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.     

Mutants of the bithorax complex and determinative states in the thorax of Drosophila melanogaster.

Homoeotic mutations of the bithorax complex cause segmental transformations. The genes in which these mutations occur are good candidates for genes that are involved in determination. The determination system in imaginal discs must have at least two functions. One is a cell heredity function that is responsible for maintaining the determined state during growth and development. A second is the expression of the determined state (e.g., different imaginal discs have different morphologies). The homoeotic mutations of the bithorax complex could be affecting either of these two functions. I have found that when posterior haltere disc cells, that are transformed by the mutation postbithorax so that they form wing cuticle in situ, regenerate anterior structures, these structures are anterior wing. This is the same result as that seen when wild-type posterior-wing disc cells regenerate anterior structures. On the other hand, when anterior haltere disc cells transformed by the mutation bithorax³, so that they produce wing cuticle in situ, regenerate, they produce posterior haltere structures. This is unlike wild-type anterior-wing disc cells, which regenerate posterior-wing structures. From these results, I conclude that bithorax³ affects the expression of the determined state and postbithorax affects the cell heredity of determination.     

Analysis of expression and chitin‐binding activity of the wing disc cuticle protein BmWCP4 in the silkworm,Bombyx mori

The insect exoskeleton is mainly composed of chitin filaments linked by cuticle proteins. When insects molt, the cuticle of the exoskeleton is renewed by degrading the old chitin and cuticle proteins and synthesizing new ones. In this study, chitin‐binding activity of the wing disc cuticle protein BmWCP4 in Bombyx mori was studied. Sequence analysis showed that the protein had a conservative hydrophilic “R&R” chitin‐binding domain (CBD). Western blotting showed that BmWCP4 was predominately expressed in the wing disc‐containing epidermis during the late wandering and early pupal stages. The immunohistochemistry result showed that the BmWCP4 was mainly present in the wing disc tissues containing wing bud and trachea blast during day 2 of wandering stage. Recombinant full‐length BmWCP4 protein, “R&R” CBD peptide (CBD), non‐CBD peptide (BmWCP4‐CBD^?), four single site‐directed mutated peptides (M₁, M₂, M₃ and M₄) and four‐sites‐mutated peptide (M_F) were generated and purified, respectively, for in vitro chitin‐binding assay. The results indicated that both the full‐length protein and the “R&R” CBD peptide could bind with chitin, whereas the BmWCP4‐CBD^? could not bind with chitin. The single residue mutants M₁, M₂, M₃ and M₄ reduced but did not completely abolish the chitin‐binding activity, while four‐sites‐mutated protein M_F completely lost the chitin‐binding activity. These data indicate that BmWCP4 protein plays a critical role by binding to the chitin filaments in the wing during larva‐to‐pupa transformation. The conserved aromatic amino acids are critical in the interaction between chitin and the cuticle protein.     

Butterfly Wings Are Three-Dimensional: Pupal Cuticle Focal Spots and Their Associated Structures in Junonia Butterflies

Butterfly wing color patterns often contain eyespots, which are developmentally determined at the late larval and early pupal stages by organizing activities of focal cells that can later form eyespot foci. In the pupal stage, the focal position of a future eyespot is often marked by a focal spot, one of the pupal cuticle spots, on the pupal surface. Here, we examined the possible relationships of the pupal focal spots with the underneath pupal wing tissues and with the adult wing eyespots using Junonia butterflies. Large pupal focal spots were found in two species with large adult eyespots, J. orithya and J. almana, whereas only small pupal focal spots were found in a species with small adult eyespots, J. hedonia. The size of five pupal focal spots on a single wing was correlated with the size of the corresponding adult eyespots in J. orithya. A pupal focal spot was a three-dimensional bulge of cuticle surface, and the underside of the major pupal focal spot exhibited a hollowed cuticle in a pupal case. Cross sections of a pupal wing revealed that the cuticle layer shows a curvature at a focal spot, and a positional correlation was observed between the cuticle layer thickness and its corresponding cell layer thickness. Adult major eyespots of J. orithya and J. almana exhibited surface elevations and depressions that approximately correspond to the coloration within an eyespot. Our results suggest that a pupal focal spot is produced by the organizing activity of focal cells underneath the focal spot. Probably because the focal cell layer immediately underneath a focal spot is thicker than that of its surrounding areas, eyespots of adult butterfly wings are three-dimensionally constructed. The color-height relationship in adult eyespots might have an implication in the developmental signaling for determining the eyespot color patterns.     

The contribution of surface waxes to pre-penetration growth of an entomopathogenic fungus on host cuticle

A locust wing bioassay, that allowed an entomopathogenic fungus to be removed from host cuticle before penetration, was used to investigate the role of surface lipids and waxes in pre-penetration growth of the specific locust pathogen Metarhizium anisopliae var. acridum. SEM and atomic force electron microscopy showed the impact of the fungus on the architecture of the cuticle surface. Although the fungus can germinate on authentic alkanes as the sole carbon source, only low levels of germination occurred on crude, non-polar wing cuticle extracts, containing a mixture of long-chain n-alkanes and other waxes (identified in particular by gas chromatography and mass spectroscopy). The fungus removed a large proportion of non-polar and polar components during pre-penetration growth on the wing. Polar crude extracts from Schistocerca gregaria hindwings, which contained fatty acids, fatty acid esters, glucose, amino acids and peptides, were strong promoters of germination, and poor germination was observed on a locust hindwing from which the extract had been taken. Thus simple polar compounds, also present on the surface, may be required to stimulate germination before the fungus can make use of a complex mixture of non-polar lipids.     

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.     

Changes in the mechanical properties of the extensible cuticle of Rhodnius through the fifth larval instar

The ultimate tensile strength (σ_UT) and the modulus of elasticity (E) of Rhodnius extensible cuticle are σ_UT = 2.20 × 10⁷ Nm^?2, E = 2.43 × 10⁸ Nm^?2 (unplasticised); σ_UT = 1.43 × 10⁷ Nm^?2, E = 9.45 × 10⁶ Nm^?2 (plasticised with 5HT) and σ_UT = 9.05 × 10⁶ Nm, E = 2.46 × 10⁶ Nm^?2 (plasticised in pH 5 buffer).The mechanical properties of cuticle from insects which have deposited additional layers of cuticle after they have been fed differ from those of cuticle from unfed insects. This is possibly due to the different composition of the additional cuticle: it is suggested that the post-feeding cuticle is providing protection and a template for the next instars cuticle.The maximum strain of extensible cuticle from starved insects is related to the amount of matrix protein present.     

Curly Encodes Dual Oxidase,Which Acts with Heme Peroxidase Curly Su to Shape the Adult Drosophila Wing

Curly, described almost a century ago, is one of the most frequently used markers in Drosophila genetics. Despite this the molecular identity of Curly has remained obscure. Here we show that Curly mutations arise in the gene dual oxidase (duox), which encodes a reactive oxygen species (ROS) generating NADPH oxidase. Using Curly mutations and RNA interference (RNAi), we demonstrate that Duox autonomously stabilizes the wing on the last day of pupal development. Through genetic suppression studies, we identify a novel heme peroxidase, Curly Su (Cysu) that acts with Duox to form the wing. Ultrastructural analysis suggests that Duox and Cysu are required in the wing to bond and adhere the dorsal and ventral cuticle surfaces during its maturation. In Drosophila, Duox is best known for its role in the killing of pathogens by generating bactericidal ROS. Our work adds to a growing number of studies suggesting that Duox’s primary function is more structural, helping to form extracellular and cuticle structures in conjunction with peroxidases.     

Endolithic Microbial Colonization of Limestone in a High-altitude Arid Environment

The morphology of endolithic colonization in a limestone escarpment and surrounding rocky debris (termed float) at a high-altitude arid site in central Tibet was documented using scanning electron microscopy. Putative lichenized structures and extensive coccoid bacterial colonization were observed. Absolute and relative abundance of rRNA gene signatures using real-time quantitative polymerase chain reaction and phylogenetic analysis of environmental phylotypes were used to characterize community structure across all domains. Escarpment endoliths were dominated by eukaryotic phylotypes suggestive of lichenised associations (a Trebouxia lichen phycobiont and Leptodontidium lichen mycobiont), whereas float endoliths were dominated by bacterial phylotypes, including the cyanobacterium Chroococcidiopsis plus several unidentified beta proteobacteria and crenarchaea. Among a range of abiotic variables tested, ultraviolet (UV) transmittance by rock substrates was the factor best able to explain differences in community structure, with eukaryotic lichen phylotypes more abundant under conditions of greater UV-exposure compared to prokaryotes. Variously pigmented float rocks did not support significantly different communities. Estimates of in situ carbon fixation based upon ¹⁴C radio-labelled bicarbonate uptake indicated endolithic productivity of approximately 2.01 g C/m²/year^?1, intermediate between estimates for Antarctic and temperate communities.     

Role of beta-alanine in cuticular tanning,sclerotization, and temperature regulation in Drosophila melanogaster

Injection of 20 nl of 1.0 M beta-alanine, about the minimal amount needed to produce wild-type tanned phenomenocopies from newly eclosed mutant black Drosophila melanogaster, increases stiffness and puncture-resistance of the wing cuticle. Increasing the concentration of beta-alanine to 2.0 M increases puncture-resistance further. Injection of 1.0 M of the beta-alanine analogue beta-aminoisobutyric acid, does not induce tanning or puncture-resistance, nor does injection of 1.0 M dopamine. However, injection of 1.0 M beta-alanine and 1.0 M dopamine increases puncture-resistance more than an injection of 1.0 M beta-alanine, though not more than an injection of 2.0 M beta-alanine alone. Within 10 min after injection of [3-³H]beta-alanine into newly eclosed normal flies, ³H becomes 8.7 times more concentrated in the cuticle than in an equal area of underlying epidermis. ³H is excluded from the epidermis or cuticle of ebony strains. Ebony strains show a deficiency of cuticular electron-absorbing material, and the cuticular lamellae show a tendency to separate from each other. Compaction of the chitinous lamellae is induced in alkali-detanned pupal sheaths by exposure to nascent quinones of N-acetyldopamine or N-beta-alanyldopamine. Glucosamine, but not N-acetylglucosamine, reacts with such quinones in tanning reactions. Under an infrared beam, black cuticular pigmentation induces more rapid heating of haemocoel fluids than does tan pigmentation. A theory of pigmentation and sclerotization relative to environmental adaptation is presented.     

Genetic Architecture of Abdominal Pigmentation in Drosophila melanogaster

Pigmentation varies within and between species and is often adaptive. The amount of pigmentation on the abdomen of Drosophila melanogaster is a relatively simple morphological trait, which serves as a model for mapping the genetic basis of variation in complex phenotypes. Here, we assessed natural variation in female abdominal pigmentation in 175 sequenced inbred lines of the Drosophila melanogaster Genetic Reference Panel, derived from the Raleigh, NC population. We quantified the proportion of melanization on the two most posterior abdominal segments, tergites 5 and 6 (T5, T6). We found significant genetic variation in the proportion of melanization and high broad-sense heritabilities for each tergite. Genome-wide association studies identified over 150 DNA variants associated with the proportion of melanization on T5 (84), T6 (34), and the difference between T5 and T6 (35). Several of the top variants associated with variation in pigmentation are in tan, ebony, and bric-a-brac1, genes known to affect D. melanogaster abdominal pigmentation. Mutational analyses and targeted RNAi-knockdown showed that 17 out of 28 (61%) novel candidate genes implicated by the genome-wide association study affected abdominal pigmentation. Several of these genes are involved in developmental and regulatory pathways, chitin production, cuticle structure, and vesicle formation and transport. These findings show that genetic variation may affect multiple steps in pathways involved in tergite development and melanization. Variation in these novel candidates may serve as targets for adaptive evolution and sexual selection in D. melanogaster.     

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.     

Wing morphometrics as a possible tool for the diagnosis of the Ceratitis fasciventris,C. anonae,C. rosa complex (Diptera,Tephritidae)

Previous attempts to resolve the Ceratitis FAR complex (Ceratitis fasciventris, Ceratitis anonae, Ceratitis rosa, Diptera, Tephritidae) showed contrasting results and revealed the occurrence of five microsatellite genotypic clusters (A, F1, F2, R1, R2). In this paper we explore the potential of wing morphometrics for the diagnosis of FAR morphospecies and genotypic clusters. We considered a set of 227 specimens previously morphologically identified and genotyped at 16 microsatellite loci. Seventeen wing landmarks and 6 wing band areas were used for morphometric analyses. Permutational multivariate analysis of variance detected significant differences both across morphospecies and genotypic clusters (for both males and females). Unconstrained and constrained ordinations did not properly resolve groups corresponding to morphospecies or genotypic clusters. However, posterior group membership probabilities (PGMPs) of the Discriminant Analysis of Principal Components (DAPC) allowed the consistent identification of a relevant proportion of specimens (but with performances differing across morphospecies and genotypic clusters). This study suggests that wing morphometrics and PGMPs might represent a possible tool for the diagnosis of species within the FAR complex. Here, we propose a tentative diagnostic method and provide a first reference library of morphometric measures that might be used for the identification of additional and unidentified FAR specimens.     

Albino (al) is a tetrahydrobiopterin (BH4)-deficient mutant of the silkworm Bombyx mori

Albino (al) is a lethal mutant of Bombyx mori that exhibits a colourless cuticle after the first ecdysis and dies without feeding on mulberry. Previous studies have indicated that sclerotisation was insufficient because of defective phenylalanine and tyrosine metabolism in albino larvae. However, the genetic mechanism underlying the albino phenotype has not been determined. Dopamine plays a central role in insect cuticle colouration and sclerotisation. The pathway for dopamine biosynthesis from phenylalanine involves phenylalanine hydroxylase (PAH; EC 1.14.16.1) and tyrosine hydroxylase (TH; EC 1.14.16.2). Tetrahydrobiopterin (BH4) is an essential cofactor of aromatic amino acid hydroxylases, including PAH and TH. Thus, BH4 is indispensable for cuticle colouration and sclerotisation. Here we report on identifying mutations in the gene that encodes for the Bombyx homolog of 6-pyruvoyl-tetrahydropterin synthase (PTS) which is involved in the biosynthesis of BH4, in 2 strains with different al alleles. In strain a60 (al), a transposable element was inserted in exon 2 of BmPTS. In strain a61 (al²), an 11-bp deletion was identified in the exon 2 region of BmPTS. After oral administration of BH4 to the al² larvae, the survival rate was effectively increased and the larval integument was pigmented. These results indicated that BmPTS was responsible for the albino mutants of B. mori. We conclude that (i) a mutation in BmPTS leads to an insufficient supply of BH4 and results in defective dopamine biosynthesis and (ii) lack of dopamine results in cuticle colouration and sclerotisation failure. Lemon (lem) is a BH4-deficient mutant. It has been reported that de novo synthesis of zygotic BH4 was indispensable for viability of the embryo in eggs laid by lem (lem/lem^l) females. We found that lem/lem, al²/al² larvae produced by lem (lem/lem) females were viable during the first instar stage, suggesting that al²/al² embryo could synthesis BH4 by using maternally transmitted BmPTS.     

Cuticular adaptations in two parasitic copepods in relation to their modes of life

The structure, histochemistry, and possible functional properties of the cuticle in two parasitic copepods Pennella elegans Gnanamuthu and Caligus savala Gnanamuthu have been studied: the former is partially embedded in the host while the latter is an ectoparasite capable of free swimming.In Pennella elegans the cuticle of the embedded anterior region of the body is soft, colourless, and lacks an outer epicuticle while that of the posterior exposed part is pigmented and hard. Conspicuous in the cuticle of the ventral region of the head are pore canals which, though not chitinized, are functional even in the intermoult stage: these canals may be involved in the transport of nutrient materials from the host. The horns, which serve to fix the parasite firmly in the host tissues, are covered by cuticle in which the epicuticle and outer layers of the procuticle are hardened by formation of disulphide linkages. The cuticle of the neck region is not hardened and the procuticle in this region shows transverse regions of dense and light zones probably related to the coiling of the neck during penetration. The epicuticle is two layered in the cuticle of the exposed posterior region, the inner epicuticle and outer region of the procuticle being partially hardened by phenolic tanning so confer rigidity and resistance. The cuticle of the plumes is soft and devoid of an outer lipid epicuticle and so possibly adapted for a respiratory function.In Caligus savala, the epicuticle is two layered, and the procuticle has pigmented, calcified, and uncalcified layers. The cuticle is hardened by phenolic tanning as well as by calcification thus recalling the cuticular organization of decapod crustaceans.     

Positional information in imaginal discs transformed by homoeotic mutations

Summary Mutations of the bithorax complex result in segmental transformations in the thorax and abdomen ofDrosophila. The haltere discs from larvae homozygous forbx ³ orpbx are transformed so that the discs contain cells that will produce wing cuticle as well as cells that produce haltere cuticle. The pattern regulation behavior of these discs has been examined. The fate maps of the two discs were established, and then the regulative behavior of a number of fragments from both types of mutant discs was established by culturing the fragments in vivo prior to metamorphosis. The most important conclusion from this work is that the cells producing, haltere cuticle and wing cuticle within the same disc share the same positional information and that they communicate during pattern regulation.     

The diffusional and osmotic water permeability of the hindgut cuticle in larval Sarcophaga bullata

The diffusional water permeability (P_D) and the pressure filtration coefficient (L_P) of isolated larval hindgut cuticle of the fleshfly, Sarcophaga bullata, were measured using tracer techniques coupled with a simple mathematical model system based on equations of non-equilibrium thermodynamics. Data obtained from the model system were matched to experimental tracer data by means of a mathematical optimization scheme. The following parameter values were obtained: P_D for tritiated water = 1.02 × 10^?6 cm-sec^?1, and L_P = 9.18 × 10^?11 cm³-dyn^?1-sec^?1. These results are now being used to determine reflection coefficients (σ's) and solute mobilities (ω's) for the cuticle system in an attempt to gain an understanding of the mechanisms controlling solute and water movements across the hindgut wall.     

Modification of the aggregation state of the multifunctional enzyme complex catalyzing the first steps in pyrimidine biosynthesis in the course of development of Drosophila melanogaster

Mutations at the bithoraxoid (bxd) and postbithorax (pbx) loci cause a transformation of posterior haltere to posterior wing. It has previously been shown that pbx and $\text{pbx}\text{Ubx}{}^{101}$ cause this transformation by affecting the maintenance (or cell heredity function) of determination so that the transformed cells are indistinguishable from normal wing cells, and have no “memory” of having been part of a haltere disk (Adler, 1978a). I report here that Tp(3) $\text{bxd}{}^{100}\text{Ubx}{}^{101}$ and bxd¹, pbx, e^w both cause the transformation of posterior haltere to posterior wing in the same way as pbx. On the other hand, bxd¹, $\text{bxd}{}^1\text{Ubx}{}^{101}$, bxd^51j, $\text{bxd}{}^{\mathrm{<mtext>51</mtext><mtext>j</mtext>}}\text{Ubx}{}^{101}$, and $\text{bxd}{}^{\mathrm{<mtext>51</mtext><mtext>j</mtext>}}\text{red pbx}$ cause this same transformation of posterior haltere to posterior wing by interfering with the expression of the determined state so that the developmental information of posterior haltere is “misread” as posterior wing. The transformed cells in these disks retain the memory of having been part of a haltere disk; that is, these posterior cells that would secrete wing cuticle during metamorphosis regenerate anterior haltere structures. Thus it appears clear that it is possible to uncouple the expression and cell heredity functions of determination in the haltere disk of Drosophila.     

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.