麦冬、土麦冬和阔叶土麦冬叶表皮形态结构的观察

用光镜和扫描电镜观察了麦冬（Ophiopogon japonicus（L．f）Ker—Gawl.]、土麦冬（Liriope spicata Lour．）和阔叶土麦冬（L．platyphylla Wanget Tang）叶表皮显微结构、亚显微结构和角质层内表面的形态结构。结果表明,气孔主要分布于麦冬、土麦冬和阔叶土麦冬叶片的下表皮,气孔密度分别为76．4、114．3和99．8个·mm^-2;仅阔叶土麦冬叶片上表皮有少量气孔分布。3种植物的气孔器均不具有副卫细胞,并在叶脉间形成纵向气孔带。表皮细胞长方形,气孔带与非气孔带处表皮细胞的形态和大小差异较明显。麦冬气孔周围的表皮细胞平周壁具明显瘤状突起,导致气孔下陷;土麦冬气孔周围的表皮细胞平周壁呈波浪状突起,使气孔相对下陷;阔叶土麦冬气孔周围的表皮细胞平周壁基本无突起,气孔不下陷。3种植物的叶表皮均有发达的角质层和丰富的蜡质,且蜡质主要分布于下表皮气孔带处。这些结构特征可能与它们所具有的喜阳、耐阴和耐旱等特性有一定的相关性。     

Phylogeny and taxonomy of Cinnamomum (Lauraceae)

Taxonomy of Cinnamomum Schaeff. of Lauraceae remains problematic because recent phylogenetic studies have suggested that this genus is not monophyletic. In this study, we assembled three sequence matrices including plastomes (datamatrix I), nrITS sequences alone (datamatrix II), and nrITS plus plastid psbA‐trnH sequences (datamatrix III) of the Cinnamomum‐Ocotea complex of Lauraceae and conducted a new phylogenetic study with thusfar the most extensive species sampling of the Cinnamomum‐Ocotea group. We determined that the Old World Cinnamomum is diphyletic: sect. Camphora Meisn. is sister to Sassafras J.Presl and sect. Cinnamomum is sister to the African Kuloa Trofimov & Rohwer. A recent study indicated that characters of leaf micromorphological anatomy can define the two clades: one possessing reticulate periclinal and the other having non‐reticulate periclinal walls. As result, we divided the genus Cinnamomum of Lauraceae into two genera, i.e., Cinnamomum and Camphora Fabr. The generic name Cinnamomum is retained for those species mainly having reticulate periclinal epidermal cell walls, inconspicuous non‐perulate terminal buds and usually tripliveined leaves; the oldest generic name, Camphora, is applied to the second group which contains those species mainly possessing non‐reticulate periclinal epidermal cell walls, prominent perulate terminal buds and pinnately‐veined leaves. A census of the species and their type specimens listed under Cinnamomum in Asia resulted in the transfer of 18 species to Camphora, including 15 new combinations.     

中国桑寄生科植物叶表皮微形态

通过扫描电镜对中国桑寄生科桑寄生亚科8属18种和槲寄生亚科1属2种植物成熟叶的上、下叶表皮内表面和下表皮外表面进行了研究。内面观发现桑寄生科植物叶上、下表皮形状为多边形,垂周壁式样平直或稍弓形,常具有角质增厚,平周壁常覆盖厚角质或颗粒状、丝状角质增厚;气孔存在于上下表皮,通常下表皮较多,气孔的形状,特别是保卫细胞的形态在亚科间、属间或种间都具有一定的差异,气孔器类型为平列型或单圈型。下表皮表面观察了的角质膜和蜡质纹饰、气孔的形状,外部气孔缘及外部气孔缘内缘的特征。这些特征在亚科或属级水平上较为稳定,有的也表现出种间差异,有一定的分类价值。从气孔形态和外部气孔周围角质膜来看,两亚科显示出明显的不同:桑寄生亚科上、下表皮均具有内部气孔缘,而槲寄生亚科没有此结构;桑寄生亚科外部气孔周围角质膜增厚成环状,其上具增厚的条纹,而槲寄生亚科外部气孔周围角质膜增厚成脊状,不具条纹。这些特征支持槲寄生亚科作为独立1个科来处理。     

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。     

蜘蛛抱蛋属植物叶表皮微形态的扫描电镜观察

在扫描电子显微镜下,观察9种蜘蛛抱蛋属植物的叶表皮微形态。结果表明,9种植物叶下表皮的细胞都为长方形,垂直壁为直的,垂周界限为凸的,外层周壁凹陷。气孔椭圆形至卵圆形,气孔外拱盖表面多平滑,其内缘近平滑、浅波状或锯齿波状;角质膜多为脊状条纹、有的外层周壁有横纹或颗粒。气孔大小与染色体的倍性有一定的正相关关系。不同种间叶表皮特征表现出一定差异,对种的划分有一定的分类鉴定意义。     

根据叶表皮微形态特征试论新麦草属、芒麦草属和三柄麦属间的系统关系

观察了禾本科新麦草属、芒麦草属和三柄麦属主要代表种的叶片表皮形态学特征,总结了三属植物叶表皮结构的异同,探讨了叶表皮特征的分类学意义。同时,根据三属植物叶表皮性状的演化趋势,分析了各属的演化关系和系统位置。结果表明,新麦草属最原始,芒麦草属较进化,三柄麦属最高级;新麦草属可能直接派生了较进化的芒麦草属,并在芒麦草属的基础上进而产生了最高级的三柄麦属。三柄麦属、芒麦草属和新麦草属的这一系统关系同它们外部形态上三联小穗的演化趋势是相互印证的。     

Plastid phylogenomics improve phylogenetic resolution in the Lauraceae

Abstract The family Lauraceae is a major component of tropical and subtropical forests worldwide, and includes some commercially important timber trees and medicinal plants. However, phylogenetic relationships within Lauraceae have long been problematic due to low sequence divergence in commonly used markers, even between morphologically distinct taxa within the family. Here we present phylogenetic analyses of 43 newly generated Lauraceae plastomes together with 77 plastomes obtained from GenBank, representing 24 genera of Lauraceae and 17 related families of angiosperms, plus nine barcodes from 19 additional species in 18 genera of Lauraceae, in order to reconstruct highly supported relationships for the Lauraceae. Our phylogeny supports the relationships: sisterhood of the Lauraceae and a clade containing Hernandiaceae and Monimiaceae, with Atherospermataceae and Gomortegaceae being the next sister groups, followed by Calycanthaceae. Our results highlight a monophyletic Lauraceae, with nine well‐supported clades as follows: Hypodaphnis clade, Beilschmiedia–Cryptocarya clade, Cassytha clade, Neocinnamomum clade, Caryodaphnopsis clade, Chlorocardium–Mezilaurus clade, Machilus–Persea clade, Cinnamomum–Ocotea clade, and Laurus–Neolitsea clade. The topology recovered here is consistent with the patterns of plastome structural evolution and morphological synapomorphies reported previously. More specifically, flower sex, living type, inflorescence type, ovary position, anther locus number, leaf arrangement, leaf venation, lateral vein number, tree height, and inflorescence location all represent morphological synapomorphies of different lineages. Our findings have taxonomic implications and two new tribes, Caryodaphnopsideae and Neocinnamomeae, are described, and the composition of four other tribes is updated. The phylogeny recovered here provides a robust phylogenetic framework through which to address the evolutionary history of the Magnoliids, the third‐largest group of Mesangiospermae.     

Systematic implications of flavonoid pigments in the fern genus hemionitis (adiantiaceae)

The closely related fern generaHemionitis L. andGymnopteris Bernhardi are separated primarily on differences in leaf architecture and venation. Studies indicate that these characters are highly variable and unreliably diagnostic. Further, the type species of the two genera readily hybridize with each other. Spore morphology, as exhibited by SEM, does not support the traditional alignment of the species in these two genera: some species ofHemionitis andGymnopteris have the same rugose to papillate spores, while other species from both genera possess crested spores. The flavonoid chemistry of these taxa coincides with spore type, i.e., taxa from both genera which possess crested spores produce kaempferol and quercetin 3-0-glycosides, while species with tuberculate spores produce only quercetin 3,4′-0-glycosides. The spore and chemical data suggest a realignment of these taxa within a single genus, which would avoid the rather tenuous dependence on a single vegetative character for generic distinctions.     

The Anatomical Structures and Floral Development of Euryale ferox Salisb

The pedicel of E. ferox possesses closed, scattered vascular bundles and contains no cambium. Four main air canals are well developed. Mesophyll of sepal is differentiated into palisade and spongy parenchyma. Petal is simpler in structure than that of sepal with no palisade tissue differentiated. Stamens show a wide varity of shapes; those in the outer whorls are usually petaloid while the inner whorls are of the conventional type bearing four-loculate anthers. Ovary is inferior, multicarpellarv and syncarpous with laminar plancentae in each locule. The flower primordium grows out from the mixed bud. It is enveloped by an axillary scale. The preliminary indication of floral initiation is the periclinal divisions of the second layer of the shoot apex which is closer to the leaf base. By the time a flower primordium becomes 465μm high, the floral parts begin to arise in a continuous acropetal sequences, namely sepals, petals, stamens and carpels successively with initiation of their primordia by periclinal divisions of the second or third layer on the flank of the floral apex respectively. By the fact that the growth of the outer layered cells of the receptacle is faster than those of the inner ones, an epigynous flower and an inferior ovary is thus to be formed. The ventral margin of the carpel has become conduplicately appressed and fused in the lower portion, while the upper part has not been fused, an ovarian canal is appeared from top of the ovary. There is no differentiation of a style. A central receptacular core is found among the carpels. On the basis of anatomical and developmental studies of the floral organs, we suggest that Euryale ferox exhibits a number of most primitive features, such as petaloid stamens, carpel with ovarian canal, elongated receptacle, prominent residual floral apex and laminar placentation. The development of floral parts and characteristics of ovary indicate that genus Euryale is much more similar to Victoria, Nymphae and Nuphar than to Nelumbo and Brasenia.     

A new species of Pseudotorellia florin (Ginkgoales) from the Middle Jurassic of Eastern Mangyshlak (Kazakhstan)

A new species of Pseudotorellia Florin, Pseudotorellia papillata sp. nov., from the Middle Jurassic of Eastern Mangyshlak (Western Kazakhstan, Tonasha Formation) is described. The main distinction of the new species from the other species of this genus is the relief cutinization of periclinal walls of cells of the lower epidermis, especially within stomatal bands, expressed in prominent cuticular ridges and papillae of irregular shape.     

贵州30种杜鹃属植物叶背表皮显微形态特征

杜鹃属植物的分类历来都十分重视叶片表皮特征的分类学价值,无论是在各亚属之间还是在种及种下等级的划分中都很强调此类特征的作用。贵州省位于世界现代杜鹃分布中心边缘及向东部散布的过渡地带,省内自然分布的杜鹃种类资源丰富而又独具特色,包括很多尚未深入研究的特有类群。为进一步研究贵州杜鹃属植物的属下系统分类关系,该文对自然分布于贵州的30种杜鹃进行了叶背显微形态特征研究,其中有28种的叶背表皮特征为首次报道。研究材料全部来自采于贵州西北部百里杜鹃自然保护区内的杜鹃属植物,包括杜鹃亚属4种、糙叶杜鹃亚属1种、常绿杜鹃亚属22种、马银花亚属1种及映山红亚属2种,共计30种。研究方法为取成熟叶片处理后在JSM-6490型扫描电镜下对叶背表皮进行观测。叶背鳞片类型的划分方法参照前人工作。结果表明:这30种杜鹃叶片叶背表皮形态特征在电子显微镜下表现出明显的多样性,如有鳞类杜鹃具有鳞片而其他类群则无,叶表面有或无表皮毛,表皮毛排列稀疏或密生,气孔器未见或偶见,散生于乳突状或非乳突状突起之间,或角质层增厚气孔器下陷,内、外拱盖表面粗糙或光滑,气孔器周围有或无间断的条形突起,突起呈环状或羽状等,但在同一亚属或亚组中又呈现出或多或少的一致性。研究讨论表明,叶背表皮显微形态特征在杜鹃属植物的属下系统分类中具有重要的研究价值。     

Ficus rubiginosa 'variegata', a chlorophyll-deficient chimera with mosaic patterns created by cell divisions from the outer meristematic layer

BACKGROUND AND AIMS: Sections leaves of Ficus rubiginosa 'Variegata' show that it is a chimera with a chlorophyll deficiency in the second layer of the leaf meristem (GWG structure). Like other Ficus species, it has a multiseriate epidermis on the adaxial and abaxial sides of the leaf, formed by periclinal cell divisions as well as anticlinal divisions. The upper and lower laminae of the leaf often exhibit small dark and light green patches of tissue overlying internal leaf tissue. METHODS: The distribution of chlorophyll in transverse sections of typical leaves was determined by fluorescence microscopy. KEY RESULTS: Patches of dark and light green tissue which arise in the otherwise colourless palisade and spongy mesophyll tissue in the entire leaf are due to further cell divisions arising from the bundle sheath which is associated with major vascular bundles or from the green multiseriate epidermis. Leaves produced in winter exhibit more patches of green tissue than leaves which expand in mid-summer. Many leaves produced in summer have no spotting and appear like a typical GWG chimera. There is a strong relationship between the number of patches on the adaxial side of leaves and the number on the abaxial side, showing that the cell division in upper and lower layers of leaves is strongly coordinated. In both winter and summer, there are fewer patches on the abaxial side of leaves compared with the adaxial side, indicating that periclinal and anticlinal cell divisions from the outer meristematic layer are less frequent in the lower layers of leaf tissue. Most of the patches are small (<1 mm in longest dimension) and thus the cell divisions which form them occur late in leaf development. Leaves which exhibit large patches generally have them on both sides of the leaves. CONCLUSION: In this cultivar, the outer meristematic layer appears to form vascular bundle sheaths and associated internal leaf tissue in the entire leaf lamina.     

High diversity of Lauraceae from the Oligocene of Ningming,South China

Lauraceae is among the largest and floristically most important woody plant families in subtropical and tropical zones. However, the Cenozoic fossil records of Lauraceae are mostly from mid-latitude regions. Here we described eight lauraceous species from the Oligocene of Ningming, Guangxi, South China on the basis of leaf compressions with cuticular structure, providing new evidence for high diversity of Lauraceae in the low latitude region of the northern hemisphere during the late Paleogene. The extant genera to which the Ningming Oligocene fossils are possibly closely related include Cinnamomum, Neolitsea, Litsea, Alseodaphne, Laurus, and Beilschmiedia. All of these extant genera except Laurus still exist in Guangxi today, whereas Laurus is currently distributed in the Mediterranean and adjacent regions. A cladistic analysis based on leaf architectural and leaf cuticular characters for Paleogene Lauraceae species in the world indicated a possible relationship between European and East Asian Paleogene species.     

Revision du genre LycopodiopsisB. Renault, 1890

The study of imprints of Lycopsida from Permianof the Gondwana has permitted to specify the organisation of the leaf cushions and their variation in the genus LycopodiopsisB. Renault. The presence of a ligula is showed off. The invalidity of the genera Cyclodendron and Lycopodiophloios is demonstrated, and the species refered to these genera must be refered to the genus Lycopodiopsis for which an emended diagnosis is proposed.     

Comparative Observation on Leaf Anatomy and Pollen of Vernicia Lour. and Aleurites J. R. et G. Forst.

The folial anatomy and pollen of one species of Aleurites and two species of Vernicia were studied. The former genus is characterized by the presence of echinolophate sculpture of pollen and a single outer stomatal ledge, curved cuticular ridges of peristomatal rim as well as large nodular ornamentation on the surface of epidermis beneath which there is no hypodermis. The latter one is characterized by the verruca-murate sculpture of pollen and the cuticular striate ornamentation on leaf surface of epidermis beneath which there is one layer of hypodermis, although they both have paracytic stomata and the Crotonic type of pollen. The genus Vernicia has not been accepted for a long time, but these micromorphological characters show as additional evidence that recent separation of the two genera by Airy Shaw (1966)^[6] is reasonable. Both genera possess very similar xeromorphic feature designated here as orbicular lustrous spot.     

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.     

Peltate Leaf Development in Brasenta schreberi Gruel

The present investigation is a report with a detailed account of peltate leaf development in Brasenia schreberi. The preliminary indication of leaf initiation is seen in periclinal divisions of the subepidrmal cells on the flank of the shoot apex. By the time a leaf primordium becomes 73 μm high, the apical growth is present, and it has undergone repeated periclinal and anticlinal divisions and introduces aew cells into the body of the primordium. The procambial strand is evident very early in ontogeny. Vacuolation of cells proceeds acropetally along the primordium. At 109 μm longitudinal sections reveal a ventral outgrowth. This ventral growth, termed a lateral zone or Querzone, is initiated by subepidermal cells on the ventral (adaxial) side of primordium. The Querzone is considered to represent the congenital fused laminar margins of the leaf. Transection analysis of a primordium of 160 μm indicates that the Querzone growth is initiated on the midbasal portion of primordium. Below the midbasal portion of primordittm which later forms the petiole of the leaf. The marginal 'growth occurs at a time when the primordinm is approximately 160 μm high. Initiation of marginal growth takes place in 42 μm from the base of a primordium. Marginal growth at first can be seen while the primordium exhibits unilateral. By anticlinal divisions, the marginal initials produce the upper and lower protoderm, which give rise to the upper and lower epidermis respectively, and submarginal initiates divide in anticlinal plane, giving rise to the adaxial and abaxial layers. Subsequent divisions of the adaxial layer are anticlinal only so that it forms a single layer which later develops as the palisade parenchyma. The cells of the abaxial layer, by divisions in all planes, form the tissues of the spongy parenchyma and all of the lateral venation system. At maturity, the mesophyll is much less compact and there are mumerous large intercellular spaces in the spongy region and between the palisade cells. The veins are collateral: There is a reduction in the amount of xylem and the ultimate veinlets terminate as single spiral tracheids. The glandular bairs are mumerous on the lower epidermis and are epidermal in origin, each consisting two basel cells and one termined cell. On the basis of morphological examination we suggest that the peltate leaf of Brasenia schreberi is clearly distinct from the foliage leaf in the development of adaxial meristem and marginal growth. We found the primordimn of Brasenia schreberi as an erect organ and arises.by monopodial growth. In the development of leaf and the form of venation the Brasenia schreberi shows marked resemblance and relationship to the Nelumbo nucifera.     

Ultrastructure and development of oil cells in Laurus nobilis L. leaves

The oil cell development in Laurus nobilis leaves has been studied. At the early developmental stage, when the cell wall consists of the outer cellulose wall only, the oil cells differ from the neighbouring mesophyll cells in their larger size, lower starch content and in their plastid organization. After the deposition of the lamellated suberin layer and the inner cellulose layer, a wall protuberance (cupule) is formed on the periclinal wall facing the epidermis. From its reaction with periodic acid-hexamine-silver nitrate, it is suggested that the cupule is cellulosic. The portion of the inner cellulose wall layer bearing the cupule seems to contain patches of suberin. Plasmodesmata occur in special wall protuberances and appear to become occluded with age. The oil produced inside the protoplast is secreted to the outside of the plasmalemma, and accumulates as a drop at the place predetermined by the cupule. Except at the cupule, the oil drop is surrounded by the plasmalemma.     

根据叶表皮特征试论国产三齿稃亚族的属间关系

根据植物叶片表皮结构,尤其下表皮特征,对国产三齿稃亚族6个属(包括1个引进属)进行了属间关系的分析。结果表明：国产三齿稃亚族中固沙草属最原始,草沙蚕属最高级,双稃草属、千金子属、三齿稃属和隐子草属演化居于其间;隐子草属可能直接起源于固沙草属,并在自身基础上派生了较为高级的三齿稃属;双稃草属与千金子属渊源关系直接,前者可能通过后者问接起生于固沙草属;草沙蚕属具有别于它属的性状级次,可能是起源于固沙草属、独树1支的顶级类群。这一结果不仅修正了前人演化理论的差误,而且为今后探讨该亚族的地理起源、散布路线提供了资料。     

Structure of mucilaginous epidermal cell walls in Passerina (Thymelaeaceae)

Leaves of Passerina are inversely ericoid. Adaxial epidermal cells are relatively small; abaxial ones are large and tanniniferous. Mucilaginous epidermal cells are usually present in many Thymelaeaceae, including Passerina , mainly in the abaxial epidermis. They are unequally divided by a periclinal wall-like septum into two separate compartments: (1) the outer, adjacent to the cuticle, containing mostly tanniniferous substances and (2) the inner, containing mucilage. This type of epidermis has often been incorrecdy described as uni-, bi- or multiseriate. Transmission electron microscopy revealed mucilage, characterized by microfibrils, embedded between die innermost wall-like septum and outermost layers of the inner periclinal cell wall. As accumulation of mucilage increases, the innermost (adjacent to the cell contents) layer of the original periclinal cell wall is pressed against the cytoplasm, thus forming a clearly demarcated cellulose periclinal wall which divides the epidermis cell into two compartments, the inner wiuh mucilage and the outer comprising the cell lumen. Existing controversy is critically discussed. Our observations confirm the authenticity of mucilagination in epidermal cell walls.