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.     

兰花蕉花部维管束系统的解剖学研究

兰花蕉花梗的维管束分散排列．子房基部的维管束排成两部分,外方为一轮大维管束环,中央为分散排列的小维管束区。前者的纸管束进入子房壁,后者进入子房的中轴,形成股座纸管束;及至延长都以后,股座维管束逐渐消失．子房壁上的维管束较易识别的有心皮背束、心皮背束伴束和隔膜束．三束心皮背束经延长部最终进入花柱和柱头．心皮背束指心皮背束务与其紧靠的大维管束,三枚心皮背束伴束最终分别进入三枚外轮雄蓝．三枚隔膜束中远轴面的两枚分别进入两校内轮雄蕊,而近轴面的一枚伴随着第六枚雄蓝的缺失最后进入唇瓣中央．子房壁其余的维管束进入延长部后,先向外分出一轮纸管束进入花幕,余下的中央部分排成一轮心形的线管来环．该环远轴面的维管束分为两半分别进入两枚侧生花瓣;近轴面即心形凹陷一侧初为两轮即外轮大的维管束与内轮小的维管束,后排成一轮并与近轴面的隔膜束一同进入唇瓣．兰花蕉的唇瓣既为花瓣成员,又含一枚缺失的雄蓝维管束,与姜目已报道的只来自退化雄蕊的竹芋科的兜状结构和美人蕉科、姜科、闭鞘姜科的唇瓣有明显区别．在旅人蕉科尚未有研究资料的情况下,作者根据已有资料,对姜目雄蕊维管束系统来源和结构进行比较,初步认为在姜目的系统演化上,兰花蕉科与芭蕉料更近．     

红蕉花部维管束系统的解剖学研究

红蕉花单性、同株 ,雄花与雌花花梗部的维管束均可分为外环维管束、中环维管束及中央维管束区。雌花外环维管束逐渐外移 ,并分支、变小、数目增多 ,至子房室区中部时几乎贴近表皮 ;中环维管束与外环维管束形态基本相似、稍大 ,至延长部中上部时与外环维管束合成一轮 ,最后进入花被片 ,成为花被维管束系统 ;中央维管束区在花梗部时排列为六组 ,组间有一些小的维管束分布。在室下区 ,近轴面隔膜维管束组消失 ,至子房室区基部时 (室下区 )其它五组逐渐聚集成明显五束 ;而组间的小维管束向中央聚拢 ,于子房室区基部时排列成环形 ,接着进入子房室中轴成为胎座维管束 ,随后束形变小 ,且随子房室的变小而外移 ,经延长部最后进入花柱 ,与心皮背束内方的三枚分支一起成为花柱维管束系统。三束心皮背束延伸至延长部时均分裂为内、外两支 ,三枚外方的分支进入三枚外轮雄蕊。两束远轴面隔膜束进入两枚内轮雄蕊。雄花与雌花的维管束系统基本相似 ,差异主要在雄花无子房室区及中轴的胎座维管束消失。     

姜花(Hedychium coronarium)花部维管束系统解剖学研究

姜花(Hedychium coronarium Koen.)花梗横切面整体轮廓呈椭圆形,可分为表皮、基本组织和维管束。维管束在基本组织中呈内、外两部分排列。内部维管束联结成网,形成明显外移的三束心皮背束和内方与心皮背束相间的三束隔膜束。至子房室区,心皮背束继续外移,其中主支进入花萼中脉;小分支内移,与内方一轮维管束联结,后来进入唇瓣中央及2枚侧生附属物。在花萼形成的同时,远轴面的两个隔膜中各形成一个上位腺体;同时两束远轴面隔膜束向外、两侧分别形成3束大分支,外方大分支继续外移成为2枚远轴面花瓣中脉,两侧大分支与原外方内移的子房壁维管束集合成一相连的环状维管束网,后进入唇瓣两侧;近轴面隔膜束形成3枚分支,外方分支成为近轴面花瓣中脉,两侧分支进入可育雄蕊。探讨了侧生附属物和唇瓣的来源,支持子房延长部形成的腺体为隔膜蜜腺的变异结构的观点。     

小草蔻花部维管束系统的解剖学研究

小草蔻花梗的维管束可分成外环和中心区两部分。进入室下区后,外环维管束向外偏移,其数目由约13束增加至约40束;中心区由不规则分布的18束变为三角形排列的12束。延伸至子房室区时,外环基本不变,而原来中心我的维管束则成为3束心皮背束、3束隔膜束及5－7束小的胎座维管束。3束心皮背束外方的主支经延长中最后进入花萼、胎座维管束于延长部基部消失。及至延长部基部,3束隔膜束的内侧横向分支,并最后与部分外环的维管束及心皮背束方的细小分支在此形成一个维管束网结,而外侧的主支直接向上延伸;近轴面的隔膜束主支分裂成4支最后进入仅有的1枚功能雄蕊,无轴面的2束隔膜束主支则各分成2－3束最后进入唇。延长部的维管束网结部分延伸入花瓣、唇瓣和腺体基部,少量进入花柱。首次提出姜科植物的花萼既代表了3枚花萼片,又包含了3枚缺失的外轮雄蕊。支持姜科的唇瓣代表了两枚缺失的内轮雄蕊及两枚腺体是隔膜腺变异结构的观点。     

鸭跖草花部维管束系统解剖学研究

鸭跖草花梗项部的维管束分布在中央的基本组织内。自花梗顶部至子永恒基部,维管束系统发生复杂的变化。6枚向外偏斜的维管束发生内外或左右分支,其中3枚维管束发生内外分支,其外侧的3个分支进入萼片成为萼片给管束系统,内侧3个分支进入3枚外轮雄蕊而成为外轮雄蕊维管束;另3枚维管束先发生内外分支,接着外侧3分支发生进一步的左右分支,各形成3－5个小分支,最后进入花瓣成为花瓣维管束系统,而内侧的分支则不再细分,最后伸入3枚内轮雄蕊,成为轮雄蕊维管束。另6枚近圆束形的维管束一直在中央向上延伸,进入子房屋区后,其中3格言 进入子房壁,成为3束心皮背束,最后3束心皮背束进入花柱成为花柱维管史,另3枚聚向中央,成为胎座维管束,胎座维管束至子房屋顶部时消失。文中对跖草及其有关类群的花部维管束系统的来源及演变进行了比较、讨论。     

兰花蕉花的形态解剖学

兰花蕉（Orchidantha chinensis)的子房室顶部闭合后向上延长成延长部,实心,但有花柱沟和隔膜蜜腺管通过,隔膜蜜腺管,可分为中央蜜腺管和三条侧蜜腺管;中央蜜腺管位于三个心皮连接处,自子房室区下部产生,向上于延长部的部顶端终止;三条侧管分别位于两个心皮连接处,于子房室区近中部产生,开口于花柱基部。兰花蕉子房室区与延长部均具6枚雄蕊的维管束系统,即3枚心皮背束的伴束与3枚隔膜束,近轴面1枚事膜向上进入唇瓣的维管束系统,位于唇瓣的中央,致使兰花蕉仅具5枚功能雄蕊,唇瓣具双重结构,本文还讨论了兰花蕉科的系统发育位置。     

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。     

大鹤望兰花部维管束系统的解剖学研究

大鹤望兰梗横切面近三角形,花梗的维管束分散公布在基本组织内。室下区的维管束大致排列三两部分,外方为一到两环维管束组成的外维管束环,中央为分散排列的中央维管束区。前者的维管束进入子房避讳,后者的维管束进入子房的中轴,形成从维管束。至延长部后,胎座维管束逐渐消失。子房壁上的维管束较易识别的有心皮背束、心成背束伴束和隔膜束。３束心皮背束经处长部最终进入花柱。３枚心皮背束伴束最终分别进入一枚１２上轮雄蕊。     

Floral vasculature in Alpinia hainanensis in relation to the nature of the labellum in gingers

Observations presented here on floral vasculature in Alpinia hainanensis indicate that the labellum incorporates elements of five androecial members rather than two or three, as suggested by previous authors for Zngiberaceae flowers. The pedicel contains an outer ring and a central region of vascular bundles. Three carpellary dorsal bundles (CDs) and three alternatively arranged parietal bundles (PBs) separate from the central region successively. The remaining bundles of the central region run upwards and become the placental bundles to supply ovules. The placental bundles terminate between the top of the locular region and the base of the prolongation. The three PBs divides into about five strands respectively. Of which the outer strand enters into the petal being its midrib and the remaining strands move into the stamen adaxially being the vasculature of the functional stamen and the labellum abaxially being the lateral strands of the labellum. The three CDs divide into about five traces, of which the outer strand becomes the midrib of each sepal and the inner strand runs into the style. The remaining traces re‐unite, re‐divide again in the course up and the two adaxial sets of carpellary dorsals finally enter into the labellum being the marginal traces of it while the abaxial single strand enters into the labellum being its midrib. The two antero‐lateral glands receive small traces without lignified tube elements from the vascular plexus, which fonn in prolongation from both PBs and CDs and a few small strands in the ovary wall. There are no subulate appendages differentiated in the flower of Alpinia hainanensis. Hereby, the median of the sepals, both the marginal portions and the median of labellum, and the style have the same origin in vasculature from the CDs and so do the stamen, the lateral portions of labellum and the median of the petals from PBs. The labellum is supposed to represent three members of the outer androecial whorl by its two marginal portions and the median and two members of the inner whorl by its two lateral parts except the median.     

Plenasium xiei sp. nov. from the Cretaceous of Northeast China: Additional evidence for the longevity of osmundaceous ferns

A new species of the Osmundaceae, Plenasium xiei sp. nov., is herein described from the Cretaceous of Northeast China. The specimens examined here represent the earliest unequivocal record of the extant genus Plenasium in Eurasia based on fossil rhizomes. The rhizome consists of a central stem with a mantle of petiole bases and adventitious roots. The stem contains an ectophloic‐dictyoxylic siphonostele and a two‐layered cortex. The C‐shaped leaf trace bears two protoxylem bundles at the point of separation from the stele. The pith is heterogeneous. The parenchymatous inner cortex is thinner than the sclerenchymatous outer cortex. Lobed sclerenchyma bands occur at the adaxial sides of the stem xylem strands, in the concavity of the leaf trace, and along the adaxial side of the vascular bundles of the petiole base. In distal petiole portions, the sclerenchyma band splits into several groups in the transverse view. Sclerenchyma rings are heterogeneous with an abaxial sclerenchymatous arc of thick‐walled fibers. Numerous sclerenchyma strands of thick‐walled fibers appear in the petiolar inner cortex and the stipular wing. These fossils provide unambiguous evidence for the existence of subgenus Plenasium of modern Plenasium by at least the Late Cretaceous, demonstrating the longevity of this extant subgenus. Altogether the leaf and rhizome fossil records of Plenasium indicate that this genus was widely distributed across North America and Eurasia from the Early Cretaceous to the Early Cenozoic, followed by a range restriction to Eurasia in the Late Cenozoic. Extant Plenasium species are only known from East and Southeast Asia.     

THE VASCULAR SYSTEM OF THE INFLORESCENCE AXIS OF ANDROPOGON GERARDII (GRAMINEAE) AND ITS BEARING ON CONCEPTS OF MONOCOTYLEDON VASCULAR TISSUE

The vascular bundles in the inflorescence axis of Andropogon gerardii occur in inner and outer systems. The inner system is made up of large, early developing strands that, at earliest stages of development, are precocious (= the appendage they are to serve has not yet been initiated). The outer system consists of later developing smaller strands that are open ended in a proximal direction (= strands differentiate basipetally in the cortex below the appendage they serve). Bundles of both the inner and outer systems are not connected to other procambium early in their development but exist as isolated strands. The veins of the inner system of the inflorescence axis occur as sympodia. The presence of inner and outer systems in the vascular tissue is common to most monocotyledons. However, amongst monocotyledons, only certain grasses have been shown to have strands of the inner system that are isolated early in development. Many dicotyledons have large strands which are precocious and some have smaller, later developing strands which are open ended in a proximal direction, hence they occur as isolated strands. These smaller strands in dicotyledons occur between large strands. Certain dicotyledons have an inner and an outer system of veins. Of these, some have veins of the inner system that differ from the inner system bundles of monocotyledons in that they also form part of the outer system of veins, or develop at a different time. One other dicotyledon with an inner and outer system, Bougainvillea, differs from monocotyledons only in that the bundles of the outer system do not seem to be isolated early in their development and anastomoses are seen between the inner and outer systems. Thus, it appears that monocotyledons differ from dicotyledons only in the presence of independent inner and outer systems of vascular bundles in the former. Thus, the hypothesis of Zimmermann and Tomlinson that there are basic differences between monocotyledon and dicotyledon vascular systems is not substantiated. It is even suspected that monocotyledon and dicotyledon vascular systems will be demonstrated to be modifications of a basic plan consisting of large, acropetally differentiating and smaller, basipetally differentiating strands.     

Comparative vegetative anatomy of Stanhopeinae (Orchidaceae)

Stanhopeinae are a group of tropical American orchids characterized by euglossine bee pollination and lateral inflorescences stemming from the bases of pseudobulbs. Leaves are hypostomatal, and all stomatal configurations are tetracytic. Chlorenchyma is homogeneous and characterized by fibre bundles in adaxial/abaxial or adaxial/median/abaxial positions. Collateral vascular bundles occur in a single row and feature phloic and xylic sclerenchymatous caps and thin-walled bundle sheath cells. Fibre bundles and vascular sclerenchyma are accompanied by stegmata containing conical silica bodies. Pseudobulbs have thick-walled turbinate epidermal cells and ground tissue of smaller, living assimilatory cells and larger, dead water-storage cells. Fibre bundles are usually absent but occur in several genera. Collateral vascular bundles show phloic sclerenchyma, but xylic sclerenchyma occurs only in die larger vascular bundles. Phloic and xylic sclerenchyma are associated with stegmata containing conical silica bodies. Roots are velamentous. Velamen cell walls have fine, spiral thickenings. Exodermal cells are thin-walled. The cortex features scattered thick-walled cells and in some cases branched bars of secondary cell wall material. Endodermis is either u-or O-thickened, but pericycle is always O-thickened opposite the phloem. Vascular tissue consists of alternating strands of xylem and phloem surrounded by a matrix of thick-walled cells. Pith cells may be parenchymatous or sclerenchymatous.