新疆鼠尾草花蜜腺的发育解剖学研究

新疆鼠尾草（Salvia deserta Schang）花蜜腺位于子房基部的花托上,为盘状的花托蜜腺,其顶部裂成4片,其裂片大小不等,比例悬殊。蜜腺由产蜜组织和分泌表皮构成,又为结构蜜腺。组织化学染色显示淀粉粒动态明显,因此又属淀粉蜜腺。在发育的过程中细胞液泡化动态明显,且淀粉粒和蛋白质具有明显的消长变化,但PAS反应和苏木精脂类染色无明显变化。其泌蜜过程可能为：原蜜汁由邻近的韧皮部提供,经薄壁细胞运送至产蜜组织,在产蜜组织中进一步积聚、合成后,最终蜜汁通过变态气孔和分泌表皮细胞的角质层泌出。     

Nectary Structure and Ultrastructure of Unisexual Flowers of Ecballium elaterium(L.) A. Rich. (Cucurbitaceae) and their Presumptive Pollinators

The structure and ultrastructure of the nectaries of the monoeciousspecies Ecballium elaterium were studied. Large differencesin size and structure of the nectaries were observed in thetwo genders of flowers, those of the staminate flowers beingmuch larger and more developed than those of the pistillateflowers. The latter do not secrete measurable amounts of nectar.In the nectariferous cells, especially of the staminate flowers,numerous plasmodesmata are present. The pre-nectar originatingin the phloem is stored in the plastids of the nectariferouscells primarily as starch grains. The nectar appears to be exudedfrom the nectary via modified stomata. Very small insects ofthe order Hemiptera were found to dwell inside the flowers ofthe two genders, but in different numbers; their number in thestaminate flowers was more than twice that in the pistillateflowers. These insects may take part in the process of pollination.Copyright 2001 Annals of Botany Company Ecballium elaterium, Cucurbitaceae, monoecious plant, nectaries, structure, ultrastructure, nectar secretion, stomata, Hemiptera insects     

THE FLORAL AND EXTRA-FLORAL NECTARIES OF PASSIFLORA. I. THE FLORAL NECTARY

Floral nectary development and nectar secretion in three species of Passiflora were investigated with light and electron microscopy. The nectary ring results from the activity of an intercalary meristem. Increased starch deposition in the amyloplasts of the secretory cells parallels maturation of the nectary phloem. Large membrane-bound protein bodies are observed consistently in phloem parenchyma cells, but their function is presently unknown. The stored starch serves as the main source of nectar sugars at anthesis. Plastid envelope integrity is maintained during starch degradation, and there is no evidence of participation of endoplasmic reticulum or Golgi in the secretion of pre-nectar. It is concluded that in these starchy nectaries granulocrine secretion, commonly reported for floral nectaries, does not occur.     

鹅掌柴花蜜腺的发育解剖学研究

对鹅掌柴(Scheffler octophylla Harms．)花蜜腺的发育进行解剖结构观察。鹅掌柴花盘蜜腺位于下位子房上方环绕花柱基部。蜜腺由分泌表皮、产蜜组织组成,心皮维管束与其相邻并发出一些伸入蜜腺基部的短分枝。蜜腺起源于心皮原基基部外侧的几层细胞。鹅掌柴花蜜腺为淀粉型蜜腺,淀粉粒为许多微小颗粒聚集成的复粒。原蜜汁由蜜腺基部维管束的筛管提供,达产蜜组织细胞和表皮细胞后以淀粉粒的形式贮藏。泌出的蜜汁一部分来自淀粉粒的降解,一部分来自泌蜜期输入的原蜜汁。表皮和产蜜组织细胞均具泌蜜功能。泌出的蜜汁大部分通过气孔排出,还有部分由角质层渗出。     

油菜花蜜腺发育过程的超微结构变化与泌蜜机理的研究

油菜花蜜腺由２枚侧蜜腺和２枝中蜜腺组成,其基本结构类似。在蜜腺发育过程中,产蜜组织细胞内的内质网、高尔基体、质体和线粒体以及液泡都发生有规律变化。泌蜜前,细胞器的数量增加。其中,质体内积累淀粉,此过程与蜜腺内初皮部的分化并和线粒体的增加相关。泌蜜时,内质网数量增多,并产生小泡．小泡向质膜移动。泌蜜后,细胞液泡化,细胞器数量减少,细胞萎缩。根据观察结果分析,其原蜜汁来源于韧皮部,转运至产蜜组织细胞的质体、内质网和高尔基体内加工成蜜汁,最后通过胞吐和渗透相结合的方式泌出。     

异株百里香花蜜腺的发育解剖学研究

异株百里香（Thymus marschallianus Willd）花蜜腺分布于子房基部的花托上,结构蜜腺盘状,成熟时膨大,环绕在花托外。蜜腺组织由分泌表皮、产蜜组织和维管束三部分组成;组织化学染色显示淀粉粒的积累是在蜜腺细胞发育的最初和最后,因此将其归为非淀粉型蜜腺。在发育的过程中细胞液泡化动态明显,而淀粉粒和多糖均不具有明显的消长变化;蜜汁是由韧皮部运转到泌蜜组织中的,再由表皮细胞的角质层渗到细胞外。     

荆条花蜜腺发育解剖学研究

荆条（Ｖｉｔｅｘ ｃｈｉｎｅｎｓｉｓ Ｍｉｌｌ．）花蜜腺属于淀粉型子房蜜腺,呈圆筒状环绕于子房的基部。蜜腺外观上无特殊结构,表面有。由分泌表皮和泌蜜组织组成,包括分泌表皮、气孔器、泌蜜薄壁组织和维管束。密腺和子房壁起源相同。花蕾膨大期,泌蜜组织细胞中产生大液泡;露冠期,泌蜜组织中形成维管束;花蕾初放期,分泌表皮细胞分化形成气孔器,无气孔下室,淀粉粒的积累在此期达到高峰;盛花期,蜜腺中已无淀粉粒,密     

Developmental and Anatomical Studies on the Floral Nectaries of Capsella bursa-pastoris

The development and structure of the floral nectaries of Capsella bursa-pastoris (L.) Medic. were examined. The nectaries consisted of four separated parts which were semiorbicular and were morphologically and anatomically similar to one another. They were located at the receptacle between stamens, and each part was composed of secretory epidermis, nectariferous tissue and vascular bundles, belonging to structural nectary. When the various floral organs were developed, 2--3 superficial layer cells of the receptacle between stamens became meristemoid and contributed to primordia the formation of nectary. By intercalary meristematic activity, the four nectaries formed synchronously. During the different stages of nectary differentiation, the content of starch gra ins and vacuolation in the cells of epidermis and nectariferous tissue changed regularly. According to the structural and histochemical changes the pre-nectar might be supplied by phloem. The nectar formed in nectariferous tissue was then secreted to the sub-stomatal chamber and where it was finally excreted from the stoma.     

药用类短命植物新疆阿魏花蜜腺的发育解剖学研究

类短命植物新疆阿魏(Ferula sinkiangensts K.M.Shen),是新疆独具特色的药用蜜源植物,其花蜜腺位于下位子房的花盘之上,由子房上部的表层细胞特化而形成的,属下位子房上的盘状蜜腺.但由于其花柱短,基部呈圆锥状,蜜腺分布于盘状结构表面除花柱外的区域,因而可以认为是花柱基部类蜜腺的一种扩展和特化,属于从子房蜜腺向花柱蜜腺过渡的类型.在蜜腺下方分布有大量的子房维管束,其泌蜜途径可能为:前蜜汁经共质体或非共质体途径到产蜜组织中,加工后再经共质体途径运进气孔下方的特殊细胞中,再分泌到孔下室,经气孔泌出.其花蜜腺在发育过程中液泡化动态明显,PAS反应测试细胞具阳性物质,淀粉粒积累动态较明显.     

牛至花蜜腺的发育解剖学研究

牛至花蜜腺位于子房基部的花盘上,属于盘状蜜腺。蜜腺组织由分泌表皮和产蜜组织组成。分泌表皮液泡化明显,并分布有气孔器。在子房发育成熟后,由花盘表面细胞恢复分裂能力形成蜜腺原基。产蜜组织在发育过程中,液泡、淀粉粒都呈现出一定的消长规律,此种规律与蜜汁的合成和分泌有关。原蜜汁由蜜腺周围的韧皮部提供,经产蜜组织积聚合成,然后通过气孔器泌出。本文还对霜冻条件下蜜腺的结构和功能进行了初步分析。     

Ultrastructural Aspects of the Nectary Spur of Limodorum abortivum (L) Sw. (Orchidaceae)

The ultrastructure of the nectary spur of Limodorum abortivum(L) Sw. was examined before and after anthesis. In cross sectionthe nectary spur shows an internal epidermal layer of thin-walledcells bordering the secretory cavity and 10–12 layersof parenchyma cells. The ultrastructure of the secretory cellssuggests the involvement of ER, Golgi and plastids in nectarsecretion. The nectar accumulated in the sub-cuticular spaceis released into the nectariferous cavity by rupture of theouter layer of the cuticle. Limodorum abortivum (L) Sw., Orchidaceae, nectary spur, nectar secretion, ultrastructure, anthesis, endoplasmic reticulum, dictyosomes, plastids     

荔枝花蜜腺发育解剖学研究

荔枝花蜜腺呈盘状,位于子房和花萼之间的花托上。花盘蜜腺由表皮、产蜜组织、维管束组成。蜜腺的原始细胞由花托表面的2~3层细胞脱分化产生。成熟蜜腺产蜜组织细胞含有淀粉粒,为淀粉型蜜腺,表皮细胞内无淀粉粒。产蜜组织出现分化:PAS反应颜色深的细胞成网状分布,与表皮下方的1~2层细胞相连,构成蜜汁的运输通道;颜色浅的细胞分布于网眼处。蜜腺表皮上的角质层波状皱折,有泌蜜孔。表皮毛主要起保护作用,大部分蜜汁通过泌蜜孔排出。     

刺五加雌花蜜腺的显微形态和超微结构观察

利用光学显微镜、扫描电镜及透射电镜对刺五加雌花蜜腺结构进行了观察,结果表明:(1)刺五加雌花蜜腺为花盘蜜腺,由表皮和泌蜜组织构成;(2)蜜腺表面几乎均匀地分布着大量变态的气孔,蜜汁从气孔泌出;(3)蜜腺发育过程中有淀粉粒的积累和水解过程,液泡也伴随规律性变化;(4)蜜腺分泌方式为渗透型,或者以渗透型为主胞吐型为辅的分泌方式;(5)金胺O染色说明蜜腺表面具有角质层,可观察到微通道从中穿过,可能是蜜汁向外界分泌的通道之一.     

Development and Ultrastructure of Cucurbita pepo Nectaries of Male Flowers

The development of the nectary of the male flower ofCucurbitapepo L. was studied from 5d before to 2d after anthesis. Thenectary consists of parenchyma that stores starch in the presecretorystages, and epidermis. An hour before nectar secretion begins,the starch is hydrolyzed. The nectar exudes from the stomataand forms a continuous layer on the nectary surface. Duringanthesis the nectar may all be collected by pollinators or someor all of it may remain in the nectary and be successively resorbed.The nectary parenchyma stores material for synthesizing thesugar component of nectar and stores similar material againafter nectar resorption. It is also responsible for nectar productionand secretion. The epidermis is actively involved in the reabsorptionprocess. The resorption of nectar is a phenomenon that allowsthe plant to recover invested energy. Few observations on thisphenomenon have hitherto been published. Amyloplasts; Cucurbita pepo L.; courgette; nectaries; Nectar resorption; plastid; secretion; starch     

长药景天花蜜腺的发育解剖学研究

长药景天花蜜腺５枚,呈侧向扁平的舌形或弯月形,分别位于５株离生心皮的外侧,两者的基部相连,属于子房蜜腺。蜜腺由分泌表皮、产蜜组织和仅含韧皮部的维管束组成。长药景天花蜜腺起源于心皮外侧基部的表层结构。产蜜组织在发育过程中,细胞中的液泡体积及淀粉粒呈现有规律的消长变化。泌蜜后期,蜜腺组织从上往下液泡化,具明显的方向性。根据其结构及多糖变化分析,来自韧皮部的原蜜汁以淀粉粒形式贮存于产蜜组织中,泌蜜期水解     

３种獐牙菜属植物花蜜腺的发育解剖学研究

獐牙菜属的红直獐牙菜、抱茎獐牙菜和四数獐牙菜３种植物花蜜腺都属花被蜜腺,其结构相似,均由分泌表皮和产蜜组织组成,为结构蜜腺,是花冠其部薄壁组织恢复分和能力形成的,分泌表皮无气孔器,原蜜汁由蜜腺周围的维管束提供,经产蜜组织加工后,由分泌表皮外薄的角质层泌出。四数獐牙菜花蜜腺裸露,凸起,而另２化蜜腺凹限为囊状、;红直獐牙菜为脱落蜜腺、而抱茎獐牙菜和四数獐牙菜为宿存蜜腺,其花蜜腺的性状基本印证了３种獐牙菜属植物的系统位置。     

The Floral Nectary ofDigitalis purpureaL., Structure and Nectar Secretion

The floral nectary of the foxglove (Digitalis purpureaL.), locatedat the base of the ovary, was examined by: scanning electronmicroscopy; quantitative bright-field microscopy via computer-aided3-D reconstruction from serial sections; morphometric procedures;transmission electron microscopy and measurement of nectar effluxunder different experimental conditions. Time-lapse video recordingvia a microscope with incident light clearly showed that thenectar escaped from the apertures of modified stomata. The volumeflux via individual stomatal apertures was 0.31±0.1 nlmin^-1; therefore only a fraction of the total number of stomataper nectary (115±8) would be sufficient to dischargethe amount of nectar reported in previous publications. Thestomatal apertures are continuous with intercellular spacestraversing the small-celled nectariferous tissue. The latteris vascularized only by phloem, whose termini consists of rowsof slender cells. These sieve-like cells are surrounded by moreor less isodiametrical sheath cells with dimensions similarto the secretory cells. Details of nectary functioning are basedon enhanced structural information, complementary data on nectardischarge after experimental manipulations and the nature ofthe effluence.Copyright 1998 Annals of Botany Company Digitalis purpureaL.; foxglove; floral nectary; (ultra-)structure; 3-D reconstruction; morphometry; nectar flow; time-lapse video recording.     

On the mechanisms of nectar secretion: revisited

Background and Scope

Models of nectar formation and exudation in multilayered nectaries with modified stomata or permeable cuticle are evaluated. In the current symplasmic model the pre-nectar moves from terminal phloem through the symplasm into the apoplasm (cell walls and intercellular spaces) with nectar formation by either granulocrine or eccrine secretion and its diffusion outwards. It is concluded, however, that no secretory granules are actually produced by the endoplasmic reticulum, and that secretory Golgi vesicles are not involved in the transport of nectar sugar. Therefore, the concept of granulocrine secretion of nectar should be discarded. The specific function of the endomembrane system in nectary cells remains unknown. According to the apoplasmic model, the pre-nectar moves from the terminal phloem in the apoplasm and, on the way, is transformed from phloem sap into nectar. However, viewed ultrastructurally, the unloading (terminal) phloem of nectaries appears to be less active than that of the leaf minor veins, and is therefore not actively involved in the secretion of pre-nectar components into the apoplasm. This invalidates the apoplasmic model. Neither model provides an explanation for the origin of the driving force for nectar discharge.

Proposal

A new model is proposed in which nectar moves by a pressure-driven mass flow in the nectary apoplasm while pre-nectar sugars diffuse from the sieve tubes through the symplasm to the secretory cells, where nectar is formed and sugars cross the plasma membrane by active transport (‘eccrine secretion’). The pressure originates as the result of water influx in the apoplasm from the symplasm along the sugar concentration gradient. It follows from this model that there can be no combinations of apoplasmic and symplasmic pre-nectar movements. The mass-flow mechanism of nectar exudation appears to be universal and applicable to all nectaries irrespective of their type, morphology and anatomy, presence or absence of modified stomata, and their own vascular system.     

葡萄两性花花蜜腺的发育解剖学研究

葡萄两性花的花蜜腺位于子房基部的花盘上,共5枚,呈椭圆形,与雄蕊相间排列,属于花盘蜜腺,蜜腺由表皮和泌蜜组织组成,缺乏维管束,表皮具薄的角质层,无气孔器,蜜腺原基由子房基部表层细胞恢复分裂能力形成,在蜜腺发育过程中,泌蜜组织的液泡规律 性变化和多糖动态变化均不明显,原蜜汁由子房维管束的韧皮部提供,蜜汁通过表皮细胞排出。