HETEROPHYLLY IN POPULUS GRANDIDENTATA (SALICACEAE) WITH EMPHASIS ON RESIN GLANDS AND EXTRAFLORAL NECTARIES

Big-tooth aspen displays heterophylly on twigs of saplings and on upper, vigorously growing twigs of larger trees. Early leaves, those present in overwintering buds which expand in spring, differ from late leaves, those that are mostly initiated and developed during the late spring and summer of the same year. The two sets of leaves differ in size, shape, number of teeth, number of marginal resin glands, and number and size of basilaminar extrafloral nectaries. Secretory structures are generally more prominent and active on late leaves. Marginal resin glands, resin-secreting stipules, and basilaminar nectaries of both early and late leaves are similar anatomically, having a secretory epidermis of cytoplasmically dense palisade-like cells separated from vascular bundle endings by several layers of isodiametric parenchyma. These secretory structures, and the dense mat of trichomes which cover the leaf until it fully expands, may help to protect the young leaves from insect damage. The basilaminar nectaries seem especially effective because they attract ants that probably discourage visits by other insects.     

DEVELOPMENT,STRUCTURE AND FUNCTION OF SECRETORY TRICHOMES IN PSYCHOTRIA BACTERIOPHILA (RUBIACEAE)

Mucilage-secreting dendroid trichomes develop from the adaxial epidermis of young stipules surrounding the shoot apex. Each trichome consists of a multicellular stalk from which radiate many branch cells. The trichome has no cuticle and the branch cell walls distally are loose cellulosic frameworks. Dictyosomes produce vesicles whose products are secreted through the plasma-lemma and cell wall. Enlarged portions of the ER are frequently associated with dictyosomes and may be part of the system for synthesis and transport of secretion products. Bacteria, which later occur in leaf nodules, are present in the mucilage surrounding trichomes and young leaves. The latter develop stomata through which the bacteria enter. As stipules and leaves grow out of the apical region, the secretory trichomes degenerate and are replaced by non-secretory ones.     

MORPHOLOGY AND ANATOMY OF RESIN GLANDS IN SALIX LUCIDA (SALICACEAE)

Resin glands on the first leaves to emerge occur at the tip of each marginal dentation of the lamina and stipule, and on the adaxial surface of the stipule and lamina bases (the latter often extend onto the petiole). Successive emerging leaves show increases in number of basilaminar glands, because increasingly elaborate multiglandular stalks develop. Glands in all locations are conical or domed, with a palisade-like epidermis subtended by 5–6 layers of parenchyma which contains druse crystals. A single vascular bundle (sometimes two or three) ends in a small knob of tracheary elements. Glands usually secrete liquid resin that covers the gland and surrounding area and under certain conditions, particularly in low humidity, resin is extruded as a filament from a pore in the gland apex, a mode of resin secretion not described previously. Glands secreting liquid resin have an apical dimple, but presence of a pore has not been established.     

中华补血草盐腺发育的解剖学研究

采用叶表皮印痕、扫描电镜以及石蜡切片法对中华补血草的叶片进行解剖研究,观察其成熟盐腺的结构、盐腺的发育与盐腺的密度。结果表明:(1)上表皮的盐腺密度比下表皮的略小。(2)成熟的盐腺由20个细胞构成,中央有4个分泌细胞,每一个分泌细胞外侧又伴有一个长方形的毗邻细胞;向外由2层杯状细胞包围,每一层分别有4个杯状细胞,使盐腺呈近似圆形;盐腺内部靠近叶肉细胞处有4个收集细胞;中央4个分泌细胞顶端的角质层各有一小孔,是盐分泌出的通道。(3)中华补血草盐腺是由一个单独的表皮细胞发育而成,分别经历单细胞时期、2细胞时期、4细胞时期、8细胞时期、16细胞时期和20细胞时期的不同发育阶段。     

EARLY LEAF ONTOGENY AND SHOOT DEVELOPMENT IN BROWNEA ARIZA (LEGUMINOSAE)

Brownea ariza Benth. (Leguminosae: Caesalpinioideae) shows early shoot tip abortion and subsequent renewal growth from the pseudoterminal bud. This species is unusual in that the entire shoot system is formed before flushing from the bud occurs, shoot tip abortion occurs during flushing, and the aborting portion contains three to six leaves as well as primordial structures varying from hood to peg shape. This study focused on the morphological changes from initiation of scale and foliage leaf primordia in the “resting” renewal bud through bud elongation to flushing and bud abortion. Scanning electron microscopy revealed that embryonic scale leaves are hood-shaped while foliage leaf primordia show early segmentation into leaflets and stipules. No transitional stages were observed. Bud scales and foliage leaves show opposite developmental trends. In bud scales, length at maturity increases from first to last formed, while length decreases in sequentially formed foliage leaves. Early in leaf development the stipules keep pace with the elongation of the rachis. When the bud reaches about one half of its final length the leaf rachis begins to exceed the lengths of its stipules. This young rachis terminates in a distinct mucro that persists until maturity at which time it abscises. Growth patterns indicate that mucro and rachis are a single developmental unit. The early abortion of a shoot tip containing several leaves cannot be easily rationalized. Previous suggestions have involved maintenance of form and ecological adaptation. We add the possibility of elimination of cell progeny encumbered by mutations. From this and other studies of this group, it is clear that at maturity leaves of different species may look alike, e.g., Hymenaea and Colophospermum are bifoliolate; Brownea, Saraca, and others are multifoliolate. However, early stages of leaf ontogeny are quite diverse and may be of systematic value, since these early differences are lost or masked by later development.     

RETRACTED ARTICLE: The AtCCX1 transporter mediates salinity tolerance in both <Emphasis Type="Italic">Arabidopsis</Emphasis> and yeast

The only species in the genus Passiflora (Passifloraceae) known to produce resin glands is P. foetida. These glands are secretory trichomes mainly present on the floral bracts and leaf stipules. The secretion produced by these glands has received attention recently due to the presence of substances with pharmacological properties. Attempts to apply in vitro cell culture methods for the large scale production of highly valuable metabolites has been rather limited due to the fact that these compounds are produced by highly differentiated secretory cells in trichomes which are seldom obtained or because differentiation is inhibited by in vitro conditions. Here we describe the in vitro plant regeneration of P. foetida obtained via organogenesis, using mature zygotic embryos as explants. Differentiated plantlets and, more important, the de novo differentiation of secretory trichomes in vitro could be observed in less than 30 days. There was a clear effect of the concentration of 2,4-dichlorophenoxyacetic acid in the culture media on the regeneration of plants and on the differentiation of glandular trichomes. Our results should be useful for the micropropagation of P. foetida, as well as for studies of the process of secretory trichome differentiation and the implemention of biotechnological methodologies for in vitro mass production of passifloricin and/or other substances present in the P. foetida resin.     

甘草腺毛的形态发生和组织化学研究

利用扫描电镜及薄切片技术对甘草的腺毛形态发生和发育过程进行了观察,并对腺毛发育过程中黄酮类成分积累进行了组织化学定位研究。结果表明：甘草腺毛为多细胞构成的盾状腺毛,有长柄和短柄2种类型;前者主要分布在花萼片上,而后者主要分布于叶片上。组化鉴定结果显示：腺毛中存在着黄酮类成分、其他亲脂类和非纤维素多糖类成分;在腺毛的发育过程中,黄酮类物质是随腺毛的发育成熟,在头部盘状结构的分泌细胞及角质层下腔中积累。研究结果对进一步探讨甘草叶中黄酮类成分的合成及其作用提供科学依据。     

抗寒性不同的油橄榄品种和单株叶片扫描电镜观察

抗寒性强的油橄榄——克里302、尼基特371的叶片,扫描电镜下的特征是:(1) 近轴表皮角质膜厚,蜡质结晶致密。(2) 远轴表皮内陷气孔,密被鳞毛。(3) 叶两面栅栏组织发达,为旱生形态阳叶结构。     

Diffusive conductances of adaxial and abaxial epidermes: Response to photon flux density during development of water stress in primary bean leaves

Maximum diffusive conductance of abaxial epidermis of primary bean leaves was considerably higher than that of adaxial epidermis. While conductances of both epidermes responded parallel to a decrease in leaf water potential (they increased slightly, reached maxima and decreased to very low values), differences in their response to photon flux density were found. The conductance of abaxial epidermis increased rapidly over lower photon flux densities and gradually over higher photon flux densities, on the other hand the conductance of adaxial epidermis increased only gradually over the whole range. The observed parallel or different response of adaxial and abaxial epidermes to leaf water potential or photon flux density did not change with changes in experimental conditions.     

臭椿不同发育阶段叶片表面结构特征

利用光学显微镜和扫描电子显微镜技术,对臭椿(Ailanthus altissima(Mill.)Swingle)叶片从叶芽到成熟叶4个发育阶段(叶芽、幼叶、近成熟叶和成熟叶)的4种叶表面结构(表皮毛、气孔器、角质层、腺体)进行了详细地观察和比较。结果显示:叶片上、下表面具单细胞非腺毛和头状腺毛两种表皮毛,其密度在叶芽阶段最大,之后随着叶片的生长和展开表皮毛密度逐渐降低;气孔器主要分布于下表面,叶片近成熟时气孔器密度最大;角质层具有条纹状结构,其隆起程度在近成熟叶阶段达到最大;叶片基部两侧具锯齿状突起,每个突起上有一个腺体,腺体发育成熟后可分泌透明黏液。说明叶片表面各结构特征是臭椿对环境长期适应的结果。     

Leaf anatomy of the Pittosporaceae R. Br.

WILKINSON, H. P., 1992. Leaf anatomy of the Pittosporaceae R. Br. An anatomical study of the leaves of 58 species representing all nine genera has been made. The anatomical characters found to be of most use in distinguishing taxa are: in surface view-cuticular architecture as seen with the SEM, stomatal outline, occasionally stomatal density, presence/absence of hairs, hair type in adult leaves; in transverse section-petiole/midrib outline, midrib number of vascular bundles and number of secretory ducts, adaxial epidermis in 1/2 layers, dimensions of adaxial epidermal cells, thickness of outer wall of adaxial epidermis, occasionally chlorenchyma interrupted/not interrupted above the midrib vascular tissue in Pittosporum species; leaf margin.     

荷花玉兰休眠芽幼叶的形态和发育特征

对荷花玉兰休眠芽的形态和发育特征进行了解剖观察。结果表明:幼叶多直立,个别旋抱状;叶片沿中脉向近轴面,在同株和异株的芽间随机性向左或向右纵向对折;叶芽内的外1～3层和花芽内的幼叶常枯死;花芽最内一层幼叶柄与其托叶贴生,并且叶片多完全退化,个别发育出较小的正常叶片。芽内幼叶枯死,是适应性的生理退化而非病害或营养不良现象,在演化上可能与其托叶替代幼叶作为芽鳞进行保护作用有相关性。     

OZONE SENSITIVITY OF LEAVES: RELATIONSHIP TO LEAF WATER CONTENT,GAS TRANSFER RESISTANCE,AND ANATOMICAL CHARACTERISTICS

Relative water content, resistance to gas transfer, stomatal spacing, and other characteristics of primary bean leaves were studied in relation to ozone sensitivity and injury. Cells of primary bean leaves are maximally sensitive to ozone exposure 9–10 days after germination under our experimental conditions. The stage of maximum sensitivity was not correlated with changes in stomatal number or resistance on either adaxial or abaxial leaf surfaces. It was deduced that bean leaf sensitivity was a function of more internal circumstances, and gas exchange was never the limiting factor through the developmental period studied. Changes in resistance were not significantly altered by ozone levels that produced no visible injury. After exposure to high ozone doses, a decrease in adaxial resistance occurred apparently as a result of palisade and epidermal cell lysis. Normally most gas exchange occurs through the adaxial surface. A 10 % decrease in relative water content accompanying a 60-min ozone exposure of 0.55 ppm could not be explained physiologically on the basis of cell injury as no visible leaf injury occurred.     

ELECTRON PROBE ANALYSIS OF SILICON AND OTHER ELEMENTS IN LEAF EPIDERMAL CELLS OF THE RICE PLANT (ORYZA SATIVA L.)

By means of electron probe analysis, the effects of significant amounts of accumulation of silicon on the accumulation of calcium, potassium, magnesium, manganese, phosphorous, iron, and sodium in the silica cells of rice leaves are described. The silica cells of both the surfaces of the leaf blade and leaf sheath were studied. Silicon accumulation in the silica cells appears to decrease the amount of accumulation of potassium on both the surfaces of the leaf blade and sheath. The effect of significant amounts of silicon accumulation on the accumulation of other elements in a particular cell varies in different organs or on different surfaces of the organ of the same plant. Magnesium, manganese, iron, and phosphorus could not be detected in the adaxial epidermis of the leaf sheath and magnesium and iron in the adaxial epidermis of the leaf blade. Manganese, magnesium, and phosphorus were not detected in the abaxial epidermis of the leaf blade nor iron in the abaxial epidermis of the leaf sheath. Sodium was not revealed in either surface of the leaf blade and leaf sheath. Possible mechanisms for the effects of silicon accumulation on the accumulation of these elements in rice leaf epidermal cells are discussed.     

Anatomical and morphological parameters of leaves and leaf petioles of Actinidia deliciosa

Differences in anatomy and morphology of the kiwifruit leaves and leaf petioles might play a considerable role in the sex-determination. Three months after bud break (June), the kiwifruit leaves of both male and female plants, grown on the vegetative and generative shoots showed different leaf area (128.6 ± 13.45 cm2 in male and 104.5 ± 4.02 cm2 in female plants) and shape. The most frequently leaf shape was determined as "folium cordatum" and "folium rotundato-cordatum". Higher values of total leaf thickness of the female leaves (190 ± 3.84 μm) in comparison to male leaves (174 ± 3.52 μm) were estimated, resulting in the thicker adaxial leaf epidermis and especially in thicker palisade parenchyma in female leaves (136 ± 2.76 μm in comparison to 104 ± 1.61 μm in male leaves). Typically bifacial leaves were observed in both male and female leaves. Anomocytic stomata in hypostomatic leaves were found. The reticulate venation appears to be the main type of leaf venation. Stalked stellate multicellular trichomes on the abaxial leaf side were frequently observed in the leaves of both sexes. No important differences between male and female plants were found in the structures of vascular system in leaves and leaf petioles. Thus leaf thickness and surface morphology of adaxial leaf epidermis can be considered as important structural parameters in the sex determination. This revised version was published online in July 2006 with corrections to the Cover Date.     

Stomatal Movements, Frequencies, and Resistances in Two Maize Varieties Differing in Photosynthetic Capacity

The Stomatal characteristics of two maize varieties previouslyfound to differ in rates of net photosynthesis were examinedin a controlled environment. Measurements with a ventilateddiffusion porometer showed that one variety exhibited a pronouncedand the other a weak periodicity in stomatal resistance of theadaxial epidermis. At equal illumination the stomatal resistanceof the adaxial epidermis decreased from upper to lower leaves,while the resistance of the abaxial epidermis changed in theopposite manner. Stomata on the adaxial and abaxial surfacesof maize leaves exhibited random not compensatory, movementsin a constant environment. The variety with the lesser stomatalfrequency and higher total leaf resistance to water loss hadnevertheless faster net photosynthesis than the variety withthe greater stomatal frequency, demonstrating the importanceof the so-called mesophyll resistance.     

STRUCTURAL CHANGES IN POPULUS DELTOIDES TERMINAL BUDS AND IN THE VASCULAR TRANSITION ZONE OF THE STEMS DURING DORMANCY INDUCTION

Morphological and anatomical changes in shoots of vigorously growing cottonwood plants (Populus deltoides Bartr.) were studied during dormancy induction in 8-hr short days (SD) and in control plants grown in 18-hr long days (LD). Pronounced structural changes occurred in terminal buds after 4 wk and full dormancy was achieved in 7 wk of SD. Leaf expansion ceased after 5 wk of SD as foliage leaves matured to the terminal bud base at leaf plastochron index 0 (LPI 0). Within the bud, total leaf length (lamina + petiole) decreased and stipule length increased progressively each week; thus, the ratio total leaf length/stipule length decreased rapidly, especially at the position of incipient bud-scale leaves LPI - 1 and LPI - 2. These bud-scale leaves were fully developed by wk 6 and were derived from enlarged stipules and aborted laminae. The full complement of primordia within the bud at the start of SD eventually matured as foliage leaves and the first bud-scale leaf (LPI - 1) was initiated immediately following transfer to SD. Acropetal advance of the primary-secondary vascular transition zone (TZ) was associated with leaf maturation. However, it did not advance throughout the entire vascular cylinder as in LD, but only in those leaf traces serving mature leaves beneath the terminal bud. In both LD and SD treatments the same linear relationship was maintained between LPI of the TZ and LPI of the most recently matured leaf; both parameters simultaneously increased in LD and decreased in SD. Thus, the relationship between leaf maturation and advance of the TZ was maintained irrespective of environment.     

AXILLARY AND DICHOTOMOUS BRANCHING IN THE PALM CHAMAEDOREA

In both Chamaedorea seifrizii Burret and C. cataractarum Martius each adult foliage leaf subtends one axillary bud. The proximal buds in C. seifrizii are always vegetative, producing branches (= new shoots or suckers); and the distal buds on a shoot are always reproductive, producing inflorescences. The prophyll and first few scale leaves of a vegetative branch lack buds. Transitional leaves subtend vegetative buds and adult leaves subtend reproductive buds. Both types of buds are first initiated in the axil of the second or third leaf primordia from the apex, P2 or P3. Later development of both types of bud tends to be more on the adaxial surface of the subtending leaf base than on the shoot axis. Axillary buds of C. cataractarum are similarly initiated in the axil of P2 or P3 and also have an insertion that is more foliar than cauline. However, all buds develop as inflorescences. Vegetative branches arise irregularly by a division of the apex within an enclosing leaf (= P1). A typical inflorescence bud is initiated in the axil of the enclosing leaf when it is in the position of P2 and when each new branch has initiated its own P1. No scale leaves are produced by either branch and the morphological relationship among branches and the enclosing leaf varies. Often the branches are unequal and the enclosing leaf is fasciated. The vegetative branching in C. cataractarum is considered to be developmentally a true dichotomy and is compared with other examples of dichotomous (= terminal) branching in the Angiospermae.     

THE LEAF OF CALYCADENIA AND ITS GLANDULAR APPENDAGES

Carlquist , Sherwin . (Rancho Santa Ana Botanic Garden, Claremont, Calif.) The leaf of Calycadenia and its glandular appendages. Amer. Jour. Bot. 46(2) : 70-80. Illus. 1959.—Large tack-shaped glands are characteristic of the leaves of Calycadenia which are associated with the inflorescence. These glands may be divided into those which are terminal on leaves and those which occur laterally on the surface of the leaf. Lateral glands show stages early in their development which are identical with those of simpler trichomes of Madinae. Terminal glands, which possess more vascularization of the stalk, show a more modified form of development. Vascularization is not derived from protoderm, but from more deeply-seated cells. These cells are included in a zone of elongation which forms the stalk. Vascular bundles may extend to the base of glands which lack vascularization in their stalks. Tack-shaped glands are considered an advanced form of trichome in which internal tissues of the leaf are involved. Within the genus Calycadenia, ontogenetic and comparative studies suggest that the following characters are advanced: reduction to a single terminal gland, “inrolling” of margins to form a cylinder of bundles, concomitant with a central core of fibers or a pectic channel. Systematic distribution of gland occurrence and of types of foliar structure are given.