On the structure of the cuticle of Mecoptera

The chitin architecture of Mecoptera cuticle is of two kinds: helicoidal and helicoidal preferred with the preferred layers being cross-plied. Comparison of both systems of terminology currently in use to differentiate the subtypes of cuticle indicates that neither provides much information about the arrangement of chitin within cuticle and that both give information only about the extent of hardening in cuticle. All of the specimens of solid cuticle broken in tension exhibited a similar fracture behaviour in which the exocuticle failed in a brittle manner and the endocuticle failed plastically. The mode of endocuticular failure is dependent upon the arrangement of chitin microfibres within this region. The ultrastructural patterns of chitin microfibres determined by electron microscopy cannot be related to current notions about the phylogenetic interrelationships among Mecoptera and the usefulness of chitin fibre arrangement as a phylogenetic tool remains an open question.     

SCARABAEID BEETLE EXOCUTICLE AS AN OPTICAL ANALOGUE OF CHOLESTERIC LIQUID CRYSTALS

1. A review is given of the optical and architectural analogies between cholesteric liquid crystals and certain insect cuticles (Coleoptera: Scarabaeidae). Earlier observations on the optical properties (reflexion of circularly polarized light and high form optical rotation) are confirmed and extended. Both cholesteric liquid crystals and lamellate cuticle have helicoidal structure (Fig. i). Even though their chemistry and physical states are very different, we are justified in making the analogy, since their optical properties depend primarily on the pitch of their helicoidal architecture. 2. The unusual optical properties were located for the first time in the outer 5 to 20 μ of the exocuticle. This layer is transparent and has regular spacings in the range required for interference colours according to Bragg's law. Among Scarabaeid beetles which show interference colours, we distinguish two types of outer exocuticle. (i) Optically active cuticles which reflect circularly polarized interference colours; show high angles of form optical rotation in transmitted light; and anomalous form birefringence perpendicular to the cuticle surface (reversible by deproteinization). (2) Optically inactive cuticles which show none of the above properties and in which the form birefringence is parallel to the cuticle surface. In the electron microscope the ultrastructure of these two types of outer exocuticle is clearly different. 3. All of the optically active species reflect left hand circularly polarized light, irrespective of the wavelength of the reflected colour. They therefore appear dark when viewed through a right hand circular analyser. The sense of reflected circularly polarized light does not reverse at higher wavelengths as recorded by previous workers. (A simple treatment is given for combinations of various wavelengths with retardation plates of varying values, as used in circular analysers.) We confirm earlier reports that the sense of reflected circularly polarized light is of the opposite sense to the transmitted light. 4. Using monochromatic light we have measured the anomalous dispersion with wavelength of the magnitude of optical rotation for various optically active cuticles. The dispersion curves change from negative values at lower wavelengths to positive values at higher wavelengths, and cross the zero optical rotation axis at a wavelength (AQ) corresponding to the interference colour of each sample. There is reasonable agreement between A₀ and the interference colour calculated from ultrastructural evidence and by comparison with interference filters of known wavelength. A dispersion curve measured for a combined sample of two cuticles with different dispersion curves showed that the resultant is an algebraic summation of the two component curves. 5. We present the first experimental verification of existing mathematical treatments of anomalous form optical rotatory dispersion curves. Although these treatments were derived for cholesteric liquid crystals, they give a reasonable fit to our measured curves for cuticle. We have confirmed from our cuticle dispersion curves that a second zero value for optical rotation occurs at a wavelength higher than A₀, as predicted by the theory of Chandrasekhar and Rao (1968). This has not yet been observed in any cholesteric liquid crystal system. 6. Our evidence shows that in optically active cuticle, interference colour is determined by helicoid pitch. In Lomaptera interference coloration follows the bilateral symmetry of the insect. Hence helicoidal pitch is controlled in a bilaterally symmetrical manner. However, the sense of helicoid rotation is the same all over the beetle and is therefore bilaterally asymmetrical. This supports the view that helicoid pitch is under the local control of the epidermal cells which secrete the cuticle, whereas its sense of rotation may be determined by an extracellular self-assembly process. In view of the self-assembling properties of cholesteric liquid crystals, it is tempting to suggest that helicoidal cuticle could be formed by the stabilization of a liquid crystal. 7. We discuss in detail the differences between optically active and inactive cuticles. The constructive interference colours arising from both types are then briefly compared with other multiple layer reflecting systems in other animals. 8. A detailed comparison is made between the optics of cuticle and cholesteric liquid crystals. The optical analogy provides a two-way contact between cuticle biophysicists and liquid crystal physical chemists.     

Organisation of wing cuticle in Locusta migratoria linnaeus,Tropidacris cristata linnaeus and Romalea microptera beauvais (Orthoptera : Acrididae)

The composite fibrous architectures of the wing cuticles of Locusta migratoria, Tropidacris (= Eutropidacris) cristata and Romalea microptera (Orthoptera : Acrididae) have been established. The wing cuticle in all the 3 species consists of: (i) an exocuticle, which is either pigmented or birefringent, and which under an electron microscope shows constantly helicoidal architecture of chitin microfibrils; (ii) endocuticle, which shows alternately birefringent and isotropic layers when sectioned transversely across the wing veins; these layers show helicoidal and unidirectional architecture, respectively of chitin microfibrils under the electron microscope. In transverse section, the chitin microfibrils appear as clear rods (2.8 nm in diameter) in a darkly stained matrix. However, in the hinge called the “claval furrow”, these microfibrils are considerably larger, being 25 nm in diameter. This presumably gives sufficient hardness to the claval hinge, which is the most vulnerable area for wear and tear during flight. The pore canals follow the parabolic pattern of microfibrils in the helicoidal layer, but remain straight in the unidirectional layers. The thickness of wing cuticle increases up to about 10–12 days, the time at which the acridids most probably attain the optimum flight ability. It is suggested that changes in the wing cuticle are related to increased wing beat frequency and speed of flight with age, and may help in resisting the simultaneous increase in the bending and twisting forces on the wing.     

Form optical activity in crustacean cuticle

Some decalcified crustacean cuticle reflects left and transmits right circularly polarized light. The form optical rotatory dispersion is negative at lower and positive at higher wavelengths than that giving the interference colour for the system. The helicoidal structure deduced from the optics is supported by parabolic patterning in electron micrographs of oblique sections. The cuticle helicoid is anti-clockwise so that the right circularly polarized light transmitted through it rotates in the same sense as the helicoid from which it is produced.     

A structural model of the chitin-binding domain of cuticle proteins

The nature of the interaction of insect cuticular proteins and chitin is unknown even though about half of the cuticular proteins sequenced thus far share a consensus region that has been predicted to be the site of chitin binding. We previously predicted the preponderance of beta-pleated sheet in the consensus region and proposed its responsibility for the formation of helicoidal cuticle (Iconomidou et al., Insect Biochem. Mol. Biol. 29 (1999) 285). Consequently, we have also verified experimentally the abundance of antiparallel beta-pleated sheet in the structure of cuticle proteins (Iconomidou et al., Insect Biochem. Mol. Biol. 31 (2001) 877). In this work, based on sequence and secondary structure similarity of cuticle proteins, and especially that of the consensus motif, to that of bovine plasma retinol binding protein (RBP), we propose by homology modelling an antiparallel beta-sheet half-barrel structure as the basic folding motif of cuticle proteins. This folding motif may provide the template for elucidating cuticle protein-chitin interactions in detail and reveal the precise geometrical formation of cuticle's helicoidal architecture. This predicted motif is another example where nature utilizes an almost flat protein surface covered by aromatic side chains to interact with the polysaccharide chains of chitin.     

"Soft"-cuticle protein secondary structure as revealed by FT-Raman, ATR FT-IR and CD spectroscopy.

The nature of the interaction of insect cuticular proteins and chitin is unknown even though about half of the cuticular proteins sequenced thus far share a consensus region that has been predicted to be the site of chitin binding. We previously predicted the preponderance of a beta-pleated sheet in the consensus region and proposed its responsibility for the formation of helicoidal cuticle (Iconomidou et al., Insect Biochem. Mol. Biol. 29 (1999) 285). In this study, we examined experimentally the secondary structure of intact and guanidine hydrochloride extracted cuticle and the cuticular protein extract. The studied cuticle came from the larval dorsal abdomen of the lepidopteran Hyalophora cecropia, a classical example of "soft" cuticle. Analysis with FT-Raman, ATR FT-IR and CD spectroscopy indicates that antiparallel beta-pleated sheet is the predominant molecular conformation of "soft-cuticle" proteins both in situ in the cuticle and following extraction. It seems that this conformation dictates the modes of chitin-protein interaction in cuticle, in agreement with earlier proposals (Atkins, J. Biosci. 8 (1985) 375).     

Fine structure of the cuticle of the desert scorpion, Hadrurus arizonensis.

The structure of the sclerite and intersegmental cuticle of the opithosoma of the desert scorpion, Hadrurus arizonensis, has been examined by transmission electron microscopy. The sclerite cuticle contains a four-layered epicuticle, a hyaline exocuticle, an inner exocuticle and an endocuticle. The outer part of the hyaline exocuticle and the whole of the inner exocuticle are constructed of helicoidally arranged planes of microfibrils. Within the endocuticle, the overall architecture is not helicoidal as previously assumed, but consists of bundles of microfibrils oriented horizontally and vertically. Microbibrils of the inner exocuticle and the endocutile are seen as simple unstained rods, but those of the hyaline exocuticle are electron dense rods with an unstained central core. The intersegmental cuticle contains a four-layered epicuticle and a procuticle. In detail, its fine structure differs in most respects from that of the sclerite cuticle. Electron microscopy reveals that hyaline exocuticle, previously assumed to be continuous from sclerite to intersegmental membrane, is absent in the latter.     

A proposed solution to a fine-structural puzzle: The organization of gill cuticle in a crayfish (Panulirus)

Crayfish gill cuticle is approximately 2 μm thick and comprises an epicuticle and an endocuticle, which is subdivided into outer and inner layers. Sections demonstrate indistinct lamellae in the outer endocuticle and vertically striated lamellae in the inner endocuticle. Microfibrils cannot be seen in sections. Difficulties in interpretation of the fibrous architecture of the cuticle from thin sections have been overcome by examining tilted series of micrographs of sections and also by making freeze-fracture replicas of the cuticle, which reveal the microfibrils clearly. A model for the endocuticle based on a helicoidal configuration of microfibrillar laminae is proposed and the vertically striated structures seen in sections of the outer layer are accounted for by including regular rows of particles oriented perpendicular to microfibrils. The model is compared with cuticles and coverings reported from other invertebrates.     

Chitin helicoids accompany protein helicoids in the periostracum of a whelk, Buccinum

The periostracum of the marine gastropod Buccinum has a helicoidal arrangement of its principal constituent which is a fibrous protein (Hunt and Oates, 1978). Chitin, chemically and physically identified, is present at a concentration of about 6% of the dry weight and can be seen in dispersates of whole periostracum as long fibrils and ribbons between 3 and 14 nm diameter. Deproteinization with hot alkali removes all protein leaving a chitinous 'ghost' of the periostracum. Dispersates, examined negatively stained, show only chitin fibrils and ribbons while sectioned material demonstrates a tenuous, part orthogonal, part helicoidal, architecture based on the chitin residue. The relative roles of the protein and polysaccharide components is speculated upon and comparisons with arthropod cuticle drawn.     

Spatial and temporal regulations in helicoidal extracellular matrices: comparison between plant and animal systems.

This paper proposes an overview of the last few years' investigations regarding the helicoid formation in extracellular matrices (ECMs). Despite the architectural polymorphism displayed among the layered ECM throughout the living kingdom, helicoidal structures are often described in ECMs and appear as an optimal mechanical device. Helicoids correspond to complex two-phases composites, formation and regulation of which are still a source of debate. Taking the time-event into consideration, it is clear that helicoid in ECMs are regulable structures. On the other hand, analogies with helicoidal formations in cholesteric liquid crystals strongly support the hypothesis of involvement of self-assembly processes. Therefore the balance between self-assemblies and cell regulation is questioned. By gathering animal and plant data on the topic and by analysing the characteristics of these helicoids in ECMs, it is clear that cells have the necessary machinery to interfere with the self-assembly processes in response to physiological or mechanical mechanisms. They are able to modify the physicochemical conditions outside the plasma membrane, therefore acting on the pattern of self-assembly. Several mechanisms are proposed to explain sudden variations occurring in the helicoidal formation with time.     

A single spiral artefact in Arthropod cuticle

Spirals are often seen in sections transverse to the axes of bumped structures in arthropod cuticle. (Sections through arthropod cornea or exocones yield excellent examples.) As arthropod cuticle has a helicoidal architecture (Bouligand, 1965), it might be expected that the spirals are a simple consequence of that structure. According to a symmetry argument, the spirals thus predicted must be double spirals. In contrast, the observed spirals are usually single. We propose that the single spirals result from an interaction between the microtome knife and the cuticle architecture. The direction of knife travel defines an orientation within the cuticle, subverting the symmetry arguments that require double spirals. Bouligand (1972) presented a model for the interaction of the knife with the cuticle. However, we offer arguments and observations which show that Bouligand's model is incorrect. We argue from detailed observations of the single spiral that it is indeed a knifing artifact and that its explanation probably lies within a certain class of models. Two related models based on relative movements of cuticle components are examined via computer techniques.     

Is beta-pleated sheet the molecular conformation which dictates formation of helicoidal cuticle?

Over 100 sequences for cuticular proteins are now available, but there have been no formal analyses of how these sequences might contribute to the helicoidal architecture of cuticle or to the interaction of these proteins with chitin. A secondary structure prediction scheme (Hamodrakas, S.J., 1988. A protein secondary structure prediction scheme for the IBM PC and compatibles. CABIOS 4, 473-477) that combines six different algorithms predicting alpha-helix, beta-strands and beta-turn/loops/coil has been used to predict the secondary structure of chorion proteins and experimental confirmation has established its utility (Hamodrakas, S.J., 1992. Molecular architecture of helicoidal proteinaceous eggshells. In: Case, S.T. (Ed.), Results and Problems in Cell Differentiation, Vol. 19, Berlin-Heidelberg, Springer Verlag, pp. 116-186 and references therein). We have used this same scheme with eight cuticular protein sequences associated with hard cuticles and nineteen from soft cuticles. Secondary structure predictions were restricted to a conserved 68 amino acid region that begins with a preponderance of hydrophilic residues and ends with a 33 amino acid consensus region, first identified by Rebers and Riddiford (Rebers, J.F., Riddiford, L.M., 1988. Structure and expression of a Manduca sexta larval cuticle gene homologous to Drosophila cuticle genes. J. Mol. Biol. 203, 411-423). Both classes of sequences showed a preponderance of beta-pleated sheet, with four distinct strands in the proteins from 'hard' cuticles and three from 'soft'. In both cases, tyrosine and phenylalanine were found on one face within a sheet, an optimal location for interaction with chitin. We propose that this beta-sheet dictates formation of helicoidal cuticle.     

Two separate zones of helicoidally orientated microfibrils are present in the walls ofNitella internodes during growth

Summary The dynamic changes in microfibril architecture in the internode cell walls of the giant unicellular algaNitella translucens were studied during cell expansion. Thin section electron microscopy in conjunction with mild matrix polysaccharide extraction techniques revealed three distinct architectural zones in the walls of fully grown cells. These zones were related to distinct phases of growth by monitoring changes in cell wall architecture of internodes during active cell expansion. The initial microfibril deposition before the onset of active cell growth is helicoidal. A helicoid is a structurally complex but ordered arrangement of microfibrils that has been detected increasingly often in higher plant cell walls. During active cell elongation microfibrils are deposited transversely to the direction of cell elongation as shown in earlier studies by birefringence measurements in the polarizing microscope. The gradual decline in cell elongation corresponds with a final helicoidal deposition which continues after cell expansion ceases entirely.The continual presence of the initial helicoidal zone in the outer wall region during the whole growth process suggests that these microfibrils do not experience strain reorientation and are continually reorganized, or maintained, in a well ordered helicoidal arrangement.     

A water-soluble protein specific to the adult cuticle in Tenebrio: Its use as a marker of a new programme expressed by epidermal cells

The water-soluble proteins of abdominal cuticle of larvae, pupae and adults subjected to electrophoresis, revealed a specific pattern for each stage. An antibody against an adult specific 18 kdaltons protein was produced. Electrophoresis analysis of SDS slab gel and Western-blots revealed that the 18 kdaltons adult protein is not present in the water-soluble fraction from haemolymph or fat body of pupae which secreted pre-ecdysial adult cuticle. Immuno-histochemical methods showed that the cross-reaction of the immune serum was limited to the apical part of the adult epidermis and to the cuticle lamellae which are not stabilized. Therefore, the 18 kdaltons protein is specific for the adult cuticle and originates in the epidermis.     

cuticleDB: a relational database of Arthropod cuticular proteins

Background  

The insect exoskeleton or cuticle is a bi-partite composite of proteins and chitin that provides protective, skeletal and structural functions. Little information is available about the molecular structure of this important complex that exhibits a helicoidal architecture. Scores of sequences of cuticular proteins have been obtained from direct protein sequencing, from cDNAs, and from genomic analyses.     

Control of cuticle formation by wing imaginal discs in vitro.

Wing discs from late final-instar Ephestia larvae form only pupal cuticle when immediately implanted into pupae which subsequently undergo metamorphosis. However, either pupal or adult structures are made in vitro depending on (1) the ecdysterone dose and/or (2) disc cell proliferation. Continuous culture in ecdysterone (0.5–5.0 μg/ml) results in the appearance of transparent cuticle. On the basis of several criteria, this untanned cuticle is postulated to be scaleless adult cuticle. Discs pulsed with 0.5 μg/ml ecdysterone for 48–120 hr, or with 5.0 μg/ml for 24 hr, formed tanned cuticle. Lower doses of ecdysterone (i.e., 0.5 μg/ml for 24 hr or continuous exposure to 0.05 μg/ml) trigger adult scale formation. Enhancement of [³H]thymidine incorporation by these latter doses suggests the occurrence of disc cell divisions and polyploidization. The choice between pupal and adult pathways by wing discs of this age can be controlled exclusively by ecdysterone; juvenile hormone need not be involved in vitro.     

The cuticle of Caenorhabditis elegans. II. Stage-specific changes in ultrastructure and protein composition during postembryonic development

The cuticle of the free-living nematode Caenorhabditis elegans is a proteinaceous extracellular structure that is replaced at each of four postembryonic molts by the underlying hypodermis. The cuticles of the adult and three juvenile stages (L1, Dauer larva, L4) have been compared ultrastructurally and biochemically. Each cuticle has an annulated surface and comprises two main layers, an inner basal layer and an outer cortical layer. The adult cuticle has an additional clear layer which separates the basal and cortical layers and is traversed by regularly arranged columns of electron-dense material. The fine structure of the cortical layer is similar in cuticles from different stages while that of the basal layer is stage specific. Purified cuticles were obtained by sonication and treatment with sodium dodecyl sulfate (SDS) and their component proteins solubilized with a sulfhydryl reducing agent. The degree of cuticle solubility is stage specific and the insoluble structures for each cuticle were localized by electron microscopy. Analysis of ³⁵S-labeled soluble cuticle proteins by SDS-polyacrylamide gel electrophoresis yields unique banding patterns for each stage. Most proteins are of high molecular weight (100–200 K) and are restricted to particular stages. Sixteen of the nineteen major proteins characterized are specifically degraded by bacterial collagenase. The results indicate that the different molts are not reiterative, but require the integration of both unique and shared gene functions. The potential use of stage-specific cuticle differences to identify and characterize regulatory genes controlling cuticle-type switching during development is discussed.     

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.     

Cuticular sclerotization in larval and adult locusts, Schistocerca gregaria

The sclerotization of both larval and adult cuticle from the desert locust, Schistocerca gregaria, has been studied by measuring the incorporation of radioactive dopamine and N-acetyldopamine into the cuticle. The results are compared with the degree of sclerotization of the cuticle and the amount of sclerotizing enzyme present. The various parts of the cuticle differ considerably with respect to the degree of sclerotization: in adult locusts the mandibles and the dorsal mesothoracic cuticle contain about twenty times as much cross-linking material per mg cuticle than is present in the abdominal tergites and sclerites.The degree of sclerotization in the various types of cuticle is apparently not determined by the amounts of sclerotizing enzyme present, and the rate at which radioactive dopamine or N-acetyldopamine is incorporated into the cuticle appears also to be unrelated to the amount of enzyme.The degree of sclerotization of the various parts of the cuticle from fifth instar larvae corresponds with the amounts of labelled dopamine which are incorporated during the first day after ecdysis, whereas there is no correlation between sclerotization and the amounts of labelled dopamine which are incorporated in older larvae. The degree of sclerotization of adult cuticle after 1 day corresponds to the incorporation of dopamine during the first day. When older animals are compared only little correlation is observed. The relative rates of sclerotization in the various parts of the cuticle must therefore change as the adult insect grows older.The changes in the incorporation pattern during the development of the locust are discussed in relation to the physiological control of the sclerotization process.     

Ultrastructure and cytochemistry of the integument of Modiolicola gracilis,parasitic copepod in mussel gills (Mytilus galloprovincialis and Mytilus edulis)

Of mussels taken from the Ebro Delta River (E. Spain), 3% have a nonmodified copepod, Modiolicola gracilis, in the gill tissues. The cuticle of different segments of the body has an epicuticle with two layers, which show external microvilli-like projections. Weakly positive reactivity to the PTA technique has been detected in the external region. The procuticle has the helicoidal architecture of the chitinous tegument in arthropods, whereas the cuticle shows discontinuities in the regions of ducts in tegumental glands. The integument is comprised of three types of cells. Epidermal cells are flat with numerous mitochondria. Muscle cells show well-developed mitochondria with several longitudinally distributed cristae. A third and secretory cell shows a well-developed rough endoplasmic reticulum and Golgi complex in the basal zone. Its apical portion is full of secretory granules. Through the cuticle, these integumental glands open directly to the cuticular surface via a short duct coated by epicuticle. The composition and specializations of this complex cuticular architecture differ markedly from those shown by an endoparasitic copepod detected in the digestive gland of the mussel. It does not appear that the specializations detected in the cuticle of M. gracilis lead to any histopathological alteration in host tissues. © 1994 Wiley-Liss, Inc.