Vapour Pressure Deficit Response of Cuticular Conductance in Intact Leaves of Fagus sylvatica L.

The cuticular conductance (g_c) of the astomatous adaxial surfaceof Fagus sylvatica L. leaves was determined under varying vapourpressure deficits at a constant temperature of 20 °C. Cuticularconductance was determined from the weight loss of detachedleaves after both the stomatous abaxial surface and the cutend of the petiole had been sealed using low melting-point paraffinwax. Cuticular conductance was found to decrease as the watervapour pressure was increased in steps. No response was observedwhen vapour pressure deficit was decreased from an initiallyhigh value. It is concluded that these results are consistentwith the hypothesis that cuticular conductance is influencedby the water content of the cuticle and that the apparent hysteresisis likely to be a result of the long time-constant for the processof cuticle rehydration in intact leaves. Key words: Cuticle, cuticular conductance, Fagus sylvatica L., Fagaceae, vapour pressure deficit, VPD     

CO2 and Water Vapor Exchange across Leaf Cuticle (Epidermis) at Various Water Potentials

Cuticular properties affect the gas exchange of leaves, but little is known about how much CO2 and water vapor cross the cuticular barrier or whether low water potentials affect the process. Therefore, we measured the cuticular conductances for CO2 and water vapor in grape (Vitis vinifera L.) leaves having various water potentials. The lower leaf surface was sealed to force all gas exchange through the upper surface, which was stoma-free. In this condition both gases passed through the cuticle, and the CO2 conductance could be directly determined from the internal mole fraction of CO2 near the compensation point, the external mole fraction of CO2, and the CO2 flux. The cuticle allowed small amounts of CO2 and water vapor to pass through, indicating that gas exchange occurs in grape leaves no matter how tightly the stomata are closed. However, the CO2 conductance was only 5.7% of that for water vapor. This discrimination against CO2 markedly affected calculations of the mole fraction of CO2 in leaves as stomatal apertures decreased. When the leaf dehydrated, the cuticular conductance to water vapor decreased, and transpiration and assimilation diminished. This dehydration effect was largest when turgor decreased, which suggests that cuticular gas exchange may have been influenced by epidermal stretching.     

Enzymatic activities involved in incorporation of N-acetyldopamine into insect cuticle during sclerotization

During sclerotization of insect cuticle, N-acetyldopamine (NADA) is enzymatically oxidized before reaction with cuticular proteins. Not all oxidized NADA reacts with cuticular structural materials, a small fraction reacts with water or other available low molecular weight compounds to give soluble products. Various types of cuticle were incubated with excess NADA and the products studied by reversed phase high performance liquid chromatography (RP-HPLC) to obtain information on the enzymatic activities in the cuticle. The occurrence of at least two enzymes competing for NADA and present in different proportions in the various types of cuticle can explain the results. NADA may be incorporated into cuticle via α,β-dehydro-NADA (β-sclerotization) or via quinone methides and o-quinones, and the actual course of sclerotization will depend upon the relative activities of the enzymes involved. The various pathways may all be used simultaneously.     

On the mechanism of formation of arterenone in insect cuticular hydrolyzates

Arterenone (2-amino-3′,4′-dihydroxy acetophenone) is an important hydrolytic product generated from lightly colored sclerotized cuticle that use N-acyldopamine derivatives for crosslinking reactions. It seems to arise from 1,2-dehydro-N-acetyldopamine (dehydro NADA) that has been crosslinked to the cuticular components. However, the mechanism of generation of arterenone, which has two protons on the α-carbon and no proton on the β-carbon atom from dehydro NADA crosslinks that have one proton each on these two side chain carbons, remained elusive and undetermined. To investigate the mechanism of this transformation, we synthesized specifically labeled β-deuterated dehydro NADA and incubated with Sarcophaga bullata cuticle undergoing larval puparial transformation. We also isolated the dimeric products formed during the tyrosinase-mediated oxidation of dehydro NADA. Hydrolysis of both β-deuterated dehydro NADA treated cuticle and β-deuterated dehydro NADA dimer generated arterenone as the major hydrolytic product. Liquid chromatography-mass spectrometric analysis of this arterenone revealed the retention of deuterium from the β-position of dehydro NADA at the α-carbon atom of arterenone. Hydrolysis of β-deuterated dehydro NADA also generated the labeled arterenone under oxidative conditions, but not under anaerobic conditions. These results indicate the unique hydride shift from β-carbon to α-carbon during acid hydrolysis and reveal the mechanism of liberation of arterenone and related compounds from dehydro NADA linked cuticle.     

The expanding alloscutal cuticle in adults of the argasid tick Argas (Persicargas) robertsi (Acari: Ixodoidea)

The extensible cuticle of Argas (P.) robertsi is tuberculate and deeply folded when the tick is unfed but expands rapidly during feeding. During this expansion the epicuticle becomes less convoluted and the underlying endocuticle stretches but there is no significant alteration in thickness. However, the stretched cuticle has taken on a more open structure. Increase in surface area is restricted to a blister-like expansion because of an inextensible lateral suture which separates the dorsal and ventral surfaces. The cuticle is very hydrophobic, contains 9.9% chitin in the female and 8.9% in the male and the cuticular proteins are largely basic. The cuticle has similar properties to that of the ixodid tick Boophilus microplus but differs from it in fine structure. These differences appear to be related to the time sequence of cuticle synthesis and deposition and to the cycle of expansion and contraction which takes place each time A. (P.) robertsi feeds.     

Needle browning and death in the flagged crown of Abies mariesii in the timberline ecotone of the alpine region in central Japan

In the flagged crown, which is asymmetric growth formed by severe stresses during winter in alpine regions, needles of evergreen conifers often became brown and died in early spring, but did not in a cushion-shaped crown. Needle browning and death is thought to occur by increasing transpiration due to a thinner cuticle or mechanical damage to the cuticle by wind-born snow and ice particles. To confirm whether the needle browning and death in the flagged crown of Abies mariesii Mast., in the alpine region of Japan conform with this concept, we assessed mechanical damage of the needle cuticle in a timberline ecotone and evaluated the effect of cuticle thickness on cuticular resistance. Mechanical damage on needle cuticles of A. mariesii was not observed. In the cushion-shaped crown, epicuticular wax covered the cuticle and plugged stomatal antechambers. In the flagged crown, epicuticular wax was mostly absent. Cuticular resistance in the flagged crown was lower than that in the cushion-shaped crown. However, the cuticle in the flagged crown was thicker than that in the cushion-shaped crown. The needle browning and death in the flagged crown of A. mariesii occurred even though needle cuticles were not mechanically damaged. The thicker cuticle of the flagged crown may play a role in other stresses. To estimate desiccation stress in relation to the cuticle, we need to elucidate not only cuticular resistance and cuticle thickness, but also cuticle quality and structure.     

一号冰川地区四种藓类植物的解剖学研究

运用石蜡切片技术和扫描电镜方法,对一号冰川地区生长的4种藓类植物茎、叶的内部结构及叶表皮角质层褶皱、疣和中肋等进行观察,结果表明：红扭口藓(Barbula asperifolia Mitt.)茎横切面呈多棱形;叶背、腹面角质层厚,粗疣不分叉,但顶端朝细胞凹陷处倾斜;叶背面细胞壁凹陷深,象张开的气孔,粗疣也藏在其中,中肋突出明显。丛叶扭藓(Tortella humilis (Hedw.) Jenn.)茎横切面呈椭圆形;叶背、腹面中上部均密被鹿角状粗疣,这些分叉的粗疣,从凹陷的细胞壁处成束突起,顶端向下弯曲成钩状,在叶的下部疣状突起则逐渐减少至无,中肋较宽。异叶提灯藓(Mnium heterophyllum (Hook.)Schwagr.)茎横切面呈五棱形;叶细胞一层,呈不规则多边形,细胞壁凹陷使叶片呈网状;中肋红色。大灰藓(Hypnum plumaeforme Wils.)茎的横切面呈圆形;叶背、腹面均密被疣状突起,且差异不大,粗疣顶部均倒向孔口呈遮盖状;中肋短而弱。     

STRUCTURE OF THE ROYAL ANN CHERRY CUTICLE AND ITS SIGNIFICANCE TO CUTICULAR PENETRATION

The structure of the Royal Ann cherry cuticle (Prunus avium L.) was determined and interpreted in the light of its possible significance to cuticular penetration by a SO₂-calcium bisulfite brine. The morphology of the cuticle was determined by standard histological and histochemical techniques. The surface structure of the cuticle was found to have a smooth to granular sheet or layer of surface wax, which when removed revealed a porous sponge-like surface. The cuticular surface showed intermittent birefringence, which increased as the fruit matured. Ectodesmata were found to occur over anticlinal walls and in guard cells on both sides of the fruit, with more on the side opposite the suture. Both sides had stomata with more occurring on the suture side. Secondary bleaching was found to alter the structure and permeability of the cuticle.     

A hundred-year-old question: is the moss calyptra covered by a cuticle? A case study of Funaria hygrometrica

Background and Aims

The maternal gametophytic calyptra is critical for moss sporophyte development and ultimately sporogenesis. The calyptra has been predicted to protect the sporophyte apex, including the undifferentiated sporogenous region and seta meristem, from desiccation. We investigate the hypothesis that this waterproofing ability is due to a waxy cuticle. The idea that moss calyptrae are covered by a cuticle has been present in the literature for over a century, but, until now, neither the presence nor the absence of a cuticle has been documented for any calyptra.

Methods

The epidermis of the calyptra, leafy gametophyte and sporophyte sporangia of the moss Funaria hygrometrica were examined using scanning and transmission electron microscopy. Thicknesses of individual cuticle layers were quantified and compared statistically. The immunochemistry antibody (LM19) specific for pectins was used to locate cell wall material within the cuticle.

Key Results

A multi-layered cuticle is present on the calyptra of F. hygrometrica, including layers analogous to the cuticular layer, cell wall projections, electron-lucent and electron-dense cuticle proper observed in vascular plants. The calyptra rostrum has a cuticle that is significantly thicker than the other tissues examined and differs by specialized thickenings of the cuticular layer (cuticular pegs) at the regions of the anticlinal cell walls. This is the first documentation of cuticular pegs in a moss.

Conclusions

The calyptra and its associated cuticle represent a unique form of maternal care in embryophytes. This organ has the potential to play a critical role in preventing desiccation of immature sporophytes and thereby may have been essential for the evolution of the moss sporophyte.     

Inhibition of cuticle production in imaginal discs of Plodia interpunctella (cultured in vitro): Effects of colcemid and vinblastine

The relationship of the microtubular system to the production of cuticle was evaluated by culturing wing imaginal discs from Plodia interpunctella in medium that contained 20-hydroxyecdysone and either colcemid or vinblastine. Examination of the treated tissue with both a dissection stereomicroscope and an electron microscope showed that the microtubule inhibitors prevented the formation of cuticle. The inhibitors also prevented the synthesis of chitin, but did not reduce protein synthesis. These results support the hypothesis that the secretion of cuticular components by insect cells requires the integrity of the microtubular system.     

Clearing pigmented insect cuticle to investigate small insects' organs in situ using confocal laser-scanning microscopy (CLSM)

Various microscopic techniques allow investigating structures from submicron to millimeter range, however, this is only possible if the structures of interest are not covered by pigmented cuticle. Here, we present a protocol that combines clearing of pigmented cuticle while preserving both, hard and soft tissues. The resulting transparent cuticle allows confocal laser-scanning microscopy (CLSM), which yields high-resolution images of e.g. the brain, glands, muscles and fine cuticular structures. Using a fluorescent dye, even single labeled neurons can be visualized and resolved up to an imaging depth of 150 μm through the cleared cuticle. Hydrogen-peroxide, which was used to clear the cuticle, does not preclude immunocytochemical techniques, shown by successful labeling of serotonin-immunoreactive neurons (5HT-ir) in the ants' brain. The ‘transparent insect protocol’ presented here is especially suited for small arthropods where dissection of organs is very demanding and difficult to achieve. Furthermore, the insect organs are preserved in situ thus allowing a more precise three-dimensional reconstruction of the structures of interest compared to, e.g., dissected or sectioned tissue.     

High Laccase2 expression is likely involved in the formation of specific cuticular structures during soldier differentiation of the termite Reticulitermes speratus

Termite soldiers are morphologically specialized for colony defense. Analysis of the mechanisms of soldier differentiation is important for understanding the establishment of termite societies. Soldiers differentiate from workers through a presoldier stage and have well-sclerotized and pigmented cuticles. These characteristics are important for nest defense and are likely to be caused by soldier-specific mechanisms of cuticular tanning. The molecular mechanisms leading to cuticular tanning have not been elucidated. Laccase2 (Lac2) plays important roles in this process in insects, and we hypothesized that Lac2 expression may be involved in soldier-specific cuticular tanning. We observed inner and outer head cuticle changes and compared the Lac2 expression patterns among three molts (worker–worker, worker–presoldier and presoldier–soldier) in the termite Reticulitermes speratus. Quantitative analyses of head cuticle colors showed that the color properties changed more conspicuously in presoldier–soldier molts than in the other two molts. Histological observations showed that the exocuticles of soldier heads were substantially thicker than those of worker and presoldier heads, underwent tanning before or just after ecdysis, and were pigmented at earlier time points than other molts. Finally, markedly higher Lac2 expression levels were observed just before and after ecdysis only in the presoldier–soldier molt. These results suggest that specific cuticular formation occurs in the exocuticles during soldier differentiation, and that the high level of Lac2 expression during the presoldier–soldier molt is related to soldier-specific cuticular tanning. We speculate that evolution of the regulatory mechanisms of Lac2 expression were important for the acquisition of soldier-specific cuticles.     

Anatomical and ultrastructural study of the pharyngeal bulb in Protodrilus (Polychaeta,Archiannelida) II. The stomodeal epithelium and its cuticle

The epidermal and stomodeal cuticles of Protodrilus are described then compared. The thin epidermal cuticle, the thickness of which is about the same over all the body, is characterized both by the absence of fibrils in its deepest part and by the extension of epidermal microvilli above the cuticle. The stomodeal cuticle, the thickness of which is as variable as that of the epithelium, presents two layers of fibrils comparable to the collagen fibrils described in the cuticle of other Annelida, as well as a relatively diversified supramicrovillous coating. The anterior cuticular thickening or grating plate, is characterized by the length of the epithelial microvilli, the thickness of the cuticular matrix and the superficial cuticular zone with supramicrovillous denticles supported by an axis of fibrous bundles. In the stomodeal cuticle, the fibrillar material seems to give to the cuticle a best resistance to deformation during the pharyngeal bulb contraction, while an especially elaborated supramicrovillous coating is found in regions most exposed to friction. These features contrast with the relative simplicity of the epidermal cuticle.     

A possible structural model of members of the CPF family of cuticular proteins implicating binding to components other than chitin

The physical properties of cuticle are determined by the structure of its two major components, cuticular proteins (CPs) and chitin, and, also, by their interactions.A common consensus region (extended R&R Consensus) found in the majority of cuticular proteins, the CPRs, binds to chitin. Previous work established that β-pleated sheet predominates in the Consensus region and we proposed that it is responsible for the formation of helicoidal cuticle. Remote sequence similarity between CPRs and a lipocalin, bovine plasma retinol binding protein (RBP), led us to suggest an antiparallel β-sheet half-barrel structure as the basic folding motif of the R&R Consensus. There are several other families of cuticular proteins. One of the best defined is CPF. Its four members in Anopheles gambiae are expressed during the early stages of either pharate pupal or pharate adult development, suggesting that the proteins contribute to the outer regions of the cuticle, the epi- and/or exo-cuticle. These proteins did not bind to chitin in the same assay used successfully for CPRs. Although CPFs are distinct in sequence from CPRs, the same lipocalin could also be used to derive homology models for one A. gambiae and one Drosophila melanogaster CPF. For the CPFs, the basic folding motif predicted is an eight-stranded, antiparallel β-sheet, full-barrel structure. Possible implications of this structure are discussed and docking experiments were carried out with one possible Drosophila ligand, 7(Z),11(Z)-heptacosadiene.     

Gated proton conduction via the coupling factor of photophosphorylation modified by N,N-orthophenyldimaleimide

The membrane bound coupling factor of photophosphorylation is studied after pretreatment of broken chloroplasts with the bifunctional N,N-orthophenyldimaleimide under energization of the thylakoid membrane by mild flashing light. The proton conduction of the membrane is monitored both via the electrochromic absorption changes and via selective pH-indicating dyes. It is found that the coupling factor, after interaction with N,N-orthophenyldimaleimide during the preillumination period, shortcircuits one of the two protons pumped inside after excitation of chloroplasts with one short flash of light. In contrast to the low proton conductivity of the unperturbed thylakoid membrane (relaxation time for a proton gradient > 5s), this extra proton channel leads to a partial relaxation of a proton gradient within a few ms. Although limited to only one proton per electron, this extra proton conducting pathway is not otherwise specific. It operates with protons resulting from both Photosystem I and Photosystem II activity. In addition it operates with protons already present in the internal phase before firing of the exciting light flash. These effects are prevented by the presence of ATP (but not GTP) during the preillumination period. It is suggested that the modified coupling factor is gated open by the light induced electric field across the thylakoid membrane while self closing after passage of one proton per activated coupling factor.     

Kinetic analysis of proton transport by the vanadate-sensitive ATPase from maize root microsomes

Proton transport by the nitrate-insensitive, vanadate-sensitive ATPase in Kl-washed microsomes and reconstituted vesicles from maize (Zea mays L.) roots was followed by changes in acridine orange absorbance in the presence of either KNO₃ or KCl. Data from such studies obeyed a kinetic model in which net proton transport by the pump is the difference between the rate of proton transport by the action of the ATPase and the leak of protons from the vesicles in the direction opposite from the pump. After establishing the steady state proton gradient, the rate of return of transported protons was found to obey first-order kinetics when the activity of the ATPase was completely and rapidly stopped. The rate of return of these protons varied with the quencher used. When the substrate Mg:ATP was depleted by the addition of either EDTA or hexokinase, the rate at which the proton gradient collapsed was faster than when vanadate was used as the quencher. These trends were independent of the anion accompanying the K and the transport assay used.     

Examination of the interior of sand fly (Diptera: Psychodidae) abdomen reveals novel cuticular structures involved in pheromone release: Discovering the manifold

The males of many species of New World Phlebotomines produce volatile terpenoid chemicals, shown in Lutzomyia longipalpis s.l. to be sex/aggregation pheromones. Pheromone is produced by secretory cells which surround a cuticular reservoir which collects the pheromone and passes it through a cuticular duct to the surface of the insect. The pheromone then passes through specialised cuticular structures on the abdominal surface prior to evaporation. The shape and distribution of the specialised structures are highly diverse and differ according to species. In this study we used SEM to examine the interior cuticular pheromone collection and transport structures of 3 members of the Lu. longipalpis s.l. species complex and Migonemyia migonei. We found a new structure which we have called the manifold which appears to be a substantial extension of the interior tergal cuticle connected in-line with the cuticular duct and reservoir. The manifold of the Campo Grande member of the complex is longer and wider than the Jacobina member whereas the manifold of the Sobral member was shorter than both other members of the complex. Overall, the secretory apparatus of the Sobral member was smaller than the other two. The manifold of M. migonei was very different to those found in Lu. longipalpis s.l. and was positioned in a pit-like structure within the tergal cuticle. The secretory reservoir was connected by a short duct to the manifold. Differences in the size and shape of the manifold may be related to the chemical structure of the pheromone and may have taxonomic value. Examination of the interior cuticle by SEM may help to locate the secretory apparatus of vector species where pheromonal activity has been inferred from behavioural studies but the external secretory structures or pheromones have not yet been found.     

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