禾本科针茅族(Stipeae)7种花粉形态比较研究

利用光学显微镜(LM)和扫描电子显微镜(SEM)观察了针茅族7种花粉形态.观察显示,花粉形态均为近球形,具远极单孔,并有萌发孔盖(Operculum).LM观察到花粉外壁纹饰具粗细不一的颗粒状结构,SEM则可辨不同种类的颗粒或瘤状结构的大小及其形成图案的差异,其中芨芨草属(Achnatherum)花粉外壁纹饰的种间差异...     

粉美人蕉花部维管束的解剖学研究

为探讨粉美人蕉(Canna glauca‘Erebus’)缺失雄蕊的去向和唇瓣的属性,对粉美人蕉花部维管束系统进行了解剖学观察分析。结果表明,粉美人蕉花梗横切面呈椭圆形,中心区的维管束聚集成6束大的维管束,形成心皮背束和隔膜束。在子房区顶部,3个隔膜束各分成3束,外方分支分别进入相应的花瓣,成为花瓣的中束。近轴面隔膜束内方的2束分支进入功能雄蕊。远轴面右侧的隔膜束内方2分支进入唇瓣,发育为唇瓣的部分维管束。远轴面左侧隔膜束内方分支进入内轮退化雄蕊。在花瓣形成时,近轴面左侧心皮背束分成2束,外侧分支进入近轴面外轮退化雄蕊,内侧分支进入功能雄蕊。近轴面右侧心皮背束外方分支进入侧生退化雄蕊。远轴面心皮背束分为2束,1束进入远轴面外轮退化雄蕊并迅速消失,另1束进入唇瓣,继续发育。从维管束来源角度证明了粉美人蕉退化雄蕊的同源异形现象。     

舞花姜花部维管束系统的解剖学研究

对舞花姜(Globba racemosa)花部维管束系统进行解剖学观察分析,以探讨其缺失雄蕊的去向及其唇瓣和腺体结构的属性.结果显示:(1)舞花姜花梗部的维管束分散排列在基本组织内.(2)子房基部的维管束排成2部分,中央区为分散排列的小维管束,外方为一轮大维管束环,且外环维管束发育为子房壁维管束,心皮背束和隔膜束均起源于中心区维管束,二者的分支在延长部形成一个维管束网结;在网结之上,近轴面的两束心皮背束分支分别进入到2枚侧生退化雄蕊中并成为其主束,远轴面心皮背束的内方分支则成为唇瓣中束,三束心皮背束的其余分支均上行入萼片.(3)唯一1枚功能雄蕊接受近轴面隔膜束的内方主支作为其主束,远轴面2枚隔膜束的主支最后进入唇瓣的两侧束,三束隔膜束的外分支均发育为花瓣束.研究认为:舞花姜的唇瓣是一个三重结构,其中央维管束代表1枚外轮雄蕊,两侧维管束则分别代表2枚内轮雄蕊;舞花姜的2枚花瓣状退化雄蕊与唇瓣的中央一起构成外轮雄蕊,唯一1枚可育雄蕊和唇瓣的两侧同属内轮雄蕊.本研究结果支持姜科子房延长部形成的腺体属于子房上部心皮边缘的维管化附属物的观点.     

4种一品红亚属植物种皮微形态特征比较研究

利用光学显微镜(LM)和扫描电镜(SEM)对大戟属一品红亚属(Subgen.Poinsettia)的4种草本植物种子进行了比较观察.结果显示:(1)在光学显微镜下,4种植物种子外形较为一致,为倒卵形至宽倒卵形,表面具瘤突.(2) SEM观察发现,4种植物的种子外种皮表面纹饰等方面存在明显差别,其中猩猩草种子表面纹饰为鳞片状,齿裂大戟为棒状、刺状,E.davidii为横棒状、疣状,而白苞猩猩草种子表面是由分泌层形成的疣状突起或假孔穴组成.研究表明,4种一品红亚属植物种子微形态特征在种的水平上具有一定的分类学意义,并可作为检疫鉴定的参考依据.     

金嘴蝎尾蕉花部维管束系统的解剖学研究

利用石蜡切片技术对蝎尾蕉科代表植物金嘴蝎尾蕉（Heliconia rostrata Ruiz＆Pavon）的花部维管束系统进行了解剖学研究。结果表明,心皮背束在延长部的基部分裂为内外2分支,内方分支与胎座维管束汇合后进入花柱,远轴面2枚外方分支在延长部的顶部分裂为2～4束进入远轴面2枚外轮雄蕊,而近轴面1枚外方分支则进入退化结构成为其中脉;隔膜束在延长部顶部亦分裂为3～5束,最终分别进入3枚内轮雄蕊;子房壁其它维管束最终进入花被片。本研究认为金嘴蝎尾蕉花部花瓣状退化结构与另外2枚外轮雄蕊具有完全相同的维管束系统来源,应属于雄蕊成员,且支持Kress关于蝎尾蕉科是姜群的姊妹群,区别于芭蕉群其它3科的观点。     

观光木的花器官发生

在扫描电镜下观察了观光木(Tsoongiodendron odorum Chun)花器官的发生发育。观光木的花原基最初为近圆形,随着顶端分生组织的活动,花原基边缘处出现浅凹,形成第一轮花被片原基,此时,花原基呈三角形排列,后两轮花被片原基依次发生,与前一轮互生;在内轮花被片发生的后期,最初几枚雄蕊原基几乎同时出现,呈螺旋状向顶发生,最后排列成三角圆锥状;雄蕊原基发育后期,心皮原基开始发育,形状与发育初期的雄蕊原基相似,随后心皮原基进行侧向生长,在近轴面出现浅凹,进而发育为凹槽,形成腹缝线,最后腹缝线完全愈合。腹缝线愈合现象表明观光木具有进化特征,与含笑属的亲缘关系较近。     

毛舞花姜花器官的发生与发育

通过扫描电镜观察了毛舞花姜(Globba barthei Gagne p.)的花序及花器官的发生与发育。3枚萼片原基首先于花顶连续发生,随后花顶的中心凹陷形成环状原基,环状原基进一步分化形成三枚花瓣—雄蕊共同原基,并在花顶的中心形成花杯。共同原基分化形成花瓣和三枚内轮雄蕊,紧接着外轮雄蕊在花杯的顶点发生。远轴的两枚内轮雄蕊延伸生长并相互融合形成了唇瓣,近轴的一枚形成了可育雄蕊;近轴的两枚外轮雄蕊发育形成了成熟花结构中的侧生退化雄蕊,而远轴的一枚缺失。近轴的两枚外轮雄蕊原基起始的同时,3枚心皮原基也在中心花杯的内侧发生而后与外轮雄蕊相间排列。对毛舞花姜花序的发生和发育的观察发现,在花序轴的头几片初级苞片中产生的是珠芽原基而非蝎尾状小花序原基,其形态特征类似于早期的蝎尾状小花序原基,由此推测珠芽很可能是蝎尾状小花序的变异。     

中国菟丝子属植物花粉的扫描电镜观察

本文作者用扫描电镜(SEM)对国产菟丝子属(Cuscuta L.)10种植物的花粉形态进行了观察。具3沟萌发孔的花粉为本属基本类型。根据萌发孔的数目,外壁纹饰等特征,该属花粉可划分为三个类型:(1)具3沟,外壁具穿孔,表面散生小刺状突起;(2)具3—5沟,外壁具网状纹饰,网脊上散生小刺状突起;(3)具3—6沟,外壁具小刺状突起,穿孔偶见。本文观察结果与刘炳仑等曾报道过光学显微镜(LM)下的结果不完全一致。最后,对菟丝子属的花粉形态的演化趋势以及属内亚属间关系进行了讨论。     

非洲菊盘状花雄蕊发育与舌状花生长着色的对应关系

非洲菊(Gerbern hybrida)头状花序由外轮舌状花和内轮盘状花构成。通过观察内轮盘状花雄蕊花粉囊和花粉粒的形态结构与发育顺序,和测定外轮舌状花花瓣的长度、宽度、花色素苷含量等,对它们之间的对应关系进行了研究。花序外轮舌状花花瓣开始着色时为P3期,此时第1轮盘状花出现成熟花粉粒。研究明确了内轮盘状花花粉粒发育与外轮舌状花生长时期和花色素苷积累的对应关系。     

北极巴罗地区2种灌木植物及其花粉形态

观察了北极巴罗(Barrow)地区2种灌木植物,全缘叶仙女木(Dryas integrifolia M.Vahl)和圆叶柳(Salix rotundifolia Trautv.)的形态、生境以及它们的花粉形态.这2种植物形态矮小或匍匐蔓生;全缘叶仙女木叶短小似披针状或扁平,全缘;圆叶柳叶圆形,叶脉显著,根、茎、叶均含丰富Vc.它们的花粉形态为球形、近球形或长球形,其萌发孔均为三孔沟或拟三孔沟,花粉均为辐射对称.全缘叶仙女木花粉外壁纹饰在光学显微镜下(LM)为细网状纹饰,在扫描电子显微镜(SEM)下为条纹状纹饰;圆叶柳在LM和SEM下均为细网状纹饰.通过与中国产和日本产相似种的比较研究,显示它们应是温带亚洲高山起源及部分起源于北极本部.     

太原黄耆(豆科)花器官及胚珠发育研究

太原黄耆是新近发表的物种,分布于中国陕西和山西。该实验利用扫描电子显微镜对太原黄耆的花器官发生和发育过程进行观察研究。结果显示:(1)太原黄耆的各轮花器官都是从远轴端向近轴端单向连续发生,在不同轮之间存在花器官重叠发生的现象。(2)在花的发育过程中,出现2种共同原基,即初级共同原基和次级共同原基,由初级共同原基发育成对萼雄蕊原基和次级共同原基,再由次级共同原基发育成花瓣原基和对瓣雄蕊原基。(3)雄蕊管近轴端基部开口是在进化过程中产生的特殊结构,是一种对传粉者的适应机制,从而有利于传粉活动的进行。(4)胚珠为倒生胚珠,具有2层珠被,认为倒生胚珠是内外2层珠被共同作用的结果。     

FLORAL DEVELOPMENT IN CAESALPINIA (LEGUMINOSAE)

Utilizing scanning electron microscopy, we studied the early floral ontogeny of three species of Caesalpinia (Leguminosae: Caesalpinioideae): C. cassioides, C. pulcherrima, and C. vesicaria. Interspecific differences among the three are minor at early and middle stages of floral development. Members of the calyx, corolla, first stamen whorl, and second stamen whorl appear in acropetal order, except that the carpel is present before appearance of the last three inner stamens. Sepals are formed in generally unidirectional succession, beginning with one on the abaxial side next to the subtending bracts, followed by the two lateral sepals and adaxial sepal, then lastly the other adaxial sepal. In one flower of C. vesicaria, sepals were helically initiated. In the calyx, the first-initiated sepal maintains a size advantage over the other four sepals and eventually becomes cucullate, enveloping the remaining parts of the flower. The cucullate abaxial sepal is found in the majority of species of the genus Caesalpinia. Petals, outer stamens, and inner stamens are formed unidirectionally in each whorl from the abaxial to the adaxial sides of the flower. Abaxial stamens are present before the last petals are visible as mounds on the adaxial side, so that the floral apex is engaged in initiation of different categories of floral organs at the same time.     

A SCANNING ELECTRON MICROSCOPIC STUDY ON THE INITIATION AND DEVELOPMENT OF FLORAL ORGANS OF BRASSICA NAPUS (CV. WESTAR)

The initiation and development of the floral organs of Brassica napus L. (cv. Westar) were examined using the scanning electron microscope. After transition of the vegetative apex into an inflorescence apex, flower primordia were initiated in a helical phyllotactic pattern. The sequence of initiation of the floral organs in a flower bud was that of sepals, stamens, petals and gynoecium. Of the four sepal primordia, the abaxial was initiated first, followed by the two lateral and finally the adaxial primordium. The four long stamens were initiated simultaneously in positions alternating with the sepals. The two short stamens were initiated basipetal to and outside the long stamens, and opposite the lateral sepals. The petals arose on either side of the two short stamens and the gynoecium was produced from the remainder of the apex. During development, the sepal primordia curved sharply at the tips and tightly enclosed the other organs. Stamen primordia developed tetralobed anthers at an early stage while filament elongation occurred just prior to anthesis. A unique pattern of bulbous cells was present on the abaxial surface of the anther. Growth of petal primordia lagged relative to the other floral organs but expansion was rapid prior to anthesis. The gynoecium primordium was characterized by an invagination early in development. At maturity, there was differentiation of a papillate stigma, an elongated style and a long ovary marked externally by sutures and divided internally by a septum. Distinct patterns of cuticular thickenings were observed on the abaxial and adaxial surfaces of the petals and stamens and on the surface of the style. The patterns were less obvious on the sepals and ovary. Stomata were present on both surfaces of the mature sepals, on the style and restricted areas on the abaxial surface of the anthers and nectaries but were absent from the petals, the adaxial surface of the stamens and the ovary. No hairs were present on any of the floral organs.     

A comparative study of floral development inTrillium apetalon andT. kamtschaticum (Liliaceae)

Trillium apetalon Makino is unique amongTrillium in having apetalous flowers. Using scanning electron microscope, the early floral development was observed in comparison with that ofT. kamtschaticum Pallas ex Pursh having petalous flowers. Morphologically petal primordia closely resemble stamen primordia in their more or less narrow and radially symmetric shape and are clearly distinct from sepal primordia with broad bases. Early in floral development sepal primordia are first initiated and subsequently two whorls of three primordia each are formed in rapid sequence, the first three at the corners and the second three at the sides of the triangular floral apex. Based on comparison in position and early developmental processes of their primordia, petals and outer stamens ofTrillium kamtschaticum are equivalent to outer stamens and inner stamens ofT. apetalon. The replacement of petals by outer stamens apparently leads to the loss of petals inTrillium apetalon flowers. Such a replacement can be interpreted in terms of homeosis. The replacement of the petal whorl leads to the serial replacement of the subsequent whorls: outer stamens by inner stamens, and inner stamens by gynoecium inTrillium apetalon. The term ‘serial homeosis’ is introduced for this serial replacement.     

Functional micromorphology of petals of <Emphasis Type="Italic">Chaenomeles japonica</Emphasis> exposed to humid and cold season

In this study, micro- and nano-traits of petal epidermises of flowers of Chaenomeles japonica extended under environmental conditions, during the humid and cold period of the year, are presented. The outer (abaxial) and the inner (adaxial) epidermises of petals of C. japonica consist of convex and papillae cells, respectively, that are covered by epicuticular wrinkled relief further ornamented by submicron motifs, forming interfaces between floral tissues and environment. Structural epidermal features of the petal relief at the nanoscale level reveal different functionality on the two sides of the corolla. The cuticular folds of convex epidermal cells display declining water retention on the outer petal surface and the exposed side of the corolla to the environmental conditions. The cuticular folds of papillae epidermal cells increase in size the inner petal surface, in comparison with the outer surface; such traits facilitate light absorption and enhanced the contact area among folds and curvatures at the inner side of the corolla. It appears that nanometric surface structures of petals may be important adaptive features of C. japonica flowers, contributing to their performance in the field.     

绞股蓝果实的发育解剖学研究

应用石蜡切片和扫描电镜的方法,观察了绞股蓝果实与种子的发育过程,结果表明:花后12 d左右,绞股蓝合子开始进行第一次分裂,极核分裂在花后6～7 d,核型胚乳在胚的发育中被吸收,胚的发育为茄型,外珠被呈网格状花纹。假果,表面有蜡质,果壁可明显分为3层,内侧细胞后期解体,种子倒三角形,表面瘤状突起。脱落花果的结构表现为珠被萎缩和胚发育受阻。     

Petal Development in Lotus japonicus

Previous studies have demonstrated that petal shape and size in legume flowers are determined by two separate mechanisms, dorsoventral (DV) and organ internal (IN) asymmetric mechanisms, respectively. However, little is known about the molecular mechanisms controlling petal development in legumes. To address this question, we investigated petal development along the floral DV axis in Lotus japonicus with respect to cell and developmental biology by comparing wild‐type legumes to mutants. Based on morphological markers, the entire course of petal development, from initiation to maturity, was grouped to define 3 phases or 13 stages. In terms of epidermal micromorphology from adaxial surface, mature petals were divided into several distinct domains, and characteristic epidermal cells of each petal differentiated at stage 9, while epidermal cells of all domains were observed until stage 12. TCP and MIXTA‐like genes were found to be differentially expressed in various domains of petals at stages 9 and 12. Our results suggest that DV and IN mechanisms interplay at different stages of petal development, and their interaction at the cellular and molecular level guides the elaboration of domains within petals to achieve their ideal shape, and further suggest that TCP genes determine petal identity along the DV axis by regulating MIXTA‐like gene expression.     

Ultrastructural Development of Plastids in the Epidermis and Starch Layer of Glossy Ranunculus Petals

The differentiation of chromoplasts and amyloplasts has beenfollowed in developing petals of Ranunculus acris, R. ficariaand R. repens from small bud stages through anthesis. Theseare typical of Ranunculus species with glossy yellow petals.The plastids in the adaxial epidermis of the glossy part developmany globules which enlarge and coalesce with the eventual completebreakdown of plastid structure. At anthesis only a few cytoplasmicremnants remain in the dispersed pigment in these cells whichpartially collapse with folding of the anticlinal walls. Inthe non-glossy proximal part of the petal the adaxial epidermalcells have more convex outer walls and the chromoplast developmentdoes not progress beyond a stage found in the glossy regionjust before the petal tips emerge from the bud: they have largeperipheral globules with irregular tubular lamellae betweenthem and in the central stroma. In the abaxial epidermis theplastids produce small globules and retain some grana; somehave small starch grains and differ little from the plastidsin the mesophyll. The starch layer beneath the adaxial epidermisin the glossy region is formed from a single embryonic celllayer. Amyloplasts differentiate rapidly in these cells andall plastid structure has disappeared before the flower budopens leaving the sloping palisade cells packed with starchgrains. Chromoplast, amyloplast, petal, ultrastructure, development, Ranunculus, buttercup, lesser celandine     

Floral developmental morphology of three Indigofera species (Leguminosae) and its systematic significance within Papilionoideae

Inflorescence and floral development of three species of Indigofera (Leguminosae-Papilionoideae), I. lespedezioides, I. spicata, and I. suffruticosa, were investigated and compared with that of other papilionoid groups, especially with members of the recently circumscribed Millettioid clade, which was merged as sister to Indigofereae in a recent cladistic analysis. Although Indigofera is a genus of special interest, because of its great richness in species and its economic importance, few studies have been made of floral development in the genus or in Indigofereae as a whole. Flower buds and inflorescences were analysed at several stages of development in the three species. Our results confirmed that Indigofera species bear a usual inflorescence type among legumes, the raceme, which comprises flowers initiated in acropetal succession, each with a subtending bract and no bracteoles initiated. The inception of the floral organs is as follows: sepals (5), petals (5), carpel (1), outer stamens (5), and, finally, inner stamens (5). Organ initiation in the sepal, petal, and both stamen whorls is unidirectional, from the abaxial side; the carpel cleft is adaxial. The vexillum is larger than other petals at maturity, covering the keels, which are fused edge-to-edge. Nine filaments are fused to form an adaxially open sheath, and the adaxial stamen of the inner whorl remains free (diadelphous androecium) in the mid-stage of development. Most of the infra-generic differences occurred in the later stages of development. Data on floral development in Indigofera obtained here were also compared with those from other members of Papilionoideae. This comparison showed that the early expression of zygomorphy is shared with other members of the Millettioid clade but is rarely found in other papilionoids, corresponding to a hypothetically morphological synapomorphy in the pair Indigoferae plus millettioids.     

瘤背石磺的生殖系统和性腺发育

2003年5~8月对瘤背石磺(Onchidium struma)的生殖系统结构和性腺发育进行了组织学研究。瘤背石磺生殖器包括两性腺、卵黄腺、蛋白腺。两性腺具有外管和内管,两管相连后通入蛋白腺,内管分支为收集管与腺泡相通。蛋白腺包括腺体部和分泌物两部分,中央为生殖输送管,蛋白腺具食指突和拇指突。性腺腺泡包括精子期腺泡、卵子期腺泡、精卵同泡和排空期腺泡4种类型。本文还对卵黄腺、受精囊、雄性交接器等结构进行了组织学观察,分析了精子和卵子的发育过程、运输路径。