Cuticle specific antigens from filarial parasite Setaria digitata

A fairly clean antigenic cuticle was isolated from the S. digitata by dissection. Crossed immunoelectrophoresis of cuticular antigens against rabbit antiserum to cuticular antigens gave 30 anodic and 5 cathodic precipitin arcs. The cuticle antiserum cross reacted with muscle, uterus and pseudocoelomic fluid. When the antiserum was absorbed individually with these cross reacting somatic preparations, analysis against cuticle antigens gave only a limited number of precipitin arcs. But the results are clear enough to indicate the presence of cuticle specific antigens. As the cuticle of the parasite is in contact with the host system, an antigenic preparation from it may prove a useful tool for the detection of filariasis.     

Disentangling the assembly mechanisms of ant cuticular bacterial communities of two Amazonian ant species sharing a common arboreal nest

Bacteria living on the cuticle of ants are generally studied for their protective role against pathogens, especially in the clade of fungus‐growing ants. However, little is known regarding the diversity of cuticular bacteria in other ant host species, as well as the mechanisms leading to the composition of these communities. Here, we used 16S rRNA gene amplicon sequencing to study the influence of host species, species interactions and the pool of bacteria from the environment on the assembly of cuticular bacterial communities on two phylogenetically distant Amazonian ant species that frequently nest together inside the roots system of epiphytic plants, Camponotus femoratus and Crematogaster levior. Our results show that (a) the vast majority of the bacterial community on the cuticle is shared with the nest, suggesting that most bacteria on the cuticle are acquired through environmental acquisition, (b) 5.2% and 2.0% of operational taxonomic units (OTUs) are respectively specific to Ca. femoratus and Cr. levior, probably representing their respective core cuticular bacterial community, and (c) 3.6% of OTUs are shared between the two ant species. Additionally, mass spectrometry metabolomics analysis of metabolites on the cuticle of ants, which excludes the detection of cuticular hydrocarbons produced by the host, were conducted to evaluate correlations among bacterial OTUs and m/z ion mass. Although some positive and negative correlations are found, the cuticular chemical composition was weakly species‐specific, suggesting that cuticular bacterial communities are prominently environmentally acquired. Overall, our results suggest the environment is the dominant source of bacteria found on the cuticle of ants.     

Development of the crystalliferous cuticle of Chamaecyparis lawsoniana (A. Murr.) Pari. (Gupressaceae)

A developmental study of the cuticle has shown that it consists of a homogeneous cuticle proper apposed on the wall and a heterogeneous cuticular layer generated by intussusception of cutin into the wall. At an early stage, the adcrusted cuticle proper is underlain by a ruthenium red-positive layer in which the cuticular layer originates. The origin of the anticlinal flange is referable to an electron-dense, ruthenium red-positive ridge which arises above the anticlinal wall and which also becomes cutinized. At leaf maturity, the inner surface of the cuticular layer, including that of the flange, forms interdigitating protuberances with the cell wall.
Development of the cuticle coincides with deposition of crystals of calcium oxalate in the epidermal cell wall. Initiation of large, early-formed crystals is associated with electron-opaque membranous structures formed close and parallel to the plasmalemma in the young cell wall. Crystals undergo periclinal and anticlinal growth and subsequently become engulfed within the cuticle by development of the cuticular layer. Cutin/polysaccharide interaction during development and the significance of crystal deposition are discussed.     

Mass spectrometrical analysis of cuticular proteins from the wing of Hebemoia glaucippe (Linnaeus, 1758) (Lepidoptera: Pieridae)

Although several insect cuticular genes and proteins are annotated and an arthropod cuticular database is available, mass spectrometrical data on cuticular proteins and their post-translational modifications are limited. Wings from Hebemoia glaucippe were analyzed by scanning electron microscopy or homogenized, proteins were extracted and run on 2DE. In-gel digestion was carried out by using trypsin, chymotrypsin and Asp-N and subsequently the resulting peptides and post-translational modifications were identified by ion trap tandem mass spectrometry (nano-LC-ESI-MS/MS; HCT). A complex wing skeleton and the cuticle of H. glaucippe were demonstrated. Cuticle protein 18.6, isoform A, pupal cuticle protein, cuticular protein CPR59A and two putative proteins, putative cuticular protein B2DBJ and putative cuticle protein CPG31 with two expression forms were identified. Two phosphorylation sites on the same peptide, T213 and S214, were identified on putative cuticle protein CPG31, quinone formation was observed at Y76 on cuticular protein CPR59A probably indicating the presence of post-translational modifications. The results may be relevant for the interpretation of mechanoelastic and physical properties of these proteins. Along with the extraordinary architecture the proteinaceous matrix is probably representing or allowing the unusual aerodynamic function of the butterfly wing. Moreover, the results may be important for mechanisms of insecticide and drought resistance.     

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.     

Studies on the Ultrastructure and Histochemistry of Plant Cuticles: The Cuticular Membrane of Agave americana L. in situ

The outer epidermal wall of Agave americana leaves was examinedin order to gain more information about the location and chemicalconstitution of the structural components. In middle aged leavesthe wall comprised six layers which were designated epicuticularwax, cuticle proper, exterior and interior cuticular layer,exterior and interior cellin wall. A lamellated structure, consistingof a series of electron translucent lamellae of uniform thicknessalternating with opaque ones of variable thickness, was observedin the thin cuticle proper on the outside of the cuticular membrane,even without heavy metal treatment. The cuticular layers underneathformed the bulk of the cuticular membrane and they also hadtwo components, an amorphous matrix permeated by a reticulumof fibrillae. Cutin, detected with osmium and with iodine/iodine-sulphuricacid–silver proteinate, was a major component of the opaquelamellae of the cuticle proper and the matrix of the cuticularlayer. Carbohydrates were absent from the cuticle proper butwere detected specifically in the fibrillae of the cuticularlayer and in the cellin wall. Pectic material seemed to be presenton both sides of the junction between cuticular membrane andcellin wall, but no discrete zone corresponding to light microscopicalobservations was detected in the electron microscope. Althoughthe lucent lamellae of the cuticle proper were tentatively ascribedto wax there was no structural or ultrahistochemical evidencefor the wax component of the cuticular layer. The various ultrahistochemicalreactions are discussed in relation to the known chemical compositionof the membrane. Agave americana L., epidermis wall, cuticular membrane, cuticle proper, cuticular layer, ultrahistochemistry, wax     

Moulting of insect tracheae captured by light and electron-microscopy in the metathoracic femur of a third instar locust Locusta migratoria

The insect tracheal system is an air-filled branching network of internal tubing that functions to exchange respiratory gases between the tissues and the environment. The light and electron-micrographs presented in this study show tracheae in the process of moulting, captured from the metathoracic hopping femur of a juvenile third instar locust (Locusta migratoria). The images provide evidence for the detachment of the cuticular intima from the tracheal epithelial cells, the presence of moulting fluid between the new and old cuticle layers, and the withdrawal of the shed cuticular lining through larger upstream regions of the tracheal system during moulting. The micrographs also reveal that the cuticular intima of the fine terminal branches of the tracheal system is cast at ecdysis. Therefore, the hypothesis that tracheoles retain their cuticle lining at each moult may not apply to all insect species or developmental stages.     

Distribution of serpins in the tissues of the tobacco hornworm (Manduca sexta) larvae. Existence of new serpins possibly encoded by a gene distinct from the serpin-1 gene

Polyclonal antibodies were raised against the isolated hemolymph serine proteinase inhibitors (serpins) of Manduca sexta larvae. Two of these antibodies, MsH49a and MsH49b, displayed characteristic differences in labelling patterns of hemocytes, fat body, integumental epidermis and cuticle on immunoblots, and in light- and electronmicroscopic sections. The serpin composition of the latter three tissue homogenates was determined by native immunoblots and inhibitor binding assays. The results were compared to the hemolymph samples containing all the known inhibitors encoded by the well-characterized serpin-1 gene. The enzyme specificity of the MsH49b-labelled cuticular serpin was similar to serpin-1J, although its electrophoretic mobility on native PAGE was not identical with any of the known proteinase inhibitors encoded by the serpin-1 gene. Based on these data, we suggest that the cuticle and hemolymph may contain novel serpin(s) encoded by a gene other than the serpin-1 gene. Since the serpin-1J proved to be involved in the activation pathway of the prophenoloxidase system in the hemolymph, the in vivo function of cuticular MsH49b serpin was investigated by prophenoloxidase tests in native cuticular homogenates. Our results demonstrated that the cuticular serpin(s) that are labelled by the MsH49b antibody may play a determinant role in the regulation of the prophenoloxidase system of the integumental cuticle.     

Periclinal penetration of potassium permanganate into mature cuticular membranes ofAgave andClivia leaves: new implications for plant cuticle development

Staining cuticular membranes ofAgave americana andClivia miniata en bloc with potassium permanganate results in a strong contrast in the interior cuticular layer while the exterior part remains unstained. This is not caused by a selective chemical reaction with the interior part but by the unidirectional penetration of the reagent from the interior side, the outside being protected by the cuticle proper. In transverse cryosections of the cuticular membrane, permanganate penetrates nearly as easily into the exterior cuticular layer as into the interior one giving the same contrast. However, compared with the periclinal penetration into the cuticle proper this penetration is accelerated five-to tenfold by the polysaccharide network within the cuticular layer which serves as a distribution-channel system. Periclinal penetration into the cuticle proper occurs independently in each cutin penetration unit included between two obvious lucent lamellae and further divided into subunits.     

The Prevalence of Pores and Canals in Leaf Cuticular Membranes

Ubiquitous, visibly discrete, natural cuticular pores and transcuticularcanals were found in the dewaxed leaf (and one herbaceous stem)cuticular membranes of 27 out of 32 taxa among 14 families.Clear evidence for their existence is provided by light photomicrographs.Both adaxial and abaxial leaf surfaces were investigated usingthin transections and chemically isolated cuticular membranes,in conjunction with ordinary staining techniques and light microscopymethods. No correlations were found between cuticle thicknessesand either the frequency of pore or the pore and canal diameters. Leaf cuticles, cuticle morphology, cuticular pores, transcuticular canals, cuticular flanges     

Fine structure of the spermatheca of the mealworm beetle (Tenebrio molitor L.)

The spermatheca of the female mealworm beetle is an inflorescence of branching cuticular ducts which is connected to the bursa copulatrix via a cuticular neck surrounded by a muscular coat. The infolded bursal cuticle consists of a distinct outer epicuticle, inner epicuticle, procuticle, and a subcuticular zone; the latter is rich in mucopolysaccharides. The cuticle of the neck lacks a distinct procuticle. The cuticle of the spermatheca itself is mostly inner epicuticle with two thin underlying lamellae of procuticle. The cells of the bursa are loosely coupled to the procuticle, whereas cuticular projections bind the epithelia of the "neck" and the spermatheca proper to the underlying epithelia. The apical plasma membranes of the spermathecal epithelium are sinuous and much infolded; we believe that this epithelium controls the micro-environment within the cuticular ducts.     

Visualization of Caenorhabditis elegans cuticular structures using the lipophilic vital dye DiI

The cuticle of C. elegans is a highly resistant structure that surrounds the exterior of the animal(1-4). The cuticle not only protects the animal from the environment, but also determines body shape and plays a role in motility(4-6). Several layers secreted by epidermal cells comprise the cuticle, including an outermost lipid layer(7). Circumferential ridges in the cuticle called annuli pattern the length of the animal and are present during all stages of development(8). Alae are longitudinal ridges that are present during specific stages of development, including L1, dauer, and adult stages(2,9). Mutations in genes that affect cuticular collagen organization can alter cuticular structure and animal body morphology(5,6,10,11). While cuticular imaging using compound microscopy with DIC optics is possible, current methods that highlight cuticular structures include fluorescent transgene expression(12), antibody staining(13), and electron microscopy(1). Labeled wheat germ agglutinin (WGA) has also been used to visualize cuticular glycoproteins, but is limited in resolving finer cuticular structures(14). Staining of cuticular surface using fluorescent dye has been observed, but never characterized in detail(15). We present a method to visualize cuticle in live C. elegans using the red fluorescent lipophilic dye DiI (1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate), which is commonly used in C. elegans to visualize environmentally exposed neurons. This optimized protocol for DiI staining is a simple, robust method for high resolution fluorescent visualization of annuli, alae, vulva, male tail, and hermaphrodite tail spike in C. elegans.     

Cuticle protein in adult Locusta migratoria

The total protein, chitin and soluble protein content of the abdominal cuticle of male adult locusts was analysed. After an initial period of increase, cuticular protein and chitin content levelled off with the onset of sexual maturation. After ecdysis, the amount of soluble cuticular protein increased unitil maturation. Specific cuticular protein electrophoretic bands decreased in staining intensity with development and were presumed to become bound within the cuticle. Incorporation of ³H-leucine into cuticular proteins was highest into pharate adult cuticle, then decreased after ecdysis to a constant level after maturation. Following sexual maturation when the total cuticular protein and soluble protein content remained constant incroporation of ³H-leucine continued indicating the dynamic nature of the cuticle.     

The fine structure of campaniform sensilla on the halteres of Drosophila melanogaster

The campaniform sensilla on halteres of Drosophila were studied by electron microscopy in order to establish the relationships of functional elements in the sensory system. The surface of the sensillum consists of an oval cuticular cap membrane which may contain resilin, the rubberlike protein. A border of denser cuticle rings the cap membrane, and extending down around the neural process is a third type of cuticle filled with a fourth light fibrous type. The four cuticular components form a system for displacement of the neural process. The neural process is differentiated into a terminal fan-shaped structure projecting from a bulbous dilatation which tapers to a neck region ending proximally with two basal bodies. The neural process is packed with microtubules. Surrounding the dendrite is an inner enveloping cell, attached to the basal body region by septate desmosomes and by desmosomes to which microtubules of the enveloping cell are applied. An outer enveloping cell surrounds the inner one. The tip of the neural process is covered with a dense secretion which is tightly bound to the cap membrane. The dense secretion is surrounded by an extracellular fluid which might be compressed hydraulically by the cuticular system. The stimulus of cuticular distortion could thus be transmitted to the neural process which may be displaced between its fixed ends.     

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.     

The cuticle of the nematode Caenorhabditis elegans: A complex collagen structure

The cuticle of the nematode Caenorhabditis elegans forms the barrier between the animal and its environment. In addition to being a protective layer, it is an exoskeleton which is important in maintaining and defining the normal shape of the nematode. The cuticle is an extracellular matrix consisting predominantly of small collagen-like proteins that are extensively crosslinked. Although it also contains other protein and non-protein compounds that undoubtedly play a significant part in its function, the specific role of collagen in cuticle structure and morphology is considered here. The C. elegans genome contains between 50 and 150 collagen genes, most of which are believed to encode cuticular collagens. Mutations that result in cuticular defects and grossly altered body form have been identified in more than 40 genes. Six of these genes are now known to encode cuticular collagens, a finding that confirms the importance of this group of structural proteins to the formation of the cuticle and the role of the cuticle as an exoskeleton in shaping the worm. It is likely that many more of the genes identified by mutations giving altered body form, will be collagen genes. Mutations in the cuticular collagen genes provide a powerful tool for investigating the mechanisms by which this group of proteins interact to form the nematode cuticle.     

Coordinated development in the fly foot: Sequential cuticle secretion

Development of the adult fly foot falls into clearly defined phases of cell division, growth, cuticle secretion and cell death. The pulvillus is composed dorsally of two giant cells and ventrally of thousands of minute tenent cells; the former produce the dorsal footpad cuticle and the latter the thousands of tenent hairs. Cell divisions are still occurring in future tenent cells when increase in size of the cells and in polyteny of the chromosomes is already occurring in the two dorsal cells. Also cell death occurs considerably earlier in the tenent cells, yet the sequential secretion of some six cuticular layers takes place at comparable times in dorsal and ventral cuticles. The cuticular layers formed are, in their order of secretion: ecdysial membrane, cuticulin of the epicuticle, dense exocuticle, homogeneous exocuticle, an intermediate layer, wax of the epicuticle, and an extensive mass of endocuticle. The ecdysial membrane seems to perform an important mechanical role in maintaining the shape of the delicate cytoplasmic projections of the tenent cells, before and during cuticle secretion, and in establishing the cuticular pattern of ridges in the dorsal cuticle. Comparisons are made with trichogen cell cuticle development and with tracheal cuticle. Tracheal, trichogen and dorsal footpad cuticle patterns are compared. Details of giant cell activity provide a working basis for studies of nuclear-cytoplasmic interactions, and the whole system raises many unsolved problems in the general field of cell differentiation and pattern formation.     

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.     

Proteomic analysis of cast cuticles from Anopheles gambiae by tandem mass spectrometry

Identification of authenticated cuticular proteins has been based on isolation and sequencing of individual proteins extracted from cleaned cuticles. These data facilitated classification of sequences from conceptual translation of cDNA or genomic sequences. The question arises whether such putative cuticular proteins actually are incorporated into the cuticle. This paper describes the profiling of cuticular proteins from Anopheles gambiae starting with cuticle cleaned by the insect itself in the course of molting. Proteins extracted from cast larval head capsules and cast pupal cuticles were fractionated by 1D SDS gel electrophoresis. Large gel slices were reduced, carbamidomethylated and digested with trypsin. The pellet remaining after SDS extraction was also treated with trypsin. The resulting peptides were separated on a C18 column and then analyzed by tandem mass spectrometry. Two-hundred-ninety-five peptides from putative cuticular proteins were identified; these corresponded to a minimum of 69 and a maximum of 119 different proteins. Each is reported as an authentic Anopheles cuticular protein for the first time. In addition to members of two known cuticular protein families, members of additional families likely to be structural components of the cuticle were identified. Furthermore, other peptides were identified that can be attributed to molting fluid, muscle and sclerotizing agents.     

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.