyte develops faster than it is allowed to expand in the nucellar mass. This may in part explain why there is gametophyte failure and reduced seed set in clovers.     

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。     

REPRODUCTIVE FEATURES OF DENTARIA LACINIATA AND D. DIPHYLLA (CRUCIFERAE), AND THE IMPLICATIONS IN THE TAXONOMY OF THE EASTERN NORTH AMERICAN DENTARIA COMPLEX

Reproductive features including ovule development, megasporogenesis, megagametogenesis, microsporogenesis, microgametogenesis, pollen tube growth, embryogeny, and natural seed germination were studied in a single population each of Dentaria laciniata Muhl. ex. Willd. and D. diphylla Michx. to test for possible agamospermy. The population of D. laciniata studied is sexual. The archesporial cell functions directly as the megasporocyte. It undergoes two meiotic divisions, but the micropylar cell of the dyad fails to undergo meiosis II, and a linear triplet of three cells is formed. The chalazal megaspore divides to form an eight-nucleate, seven-celled megagametophyte of the Polygonum type. Simultaneous cytokinesis follows the second meiotic division of the microsporocyte yielding a tetrahedral tetrad of microspores. A three-celled pollen grain is formed prior to anther dehiscence. Following apparent fertilization, the Capsella-variation of the Onagrad type of embryogeny results in a conduplicate embryo. Endosperm is initially nuclear, but eventually becomes cellular. Seeds readily germinate in nature. Similar events are documented in one population of D. diphylla up to the organization of the embryo-sac, which disintegrates before cellularization. These reproductive events and other data indicate that the eastern North American species of Dentaria may form a sexual polyploid complex with some sexual populations and some sterile ones.     

Embryology of Clitoria ternatea (Fabaceae)

ABSTRACT

The embryology of Clitoria ternatea was studied. Anthers contain four sporangia. The anther wall comprises an epidermis, an endothecium, a middle layer and a glandular tapetum. Microspore tetrads are tetrahedral and pollen grains are shed at the 2-cell stage. The ovule is campylotropous, bitegmic and crassinucellate. The micropyle is formed by both the integuments. The megaspore tetrad is linear or T-shaped. The chalazal megaspore is functional and embryo sac development follows the monosporic Polygonum type. Endosperm development is of the nuclear type. The chalazal part of the endosperm forms a haustorium. Embryo development follows the Onagrad type.     

Megasporogenesis,Microsporogenesis and Development of Gametophytes in Eleutherococcus senticosus (Araliaceae)

This paper describes megasporogenesis, microsporogenesis, and development of female and male gametophytes in Eleutherococcus senticosus. The main results are as follows: Flowers of E. senticosus are epigynous, pentamerous. Anthers are 4 -microsporangiate. An ovary has 5 loculi. Each ovary loculus has 2 ovules: the upper ovule and the lower ovule. The upper one is orthotropous and degenerates after the formation of archesporial cell, while the lower one is anatropous, unitegmic and crassinucellar, and able to continue developing. In male plants, microsporogenesis and development of male gametophytes took place in regular way, but a series of abnormal phenomena were found in megasporogenesis and development of female gametophytes. The microspore mother cells gave rise to tetrahedral tetrads by meiosis. Cytokinesis was of the simultaneous type. The mature pollen was 3-celled and shed singly. The anther wall formation belonged to the dicotyledonous type. At the stage of microspore mother cell, the anther wall consisted of four layers, i.e. epidermis, endothecium, middle layer, and tapetum. The tapetum was of glandular type and its most cells were binucleate. When microspores were at the uninucleate stage, the tapetum began to degenerate in situ. When microspores developed into 3-celled pollen grains, the tapetum had fully degenerates. In the lower ovule of male flower, the megaspore mother cell gave rise to a linear or “T” -shaped tetrad. In some cases, a new archesporial cell over the tetrad or two tetrads parallel or in a series were observed. Furthermore, the position of functional megaspore was variable; any one or two megaspores might be functional, or one megaspore gave rise to a uninucleate embryo sac, but two other megaspores also had a potentiality of developing into the embryo sac. In generally, on the day when flowers opened, female gametophytes contained only 4 cells: a central cell, two irregular synergids and one unusual egg cell. In female plants, microspore mother cells and secondary sporogenous cells were observed. But at the stage of secondary sporogenous cell, the newly differentiated tapetum took the appearance of degeneration. Later, during the whole stage of meiosis, the trace of degenerative tapetum could be seen. At last, the microsporangium degenerated and no tetrad formed. On the blossom day, all anthers shriveled without pollen grains. In female flowers, megasporogenesis and development of female gametophytes were normal: the tetrad of megaspores was linear or “T”-shaped; the chalazal megaspore was usually functional; the development of embryo sac was of the Polygonum type. On the blossom day, most embryo sacs consisted of 7 cells with 8 nuclei or 7 cells with 7 nuclei; but the egg apparatus was not fully developed. In hermaphroditic plants, microsporogenesis was normal but the development of male gametophytes was partially abnormal. When the hermaphroditic flowers blossomed, there were more or less empty pollen grains in the microsporangium and these pollen grains were quite different in size. The development of most gynoecia was normal but numerous abnormal embryo sacs could be seen. On the blossom day, female gametophytes were mainly 7-celled with 8-nuclei or with 7-nuclei or 4-celled with antipodal cells degenerated; the egg apparatus wasnot fully developed either.     

多花地宝兰胚囊和胚发育的细胞学研究

为探讨多花地宝兰(Geodorum recurvum)胚胎发育的系统分类学意义,采用石蜡制片法对多花地宝兰胚囊和胚的发育进行解剖学观察。结果表明,在开花前,多花地宝兰胚珠原基发育缓慢,开花授粉后胚珠原基快速发育成"树状二杈分枝结构",随后在"分枝结构"末端形成孢原细胞,开始胚囊发育。多花地宝兰的胚囊发育属于单孢蓼型胚囊,胚珠具有双层珠被。孢原细胞形成后,经过细胞膨大延长发育形成胚囊母细胞,胚囊母细胞经过减数分裂形成线性四分体,在珠孔端形成1个功能大孢子,功能大孢子经过3次有丝分裂形成8核胚囊。多花地宝兰的胚发育具有藜型和紫苑型两种方式。双受精完成后,多花地宝兰合子进行一次橫裂后形成基细胞和顶细胞;基细胞经过多次分裂形成细胞团,细胞团中的细胞向不同方向膨大延长形成多个胚柄细胞;顶细胞有两种分裂方式,一种是横裂形成藜型胚,一种是纵裂形成紫苑型胚。因此,推测多花地宝兰在兰科植物系统分类学上属于较为原始种。     

DEVELOPMENT OF THE OVULE AND FEMALE GAMETOPHYTE IN EUSTACHYS PETRAEA AND E. GLAUCA (POACEAE)

The unilocular pistil in Eustachys contains a single ovule with lateral placentation. In E. petraea and E. glauca, the mature ovule is bitegmic, tenuinucellate, and amphitropous with the endostomic micropyle oriented toward the base of the locule. A single hypodermal archesporial cell enlarges to form the megasporocyte. The chalazal dyad member is larger than the micropylar one, and meiosis II is nonsynchronized. Two-thirds of the tetrads are linear and one-third T-shaped. The chalazal megaspore is functional. Initially ovoid, the two-nucleate female gametophyte becomes curved as it enlarges. The four-nucleate stage becomes wider at its extremities and constricted in the center. Synchronous mitotic divisions establish the eight-nucleate stage with four nuclei at each pole separated by a large central vacuole. In E. petraea, the maturation sequence begins with antipodal differentiation, followed by differentiation of the egg apparatus, migration of the polar nuclei to the center, and division of the antipodals to produce twelve cells. The sequence in E. glauca begins with migration of the polar nuclei followed by differentiation of the antipodals, egg apparatus, and antipodal replication to six cells. The polar nuclei fuse to form a secondary nucleus appressed to the egg cell in E. glauca and separated from it by a vacuole in E. petraea. T-tests for length measurements for various stages of development indicate that the functional megaspore and two-nucleate female gametophyte are significantly larger in E. glauca than in E. petraea. There is no significant difference in gametophyte length at the four-nucleate stage, and at the eight-nucleate stage, length in E. petraea surpasses that in E. glauca. This gap widens significantly at the mature stage. Nuclear volumes are significantly greater in E. glauca than in E. petraea in the functional megaspore and two-nucleate stage, but the volumes are similar at the four-nucleate stage. Consideration of the differences in structural complexity between the sporophyte and gametophyte generations leads to the conclusion that the female gametophytes of these species are more distinctive than are the sporophytes.     

STUDIES IN THE EMBRYOLOGY OF COMPOSITAE. IV. THE TRIBE INULEAE

Embryology of Blumea malabarica, B. membranacea, Laggera pterodonta, Anaphalis busna and Vicoa auriculata has been studied. The anther is tetrasporangiate in all the members except in Blumea membranacea where it is bisporangiate. The anther tapetum is of the Periplasmodial type. Both tetrahedral and isobilateral pollen tetrads are found. Mature pollen grains are three-celled with thick spinous exine. The ovary is bicarpellary syncarpous and unilocular with a single basal ovule. In one instance in Blumea malabarica two ovules per ovary with a rudimentary septum separating them was observed. The single hypodermal archesporial cell functions directly as the megaspore mother cell. The embryo sac develops according to the Polygonum type. The synergids in Blumea malabarica are hooked while in other members they are pear shaped. There are three antipodal cells except in Blumea membranacea where they increase up to eight. Endosperm development in Blumea malabarica is of the Nuclear type while in Blumea membranacea and Laggera pterodonta it is of the Cellular type. One or two layers of endosperm persist up to maturity. Embryo development follows the Senecio variation of Asterad type. The embryological information of this tribe along with that of other tribes will be utilized in evaluating the interrelationships of the family Compositae in a later paper.     

黄顶菊的大孢子发生、雌配子体与胚胎发育

用常规石蜡制片对黄顶菊(Flaveria bidentis(L.) Kuntze)大孢子发生、雌配子体和胚胎的发育过程进行了观察.黄顶菊雌蕊柱头二裂,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直列四分体...     

A NOMARSKI INTERFERENCE STUDY OF MEGASPOROGENESIS AND MEGAGAMETOGENESIS IN SMELOWSKIA CALYCINA (CRUCIFERAE)

Ovule development, megasporogenesis and megagametogenesis in an aneuploid population of the arctic-alpine crucifer, Smelowskia calycina, were examined to test for the possibility of apomictic seed production. Whole mounts of ovules cleared in Herr's “4½” clearing fluid were examined using Nomarski differential interference microscopy. The campylotropous ovule was bitegmic, with a micropyle formed by both integuments. The single archesporial cell of a crassinucellar nucellus functioned directly as a megasporocyte, dividing to form a linear tetrad of megaspores. The chalazal megaspore divided to form an 8-nucleate, 7-celled gametophyte of the Polygonum type, having hooked synergids with a well-developed filiform apparatus and polar nuclei that fused prior to fertilization. In the absence of any anomalous development indicative of agamospermy, seed production was assumed to be sexual.     

Different patterns of callose wall formation during megasporogenesis in two species ofOenothera (Onagraceae)

The homozygousOenothera hookeri Torr. etGray shows the typical pattern ofOnagraceae with ± callose on the external walls of megaspore mother cells and tetrads. Megasporogenesis is heteropolar, and the micropylar megaspore is the mother-cell of the 4-celled embryo sac. The complex-heterozygousOenothera biennis L. during megasporogenesis generally has callose not on the external cell walls but only on the transversal walls of the tetrad. In 95% of the ovules both the external chalazal and the micropylar megaspores develop to embryo sac mother-cells. Megasporogenesis is homopolar, and competition between two developing embryo sacs for nutrition in the ovule occurs. The embryo sac with the stronger genotype wins the race against the other one. Polarity phenomena during ontogeny of the female gametophyte are related to nutritional supply and hormonal induction from the ovule. The introduction of a developmental-physiological point of view into the discussion about the evolution of the embryo sac inOnagraceae is therefore justified.Stipendiatin der Alexander von Humboldt-Stiftung 1974/76.     

短柄五加大,小孢子发生和雌,雄配子体发育的研究

短柄五加花药５枚,每个花药四个花粉囊。小孢子母细胞减数分裂时,胞质分裂为同时型,产生正四面体形的四分体。花药壁由表皮、药室内壁、中层和绒毡层四层细胞组成,其发育类型为双子叶型。腺质绒毡层,其细胞为二核。三细胞型花粉。子房５室,每室两个胚珠,上胚珠败育,下胚珠可育。下胚珠倒生,具单珠被,厚珠心。大孢子母细胞减数分裂形成线性排列的四个大孢子,雌配子体发育属蓼型。开花当天,花粉散开,雌配子体尚未成熟,处     

孝顺竹(Bambusa multiplex)大孢子发生与雌配子体发育研究

为了解孝顺竹（Bambusa multiplex）的大孢子及雌配子体的发育过程,利用扫描电镜对孝顺竹的雌蕊形态以及大孢子和雌配子体的发育进行了观察。结果表明,孝顺竹雌蕊单子房,1室,双珠被,薄珠心;大孢子母细胞是由1个雌性孢原细胞直接发育而成,大孢子四分体为线性,位于珠孔端的1个大孢子分化成为功能大孢子,然后由功能大孢子依次经历二核、四核、最终形成1卵细胞2助细胞2极核3反足细胞的成熟胚囊。此外,孝顺竹为雌雄同熟类型,根据雌、雄蕊发育的对应关系,从雄蕊形态可估测雌配子体发育阶段。有少数雌蕊出现败育现象,可能是孝顺竹结实率低的原因之一。     

Development and structure of the pericarp and seed of Rhus lancea L. fil. (Anacardiaceae), with taxonomic notes

The pedicel of the female flower of Rhus lancea is distinctly articulated and usually carries three bracteoles. In the linear tetrad the micropylar megaspore forms the 8-nucleate embryo sac of the Oenothera-type. The single, bitegmic ovule is anatropous. The ripe, loose, papery exocarp consists mainly of the outer epidermis and a sclerified hypodermis. The mesocarp is not a typical sarcocarp, since the ridges and the inner layers are sclerenchymatous. The endocarp, originating from the inner epidermis, consists of four layers and its structure and microchemistry emphasize the close alliance of Rhus with other genera of the section Rhoideae. The endotestal seed indicates a phylogenetic affinity between the Anacardiaceae and the Burseraceae.