The Prevalence of Pores and Canals in Leaf Cuticular Membranes. 2. Supplemental Studies

Evidence is presented for the existence of discrete, naturalcuticular pores concomitant with anticlinally-oriented transcuticularcanals found in the mature leaf surfaces of 26 out of 37 taxaamong 19 families. This investigation is an extension of earlierobservations made on 32 other taxa among 14 families. Dewaxed,chemically isolated, adaxial and abaxial cuticular membranesin conjunction with transverse leaf sections were examined usingordinary staining techniques. The ubiquitous pores occur randomlywith no evidence of clustering. Pore and canal diameters averageapprox. 1 µm. Canal lengths are directly related to cuticlethickness. No correlations were found between cuticle thicknessesand either pore frequencies or pore and canal diameters. Evidenceis provided by light microscopy photomicrographs. Leaf cuticles, cuticular membranes, cuticular pores, transcuticular canals, cuticular flanges     

The Morphology and Permeability of Isolated Cuticular Membranes of Hoya carnosa R. Br. (Asclepiadaceae)

This investigation is in part an extension of previous leafcuticle observations made on 52 other taxa among 34 families.Dewaxed, chemically isolated, adaxial and abaxial cuticularmembranes and transverse leaf sections of the wax-flower plant(Hoya carnosa R. Br.) were examined using ordinary stainingtechniques and light-microscopy methods. Evidence is presentedfor the existence of ubiquitous, discrete, naturally occurringcuticular pores, concomitant with anticlinally oriented trans-cuticularcanals, distributed randomly throughout the cuticular matrix.The surface of the adaxial cuticular membrane contains approx.6540 unclustered pores per mm², the abaxial approx. 4680 poresper mm². Pore and canal diameters range between 0.5 and 0.75µm. The canals are often arcuate and their lengths aredirectly related to cuticle thickness. No correlations werefound between cuticle thickness and either pore numbers or poreand canal diameters. Based upon experiments with various pHindicators, solutions, and stains, the dewaxed, dry cuticularmembrane of H. carnosa appears to be both distinctly hydrophilicand selectively permeable through a myriad of microscopicallyvisible pores and canals permeating its matrix. A de novo interpretationof gross cuticle morphology based solely upon light microscopyobservations is presented by semi-diagrammatic illustrations. Hoya carnosa R. Br., wax-flower (wax-plant), cuticular membranes, cuticular pores, transcuticular canals, permeability     

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.     

Cuticular Pores and Transcuticular Canals in Diverse Fruit Varieties

Dewaxed thin-sectioned and dewaxed isolated mature fruit cuticlesrevealed the unequivocal presence in situ of visibly discrete,ubiquitous, cuticular pores or orifices concomitant with anticlinally-orientedtranscuticular canals in 51 varieties of fruit among 20 plantfamilies. More than 66 per cent of the fruit cuticles have poresand/or canals. No correlation exists between either fruit sizeor pore size and cuticle thickness. Dewaxed cuticles rangedfrom 1.25–22.5 µm in thickness. Canal lengths aredirectly related to cuticle thickness. Cuticular occlusionsof the epidermal cells were found in 76 per cent of the fruitsexamined. Evidence is provided by light microscopy photomicrographs. Fruit cuticles, cuticle morphology, cuticular pores, transcuticular canals     

The Multiple Epidermis-Cuticle Complex of Medlar Fruit Mespilus germanica L. (Rosaceae)

In order to determine the authenticity of the multiple epidermallayers in the pomaceous fruit of Medlar or Mespil (Mespilusgermanica L.), developmental studies were made from 2 weeksbefore anthesis through harvest and storage. Various histochemicaltechniques were used for the determination of epidermal cellwall structures and cell contents, and for the isolation andstudy of the cuticular membranes. The multiseriate epidermisis derived from successive tangential divisions of the initiallyuniseriate epidermis commencing about 3 weeks post-anthesis.The divisions occur simultaneously around the fruit circumferenceand result in the formation of a normally four- to five-layeredepidermis at fruit maturity. As each epidermal layer is derivedit concomitantly develops a distinct, flanged cuticle that remainspersistent until sloughing of the layer occurs. Evidence providedby light and scanning electron microscopy indicates the presenceof discrete ubiquitous pores and non-anastomosing, anticlinallyoriented canals in the cuticular membranes. Measurements weremade of individual cuticular membrane thicknesses during development,and of cuticular pore dimensions in the mature fruit; cuticularpore numbers were calculated. A brief study was made of therelationship between lenticel development and development ofthe multiseriate epidermis. Mespilus germanica L., Medlar (Mespil) fruit, multiseriate epidermis, cuticular membrane, cuticular pores, transcuticular canals, lenticels     

Apple Fruit Cuticles and the Occurrence of Pores and Transcuticular Canals

Developmental studies were made on the dewaxed thin-sectionedapple fruit cuticles of 10 Malus sylvestris Mill, cultivarsfrom 4 weeks before anthesis through fruit maturation and harvest.Cuticular development appears to correlate well with the generalgrowth of the fruit. However, no correlation exists betweenfruit size and cuticle thickness. Cuticular pores were evidentas early as 1 week before anthesis and transcuticular canalsbecame evident by 1 week following anthesis. Dewaxed thin-sectioned,as well as isolated, mature fruit cuticles of 16 cultivars andfour crab-apples consistently revealed the distinct presenceof ubiquitous pores and canals. Evidence is provided by lightmicroscopy and scanning electron microscopy (SEM). Measurementswere taken of cuticle thicknesses during development and ofcuticular pore dimensions, and calculations were made of poreand canal numbers. Fruit size alone is not directly indicativeof total pore numbers per surface area. Canal lengths are directlyrelated to the developmental thickness of the cuticle. No correlationwas found between the thickness of the mature cuticle and eitherthe number of pores present or the pore diameters. Malus sylvestris Mill, apple fruit, morphology, cuticle, cuticular flanges, cuticular pores, transcuticular canals, ultrastructure     

Adaptations to foliar absorption of faeces: a pathway in plant carnivory

BACKGROUND AND AIMS: Roridula plants capture insects but have no digestive enzymes. It has been hypothesized that Roridula leaves absorb nitrogen from the faeces of obligately associated, carnivorous hemipterans. But rapid movement across the leaf surfaces of most plant leaves is prevented by the presence of an impermeable cuticle. However, in carnivorous plants, cuticular gaps or pores in digestive/absorptive cells allow rapid movement across the leaf surface. Recently, it was suggested that the hemipteran-plant interaction constituted a new pathway for plant carnivory. Here, a further adaptation to this pathway is described by demonstrating how Roridula plants probably absorb hemipteran faeces rapidly through their leaf cuticles. METHODS: The dye neutral red was used to document the rapidity of foliar absorption and TEM to determine the nature of cuticular discontinuities in the leaf of Roridula. KEY RESULTS: Aqueous compounds diffuse rapidly across the cuticle of Roridula's leaves but not across the cuticles of co-occurring, non-carnivorous plant leaves. Furthermore, immature Roridula leaves were unable to absorb neutral red whereas mature leaves could. Using TEM, cuticular gaps and pores similar to those in other carnivorous plants were found in the epidermal cells of mature Roridula leaves. CONCLUSIONS: The leaf cuticle of Roridula is very thin (0-120 nm) and cell wall elements project close to the leaf surface, possibly enhancing foliar absorption. In addition to these, cuticular gaps were frequently seen and probably perform a function similar to those found in other carnivorous plants: namely the absorption of aqueous compounds. The cuticular gaps of Roridula are probably an adaptation to plant carnivory, supporting the newly described pathway.     

Effect of humidity on cuticular water permeability of isolated cuticular membranes and leaf disks

The effects of humidity on water permeability of astomatous, isolated cuticular membranes and leaf disks of Citrus aurantium L., Vinca major L., Prunus laurocerasus L., Hedera helix L. and Forsythia intermedia (Thunb.) Vahl. were investigated by a new method using 3H2O. With isolated cuticular membranes of P. laurocerasus the isotope method resulted in values similar to those obtained by a well-established gravimetric method. Cuticular water permeability significantly increased by factors of 2 to 3 when air humidities increased from 2 to 100%. Plots of permeances vs. air humidity were non-linear and the slope increased with increasing air humidity. Permeances of intact leaf disks showed a response to increasing humidity similar to those of isolated cuticular membranes. When cuticular water permeability was measured using wax-free, isolated polymer matrix membranes that had been methylated, the effect of air humidity was significantly suppressed compared to non-methylated polymer matrix membranes. From this observation it is concluded that non-esterified, free carboxyl groups present in the cutin polymer matrix significantly contribute to the effect of humidity on cuticular water permeability. These and other polar groups sorb water, which in turn increases the water permeability of polar domains of the cuticle. This humidity-sensitive, polar path of cuticular water permeability is arranged in parallel with the major, dominating and humidity-independent, non-polar path of cuticular water permeability formed by the lipophilic wax components of the cuticle. This conclusion is supported by the fact that cuticular transpiration can be increased by orders of magnitude upon (i) wax extraction, (ii) increase in temperature or (iii) the action of plasticizers, none of which influenced or only marginally influenced the permeability of inorganic ions penetrating plant cuticles across humidity-sensitive polar pores.     

STUDIES ON PLANT CUTICLE: THE CUTIN COMPONENT OF THE CUTICLES OF LEAVES

Methods are described for the chemical separation from leaf material of the ventral and dorsal surface cuticular membranes and for the determination of cutin in the membranes and leaf tissues.
The cutin contents of the cuticular membranes separated from leaves of laurel, rhododendron, and Euonymus , and of leaf tissues of cauliflower, red beet, banana, tomato, strawberry and blackcurrant are reported. The relationship between the cutin and waxy components of the leaf cuticle is discussed, and earlier work on the development, structure and chemistry of the cuticle is reviewed.     

Giant cuticular pores in Eidothea zoexylocarya (Proteaceae) leaves

Ubiquitous, large diameter pores have not previously been adequately demonstrated to occur in leaf cuticles. Here we show conclusively that such structures occur in Eidothea zoexylocarya, a rainforest tree species of Proteaceae restricted to the Australian Wet Tropics. The pores are abundant, large-diameter apertures (～1 μm), that extend perpendicularly most of the way through the cuticle from the inside. They occur on both sides of the leaf, but are absent from the cuticle associated with stomatal complexes on the abaxial side. No such pores were found in any other species, including the only other species of Eidothea, E. hardeniana from New South Wales, and other species that have previously been purported to possess cuticular pores. To determine whether these pores made the cuticles more leaky to water vapor, we measured astomatous cuticular conductances to water vapor for E. zoexylocarya and seven other Proteaceae species of the Wet Tropics. Cuticular conductance for E. zoexylocarya was relatively low, indicating that the prominent pores do not increase conductance. The function of the pores is currently obscure, but the presence of both pores and an adaxial hypodermis in E. zoexylocarya but not E. hardeniana suggests evolution in response to greater environmental stresses in the tropics.     

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.     

Characterization of aqueous pores in plant cuticles and permeation of ionic solutes

Plant cuticles are lipid membranes with separate diffusion paths for lipophilic non-electrolytes and hydrated ionic compounds. Ions are lipid insoluble and require an aqueous pathway across cuticles. Based on experimental data, the aqueous pathway in cuticles has been characterized. Aqueous pores arise by hydration of permanent dipoles and ionic functional groups. They can be localized using ionic fluorescent dyes, silver nitrate, and mercuric chloride. Aqueous pores preferentially occur in cuticular ledges, at the base of trichomes, and in cuticles over anticlinal walls. Average pore radii ranged from 0.45 to 1.18 nm. Penetration of ions was a first order process as the fraction of the salt remaining on the cuticle surface decreased exponentially with time. Permeability of cuticles to ions depended on humidity and was highest at 100% humidity. Wetting agents increased rate constants by factors of up to 12, which indicates that the pore openings are surrounded by waxes. The pores in cuticular ledges of Helxine soleirolii allowed passage of berberine sulphate, which has a molecular weight of 769 g mol(-1). Increasing the molecular weight of solutes from 100 to 500 g mol(-1) decreased the rate constants of penetration by factors of 7 (Vicia faba) and 13 (Populus canescens), respectively. Half-times of penetration of inorganic salts and organic ions across Populus cuticles and Vicia leaf surfaces varied between 1 and 12 h. This shows that penetration of ionic compounds can be fairly rapid, and ions with molecular weights of up to 800 g mol(-1) can penetrate cuticles that possess aqueous pores.     

Equivalent pore radii of hydrophilic foliar uptake routes in stomatous and astomatous leaf surfaces – further evidence for a stomatal pathway

Foliar uptake pathways for hydrophilic solutes were studied by the analysis of co-uptake of ¹⁵N-labelled urea, NH₄⁺ or NO₃⁻ and ¹³C-labelled sucrose across leaf surfaces of various plant species. Uptake of N (y) and sucrose (x) were strongly correlated. Curvilinear regression revealed significantly positive intercepts with the y-axis indicating the involvement of a sucrose-excluding pathway consisting of small pores with radii <0.5 nm. Depending on plant species, N source, leaf side and aperture of stomata, these small pores accounted for 6–62% of total N uptake. Regression analysis revealed that in stomatous leaf surfaces of Vicia faba L., Coffea arabica L. and Prunus cerasus L., the remaining N uptake occurred via another pathway with an estimated average pore radius (r_P) greater than 20 nm. This is two orders of magnitude greater than previous estimations of cuticular r_P, indicating that this pathway, which was only found in stomatous leaf surfaces, was probably not located in the cuticle but at the surfaces of the stomatal pores. In astomatous leaf surfaces of C. arabica and Populus × canadensis Moench, average r_P was 2.0 and 2.4 nm, respectively, which is four to eight times larger than previous estimations of cuticular r_P. These results indicate that for polar solutes, the size exclusion limits of plant surfaces can be considerably larger than previously estimated. The far-reaching implications of these findings are discussed.     

The setae of parasitic Liphyra brassolis butterfly larvae form a flexible armour for resisting attack by their ant hosts (Lycaenidae: Lepidoptera)

Caterpillars of the lycaenid butterfly, Liphyra brassolis, live inside the nests of arboreal weaver ants, Oecophylla smaragdina, and eat their brood. Observations of mature larvae suggest that they are impervious to relentless ant molestation, yet they lack sclerotized cuticular plates. We document a novel form of integumental defence that imparts protection from ant attack whilst maintaining the flexibility necessary to walk with a hydraulic skeleton. Analysis of the trunk integument and cuticular structures of early and late instars of L. brassolis using light microscopy, scanning electron microscopy, and histology revealed three new setae types (disc, clavate, and lanceolate), as well as three new cuticular structures (pored sockets, cuticular pores, and cuticular domes). The unique cuticle is covered with lanceolate setae, which act as endocuticular struts, and overlapping scale‐like sockets, which form a hard, flexible integument. The imperfect armour of the early‐instar larvae suggests that abundant, putatively secretory pores are likely to be homologous to pore cupola organs (PCOs) found in other lycaenid larvae and thus may exude semiochemicals to allay ant aggression. The importance of these pores presumably wanes as structural (setal) cuticular defenses are reinforced in later instars, when adult ants have been observed attacking caterpillars to no avail. The caterpillar's antennae are unusual and seem to be involved in manipulating ant larvae into the caterpillar's mouth. Behavioural observations indicate that the dexterity of these structures is associated with eating ants (myrmecophagy).     

BINDING SITES FOR INORGANIC IONS AND UREA ON ISOLATED CUTICULAR MEMBRANE SURFACES

Binding sites for calcium and chloride ions, and urea on cuticular membrane surfaces were identified by microautoradiography. There was no localization of binding on either the smooth outer or irregular inner surfaces of the astomatous tomato fruit cuticle, and urea was bound to a lesser degree than inorganic ions. Calcium and chloride binding sites on surfaces of green onion leaf cuticles were closely associated with stomatal pores and above the periclinal cell walls. Binding of calcium was more pronounced than of chloride. These results are discussed in light of possible sites of entry for foliar applied nutrients.     

Protecting against water loss: analysis of the barrier properties of plant cuticles

The cuticle is the major barrier against uncontrolled water loss from leaves, fruits and other primary parts of higher plants. More than 100 mean values for water permeabilities determined with isolated leaf and fruit cuticles from 61 plant species are compiled and discussed in relation to plant organ, natural habitat and morphology. The maximum barrier properties of plant cuticles exceed that of synthetic polymeric films of equal thickness. Cuticular water permeability is not correlated to the thickness of the cuticle or to wax coverage. Relationships between cuticular permeability, wax composition and physical properties of the cuticle are evaluated. Cuticular permeability to water increases on the average by a factor of 2 when leaf surface temperature is raised from 15 degrees C to 35 degrees C. Organic compounds of anthropogenic and biogenic origin may enhance cuticular permeability. The pathway taken by water across the cuticular transport barrier is reviewed. The conclusion from this discussion is that the bulk of water diffuses as single molecules across a lipophilic barrier while a minor fraction travels along polar pores. Open questions concerning the mechanistic understanding of the plant cuticular transport barrier and the role the plant cuticle plays in ensuring the survival and reproductive success of an individual plant are indicated.     

Monitoring and visualising plant cuticles by confocal laser scanning microscopy

The present work shows the visualisation of phenolics and flavonoids of plant cuticles by confocal laser scanning microscopy (CLSM). Selected isolated fruit and leaf cuticles were monitored on the basis of autofluorescent phenolics and flavonoids which, in most cases, permitted us to obtain three-dimensional images of the cuticular membranes. The utility of this technique in investigations of cuticular translocation and diffusion of exogenous applied chemicals and cuticle degradation has also been explored.     

The citrus leaf cuticle in relation to measurement of leaf water potential using thermocouple psychrometers*

Abstract. Cuticular resistance to water vapour diffusion is an important aspect of thermocouple psychrometry and may introduce significant error in the measurement of leaf water potential (Ψ). The effect of the citrus (Citrus mitis Blanco) leaf cuticle on water vapour movement was studied using the times required for vapour pressure equilibration during thermocouple psychrometric measurement of Ψ. Cuticular abrasion with various carborundum powders was used to reduce the diffusive resistance of both the adaxial and abaxial leaf surfaces, and the extent of the disruption to the leaf was investigated with light and electron microscopy. Cuticular abrasion resulted in reduced equilibration times due to decreased cuticular resistance and greater water vapour movement between the leaf and the psychrometer chamber. Equilibration times were reduced from over 5 h in the unabraded control leaves to 1 h with cuticle abrasion. This was associated with the decrease in diffusive resistance with cuticular abrasion from over 55 s cm^?1 to less than 8 s cm^?1 for both the adaxial and abaxial leaf surfaces. Scanning electron micrographs of the abraded leaf tissue revealed considerable disruption of the stomatal ledge and of the guard cells, surface smoothing and displacement of waxes into the stomatal aperture, and damage to veins. Observations with the transmission electron microscope revealed frequent disruption of epidermal cell walls, and damage to both the cytoplasmic and vacuolar membranes.     

Cuticular anatomy of Sphenobaiera huangii (Ginkgoales) from the Lower Jurassic of Hubei, China

Sphenobaiera huangii (Sze) Hsü is typical Early Mesozoic fossil foliage of Ginkgoales in China. It has been recorded from the Upper Triassic to the Lower Jurassic. The cuticular anatomy is investigated based on material from the type locality, Lower Jurassic Hsiangchi Formation, Zigui County, Hubei Province. The specimens are similar to S. huangii, but contain new information about leaf morphology and cuticular anatomy. Lower and upper cuticle is investigated using light and electron microscopy (LM, SEM, and TEM). Many features are described for the first time, including general structures of lower and upper cuticle, stomata, papillae, and cuticular ultrastructure. At the ultrastructural level, two layers have been distinguished in both lower and upper cuticle, including a homogeneous outer layer with granules and a heterogeneous inner layer with fibrils. Based on a literature comparison between S. huangii and other relevant species of Sphenobaiera, S. huangii may represent the best-known taxon in the genus Sphenobaiera in both leaf morphology and cuticular structures. This study provides the first detailed ultrastructural data on the leaf cuticle of Sphenobaiera, one of the oldest foliage taxa of Ginkgoales, and offers further evidence for potential discussion on the taxonomic relationships of S. huangii with other ginkgoalean taxa.     

Guticular features of the Central Australian bloodwoods Eucalyptus, section Corymbosae (Myrtaceae)

The morphological features of the cuticles of the leaves, nectaries and stamen filaments of eleven newly published species of Eucalyptus from Central Australia are described and illustrated. The species form four groupS. Within each group, the gross morphology of the species is sufficiently uniform to present difficulty in identification of specimenS. However, the species differ from each other in both qualitative and quantitative cuticular features. The quantitative features include stomatal size and the frequency spectra of subsidiary cells. The abaxial and adaxial frequency spectra of a given species are usually different from each other, but the spectra of different specimens of the same species are closely similar and differ from those of other species of the same group. The general features of the nectary are described. The species differ in nectary pore size, whether the pores are complanate or sunk, etc. Other microscopic features of the nectary cuticles are also species-specific. Different species are shown to have different patterns of the cuticular ornamentation of the stamen filaments.
The importance of cuticular features in identification and definitions of the term 'subsidiary cell' are discussed. Cuticular ornamentation differs in leaves, nectaries and stamen filaments, yet the nature of the cuticle remains the same. Species with relatively large stomata may have small nectary pores, and vice versa. The genetic control of the cuticular features is different in and independent for each tissue, in the leaf even for the abaxial and adaxial surfaces. The adaptive value of cuticular features, especially of the leaves, and the radiative evolution of the Central Australian bloodwoods are discussed.