Leaf and tepal anatomy, plastid ultrastructure and chlorophyll content in Galanthus nivalis L. and Leucojum aestivum L.

The leaf structure of Galanthus nivalis L. (snowdrop) and Leucojum aestivum L. (snowflake) is characterized by a homogeneous mesophyll tissue. The dominant characters of the leaves are cavities with mucose substance. There is a striking difference between these plants tepal anatomy. A central cavity occurs only in snowdrop tepals. Plastids from white parts of the tepals have a poorly developed membrane system. Leaves and green parts of tepals of both species possess amoeboid chloroplasts and contain chlorophyll a and b. The chlorophyll content in tepals is lower than in leaves, but the chlorophyll a:b ratio is always 2:1. Both, snowdrop and snowflake are from the family Amaryllidaceae, but their ecology is different. This paper presents common features related to systematic relatedness and differences induced by ecological factors.     

Structure and distribution of floral trichomes in Lycaste and Sudamerlycaste (Orchidaceae: Maxillariinae s.l.)

Phylogenetic analysis indicates that Lycastinae should be incorporated into a more broadly defined Maxillariinae. This is supported by several anatomical features, including the presence of sunken, glandular trichomes in both Lycastinae and Maxillariinae s.s. Until recently, these were known only from vegetative organs, but have since been reported from flowers of Maxillaria dichroma. One character currently used to distinguish between Lycaste and Sudamerlycaste is the distribution of floral trichomes. In this article, we test the reliability of this character, describe the floral micromorphology of Lycaste and Sudamerlycaste and investigate whether their flowers bear sunken hairs. Their floral micromorphology is compared with that of other genera currently assigned to Maxillariinae s.l. Flowers of Lycaste and Sudamerlycaste bear conical or obpyriform papillae and unbranched and unequally branched multicellular trichomes. Contrary to previous reports that trichomes are confined to the column in Sudamerlycaste, they also occur in the tepal axils. Labellar trichomes, although often present in Lycaste, are lacking in Sudamerlycaste. In Lycaste sections Lycaste and Aromaticae, floral trichomes tend to be unbranched, whereas section Intermediae has both unbranched and branched hairs. Branched hairs are more common in Sudamerlycaste. Some hairs are tracheoidal, pitted and lignified. These mainly occur in section Lycaste and, to a degree, in section Intermediae, but are absent from section Aromaticae and most species of Sudamerlycaste. Branched column hairs, present in Sudamerlycaste, are absent from all sections of Lycaste, and tracheoidal column hairs occur only in Sudamerlycaste. Sunken floral hairs are absent from both genera. Trichome structure and distribution may prove useful in distinguishing between these taxa and in elucidating the intergeneric relationships of Maxillariinae s.l.© 2010 The Linnean Society of London, Botanical Journal of the Linnean Society, 2010, 164 , 409–421.     

Morphogenesis of Pistillate Flowers of Cercidiphyllum japonicum(Cercidiphyllaceae)

Floral morphogenesis and the development of Cercidiphyllum japonicum Sieb.et Zucc.were observed by scanning electronmicroscopy(SEM).The results showed that the pistillate inflorescences were congested spikes with the flowers arrangedopposite.Great differences between the so-called"bract"and the vegetative leaf were observed both in morphogenesis andmorphology.In morphogenesis,the"bract"primordium is crescent-shaped,truncated at the apex and not conduplicate,has no stipule primordium at the base but does have some inconspicuous teeth in the margin that are not glandular.Theleaf primordium is triangular,cycloidal at the apex,conduplicate,has two stipule primordia at the base,has one gland-toothat the apex occurring at first and some gland-teeth in the margin that occur later.In morphology,the"bract"is also differentto the vegetative leaf in some characteristics that were also illustrated in the present paper.Based on the hypothesis thatthe bract is more similar to the vegetative leaf than the tepal,we considered that the so-called"bract"of C.japonicum mightbe the tepal of the pistillate flower in morphological nature.Therefore,each pistillate flower contains a tepal and a carpel.We did not find any trace of other floral organs in the morphogenesis of the pistillate flower.Therefore we consideredthat the unicarpellate status of extant Cercidiphyllum might be to highly reduce and advance characteristics that make theextant Cercidiphyllum isolated from both fossil Cercidiphyllum-like plants and its extant affinities.     

Flower structure and development of Araceae compared with alismatids and Acoraceae

Floral development of Araceae is compared with that of other basal monocots such as alismatids and Acorus. Flowers of Araceae, Acorus and several alismatids with spicate inflorescences lack a subtending floral bract. In Araceae and some Potamogetonaceae the subtending floral bract is suppressed, and not incorporated into the perianth. This differs from Acorus and some alismatids, where a bract-like median abaxial tepal is formed in the outer perianth whorl (i.e. developmental merger of flower-subtending bract and tepal). In Araceae, Acorus and spicate alismatids flowers develop unidirectionally, correlated with bract reduction. Araceae lack unidirectionality in the outer perianth whorl, in contrast t o Acorus and Juncaginaceae. The transition from trimerous to dimerous flowers in Onintiurn (Araceae) is by accentuation of the unidirectionality of the inner perianth. The gynoecium of Araceae and Acorus is synascidiate. However, in most Araceae the synascidiate portion is shorter than in Acorns, and a distinct basal elongation phase as in Acorus and Juncaginaceae was not found. The perianth and androecium of Lysichiton and Symplocarpus and the gynoecium of Gymnostachys differ from other Araceae and resemble those in Potamogetonaceae. Developmental findings support the isolation of Acorus from Araceae, and show similarities of Araceae with Potamogetonaceae and of Acorus with Juncaginaceae.     

八角目(Illiciales)植物花被片表皮比较形态

在光学显微镜和扫描电镜下,观察了八角科(Illiciaceae)八角属(Illicium Linn.)2组11种20个材料、五味子科(Schisandraceae)南五味子属(Kadsura Ksempf. ex Juss.)2亚属2组8种15个材料和五味子属(Schisandra Michx.)2亚属4组6种17个材料的花被片表皮形态特征。首次报道了八角目2个科（八角科和五味子科）3个属（八角属、南五味子属和五味子属）植物花被片表皮细胞的形状、分泌细胞的形状及分布、气孔器的形状及分布、花被片表面的纹饰。通过与八角目2个科3个属植物的叶表皮形态比较,发现花被片表皮气孔器外拱盖均为单层,与叶表皮气孔器外拱盖层数（常绿种类为双层和落叶种类为单层）之间没有相关性,还在五味子科中发现2个新的性状（气孔对和环列型气孔）。通过对两性花、雌花和雄花花被片表皮观察,发现花被片表皮形态与花的性别之间没有相关性。通过对八角属、南五味子属和五味子属花被片表皮比较,发现五味子属与南五味子属相比,其花被片表皮表现出更多的衍生性状;南五味子属与八角属相比,前者花被片表皮具有更多的衍生性状;而南五味子属花被片表皮形态与五味子属的相似性程度较大,支持五味子科包含南五味子属和五味子属、八角科包含八角属的观点。     

A kinematic analysis of tepal growth in Lilium longiflorum

Time-lapse marking experiments indicate that the growth of tepals in Lilium longiforum Thunb. from 3.7 mm to maturity is triphasic. Phase I (tepal lengths 3.7–10 mm) is characterized by spatial and temporal variation in growth rate and, in the epidermis, a random distribution of mitoses with an acropetal increase in cell area. During phase II (10–90 mm) cell elongation and (later) cell division is restricted largely to basal regions. Cell division ceases when tepals are less than one-third of their mature length of 155 mm. Phase III (90–155 mm) is characterized by the gradual transition from basal to apical growth, and a modification of epidermal cell shape. A sharp peak in growth at the extreme tip of the tepal coincides with anthesis.Abbreviations LRGR local relative growth rate - RER relative elemental rate of growth     

Comparative morphology of the carpel in the Liliaceae: Uvularieae

Three genera of the Uvularieae (Kreysigia, Schelhammera, Uvularia) have tricarpellate, syncarpous pistils. Ventral bundles (presumably the united simple septal and placental bundles of a carpellary wing) may be present in Kreysigia and Schelhammera. In Kreysigia the two presumptive ventral bundles from adjoining carpels are fused basipetally in each septum. The septal bundles of the other two genera are either simple (Schelhammera) or in part compound (united) below and simple (separate) above (Uvularia) , hence fused acropetally. In Uvularia , the dorsal bundle of the carpel and the median bundle of the tepal are uniquely tripartite and probably homologous. No raphides were found in the carpels of these genera.     

中国荞麦属花粉形态及花被片和果实微形态特征的研究

研究了中国荞麦属Fagopyrum　Mill.的花粉形态、花被片和果实微形态特征。根据沟膜的有无,花粉可以明显地区分为具沟膜者和不具沟膜者2类。透射电镜下显示,荞麦F. esculentum Moench的花粉外壁分化成两个明显的层次,即外壁外层和外壁内层。其外壁外层由覆盖层及柱状层组成,无基层。对花被片腹面的扫描电镜观察表明,根据细胞形状和表面纹饰,这些种类的花被片可分为3类。对果实表面的扫描电镜观察表明,这些种类的果实纹饰也可分为3类。根据上述结果,讨论了荞麦属的种间关系及花粉形态、花被片和果实一些微观性状的演化趋势。荞麦属的花粉形态极为一致,其外壁纹饰均为细网状,萌发孔为三孔沟,这支持将荞麦属从蓼属中分出独立成属的观点。本文还根据花粉形态特征及花被片和果实微形态特征讨论了国产荞麦属的种间关系,探讨了一些特征的演化趋势。