弯齿盾果草(紫草科)花序及花的形态发生

以弯齿盾果草不同发育时期的花芽为材料,在体视显微镜解剖观察的基础上使用扫描电镜对弯齿盾果草花序、花及果实的发育过程进行了观察。结果显示:(1)弯齿盾果草的花序是由最初的一个球形花序原基经过多次分裂形成的,且花序发生式样符合蝎尾状聚伞花序结构,而非通常所描述的镰状或螺状聚伞花序;花序发生过程中无单一主轴,花序轴是由侧枝连接而成,每一朵花原基有其对应的1枚苞片,下一花原基是从相邻的上一枚苞腋里发生,相邻两花原基交错互生。(2)花器官的发生是按照花萼原基、花冠原基、雄蕊原基和雌蕊原基的顺序发育,但雄蕊原基的花药部分发育速度要比花冠原基快,所以花器官的发育是按照花萼、雄蕊、花冠和雌蕊的顺序发育。(3)子房四深裂结构是由4个原基分别发育,而后相互靠拢而成。(4)小坚果表面的附属结构发生于子房发育后期,其背面的内外层突起分别是由生长较快的外部组织的边缘通过上部内缩和下部向外环状生长形成。     

商陆属植物的花器官发生

为进一步研究商陆科的系统位置提供花器官发生和发育的证据,在扫描电子显微镜下观察了商陆Phytolacca acinosa、多雄蕊商陆P. polyandra和垂序商陆P. americana的花器官发生.结果表明: 商陆属植物花被的发生均为2/5型螺旋发生.在同一个种不同的花蕾中,花被的发生有两种顺序:逆时针方向和顺时针方向.远轴侧非正中位的1枚先发生.雄蕊发生于环状分生组织.在单轮雄蕊的种中8-10枚雄蕊为近同时发生;两轮雄蕊的种8枚内轮雄蕊先发生,6-8枚外轮雄蕊随后发生,内轮雄蕊为同时发生,外轮雄蕊发生次序不规则.心皮原基也发生于环状分生组织,8-10枚心皮原基为同时发生.在后来的发育过程中,商陆的心皮发育成近离生心皮雌蕊;其他2种心皮侧壁联合发育成合生心皮雌蕊.对商陆属植物花器官发生的类型及发育形态学做了分析,结果支持商陆科在石竹目系统发育中处于原始地位的观点.     

Floral development in Astragalus caspicus Bieb. (Leguminosae: Papilionoideae: Galegeae)

Floral organogenesis and development of the bushy perennial legume Astragalus caspicus were studied using epi-illumination light microscopy techniques. Based on our observations, flowers are in axillary two-flowered racemes, initiate all 21 floral organs and show precocious appearance of zygomorphy. The order of floral organ initiation is unidirectional in whorls starting from the abaxial position of the flower with a high degree of overlap. Another important ontogenetic feature is the existence of two successive common primordial stages categorized as primary and secondary. The primary common primordia produce antesepalous stamens and secondary common primordia. In contrast, the five secondary common primordia subdivide into a petal and an antepetalous stamen primordia. Our findings on floral ontogeny of A. caspicus provide new evidence for the complex and variable floral initiation and development in legumes. The floral apex with strong overlapping initiation of different organs illustrates a paradox in which different capabilities must be presumed to exist simultaneously. Moreover, two extraordinary types of common primordia represent possibly an advanced evolutionary trend where time intervals between the initiations of different floral organs in Papilionoideae are shortened.     

吉祥草的花部器官发生及其系统学意义

利用扫描电镜（SEM）观察了吉祥草（Reineckia carnea）（铃兰科）的花部器官发生发育过程。吉祥草花被片、雄蕊的发生方式是由近轴端向远轴端发生的逆单向型（reversed unidirection）,花发育后期花被片合生形成花被筒,花丝与之贴生。伴随花被片、雄蕊发生,三枚心皮也由近轴向远轴方向相继发生,随后彼此合生发育。花序顶部的花易发生花器官数目变异。结合早期花原基形态以及花器官数目变异情况分析,吉祥草的花被片与雄蕊可能是由共同原基分化而成。从花部器官发生式样和花被筒形成时间两方面比较吉祥草属、白穗花属和铃兰属的特征发现,三属中,铃兰属处于相对进化的位置,而白穗花属比吉祥草属更为原始。     

宽叶泽苔草的花器官发生

通过扫描电镜观察了宽叶泽苔草Caldesia grandisSamuel.的花器官发生。宽叶泽苔草 的萼片3枚,逆时针螺旋向心发生 ;花瓣3枚,呈一轮近同时发生,未观察到花瓣_雄蕊复合原基;雄蕊、心皮原基皆轮状向心 发生,最先近同时发生的6枚原基全部发育成雄蕊,随后发生的6枚原基早期并无差别,在发 育过程中逐渐出现形态差异,直至其中1－4枚发育成心皮,其余的发育成雄蕊;而后的几轮 心皮原基,6枚一轮,陆续向心相间发生。本文揭示了3枚萼片螺旋状的发生方式,并推测这种螺旋方式是泽泻科植物进化过程中保留下来     

Floral development of Iris decora Wall. (Iridaceae)

The outer tepal and stamen primordia arise as secondary primordia on the outer tepal-stamenprimordia, which are formed on the floral apex. The inner tepal primordia are formed directly on the floral apex. All the floral appendages are initiated in the second tunica layer and are homologous with regard to their origin and early development. A short perianth tube is formed as a result of intercalary growth in the common bases of the tepal primordia. The intercalary growth in the fused bases of the floral appendages elevates the peripheral zone. The floral apex thus appears as a shallow cup. Further intercalary growth results in the formation of an inferior ovary. The ovules are initiated as outgrowths on placental ridges from the lateral ovary wall, the trilocular appearance being the result of secondary cohesion of the parietal placentae.     

茄科马尿泡和天仙子的花器官发生

利用扫描电镜研究了茄科 (Solanaceae)天仙子族 (Hyoscyameae)中国特有属马尿泡属 (PrzewalskiaMaxim .)马尿泡 (PrzewalskiatanguticaMaxim .)和天仙子属 (HyoscyamusL .)天仙子 (HyoscyamusnigerL .)的花器官发生和发育 ,研究结果表明 :马尿泡和天仙子花器官的发生和发育具有以下 3个共同特征 :1)符合Hofmeister规律 ,即新器官的发生首先出现在花顶已经存在的器官之间 ;2 )花冠的发育模式符合茄科植物所具有的“后合瓣”(“latesympetaly”)现象 ,即花瓣单独发生但后来又通过它们基部分生组织的融合而连合起来 ;3)花被五基数且花器官原基发生顺序为向心发育。但是它们的花萼原基具有不同的发生方式。天仙子花萼裂片原基的发生方式为环状发生 ;马尿泡花萼裂片原基的发生方式为螺旋状发生 ,但 5个花萼裂片原基在都出现后就连成了一个环。马尿泡是介于天仙子属和山莨菪属之间的类群 ,它比天仙子属原始但较山莨菪属进化。     

PATTERNS OF FLORAL DEVELOPMENT IN AGALINIS AND ALLIES (SCROPHULARIACEAE). II. FLORAL DEVELOPMENT OF AGALINIS DENSIFLORA

Initiation of floral primordia begins in Agalinis densiflora with production of two lateral adaxial calyx lobe primordia followed by a midadaxial primordium, and then primordia of two abaxial calyx lobes. Initiation of three abaxial corolla lobe primordia is succeeded by that of two stamen pairs and then by primordia of two adaxial corolla lobes. The primordium of the abaxial carpel appears before the adaxial one. Except for the calyx, initiation of primordia proceeds unidirectionally from the abaxial to the adaxial side of the floral apex. Zygomorphy in the calyx, corolla, and androecium is evident during initiation of primordia and is accentuated during organogenesis. The calyx undergoes comparatively rapid organogenesis, but the inner three floral series undergo a protracted period of organogenesis. The perianth series reach maturation prior to meiosis in the anthers. Maturation of the androecium and gynoecium are postmeiotic events.     

离体黄瓜子叶节花芽分化与内源激素及多胺的关系

用高效液相色谱法(HPLC)测定了黄瓜子叶节花芽分化期(0-6天)内源激素及多胺的变化。结果显示,子叶培养0-2天生长素(IAA)、赤霉素(GA_3)、玉米素(ZT)、脱落酸(ABA)等4种内源激素均明显下降,4-5天略有上升,表明0-2天IAA、GA_3和ABA的剧降有利于花原基形成,3-5天较高的ZT含量有利于花器官原基的形成。除腐胺(Put)外,精胺(Spm)、亚精胺(Spd)、尸胺(Cad)在0-1天均下降,1-4天上升,4-5天再下降,Put在0-1天急剧上升,而后持续下降,表明高水平的内源多胺总量和Put可能有利于花原基分化,2天后Spm含量上升有利于花器官原基分化,而Cad含量变化可能是区别花芽和营养芽分化的特征之一。     

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。     

离体黄瓜子叶节花芽分化与内源激素及多胺的关系

用高效液相色谱法(HPLC)测定了黄瓜子叶节花芽分化期(0—6天)内源激素及多胺的变化。结果显示,子叶培养0—2天生长素(IAA)、赤霉素(GA3)、玉米素(ZT)、脱落酸(ABA)等4种内源激素均明显下降,4—5天略有上升,表明0-2天IAA、GA3和ABA的剧降有利于花原基形成,3—5天较高的ZT含量有利于花器官原基的形成。除腐胺(Put)外,精胺(Spm)、亚精胺(Spd)、尸胺(Cad)在0—1天均下降,1—4天上升,4—5天再下降,Put在0—1天急剧上升,而后持续下降,表明高水平的内源多胺总量和Put可能有利于花原基分化,2天后Spm含量上升有利于花器官原基分化,而Cad含量变化可能是区别花芽和营养芽分化的特征之一。     

Floral Organogenesis and Development of Two Taxa in Tribe Hyoscyameae (Solanaceae)?aPrzewalskia tangutica and Hyoscyamus niger

Floral organogenesis and development of Przewalskia tangutica Maxim.endemic to China and Hyoscyamus niger L., which belong to the tribe Hyoscyameae (Solanaceae), were studied using scanning electron microscope. They have three common characters of floral organ initiation and development: 1) initiation of the floral organs in the two species follows Hofmeister’s rule; 2) the mode of corolla tube development belongs to the “late sympetaly” type; 3) primordia of the floral appendages initiated in a pentamerous pattern and acropetal order. But initiation of the calyx lobe primordia showed different modes in these two species. The calyx lobe primordia of H. niger have simultaneously whorled initiation, while those of P. tangutica have helical initiation, but the five calyx lobe primordia form a ring after all five calyx lobe primordia occur. The systematic significance of the present results in the genera Hyoscyamus and Przewalskia is discussed in this paper.     

Wound-Induced Initiation of Involucral Bracts and Florets in the Developing Sunflower Inflorescence

The production of additional floral organs by the inflorescenceof Helianthus annuus as a boron deficiency symptom was examinedand found to be related to the occurrence of minute splits inthe receptacle of the young capitulum. Wounding the receptacleby puncturing or cutting at an early stage when the receptacledome was forming (floral stage 3) or later when the receptaclehad either become saucer-shaped (floral stage 4) or the firstrows of disc floret primordia were appearing on the rim of thereceptacle (floral stage 5) resulted in the initiation of involucralbracts, ray and disc florets in the wound area, reproducingthe symptoms of boron deficiency. When the receptacle was woundedat later floral stages, when the receptacle was partially orwholly covered by disc floret primordia, involucral bracts andray florets were not formed in the proximity of the wound, leadingto the conclusion that the commitment of floral organ primordiabegins at the time of their initiation. The inductive effectsof wounding could not be reproduced by indoleacetic acid, naphthaleneaceticacid or benzyladenine applied to the receptacle surface in lanolinepaste. The results are related to the normal development ofthe sunflower inflorescence and it is concluded that the firstfloral organ primordia that appear in floral stage 3 and developinto involucral bracts during floral stage 4 may determine thepositions of subsequent primordia and establish the radial symmetryof the inflorescence. ¹ Supported by a grant from the Australian Research Grants Scheme. (Received August 10, 1982; Accepted October 12, 1982)     

泽苔草的花器官发生

本文用扫描电镜观察了泽苔草的花器官发生过程,观察结果表明：花萼以螺旋状方式向心发生,花瓣以接近轮状方式近同时发生,不存在花瓣雄蕊复合原基。雄蕊和心皮均以轮状向心方式发生,6枚雄蕊分两轮分别在对萼和对瓣的位置先后发生,至发育的后期排成一轮,但仍分别处于对萼和对瓣的位置;随后发生的第一轮3个心皮原基与3枚萼片相对,第二、三轮心皮原基分别为1~3个,与前一轮心皮相间排列向心发生。本文首次揭示了泽苔草花被的外轮3个萼片螺旋状发生方式,这种螺旋状方式很可能是泽泻科植物的花部结构在进化过程中适应环境而保留下来的一种较原始的叶性特征。     

Developmental study on the inflorescence and flower of Caldesia grandis Samuel (Alismataceae)

The inflorescence and floral development of Caldesia grandis Samuel is reported for the first time in this paper. The basic units of the large cymo‐thyrsus inflorescence are short panicles that are arranged in a pseudowhorl. Each panicle gives rise spirally to three bract primordia also arranged in a pseudowhorl. The branch primordia arise at the axils of the bracts. Each panicle produces spirally three bract primordia with triradiate symmetry (or in a pseudowhorl) and three floral primordia in the axils of the bract primordia. The apex of the panicle becomes a terminal floral primordium after the initiations of lateral bract primordia and floral primordia. Three sepal primordia are initiated approximately in a single whorl from the floral primordium. Three petal primordia are initiated alternate to the sepal primordia, but their subsequent development is much delayed. The first six stamen primordia are initiated as three pairs in a single whorl and each pair appears to be antipetalous as in other genera of the Alismataceae. The stamen primordia of the second whorl are initiated trimerously and opposite to the petals. Usually, 9–12 stamens are initiated in a flower. There is successive transition between the initiation of stamen and carpel primordia. The six first‐initiated carpel primordia rise simultaneously in a whorl and alternate with the trimerous stamens, but the succeeding ones are initiated in irregular spirals, and there are 15–21 carpels developed in a flower. Petals begin to enlarge and expand when anthers of stamens have differentiated microsporangia. Such features do not occur in C. parnassifolia. In the latter, six stamen primordia are initiated in two whorls of three, carpel primordia are initiated in 1–3 whorls, and there is no delay in the development of petals. C. grandis is thus considered more primitive and C. parnassifolia more derived. C. grandis shares more similarities in features of floral development with Alsma, Echinodorus, Luronium and Sagittaria. © 2002 The Linnean Society of London, Botanical Journal of the Linnean Society, 2002, 140 , 39–47.     

FLORAL DEVELOPMENT IN MYRISTICA (MYRISTICACEAE)

Myristica fragrans and M. malabarica are dioecious. Both staminate and pistillate plants produce axillary flowering structures. Each pistillate flower is solitary, borne terminally on a short, second-order shoot that bears a pair of ephemeral bracts. Each staminate inflorescence similarly produces a terminal flower and, usually, a third-order, racemose axis in the axil of each pair of bracts. Each flower on these indeterminate axes is in the axil of a bract. On the abaxial side immediately below the perianth, each flower has a bracteole, which is produced by the floral apex. Three tepal primordia are initiated on the margins of the floral apex in an acyclic pattern. Subsequent intercalary growth produces a perianth tube. Alternate with the tepals, three anther primordia arise on the margins of a broadened floral apex in an acyclic or helical pattern. Usually two more anther primordia arise adjacent to each of the first three primordia, producing a total of nine primordia. At this stage the floral apex begins to lose its meristematic appearance, but the residuum persists. Intercalary growth below the floral apex produces a columnar receptacle. The anther primordia remain adnate to the receptacle and grow longitudinally as the receptacle elongates. Each primordium develops into an anther with two pairs of septate, elongate microsporangia. In pistillate flowers, a carpel primordium encircles the floral apex eventually producing an ascidiate carpel with a cleft on the oblique apex and upper adaxial wall. The floral ontogeny supports the morphological interpretation of myristicaceous flowers as trimerous with either four-sporangiate anthers or monocarpellate pistils.     

Floral organogenesis of Potamogeton distinctus A. Benn. (Potamogetonaceae)

The floral organogenesis of Potamogeton distinctus A. Benn. was observed under the scanning electron microscope (SEM). The floral buds are first initiated on the lower portion of inflorescence in alternating whorls of three. Each of the floral buds is subtended by a bract primordium during the early stages. The primordia of the floral appendages arise on the floral bud acropetally. Two lateral tepals are first initiated and then two median ones soon after. Stamens are normally initiated as elongate primordia opposite the tepals, with the two lateral stamens preceding the median ones. The two carpel primordia arise alternating with the stamens. In some flowers, one of the two gynoecial primordia becomes inactive soon after they are initiated, or only one carpel primordium is initiated. The present observation of the gynoecial development supports the viewpoint that the evolution of flower in Potamogeton involves a reduction in number of parts. The existence of bract primordium during the early stages in many species of Potamogeton indicates that the absence of bractin mature flowers should be the result of reduction.     

Inflorescence and floral development in Astragalus lagopoides Lam. (Leguminosae: Papilionoideae: Galegeae)

Inflorescence and floral organogenesis and development of the bushy perennial legume Astragalus lagopoides of the section Hymenostegis were studied by means of epi-illumination light microscopy. Based on our observations, the primordia of lanceolate racemose inflorescences are born in the axils of leaves. Each inflorescence apex initiates acropetally bracts and floral apices for some time and then eventually ceases meristematic activity and forms an oblong-shaped terminal structure. The formation of such atypical terminal protrusion on the inflorescence meristem is judged to be a diagnostic feature for well-organized cessation of meristem morphogenesis. Pentamerous perfect flowers of the plant show strong zygomorphy and marked overlap in time of initiation among different organ primordia. Unexpectedly, sepal initiation is bidirectional starting from the lateral sides of the floral apex. Other significant developmental feature includes the existence of two types of common primordia, which are formed successively. From the primary common primordia there are produced antesepalous stamens and secondary common primordia. In comparison, the five secondary common primordia subdivide into a petal and an antepetalous stamen primordia. Initiation of two different types of common primordia is possibly the result of rising overlap in time of initiation of organs and demonstrates an advanced developmental style in the genus Astragalus.     

Floral morphogenesis of Caltha and Trollius (Ranunculaceae) and its systematic significance

The floral morphogenesis of Caltha palustris L. and Trollius buddae Schipcz. was observed with a scanning electron microscope (SEM). The primordia of all floral organs initiate spirally and centripetally and develop centripetally. The spiral initiation sequence may be a basic pattern in Ranunculaceae. The primordia of bracts, sepals, and other floral organs are different in shape: the bract primordia are triangle, the sepal primordia crescent, and the petal (in Trollius), stamen, and carpel primordia hemispheric. This may indicate that the bracts, the sepals and other floral organs are different in origin. The petals are retarded in early developmental stages in Trollius buddae Schipcz, and have purses at the base. The retarded petals are very common in Ranunculaceae and the purse of the petal is similar to that of some Aquilegia species. The microspores in a longitudinal series of stamens develop centripetally in Caltha and Trollius; this may be a basic pattern in Ranunculaceae. The carpel primordia are plicate. In the developmental process of the carpels, the stigmatic tissue appears from the apex of the style and is decurrent along the ventral suture in Caltha, but there is no obvious stigmatic tissue in Trollius. Based on floral morphogenesis characteristics as well as the results from molecular systematics, comparative morphology and palynology studies, we consider that Caltha is not closely related to Trollius and that these two genera should not be treated in the same tribe.     

A putative lipase gene EXTRA GLUME1 regulates both empty-glume fate and spikelet development in rice

Recent studies have shown that molecular control of inner floral organ identity appears to be largely conserved between monocots and dicots, but little is known regarding the molecular mechanism underlying development of the monocot outer floral organ, a unique floral structure in grasses. In this study, we report the cloning of the rice EXTRA GLUME1 ( EG1 ) gene, a putative lipase gene that specifies empty-glume fate and floral meristem determinacy. In addition to affecting the identity and number of empty glumes, mutations in EG1 caused ectopic floral organs to be formed at each organ whorl or in extra ectopic whorls. Iterative glume-like structures or new floral organ primordia were formed in the presumptive region of the carpel, resulting in an indeterminate floral meristem. EG1 is expressed strongly in inflorescence primordia and weakly in developing floral primordia. We also found that the floral meristem and organ identity gene OsLHS1 showed altered expression with respect to both pattern and levels in the eg1 mutant, and is probably responsible for the pleiotropic floral defects in eg1 . As a putative class III lipase that functionally differs from any known plant lipase, EG1 reveals a novel pathway that regulates rice empty-glume fate and spikelet development.