The presence of cutan limits the interpretation of cuticular chemistry and structure: Ficus elastica leaf as an example

Plant cuticles have been traditionally classified on the basis of their ultrastructure, with certain chemical composition assumptions. However, the nature of the plant cuticle may be misinterpreted in the prevailing model, which was established more than 150 years ago. Using the adaxial leaf cuticle of Ficus elastica, a study was conducted with the aim of analyzing cuticular ultrastructure, chemical composition and the potential relationship between structure and chemistry. Gradual chemical extractions and diverse analytical and microscopic techniques were performed on isolated leaf cuticles of two different stages of development (i.e. young and mature leaves). Evidence for the presence of cutan in F. elastica leaf cuticles has been gained after chemical treatments and tissue analysis by infrared spectroscopy and electron microscopy. Significant calcium, boron and silicon concentrations were also measured in the cuticle of this species. Such mineral elements which are often found in plant cell walls may play a structural role and their presence in isolated cuticles further supports the interpretation of the cuticle as the most external region of the epidermal cell wall. The complex and heterogeneous nature of the cuticle, and constraints associated with current analytical procedures may limit the chance for establishing a relationship between cuticle chemical composition and structure also in relation to organ ontogeny.     

STRUCTURE OF THE PEAR LEAF CUTICLE WITH SPECIAL REFERENCE TO CUTICULAR PENETRATION

Study of the pear leaf cuticle (Pyrus communis L. ‘Bartlett‘), in both intact and enzymatically isolated forms, has revealed that the cuticular membrane is separated from the underlying epidermal cell wall by a layer of pectic substances which extend into but not through the membrane. A layer of embedded birefringent waxes occurs towards the outer surface of the cuticular membrane. Platelet-like epicuticular waxes are deposited on the outer surface. The upper cuticular membrane is astomatous. The lower epidermis is stomatous, and the outer cuticular membrane is continuous with that lining the substomatal cavity. The lower cuticular membrane is also generally thicker than the upper, and both the upper and lower cuticular membranes are thicker over veinal than over mesophyll tissue. The birefringence frequently is discontinuous over anticlinal walls and over veinal tissue. The lower cuticle appears to contain fewer embedded waxes (as indexed by birefringence) than the upper. Enzymatic isolation of the cuticular membrane from the underlying tissues does not appear to cause any discernible change in structure as viewed with a light microscope. These findings are discussed in light of current knowledge concerning penetration of foliar applied substances into the leaf.     

Computer-based studies of diffusion through stomata of different architecture

BACKGROUND AND AIMS: The influence of stomatal architecture on stomatal conductance and on the developing concentration gradient was explored quantitatively by comparing diffusion rates of water vapour and CO(2) occurring in a set of three-dimensional stoma models. The influence on diffusion of an internal cuticle, a sunken stoma, a partially closed stoma and of substomatal chambers of two different sizes was considered. METHODS: The study was performed by using a commercial computer program based on the Finite Element Method which allows for the simulation of diffusion in three dimensions. By using this method, diffusion was generated by prescribed gas concentrations at the boundaries of the substomatal chamber and outside of the leaf. The program calculates the distribution of gas concentrations over the entire model space. KEY RESULTS: Locating the stomatal pore at the bottom of a stomatal antechamber with a depth of 20 microm decreased the conductance significantly (at roughly about 30 %). The humidity directly above the stomatal pore is significantly higher with the stomatal antechamber present. Lining the walls of the substomatal chamber with an internal cuticle which suppresses evaporation had an even stronger effect by reducing the conductance to 60 % of the original value. The study corroborates therefore the results of former studies that water will evaporate preferentially at sites in the immediate vicinity to the stomatal pore if no internal cuticle is present. The conductance decrease affects only water vapour and not CO(2). Increasing the substomatal chamber increases CO(2) uptake, whereas transpiration increases if an internal cuticle is present. CONCLUSIONS: Variation of stomatal structure may, with unchanged pore size and depth, profoundly affect gas exchange and the pathways of liquid water inside the leaf. Equations for calculation of stomatal conductance which are solely based on stomatal density and pore depth and size can significantly overestimate stomatal conductance.     

Development of plant cuticles: occurrence and role of non-ester bonds in cutin of Clivia miniata Reg. leaves

The effect of BF₃-methanol treatment on the mass and fine structure of isolated Clivia leaf cuticles at different stages of development has been investigated. BF₃-methanol cleaves ester linkages in cutin; however, the cuticles are not completely depolymerized. With increasing age, the residue left after BF₃-methanol treatment increases in mass. In very young cuticles, 10% of the total cutin resisted BF₃-methanol and the fraction of nonester cutin increased up to 62% in mature leaves. Transmission electron microscopy shows that fine structure of the cuticle proper is severely distorted but not destroyed. The internal cuticular layer, which exhibits a heavy contrast when fixed with KMnO₄, is completely depolymerized, while the external cuticular layer is hardly affected. The results are discussed in relation to cuticle development and to the function of cuticles as transpiration resistances.Abbreviation CP cuticle proper - ECL external cuticular layer - E cutin ester bonded cutin - ICL internal cuticular layer - MX-membrane polymer matrix membrane - NE-cutin non-ester bonded cutin - TEM transmission electron microscopy     

Ectodesmata in relation to binding sites for inorganic ions and urea on isolated cuticular membrane surfaces

Binding of radioactive ions and molecules penetrating isolated cuticles of green onion leaves does not occur in the whole cuticular membrane but is restricted to pointlike areas of a characteristic distribution as was recently demonstrated by microradioautography. Comparison of the localization of these binding sites in isolated cuticles and of ectodesmata in outer epidermal walls reveals that the pattern of binding sites coincides with that of ectodesmata. It is concluded that in intact epidermal cells the binding sites in the cuticle lie on top of ectodesmatal spaces in the wall and that together they form combined pathways of favored penetrability for aqueous solutions which are to be absorbed or excreted.     

Development of plant cuticles: fine structure and cutin composition of Clivia miniata Reg. leaves

The fine structure and monomeric composition of the ester-cutin fraction (susceptible to BF₃/CH₃OH transesterification) of the adaxial leaf cuticle of Clivia miniata Reg. were studied in relation to leaf and cuticle development. Clivia leaves grow at their base such that cuticle and tissues increase in age from the base to the tip. The zone of maximum growth (cell expansion) was located between 1 and 4 cm from the base. During cell expansion, the projected surface area of the upper epidermal cells increased by a factor of nine. In the growth region the cuticle consists mainly of a polylamellate cuticle proper of 100–250 nm thickness. After cell expansion has ceased both the outer epidermal wall and the cuticle increase in thickness. Thickening of the cuticle is accomplished by interposition of a cuticular layer between the cuticle proper and the cell wall. The cuticular layer exhibits a reticulate fine structure and contributes most of the total mass of the cuticle at positions above 6 cm from the leaf base. The composition of ester cutin changed with the age of cuticles. In depolymerisates from young cuticles, 26 different monomers could be detected whereas in older ones their number decreased to 13. At all developmental stages, 9,16-/10,16-dihydroxyhexadecanoic acid (positional isomers not separated), 18-hydroxy-9-octadecenoic acid, 9,10,18-trihydroxyoctadecanoic acid and 9,10-epoxy-18-hydroxyoctadecanoic acid were most frequent with the epoxy alkanoic acid clearly predominating (47% at 16 cm). The results are discussed as to (i) the age dependence of cutin composition, (ii) the relationship between fine structure and composition, (iii) the composition of the cuticle proper, the cuticular layer and the non-depolymerizable cutin fraction, and (iv) the polymeric structure of cutin.Abbreviations CL cuticular layer - CP cuticle proper - MX cutin polymer matrix     

Cuticle of Caenorhabditis elegans: its isolation and partial characterization

The adult cuticle of the soil nematode, Caenorhabditis elegans, is a proteinaceous extracellular structure elaborated by the underlying layer of hypodermal cells during the final molt in the animal's life cycle. The cuticle is composed of an outer cortical layer connected by regularly arranged struts to an inner basal layer. The cuticle can be isolated largely intact and free of all cellular material by sonication and treatment with 1% sodium dodecyl sulfate (SDS). Purified cuticles exhibit a negative material in the basal cuticle layer. The cuticle layers differ in their solubility in sulfhydryl reducing agents, susceptibility to various proteolytic enzymes and amino acid composition. The struts, basal layer, and internal cortical layer are composed of collagen proteins that are extensively cross-linked by disulfide bonds. The external cortical layer appears to contain primarily noncollagen proteins that are extensively cross-linked by nonreducible covalent bonds. The collagen proteins extracted from the cuticle with a reducing agent can be separated by SDS-polyacrylamide gel electrophoresis into eight major species differing in apparent molecular weight.     

Studies on turfgrass snow mold caused byTyphula ishikariensis. II. Microscopical observation of infected bentgrass leaves

Light and transmission electron microscopy revealed thatTyphula ishikariensis penetrated into bentgrass leaves either through cuticles or stomata either by single hyphae or infection cushions formed on host surfaces. Time course study on infected leaves showed that penetration through stomatal subsidiary cells and their adjacent cells seemed to occur earlier than that through epidermal cells located farther from stomata. More than 30% of epidermal cells were infected by 10 days after inoculation. When hyphae penetrated through an intact cuticle of epidermal cells, they seemed to dissolve host cell walls enzymatically at penetration sites. Physical pressure also seemed to be involved in penetration.     

Incorporation of calliphorin into the cuticle of the developing blowfly,Calliphora vicina

Summary The stage-specific appearance of calliphorin in cuticles of Calliphora vicina was analysed by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotting. The fate of the protein, injected into last instar larvae, was pursued by autoradiography of histological sections. Fractionation of sclerotized pupal cuticle in buffer-soluble, urea-soluble and NaOH-soluble fractions shows that calliphorin forms covalent and non-covalent links with other cuticle components. Calliphorin traverses the epidermal cells and enters the cuticle in an undegraded state and appears to be an important constituent of the sclerotizing system.     

Water Pathways in Higher Plants: III. THE TRANSPIRATION STREAM WITHIN LEAVES

Water in the transpiration stream is distributed throughoutthe leaves in the vascular bundles. In wheat, water appearsto be confined to the main veins by the mestome sheath and toenter the mesophyll through the walls of the smaller veins.Within the mesophyll the water in the transpiration stream movesin the free space of the cell walls to the evaporating surfacesof the leaf. The lead chelate, which is used to trace the transpirationstream, accumulates at the final points of evaporation at themargin of the leaf. Lead chelate accumulates beneath and onthe surface of the cuticle, being partly associated with theanticlinal walls of the epidermal cells, the walls of the stomatalguard cells and specialized epidermal cells. Chelate does notaccumulate at the base of substomatal cavities, indicating thatthe cuticle of the epidermis is the main evaporating surfaceof the leaf. The behaviour in broad bean, laurel, and plantainis essentially the same. The rate of peristomatal and cuticulartranspiration is closely related to the size of the stomatalaperture. Conditions which control stomatal aperture also causechanges in the dimensions of the epidermal cells.     

Ultrastructural differences between larval and pupal cuticles ofPieris brassicae (lepidoptera)

Summary The study of larval and pupal cuticles ofPieris brassicae has revealed some differences in ultrastructural architecture. The lamellated cuticle of larvae is traversed by processes of epidermal cells connected with fibrils possibly acting as supports for the arched cuticle but never developing into a space system. In contrast pupal cuticles are traversed by a space system containing bundles of fibrils which are involved in the transport of lipid containing material.Ultrastructural changes occuring in the pupal cuticle few days after ecdysis are described.These results are discussed in relation to the present knowledge of cuticle structure.     

The mode of action of fatty alcohols on leaf tissue

The mode of action of a mixture of C₈ and C₁₀ fatty alcohols, formulated in polyoxyethyelene (20) sorbitan mono-oleate (SMO) and used as an emulsion (FAE) to inhibit axillary bud (sucker) growth in tobacco production, was studied using infrared spectroscopy (NIR), photoacoustic spectroscopy (PAS), electrical resistance, and the ability of treated cells to reverse plasmolysis on leaf tissues fromNicotiana tabacum L. and other dicotyledonous species. NIR spectra showed that isolated cuticles were affected optically when treated with FAE, but did not dissolve. PAS absorbances in the UV of isolated cuticles and of epidermal peels were similar and showed that cuticles were homogeneous, unilamellar structures. In intact leaf segments, it was possible, over time using PAS absorbances in the visible region, to separate absorbance of the surface components (cuticle) from the absorption of chlorophyll and other subsurface components and to monitor the penetration by FAE into the leaf. Penetration of the FAE to the subcuticular cells took approximately 2 h. Electrical resistance measurements of FAE-treated isolated midveins of tobacco leaves decreased with time, indicating that the plasma membranes of the cells became leaky. The effect of FAE on plasma membranes of cells was confirmed withElodea sp. where leaf cells after treatment with 1 and 5% FAE lost the ability with time to plasmolyze upon exposure to a 10% solution of Ca(NO₃)₂. The results of the various studies were interpreted to mean that at the labeled concentration (4–5%) for use in the control of axillary bud growth on decapitated tobacco, FAE passed through the cuticle without disrupting it. However, the plasma membranes of the subtending cells were altered so that, in time, bud tissues desiccated (appeared burned) and growth of the sucker was controlled.     

Leaf Epidermal Cells： A Trap for Lipophilic Xenobiotics

Plant surfaces are covered by a layer of cuticle, which functions as a natural barrier to protect plants from mechanical damage, desiccation, and microbial invasion. Results presented in this report show that the epicuticular wax and the cuticle of plant leaves also play an important role in resisting xenobiotic invasion. Although the epicuticular wax is impermeable to hydrophilic xenobiotics, the cuticle not only restricts the penetration of hydrophilic compounds into leaf cells, but also traps lipophilic ones. The role of the epidermal cells of plant leaves in resisting xenobiotic invasion has been neglected until now. The present study shows, for the first time, that the epidermal cells may reduce or retard the transport of lipophilic xenobiotics into the internal tissues through vacuolar sequestration. Although the guard cells appear to be an easy point of entry for xenobiotics, only a very small proportion of xenobiotics present on the leaf surface actually moves into leaf tissues via the guard cells .     

Dispersed cuticles from the Eocene of North America

KOVACH, W. L. & DILCHER, D. L., 1984. Dispersed cuticles from the Eocene of North America. Macerations of organic-rich clay from the Claiborne Formation (Middle Eocene) of Tennessee have yielded a wide variety of well-preserved dispersed cuticles. Details of the epidermal cell patterns, arrangement of the stomata1 complex, trichomes and trichome attachment have made possible the association of some dispersed cuticles with leaf types known from this formation which have similar cuticle, and with modern families. All dispersed cuticles are classified in a morphologic system. Through both our own work and a review of previous investigations we have found that distinct dispersed cuticle types can be recognized and may be used biostratigraphically to characterize geologic strata, palaeo-ecologically to provide insights into environmental reconstruction, and systematically to follow the history of certain taxa.     

伯乐树不同发育阶段叶片表面附属结构特征

利用石蜡切片及电子显微镜扫描技术,对伯乐树（Bretschneidera sinensis）不同发育阶段的叶表面表皮毛、角质层、乳突和气孔器4种附属结构进行了观察。结果显示：伯乐树叶的上、下表面和叶脉处分布着单细胞或多细胞的单列表皮毛,表皮毛的密度随着叶片的生长发育逐渐稀疏;叶片上表面覆盖着条纹状的角质层;叶片的下表面有鲜花状乳突,密度随叶片的生长逐渐稀疏;气孔仅见于下表面,气孔器类型为无规则型。伯乐树和叠珠树叶片具有相似的乳突结构,结合形态学、解剖学及分子证据,在一定程度上显示了伯乐树与叠珠树科可能存在较密切的关系;叶表面附属结构的特点反映了伯乐树对环境的长期适应。     

A new technique for measurement of water permeability of stomatous cuticular membranes isolated from Hedera helix leaves

Transpiration of cuticular membranes isolated from the lower stomatous surface of Hedera helix (ivy) leaves was measured using a novel approach which allowed a distinction to be made between gas phase diffusion (through stomatal pores) and solid phase diffusion (transport through the polymer matrix membrane and cuticular waxes) of water molecules. This approach is based on the principle that the diffusivity of water vapour in the gas phase can be manipulated by using different gases (helium, nitrogen, or carbon dioxide) while diffusivity of water in the solid phase is not affected. This approach allowed the flow of water across stomatal pores ('stomatal transpiration') to be calculated separately from the flow across the cuticle (cuticular transpiration) on the stomatous leaf surface. As expected, water flux across the cuticle isolated from the astomatous leaf surface was not affected by the gas composition since there are no gas-filled pores. Resistance to flux of water through the solid cuticle on the stomatous leaf surface was about 11 times lower than cuticular resistance on the astomatous leaf surface, indicating pronounced differences in barrier properties between cuticles isolated from both leaf surfaces. In order to check whether this difference in resistance was due to different barrier properties of cuticular waxes on both leaf sides, mobility of 14C-labelled 2,4-dichlorophenoxy-butyric acid 14C-2,4-DB) in reconstituted cuticular wax isolated from both leaf surfaces was measured separately. However, mobility of 14C-2,4-DB in reconstituted wax isolated from the lower leaf surface was 2.6 times lower compared with the upper leaf side. The significantly higher permeability of the ivy cuticle on the lower stomatous leaf surface compared with the astomatous surface might result from lateral heterogeneity in permeability of the cuticle covering normal epidermal cells compared with the cuticle covering the stomatal cell surface.     

The mode of action of fatty alcohols on leaf tissue

The mode of action of a mixture of C₈ and C₁₀ fatty alcohols, formulated in polyoxyethyelene (20) sorbitan mono-oleate (SMO) and used as an emulsion (FAE) to inhibit axillary bud (sucker) growth in tobacco production, was studied using infrared spectroscopy (NIR), photoacoustic spectroscopy (PAS), electrical resistance, and the ability of treated cells to reverse plasmolysis on leaf tissues fromNicotiana tabacum L. and other dicotyledonous species. NIR spectra showed that isolated cuticles were affected optically when treated with FAE, but did not dissolve. PAS absorbances in the UV of isolated cuticles and of epidermal peels were similar and showed that cuticles were homogeneous, unilamellar structures. In intact leaf segments, it was possible, over time using PAS absorbances in the visible region, to separate absorbance of the surface components (cuticle) from the absorption of chlorophyll and other subsurface components and to monitor the penetration by FAE into the leaf. Penetration of the FAE to the subcuticular cells took approximately 2 h. Electrical resistance measurements of FAE-treated isolated midveins of tobacco leaves decreased with time, indicating that the plasma membranes of the cells became leaky. The effect of FAE on plasma membranes of cells was confirmed withElodea sp. where leaf cells after treatment with 1 and 5% FAE lost the ability with time to plasmolyze upon exposure to a 10% solution of Ca(NO₃)₂. The results of the various studies were interpreted to mean that at the labeled concentration (4–5%) for use in the control of axillary bud growth on decapitated tobacco, FAE passed through the cuticle without disrupting it. However, the plasma membranes of the subtending cells were altered so that, in time, bud tissues desiccated (appeared burned) and growth of the sucker was controlled.Cooperative investigations of the Agricultural Research Service of the United States Department of Agriculture with the Agricultural Research Service of the North Carolina State University and the National Institutes of Environmental Health Sciences of the Department of Health and Human Services. The use of trade names in this publication does not imply endorsement by USDA, NCSU, and NIEHS of products named nor criticism of similar ones not mentioned.     

Penetration of chemicals into the Malus leaf cuticle

The adaxial leaf cuticle of Malus pumila was examined by electron microscopy to determine possible avenues for transcuticular movement of foliarly applied chemicals. Cutin-embedded polysaccharide microfibrils originated at the outer epidermal cell wall and occasionally extended to the cuticle surface. Lamellae, ca. 4 nm wide, usually were oriented parallel to the cuticle surface. When oriented perpendicular to the surface, they extended nearly to the subjacent wall layer from the surface. Aqueous solutions of uranyl acetate, silver nitrate and phenyl mercuric acetate applied to the cuticle surface of leaf segments floated on solutions of phosphate salts or thiocarbohydrazide (TCH) reacted within the cuticle to form insoluble electron-opaque deposits indicative of their avenues of transcuticular movement. Uranyl phosphate deposits were observed only in the polysaccharide microfibrils of chloroform: methanolextracted leaves. Silver-TCH deposits were observed in the microfibrils of both extracted and nonextracted leaf cuticles. Phenyl mercuric acetate-TCH deposits were randomly dispersed throughout the extracted cuticle and not associated with the polysaccharide microfibrils.Abbreviations TCH thiocarbohydrazide - PMA phenyl mercuric acetate