烟草花蜜腺发育的解剖学研究

烟草的花蜜腺位于子房基部 ,围绕子房 ,属于子房蜜腺。蜜腺由分泌表皮和泌蜜组织组成 ,分泌表皮角质膜厚薄不匀 ,表皮上分布少量气孔器 ,气孔凹陷 ,孔下室不明显 ,泌蜜组织细胞多层。蜜腺邻接子房壁维管束 ,本身没有维管组织。蜜腺由子房基部的外壁表皮及其相邻的内侧细胞经分裂、生长、分化而来 ,在发育过程中 ,细胞中的液泡和淀粉粒都呈现一定的消长规律。原蜜汁由子房壁维管束提供 ,经过泌蜜组织细胞加工后 ,蜜汁通过气孔和薄的角质膜处泌出。     

Ontogeny and structure of the drupe of Ozoroa paniculosa (Anacardiaceae)

An exocarp sensu stricto develops from the outer epidermis of the ovary wall. At maturity it comprises extensively radially elongated palisade-like parenchyma cellS. Besides having an outer cuticle, the outer tangential and outer parts of the radial cell walls of these cells are strongly cutinized. Large, permanently open stomata and saucer-shaped depressions also characterize the exocarp. The mature mesocarp sensu stricto consists of secondarily thickened parenchyma and brachysclereidS. An abundance of tanniniferous deposits and crystals, as well as secretory ducts associated with the vascular bundles also form part of the mature mesocarp. Derivatives of the inner epidermis of the ovary wall differentiate into the stratified endocarp sensu stricto. At maturity this comprises consecutive layers of macrosclereids, osteosclereids (typified by a capitate part and cell wall flutes), brachysclereids, and crystalliferous sclereidS. Pericarp structure is related to its taxonomic significance and the possible role of micromorphological characters in the survival strategy of Ozoroa paniculosa. It is shown that ontogenetic studies contribute to the precise interpretation of previously described cell layers, ensuring that homologous tissues are compared in different taxa.     

Comparative leaf anatomy of New Zealand and Tasmanian Inuleae (Compositae)

Leaf anatomy is compared for 47 taxa of the tribe Inuleae (Compositae) from New Zealand and Tasmania. The taxa are tabulated according to their lamina structure. Noteworthy anatomical features are lamina type and grade of differentiation, stomatal position, epidermis and cuticle thickness, shape of palisade cells, number of bundle-sheath layers; presence or absence of sclerenchyma caps, water storage cells, secretory canals, abaxial collenchyma and protruding midrib. It is shown that leaf anatomy data provide characters which are taxonomically useful in classification of Inuleae.     

龙眼果皮形态结构比较观察及其与果实耐贮运的关系

比较了福建省 1 0个主栽龙眼品种果实的果皮形态和结构 ,结果表明 :不同品种在果皮厚度、外果皮表面颜色、龟状纹、放射线、瘤状突、刺毛、外果皮皮孔、周皮层厚度、栓质层厚度和连续性、中果皮薄壁组织细胞排列、石细胞大小、含量、排列和分布 ,维管束发达状况、排列和分布 ,内果皮表皮细胞排列和角蜡质层厚度等方面均存在着明显差异。风梨味、东壁、油潭本、乌龙岭、红核子、蕉眼龙眼果皮厚 ,外果皮表面瘤状突和剌毛多 ,外果皮周皮层、栓质层厚且连续性好 ,中果皮石细胞 (团 )含量多且排列紧密 ,分布在中果皮外侧且在中果皮中所占比例大 ,维管束发达且排列有序 ,内果皮角蜡质层厚 ;这些品种果实耐贮运、抗病性强。而水涨、赤壳、福眼、普明庵龙眼果皮薄 ,外果皮周皮层薄、栓质层不发达 ,中果皮石细胞 (团 )含量少、分布分散 ,维管束不发达 ,薄壁组织细胞胞间隙大 ,皮孔间隙大、皮孔通道与中果皮组织细胞间隙相通 ;这些品种的果实不耐贮运、抗病性弱。讨论了龙眼外果皮表面主色为褐色和内果皮比外果皮更容易褐变的解剖学原因及龙眼果皮形态结构与果实耐贮运的关系。     

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。     

地椒花蜜腺发育的解剖学观察

通过显微和亚显微观察对地椒花蜜腺的发育进行了研究。地椒花蜜腺位于子房基部的花盘上,属于盘状蜜腺,新鲜时呈绿色。蜜腺由分泌表皮和泌蜜组织组成,分泌表皮为一层细胞,表皮细胞角质膜较厚,表皮上分布着大量的气孔器,气孔器突出于表面;泌蜜组织细胞多层。花盘中央有维管束通向子房,在维管束和泌蜜组织之间有４￣５层大型的薄壁细胞。蜜腺由花盘的表皮及其内侧相邻的细胞发育而来,在发育过程中,其细胞中的液泡和贮藏的淀粉     

密花香薷花蜜腺的解剖学研究

密花香薷花密腺分布于子房基部和子房表面,属于一朵花中具二种花蜜腺类型,子房基部的盘状蜜腺由分泌表皮、产蜜组织及维管束三部分组成,分泌表皮上角质层局部有小孔。子房蜜腺由分泌表皮和产蜜组织组成。     

柽柳大、小孢子发生和雌、雄配子体发育的观察

利用常规石蜡制片技术,对柽柳(Tamarix chinensis Lour.)的大、小孢子发生及雌、雄配子体发育过程进行了观察。主要结果如下:(1)花药壁由五层细胞组成,从外向内分别为表皮、药室内壁,两层中层和绒毡层。药壁的发育属于基本型。绒毡层为分泌型。(2)孢原细胞为多孢原起源。小孢子母细胞减数分裂过程中的胞质分裂为连续型,形成的四分孢子为四面体型;同一药室的小孢子母细胞减数分裂几乎完全同步。(3)成熟花粉粒为2细胞型,具3个萌发孔。(4)柽柳为三心皮构成的单室复子房,每子房具有10~20个胚珠,基底胎座,胚珠为双珠被、厚珠心、倒生型。大孢子母细胞减数分裂形成1+3排列的4个大孢子, 4个大孢子全部参与胚囊的形成。(5)胚囊发育为贝母型,反足细胞在胚囊成熟时充分发育。(6)同一朵花中,前期雄蕊的发育早于雌蕊的发育,后期当花粉成熟时,雌配子体也达到成熟,雌雄蕊发育趋于同步。     

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     

Structure and biology of nectaries in Tabebuia serratifolia Nichols (Bignoniaceae)

THOMAS, V. & DAVE, Y., 1992. Structure and biology of nectaries in Tabebuia serratifolia Nichols (Bignoniaceae) . Tabebuia has both floral and extrafloral nectaries, situated on the petiole, bract, calyx, around the ovary and on the pericarp. The floral nectary present around the ovary base is differentiated into epidermis, secretory zone and sub-secretory zone. It is supplied by phloem strands up to the secretory zone. A mature extrafloral nectary consists of a single large basal cell and a head comprising a layer of vertically arranged elongated cells. Starch, protein and lipid are present in the floral nectary. The major insect visitors to both types of nectaries are honey bees, houseflies and ants.     

Development and structure of the drupe in Sclerocarya birrea (Richard) Hochst. subsp. caffra Kokwaro (Anacardiaceae), with special reference to the pericarp and the operculum

The development and structure of the exo-, meso- and endocarp of the drupe of Sclerocarya birrea subsp. caffra were examined. The mature exocarp comprises the outer epidermis with stomata and lenticels, subepidermal collenchyma and parenchymatous layers with secretory canals. This exocarp sensu lato develops from the outer epidermis and the outer layers of the ovary wall. The fleshy parenchymatous mesocarp or sarcocarp also contains secretory tissue. The mesocarp develops after endocarp differentiation and lignification. The developmental sequence within the pericarp corresponds to the general pattern in drupes. The endocarp or sclerocarp, which is not stratified, consisting mainly of brachysclereids, fibres and vascular elements, develops from the inner epidermis and adjacent tissue of the young ovary wall including the procambium strands. The operculum represents a well-defined part of the endocarp. Early in its development a parenchymatous zone already clearly demarcates the operculum. The literature on the pericarp of the Anacardiaceae drupe is discussed to establish the diagnostic value of these morphological characteristics for future taxonomic studies.     

The composition of pericarp,cell aging,and changes in water absorption in two tomato genotypes: mechanism,factors, and potential role in fruit cracking

Cracking, a serious problem in many fruits, may cause significant economic losses. It may occur when internal pressure cannot sustain by the epidermis any longer. Water absorption and epidermis are among the most important factors that associated with cracking. To determine whether pericarp composition and its mechanical performance, endogenous cell wall disassembly, and water-absorbing capacity influences tomato fruit cracking, we grew a cracking-resistant genotype ‘LA1698’ and susceptible genotype ‘LA2683’. The results illustrated that the cuticle and subcutaneous layer were thicker in ‘LA1698’ than in ‘LA2683’. Compared with ‘LA2683’, the fruit firmness, consistency, and bursting strength of ‘LA1698’ were all higher. Fruits of ‘LA1698’ had decreased activities of polygalacturonase, β-galactosidase, and cellulose, which can disassemble the polysaccharide network. As a result, it had reduced water-soluble pectin and more covalently and ionically bound pectin that can crosslink with Ca²⁺ and B. These fruits also have a greater abundance of hemicelluloses. In addition, ‘LA1698’ had higher SOD activities and lower relative conductivity, meaning its cells might have a better biological activity to resist changes of the external environment (such as water variation) and to prevent fruit cracking. However, POD in ‘LA2683’ was more abundant than in ‘LA1698’. ‘LA1698’ produced juice with lower total soluble solids, which led to a lower initial water-absorbing ability and difference between the exocarp and mesocarp. In conclusion, a stronger pericarp and cells with a better biological activity in addition to the lower water-absorbing difference between the exocarp and mesocarp made ‘LA1698’ more resistant to cracking.     

The taxonomic value of floral characters in Rapateaceae (Poales-Monocotyledons)

The floral anatomy of Cephalostemon, Monotrema, Rapatea, Spathanthus, and Stegolepis was studied for taxonomic purposes. All species studied share colleters between the floral parts; sepals, petals, anthers, and style covered by an ornamented cuticle; short epidermal cells with sinuous walls on the abaxial surface of the petals; tetrasporangiate anthers with phenolic idioblasts in the epidermis; endothecium with spiral thickenings; incompletely septate ovary; and anatropous, bitegmic ovules. The floral anatomy is useful not only for characterizing the family, but also for delimiting the subfamilies and genera. Sepals with silica bodies in the epidermal cells; mature anther wall composed of epidermis, endothecium, and middle layer; absence of phenolic idioblasts in the sepals, filaments, and ovary; and stylar epidermal cells with thickened external periclinal wall support Rapateoideae. Cephalostemon and Rapatea show a great number of similarities, corroborating their close relationship indicated in the phylogenetic analyses of the family. Monotrema shares few characters with the genera of Rapateoideae, corroborating its placement in Monotremoideae. Stegolepis shows several distinctive characters, probably related to the greater diversity found in this genus.     

中国伞形科天胡荽亚科果实解剖特征及其系统学意义

经对中国伞形科天胡荽亚科 (Hydrocotyloideae)中天胡荽属 (HydrocotyleL .)积雪草属 (CentellaL .)和马蹄芹属(DickinsiaFranch .) 10种植物果实解剖结构的观察比较 ,发现 3属的果实横切面以合生面为基准可以分成 2个类型 ,即两侧压扁类型 (天胡荽属和积雪草属 )和背腹压扁类型 (马蹄芹属 )。除此之外 ,中果皮的外侧是否有色素块沉积、内侧是否有木化细胞层或厚壁细胞层以及最内层是否形成晶体细胞层 ,内果皮细胞的层数、排列方向以及有无棱槽油管等性状 ,可以作为区分 3属的重要解剖学特征。在此基础上 ,结合外部形态特征 ,讨论了该亚科及其内部各属的解剖学特征、属间区别及其演化关系。认为马蹄芹属应归属于Mulineae族 ,另外 2个属应归属于天胡荽族(Hydrocotyleae) ;3属中积雪草属原始而马蹄芹属进化 ;天胡荽亚科可能不是自然的类群 ,它的分类系统和演化地位有待深入研究。     

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。     

Fruit structure of Amborella trichopoda (Amborellaceae)

The indehiscent fruitlets of the apparently basalmost extant angiosperm, Amborella trichopoda, have a pericarp that is differentiated into five zones, a thin one‐cell‐layered skin (exocarp), a thick fleshy zone of 25–35 cell layers (outer mesocarp), a thick, large‐celled sclerenchymatous zone (unlignified) of 6–18 cell layers (middle mesocarp), a single cell layer with thin‐walled (silicified?) cells (inner mesocarp), and a 2–4‐cell‐layered, small‐celled sclerenchymatous zone (unlignified) derived from the inner epidermis (endocarp). The border between inner and outer mesocarp is not even but the inner mesocarp forms a network of ridges and pits; the ridges support the vascular bundles, which are situated in the outer mesocarp. In accordance with previous observations by Bailey & Swamy, no ethereal oil cells were observed in the pericarp; however, lysigenous cavities as mentioned by these authors are also lacking; they seem to be an artefact caused by re‐expanding dried fruits. The seed coat is not sclerified. The fruitlets of Amborella differ from externally similar fruits or fruitlets in other basal angiosperms, such as Austrobaileyales or Laurales, in their histology. © 2005 The Linnean Society of London, Botanical Journal of the Linnean Society, 2005, 148 , 265–274.     

Morphogenesis of the antenna of the male silkmoth, Antheraea polyphemus. I. The leaf-shaped antenna of the pupa from diapause to apolysis

The antenna of the male silkmoth Antheraea polyphemus is a featherlike structure consisting of a central stem and ca. 120 side branches, which altogether carry about 70,000 olfactory sensilla. We investigate the development during the pupal phase. At the end of diapause, the antennal rudiment consists of a leaf-shaped, one-layered epidermal sac. It is supplied with oxygen via a central main trachea, which gives off numerous thin side branches. These are segmentally arranged into bundles which run to the periphery of the antennal blade. When the epidermis retracts from the pupal cuticle (apolysis; stage 1), it consists of cells which are morphologically uniform. The epidermal cells form a network of long, irregular basal protrusions (epidermal feet), which crisscross the antennal lumen. During the first day post-apolysis (stage 2), the antennal epidermis differentiates into alternating thick 'sensillogenic' and thin 'non-sensillogenic' areas arranged in stripes which run in parallel to the tracheal bundles. Numerous dark, elongated cells, which might be the sensillar stem cells, are scattered in the sensillogenic epithelium. A number of very early sensilla has been found at the distal edges of the sensillogenic stripes in positions which later will be occupied by sensilla chaetica. The whole antennal blade is enveloped by the transparent ecdysial membrane, consisting of the innermost layers of the pupal cuticle which are detached during apolysis.     

Anatomy and development of fruits of Lauraceae from the Middle Eocene Princeton Chert

Investigations of the Middle Eocene Princeton Chert reveal evidence for the connection of lauraceous flowers to fruits through a developmental series. Youngest fruits are found with attached floral remnants. Later stages show receptacle enlargement, fruit wall thickening, and the development of abundant sclereid clusters. Mature fruits are borne on a shallow receptacle and have an endocarp palisade layer of radially elongate cells with stellate outlines, an inner mesocarp layer of radiately arranged sclereid clusters, and a fleshy outer mesocarp layer containing numerous idioblasts with contents. Each mature fruit bears a single seed retaining the outer integument with an innermost radially elongate transfusion cell layer. Mature seeds contain a cellular embryo bearing idioblasts. Fruits are distinguishable from previously described anatomically preserved fossil taxa. This study represents the only documented developmental reconstruction of fossil fruits of Lauraceae and that self-pruning evolved prior to the Eocene. Anatomical modifications over the developmental sequence indicate that different stages of maturity preserved together, may be erroneously identified as several taxa at a fossil locality. Fossil morphotypes typically underestimate species number, but this study suggests that the number of inferred species based on fruit types may be inflated for Lauraceae, potentially exaggerating the tropical interpretation of the paleoenvironment.     

Fine structure of the cuticle of the black widow spider with reference to surface lipids

The surface and transverse sections of the cephalothorax, abdomen, and walking leg cuticle of the black widow spider, Latrodectus hesperus, were examined by scanning and transmission electron microscopy. Cuticle that was untreated prior to normal EM preparative procedures was compared with cuticle subjected to lipid solvents and/or concentrated alkali. The surface of untreated dorsal cephalothorax cuticle contained droplets and a lipid film that obscured fine surface detail. Immersing the cuticle in chloroform: methanol removed the droplets and lipid film, exposing previously covered openings to dermal gland ducts. An epicuticle, exocuticle, and endocuticle were present in all transverse sections of cuticle as was a complex system of pore and wax canals that connected the epidermis with the cuticle surface. The epicuticle of the walking leg was composed of three sublayers: outer membrane, outer epicuticle, and the dense homogeneous layer. A cuticulin layer was not observed. Lipid solvents did not significantly alter the morphology of any of these layers or the contents of the wax/pore canals.     

Ultrastructural shape and three-dimensional organization of the intracuticular canal systems in the mineralized cuticle of the green crab Carcinus maenas

Two main self-contained canal systems are present in the crab mineralized cuticle. The first, or fibre canal system, is constituted by simple, unbranched vertical canals containing axially running fibres in close association with myoepidermal junctions. The second, or pore canal system, is composed of procuticular pore canals and epicuticular channels that prolong the procuticular canals. In opposition to widespread opinion, pore canals make up a three-dimensional branched system extending from the apical plasma membrane of the epidermis up to the epicuticle. Branching occurs by projections of lateral horizontal from the vertical canals at the lower level of the pigmented layer and by innumerable ramifications of epicuticular canals. In agreement with Neville's model for insects, vertical procuticular pore canals of crustacean mineralized cuticle, and also fibre canals, exhibit a twisted ribbon structure reflecting the helicoidal arrangement of the horizontal chitin-protein microfibrils.