喜树大小孢子发生和雌雄配子体的发育

喜树子房下位,一室,有1枚倒生胚珠,悬垂,具单珠被。假厚珠心胚珠类型,胚囊发育为蓼型。喜树小孢子母细胞减数分裂胞质分裂方式为同时型,四分体主要为四面体形和左右对称形,单核小孢子呈三角形,成熟花粉粒有三角形、四边形和圆形。本文主要研究喜树大小孢子发生和雌雄配子体的发育过程,并初步探讨了喜树部分雌蕊败育的原因。     

INCOMPATIBILITY OF MERISTEMATIC AND FILAMENTOUS GROWTH IN THE FERN GAMETOPHYTE

Gametophytes of Pteridium aquilinum can be maintained in red light as either 1- or 2-dimensional structures. The mode of growth realized in red light is dependent upon the activity of the meristem. An active meristem in a 2-dimensional structure will permit a continued development of that structure. A breakdown in meristematic activity results in filament formation. It is suggested that a group of actively dividing cells in some manner inhibits cell elongation and thus prevents filament formation in red light.     

侧柏小孢子的发生和雄配子体的形成

侧柏[Platycladusorientalis（L．）Franco]初生造孢细胞在8月下旬（1992年）形成,11月上旬形成小孢子母细胞,1993年2月中旬形成四分体,2月下旬小孢子从四分体内释放出来,3月中旬形成成熟花粉粒并开始传粉,4月上旬花粉粒在珠心上萌发,5月上旬生殖细胞分裂,6月上旬精原细胞分裂。小孢子母细胞在休眠以前开始减数分裂,解除休眠以后形成成熟的花粒粒。减数分裂从11月上旬开始至次年2月17日结束。小孢子母细胞减数分裂存在扩散双线期。小孢子母细胞以双线期渡过休眠。精原细胞接近颈卵器时开始分裂,形成两个大小相同的精细胞。精细胞独立存在的时间很短。精细胞的细胞质分为三个区域。小孢子母细胞在发育过程中,发现有部分小孢子母细胞退化,在小孢子囊内形成一大的空腔的现象。     

THE GAMETOPHYTE OF ANEMIA COLIMENSIS

Anemia colimensis, the most primitive known species of the genus, has been investigated with respect to gametophyte development and morphology. In the early stages the thalli are in general similar to those of species of Anemia which are charcterized by the development of an initially lateral marginal meristem. One significant difference was noted in the frequent appearance of meristematic zones on both sides of the young plate. One of these becomes the marginal meristem; the other eventually ceases activity. The mature gametophyte is a spherical cushion of complex organization, the result of extreme ruffling of the wings of the thallus and the remarkable abundance of filamentous outgrowths and deep lobing of the wings. This form of gametophyte is unique among the investigated anemias. It is proposed that the formation of a lateral meristem, the “Ceratopteris type” of prothallial development, is primitive in Anemia and that the “Adiantum type,” at least in the Schizaeaceae, is derived. This suggestion is discussed in relation to other possible interpretations.     

SPORE GERMINATION AND EARLY DEVELOPMENT OF THE GAMETOPHYTE OF SCHIZAEA PUSILLA

During germination of the spore of Schizaea pusilla, the first division of the protoplast was perpendicular to the polar axis and resulted in the formation of the rhizoid. The next division parallel to the polar axis of the spore gave rise to the protonemal initial. Following this “Vittaria”-type germination, the protonema that developed was characterized by an extensive branching to produce uniseriate filaments and rhizoidophores.     

宁夏枸杞的大、小孢子发生和雌、雄配子体发育

在幼小花药横切面上,每个角隅处可见一层拱形孢原细胞,其经过平周分裂形成初生造孢细胞、次生造孢细胞,发育为小孢子母细胞。减数分裂过程中胞质分裂为同时型。四分体为四面体型。成熟花粉粒含二细胞,具三孔沟型萌发孔。花药绒毡层由二部分组成:药壁区的绒毡层由初生壁细胞所产生,药隔区的由药隔细胞直接转化成,为双重起源,呈二型性,属分泌型。雌蕊由二个心皮构成二室子房,中轴胎座。倒生胚珠具单珠被、薄珠心,珠被绒毡层。胚囊发育为蓼型。在胚囊细胞分化后,组成胚囊的四种细胞继续发育,表现出各自的形态学变化。     

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     

凹叶厚朴大、小孢子发生和雌、雄配子体发育的研究

凹叶厚朴花药四囊型,腺质绒毡层有1-2层细胞,小孢子形成时胞质分裂方式为修饰性同时型,小孢子四分体排列方式为左右对称型．成熟花粉粒为二细胞型。四分体和小孢子在发生时有不规则变形。子房单心皮,心皮腹面壁上着生2个胚珠,胚珠倒生型,厚珠心,双珠被;孢原细胞一个,并且自表皮下第2层细胞处分化。胚囊发育为单孢蓼型。凹叶厚朴的胚胎学特征与木兰科其它植物的胚胎学特征基本相同,属于较原始的被子植物胚胎类型。在凹叶厚朴大、小孢子发生和雌、雄配子体发育过程中存在部分败育现象。本文初步探讨了凹叶厚朴濒危的生殖生物学原因。     

五唇兰雌配子体发育和胚胎发生的研究

五唇兰的胚珠倒生型,具薄珠心,两层珠被。胚囊发育为双孢子葱型,成熟胚囊８核。从传粉到受精约５０ｄ,正常双受精。胚具５－６细胞的胚柄,种子成熟时胚柄及胚乳核消失,成熟种子只具单层细胞的种皮和一个未分化的珠珠形胚。     

凹叶厚朴大、小孢子发生和雌、雄配子体发育的研究

凹叶厚朴花药四囊型,腺质绒毡层有1-2层细胞,小孢子形成时胞质分裂方式为修饰性同时型．小孢子四分体排列方式为左右对称型,成熟花粉粒为二细胞型。四分体和小孢子在发生时有不规则变形。子房单心皮。心皮腹面壁上着生2个胚珠,胚珠倒生型,厚珠心,双珠被;抱原细胞一个,并且自表皮下第2层细胞处分化。胚囊发育为单孢蓼型。凹叶厚朴的胚胎学特征与木兰科其它植物的胚胎学特征基本相同,属于较原始的被子植物胚胎类型。在凹叶厚朴大、小孢子发生和雌、雄配子体发育过程中存在部分败育现象。本文初步探讨了凹叶厚朴濒危的生殖生物学原因。     

水曲柳大孢子发生及雌配子体发育的研究

水曲柳（ＦｒａｘｉｎｕｓｍａｎｄｓｈｕｉｃａＲｕｐｒ．）子房为二心皮;二室,中轴胎座,每室内具二个倒生胚珠,薄珠心,单珠被。单个孢原细胞分化于珠心顶端表皮之下,直接发育成为大孢子母细胞,大孢子四分体为直线形,通常为合点端第一大孢子具功能,胆囊发育为蓼型。     

DIVISION OF THE GENERATIVE CELL AND LATE DEVELOPMENT IN THE MALE GAMETOPHYTE OF GINKGO BILOBA

Division of the generative cell in the male gametophyte of Ginkgo biloba to yield the sterile cell and spermatogenous cell was examined in vivo and in vitro. Evidence is presented in support of a new interpretation of development in which the sterile cell and spermatogenous cell arise from an unusual anticlinal ringlike division of the generative cell. This type of cell division is only known to occur during antheridial development in leptosporangiate ferns and stomatal development among certain ferns in the Schizaeaceae and Polypodiaceae. The strong similarities in development and cell arrangement within the male gametophytes of cycads and Ginkgo suggest that division of the generative cell in cycads may be the same as in Ginkgo. Although the ringlike (conically annular) divisions in the antheridia of leptosporangiate ferns and the male gametophytes of Ginkgo (and probably cycads) are remarkably similar and result in the production of a central spermatogenous cell, it is conjectural as to whether these patterns represent a striking convergence or evolutionary homology.     

THE EFFECT OF DIFFERENT LIGHT CONDITIONS AND SUCROSE ON THE GROWTH AND DEVELOPMENT OF THE GAMETOPHYTE OF THE FERN,ONOCLEA SENSIBILIS

Miller , J. H. (Yale U., New Haven, Conn.), and P. M. Miller . The effect of different light conditions and sucrose on the growth and development of the gametophyte of the fern, Onoclea sensibilis. Amer. Jour. Bot. 48(2): 154–159. Illus. 1961.—Gametophytes grow rapidly under the highest intensity white fluorescent light used, 400 ft.-c. Growth is correspondingly less at 220 and 28 ft.-c., and at the lowest light intensity the gametophytes are markedly longer than wide. One percent sucrose added to the medium reverses the growth limitation imposed by low light intensity and produces a morphology comparable to that found under higher intensities. Sucrose does not sustain heterotrophic growth in total darkness, but permits growth if the gametophytes are given low dosages of red light. The effect of red light is reversible by far-red illumination.