Clearing, Cuticle Removal, And Staining For The Fertile Bracts (Lemmas And Paleas) Of Grass Anthoecia

The epidermis of the bracts enclosing the flower of grasses contains epidermal cell patterns which are indicative of phylogenetic and systematic relationships among taxa. Treating the heavily cutinized anthoecial bracts (fertile lemma and palea) with 10% NaOH results in the removal of sufficient cuticle to allow examination of the cells of the epidermis. After clearing and removal of the cuticle, the bracts are bleached, washed, dehydrated, and if studied by light microscopy, stained in 2 % chlorazol black E and mounted in Diaphane; or, if studied by scanning electron microscopy, dried by the critical-point method and either left uncoated or coated with a film of various conductive metals.     

不同色彩珙桐叶片和苞片解剖结构及色素含量比较研究

以生长于同一生境下的粉红珙桐(粉红色叶片、苞片)与普通珙桐(绿色叶片、白色苞片)为试材,对比两种色彩珙桐叶片/苞片解剖结构和色素含量的差异,以揭示珙桐色彩转变的规律。结果显示：(1)两种珙桐叶片均属于异面叶类型,栅栏组织由一层长柱形细胞整齐排列而成,海绵组织排列疏松,部分粉红叶片的上表皮细胞向外凸起,绿叶无此现象;粉红叶片的总厚度及其表皮角质层、栅栏组织和海绵组织厚度都高于绿叶,而表皮较薄。(2)两种珙桐苞片均无栅栏组织和海绵组织的分化,粉红苞片上表皮细胞明显隆起,上表皮角质层增厚,而下表皮变薄。(3)粉红叶片的类黄酮、花色苷含量分别是绿色叶片的1.52倍、3.67倍,两者的光合色素含量无显著差异,但粉红叶片的叶绿素a/b值比绿色叶低很多;粉红苞片花色苷含量显著高于白色苞片,而两者类黄酮含量差异不大。研究表明,花色苷是珙桐叶片和苞片色彩转红的直接因素,类黄酮有助于叶片呈红色;粉红珙桐叶片/苞片的解剖结构发生了一定变化,对光能的利用效率更高,对阴湿环境的适应性增强。     

中国特有濒危植物伯乐树叶的结构特征

伯乐树（Bretschneider asinensis Hemsl.）是中国特有濒危的第三纪孑遗植物。采用石蜡切片、刮片法和扫描电镜等技术研究了叶的结构和表皮微形态特征。结果表明,伯乐树表皮细胞的形状无规则,垂周壁稍弯曲,外壁角质膜较薄;上表皮细胞壁上被条纹状的蜡质;气孔仅见于下表皮,略下陷,其周围的表皮细胞向外呈鲜花状隆起;栅栏组织一层,海绵组织较发达,多层,内有含芥子酶的分泌细胞和含晶细胞。叶片厚度、栅栏与海绵组织厚度比值和叶绿体大小等随不同发育时期及部位有较明显变化,表明了在生长过程中苗期需要荫蔽生境,而成株则趋向中性生境的特殊要求;其下表皮细胞上鲜花状隆起结构仅与无患子目的无患子科相似,但与该科存在其它差异,为此,支持了伯乐树科在无患子目中与无患子科亲缘关系较近并独立成科的观点。     

Fine structure of the cuticle and structural changes occuring during moulting in the mite Tetranychus urticae. II. Moulting process (Chelicerata,Acarina)

Summary Processes occurring during moulting in Tetranychus urticae (Acari, Tetranychidae) are described by means of electron microscopy.Moulting is characterized by a pre-ecdysial phase which is initiated by the detachment of cuticle and epidermis. Epicuticular material is deposited as plaques but fuses to form a continuous layer. The epidermis folds up and ridges become determined. Procuticular material is synthesized inside the epidermis and packed into granules which accumulate below the epicuticular portions already deposited. Prior to ecdysis, portions of the old cuticle are dissolved. Ecdysis is achieved by moulting glands which effect bursting of the old cuticle. During the post-ecdysial phase, the endocuticle is synthesized during which a lamellation becomes obvious.Processes occuring during moulting are compared to published information on the tick cuticle.     

The ‘Embryonic moults’ of the milkweed bug as seen by the S.E.M.

Deposition, detachment and removal of the three embryonic cuticles are studied. The menbrane-like cuticle 1 covers the embryo during katatrepsis and ‘disappears’ thereafter. Cuticle 2 deposition starts shortly before dorsal closure. Its apolysis is accompanied by contractions of the embryo. Ecdysis of cuticle 2 takes place during hatching. Only cuticle 3 (= first larval cuticle) shows differentiations like sensilla and cornea. Peaks of ecdysteroid (and probably JH) titre are observed during apolysis of cuticle 1 and cuticle 2 (Dorn, 1981). Transition from ectoderm to epidermis proper takes place shortly before and during onset of cuticle 2 synthesis.     

Anatomical considerations related to photosynthesis in cotton (Gossypium hirsutum L.) leaves, bracts, and the capsule wall

Light and electron microscopy was used to relate histologicaland ultrastructural differences of cotton (Gossypium hirsutumL.) leaves, bracts, and capsule walls to their different photosyntheticactivities. Light microscopy revealed that the leaf thicknesswas approximately 152µm, had a well-defined internal organizationwith elongated palisade mesophyll cells and loosely packed spongymesophyll cells. In contrast, the bract was thinner (111 µm),lacked a defined palisade layer, and was largely composed ofinternal air spaces. The capsule wall was very thick (1013µm)and composed of numerous tightly packed, paren-chymatous corticalcells with little or no intercellular air space. Chloroplastswith well-defined granal stacks and extensive stroma lamellaewere observed in each of these three tissues, however, theirdensity was always greater in the palisade cells of the leafcompared to spongy mesophyll cells of the bract and the parenchymatouscells of the capsule wall. The low rates of photosynthesis inthe bracts and the capsule wall were associated with the internalorganization of these tissues. Key words: Cotton, photosynthesis, anatomy, cuticle, tissues     

ELECTRON PROBE MICROANALYSIS OF SILICON DEPOSITION IN THE INFLORESCENCE BRACTS OF THE RICE PLANT (ORYZA SATIVA)

The deposition of silicon in tissues of the inflorescence bracts of rice has been studied with the electron probe microanalyzer. Tissues for analysis were prepared by means of peels, frozen transverse and longitudinal sections, chromations and macerations. The microanalysis shows the heaviest deposition in a layer external to the abaxial (outer) epidermis. The cells of this epidermis are only sparsely silicified, but the’ imprints of these cells are left on the outer silica layer. In the inner tissues of the bracts, silicon deposition is mostly associated with the cell walls.     

Water sorption-desorption in conifer cuticles: The role of lignin

Current information on the type and amount of biopolymers present in the epidermis of conifer species is still insufficient. This work presents the detailed morphology and chemical composition of Araucaria bidwillii cuticle after selective treatments to remove the different types of biopolymers. After removal of the waxes, cutin and polar hydrolyzable components, a lignin-like fraction, which makes up 25% of the initial cuticle weight, was identified by GC-MS and infrared spectroscopy. The isolated lignin is of G type, mainly formed by guaiacyl units. This composition indicates that the conifer cuticle investigated here has similar composition to other conifer-isolated cuticles. Water sorption and desorption by the isolated cuticle and the different cuticle fractions, including lignin, were studied. The analysis of the isotherms, following distinct physicochemical models, gave useful information on the structural and physiological role of the different biopolymers present in the cuticle. Lignin fraction showed both a high water sorption and capability of retaining it in comparision to other cuticle components. Hysteresis effect on water sorption–desorption cycle and water cluster formations has also been studied, and their physiological role discussed.     

An ultrastructural study of the cuticle in the marine annelid Heterodrilus (Tubificidae, Clitellata)

The ultrastructure of the cuticle in four species of the marine Heterodrilus (H. paucifascis, H. pentcheffi, H. flexuosus, H. minisetosus) is investigated with transmission electron microscopy. The noncellular cuticle consists of several parts; closest to the epidermis is a thick zone of collagen fibers embedded in a matrix. The matrix continues outside the fiber zone, forming a layered epicuticle. The external surface of the epicuticle is covered by evenly distributed, membrane-bound bodies, termed epicuticular projections. The epicuticular projections have their longitudinal axis perpendicular to the surface of the cuticle and are attached to the surface by either the surrounding membrane itself or by short pedestals. Microvilli, extensions from the epidermal cells, penetrate and sometimes pass completely through the cuticle. There is interspecific variation in the morphology of the cuticle. The four studied species differ in the arrangement of the collagen fibers, from irregularly distributed fibril bundles to orthogonally arranged fiber layers, as well as in the number and density of layers in the epicuticle. One of the studied species, H. paucifascis, shows intraspecific variation, which is associated with sample locality. The Bahamian specimens of H. paucifascis have four layers in the epicuticle, club-shaped epicuticular projections, and collagen fibers forming a less defined orthogonal grid, while the Belizean specimens have three layers in the epicuticle, epicuticular projections with a bulging part at midlevel, and a distinct orthogonal grid. Based on these findings the variation in the morphology of the cuticle appears to be dependent on both phylogenetic constraints, and functional and environmental factors.     

Die Feinstruktur des Integumentes und der Muskelansatzstellen vonEchiniscoides sigismundi (Heterotardigrada)

The structure of the integument and the muscle attachments of the marine heterotardigradeE. sigismundi (M. Schultze) was studied by electron microscopy. The cuticle consists of several layers: an outer tripartite (or multilayered) epicuticle, perhaps with an outermost coat; a homogeneous inner epicuticle; a trilaminated layer; an intracuticle; and a fibrous procuticle. These features resemble the cuticle described in Eutardigrada; in contrast, areas on the legs and near the claws, with an outer multilayered epicuticle and a striated layer (inner epicuticle), are — as far as investigated — more similar to the cuticle in Heterotardigrada. The epidermis consists of a single cell layer without glands. The muscle attachments are in line with the general pattern described in the eutardigradeMacrobiotus hufelandi and in Arthropoda.     

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。     

Correlations between epidermal cell structure and endogenous hormone titers during the fifth larval instar of the tobacco hornworm, Manduca sexta

Epidermal cell morphology and cuticle production in Manduca sexta are directly influenced by both ecdysterone and juvenile hormone. Up to day 6 of the last larval instar, post-molt endocuticle is continuously deposited even though cells undergo a partial and temporary separation from the overlying cuticle at the time when a small ecdysteroid peak is detected (approximately day 3.5). At about days 6--7 when another, larger ecdysteroid peak is present, apolysis occurs accompanied by the appearance of edcysial droplets. Following apolysis, layers of pupal cuticle are deposited. Increased quantities of rough endoplasmic reticulum characterize the epidermis at times of peak endocuticle deposition (day 3, larval cuticle; day 9, pupal cuticle). Dense pigment inclusions are found in epidermis from the day of ecdysis to the last larval instar until they are eliminated 5 days later. These dense bodies migrate from cell apex to base in the absence of juvenile hormone (or in the presence of a negligible amount of juvenile hormone) and probably contain insecticyanin.     

Correlations between juvenile hormone esterase activity,ecdysone titre and cellular reprogramming in Galleria mellonella

Juvenile hormone esterase (JHE) activity, ecdysone titre, and developmental competence of the epidermis were determined in last instar larvae and pupae of Galleria mellonella. Haemolymph JHE activity reaches a peak before increases are observed in ecdysone titre both during larval-pupal and pupal-adult metamorphosis. JHE activity is low during the penultimate larval instar although general esterase activity is relatively high. In last instar larvae two ecdysone peaks are noted after the increase in JHE activity. Furthermore, epidermal cell reprogramming occurs just after the increase in haemolymph JHE activity and possibly before the first increase in ecdysone titre. This was tested by injection of high doses of β-ecdysone into last instar larvae of different ages resulting in rapid cuticle deposition. Reprogramming occurred if the resulting cuticle was of the pupal type. These correlative observations may increase our understanding of the relative importance of an ecdysone surge in the absence of JH in reprogramming of the insect epidermis.     

Selective light transmittance of translucent bracts in the Himalayan giant glasshouse plant Rheum nobile Hook. f. & Thomson (Polygonaceae)

Translucent bract transmittance of ultraviolet (UV) to infrared (IR) radiation (between 320 and 800 nm) and leaf anatomy were examined in a glasshouse plant, Rheum nobile Hook. f. & Thomson (Polygonaceae) to assess the function of avoiding injury by UV radiation while keeping the inflorescence warm by photosynthetically active (PA) and IR radiation. Although the translucent bracts and rosulate leaves transmitted little UV radiation, the former always transmit more PA and IR radiation. Additionally, the bracts transmit much more scattered solar radiation than direct radiation. The bracts are also anatomically different from the rosulate leaves. They have two or three layers of mesophyll cells with neither palisade nor spongy parenchymatous cells; in addition, the uppermost layer of mesophyll and the epidermis stain easily, and both are thought to play a role in attenuating UV radiation. The leaf epidermis of many land plants has UV absorbing pigments such as flavonoids, which absorb almost all UV radiation. Thus the role of the bracts of R. nobile is to protect the reproductive organs by absorbing UV radiation and to keep them warm by transmitting PA and IR radiation. The bracts are believed to have adapted function and form to the environment, in particular, to the weather conditions of the eastern Himalaya.     

Tissue abscission and wound healing in the operculum of Pomatoceros lamarckii Quatrefages (Polychaeta: Serpulidae)

Following opercular amputation in Pomatoceros lamarckii Quatrefages, wound healing is initiated from a predetermined point on the peduncle. The events of abscission, cell migration and cuticle deposition during wound healing have been studied by light and electron microscopy. Abscission occurs at a predetermined point on the peduncle indicated by specialized epidermal cells, the easy break-point cells (EBP). Following detachment of tissues distal to the EBP cells, the resultant wound is plugged by a knot of coelomocytes which provide a substratum over which epidermal cells migrate to seal and restore the epidermis. During their migration, the epidermal cells undergo differentiation and deposit a new cuticle. Cuticle formation is initiated by the deposition of a finely filamentous matrix. The fine filaments subsequently coalesce to form thicker fibrils which become aggregated into layers of orthogonally-arranged fibril bundles. The mechanisms involved in abscission, cell migration and cuticle deposition during wound healing of the opercular filament are discussed.     

An ultrastructural analysis of the cuticle,epidermis and esophageal epithelium of Eisenia foetida (Oligochaeta)

The epidermis of Eisenia is covered by a cuticle and rests on a basement lamella. The cuticle, which is resistant to a variety of enzymes, is composed of non-striated, bundles of probable collagen fibers that are orthogonally oriented and are embedded in a proteoglycan matrix. The basement lamella consists of striated collagen fibers with a 560 Å major periodicity. Proximity and morphology suggest that the epidermis may contribute to both the cuticle and the basement lamella — that is, the single tissue may synthesize at least two types of collagen. The epidermis is a pseudostratified epithelium containing three major cell types (columnar, basal and gland) and a rare fourth type with apical cilia. The esophagus is lined by a simple cuticulated epithelium composed predominantly of a single cell type, which resembles the epidermal columnar cell. Rare gland cells occur in the esophageal epithelium, but basal cells are lacking.     

The structure of the integument of the sea cucumber,Thyone briareus

The integument and podia of the sea cucumber Thyone briareus were examined by bright field and electron microscopy. The epidermal surface was found to be covered by an acellular, PAS positive cuticle which appeared to be secreted by the underlying epidermal cells. Although the superficial portion of the cuticle contains numerous fine filaments, their ultrastructure bears no resemblance to collagen fibers. The epidermal cells are widely spaced and have long apical processes that extend along the under surface of the cuticle forming a contiguous epithelium. The apical expansions of the epidermal cells are attached to one another by means of septate desmosomes which may run continuously around all epidermal cells. Special attachment structures within these apical expansions appear to bind the cuticle to the dermis. The epidermal cells and their apical expansions are separated from the dermis by an 800 Å thick basement membrane. Granule containing cells in the upper dermis send processes up to the cuticle where they are bound to the typical epidermal cells by septate desmosomes. The abundant membrane bound granules of the cells enter villous-like processes which pass through the cuticle. The function of these cells may be to produce an adhesive material on the podia or they may be pigment cells. The thick dermis consists of a superficial zone, containing largely ground substance; a middle or laminated zone containing laminae of collagen fibers arranged in an orthogonal fashion; and a hypodermis consisting largely of ground substance and reticular fibers. Fibroblasts are abundant in the superficial dermis and between the collagen laminae. Wandering coelomocytes, or morula cells, accumulate between the collagen laminae and in the hypodermis. They may also become an integral part of the epidermis by forming septate desmosomes with epidermal cells. Morula cells contain highly specialized spherules whose tinctorial properties and electron microscopic appearance suggest that they contain protein and mucopolysaccharide.     

The internal cuticle of Cirsium horridulum (Asteraceae) leaves

Leaf internal cuticle has not previously been studied in detail, and yet its existence has profound implications for the path of water movement. The internal cuticle forms a uniform layer on the inner periclinal epidermal walls that border substomatal cavities. This cuticle is continuous with the external cuticle through the stomatal pores. The thickness of the internal cuticle on nonstomatal epidermal cells is approximately one-third that of the external cuticle on the same cells. On both the abaxial and adaxial sides of the leaf the internal cuticle forms irregularly shaped islands bordered by mesophyll cells. The size of the islands coincides with the epidermal area of the substomatal cavity. The internal cuticle remains intact and connected to the external cuticle after incubation in cellulytic enzymes. After treatment with sulfuric acid or chloroform, both cuticles remain intact. The autofluorescence of both cuticles is increased by staining with auramine O. These results indicate that large portions of the leaf epidermis are covered by both an internal and an external cuticle.     

Pupal cuticle formation by Manduca sexta epidermis in vitro: Patterns of ecdysone sensitivity

During the larval-pupal transformation, various regions of the epidermis of Manduca sexta larvae have previously been found to require different lengths of exposure to the prothoracic glands in order to form pupal cuticle. To distinguish between requirements for differing threshold concentrations of ecdysone and those for differing durations of exposure to ecdysone, wandering stage larval epidermis was cultured in Grace's medium. When most of the thick larval cuticle was removed, the epidermis responded to concentrations of β-ecdysone of 1.0 μ/ml or greater for 4 days by forming cysts which later formed tanned pupal cuticle. No fat body or protein supplement was required. When the larval integument was explanted intact, similar requirements for cuticle formation and for tanning were found. All regions of the fifth abdominal segment required similar concentrations of β-ecdysone (0.4–0.6 μg/ml) for 4 days for 50% to form pupal cuticle, but gin trap epidermis required the least exposure to a threshold concentration of ecdysone (1.5 days in 0.9 μg/ml). The anterior dorsal intersegmental region required about 0.5 day longer, followed by the posterior intersegmental and the dorsal intrasegmental regions. Thus, the duration of exposure seemed more important. About 1 day longer of exposure to ecdysone was required for subsequent tanning of the new cuticle than for cuticle formation, yet tanning of the cuticle did not occur with prolonged exposure to ecdysone.