Stage- and tissue-specific expression of the genes encoding calliphorin,the major larval serum protein of Calliphora vicina

Summary The stage- and tissue-specific biosynthesis of calliphorin was analysed during the development of the blowfly, Calliphora vicina. Western blot analyses show that the protein is not present in eggs, whereas it can be detected in fat body, brain, imaginai disk, salivary gland and epidermis throughout all postembryonic stages, including the adult one. By Northern analysis a unique 2.6 kb mol.wt. mRNA coding for calliphorin is identified exclusively in the fat body tissue of larvae, pupae and adults. Hybridization experiments of in vivo labelled poly(A)⁺ RNA with filter-bound calliphorin genes indicate that the genes are transcribed until pupariation. However, the translation of the calliphorin mRNA stops at the end of the feeding stage, as shown by [³⁵S]-methionine incorporation.     

Cuticle differentiation in the embryo of the amphipod crustacean Parhyale hawaiensis

The arthropod cuticle is a multilayered extracellular matrix produced by the epidermis during embryogenesis and moulting. Molecularly and histologically, cuticle differentiation has been extensively investigated in the embryo of the insect Drosophila melanogaster. To learn about the evolution of cuticle differentiation, we have studied the histology of cuticle differentiation during embryogenesis of the amphipod crustacean Parhyale hawaiensis, which had a common ancestor with Drosophila about 510 million years ago. The establishment of the layers of the Parhyale juvenile cuticle is largely governed by mechanisms observed in Drosophila, e.g. as in Drosophila, the synthesis and arrangement of chitin in the inner procuticle are separate processes. A major difference between the cuticle of Parhyale and Drosophila concerns the restructuring of the Parhyale dorsal epicuticle after deposition. In contrast to the uniform cuticle of the Drosophila larva, the Parhyale cuticle is subdivided into two regions, the ventral and the dorsal cuticles. Remarkably, the boundary between the ventral and dorsal cuticles is sharp suggesting active extracellular regionalisation. The present analysis of Parhyale cuticle differentiation should allow the characterisation of the cuticle-producing and -organising factors of Parhyale (by comparison with the branchiopod crustacean Daphnia pulex) in order to contribute to the elucidation of fundamental questions relevant to extracellular matrix organisation and differentiation. This work was supported by the German Research Foundation (DFG, grant number MO 1714/1-1).     

The role of cuticle and epidermal cell wall in resistance of rapeseed and mustard to Rhizoctonia solani

A study was conducted to determine whether the cuticles in two genera of the family Cruciferae are effective barriers to infection by Rhizoctonia solani, and whether differences in cuticle and epidermal cell wall thickness and morphology of epicuticular wax exist between resistant and susceptible cultivars. As Canola/rapeseed (Brassica napus) and mustard (Sinapis alba) plants develop from 1 to 3 weeks of age, they become increasingly resistant to R. solani AG2-1 seedling root rot. Seven-day-old seedlings of S. alba cultivars are invariably more resistant than B. napus cultivars. Brassica napus cultivars do not show an obvious cuticle layer at 1 week but at 3 weeks the presence of a cuticle is seen through autofluorescence with a concomitant increase in resistance to R. solani. Removal of the cuticle from 3-week-old hypocotyls by chloroform treatment results in a decrease in cuticular autofluorescence and a significant increase in disease severity in both resistant and susceptible cultivars. Three-week-old plants of S. alba have a much lower percent disease rating and a significantly (p=0.05) thicker cuticle layer than similar-age plants of B. napus. The results suggest that the cuticle plays an important role in the resistance of S. alba and older plants of B. napus to infection by R. solani.     

Effects of exogenous N-acetylhexosaminidase on the structure and mineralization of the post-ecdysial exoskeleton of the blue crab, Callinectes sapidus

A cuticular glycosidase with characteristics of N-acetyl-β- -hexosaminidase (HexNAcase) was identified in post-ecdysial crab cuticle. Its appearance coincided with changes in cuticular glycoproteins and the onset of mineralization. To test if HexNAcase might be the causative agent in the alteration of the glycans and initiation of calcification, newly molted crab cuticle was treated with exogenous HexNAcase. Treating cuticular extracts from crabs at 0 h post-ecdysis with exogenous HexNAcase mimicked those changes observed in vivo. Specifically, the enzyme decreased the concanavalin A affinity of an 83-kDa glycoprotein that binds to calcite crystals in vitro. Treating pieces of 0 h post-ecdysial cuticle with HexNAcase rendered them capable of nucleating calcite in vitro (similar to 5 h post-ecdysial cuticle), while untreated, 0 h controls remained uncalcified. The data imply a role of the cuticular HexNAcase-like enzyme in the initiation of calcite nucleation in the newly formed exoskeleton.     

Morphological Alterations of Metarhizium anisopliae During Penetration of Boophilus microplus Ticks

Chronological histological alterations of Metarhizium anisopliae during interaction with the cattle tick Boophilus microplus were investigated by light and scanning electron microscopy. M. anisopliae invades B. microplus by a process which involves adhesion of conidia to the cuticle, conidia germination, formation of appressoria and penetration through the cuticle. Twenty-four hours post-infection conidia are adhered and germination starts on the surface of the tick. At this time, the conidia differentiate to form appressoria exerting mechanical pressure and trigger hydrolytic enzyme secretion leading to penetration. Massive penetration is observed 72 h post-inoculation, and after 96 h, the hyphae start to emerge from the cuticle surface to form conidia. The intense invasion of adjacent tissues by hyphae was observed by light microscopy, confirming the ability of M. anisopliae to produce significant morphological alterations in the cuticle, and its infective effectiveness in B. microplus.     

Cuticular and non-cuticular substrate influence on expression of cuticle-degrading enzymes from conidia of an entomopathogenic fungus,Nomuraea rileyi

Larval cuticle fromTrichoplusia ni, Helicoverpa (=Heliothis)zea, andHeliothis virescens and a cellulose substrate were used to quantify release of proteolytic, chitinolytic, and lipolytic enzymes by germinating conidia of the entomopathogenic fungus,Nomuraea rileyi. There was no significant difference in conidial viability incubated withT. ni, H. zea or cellulose substrates. Conidial viability onH. virescens cuticle, however, was significantly lower (ca. 19–25%) than the other three substrates. The presence of cuticle substrates, especially cuticle ofT. ni, stimulated germination. The nature of the substrate influenced both the time and quantity of the enzymes expressed. Specific proteases (aminopeptidase, chymoelastase, trypsin) generally were expressed earlier and/or in greater quantities on cuticular than on the cellulose substrate. Although both chitinolytic enzymes (endochitinase, N-acetylglucosaminidase) were detected on all three cuticular substrates, their activity was substantially lower than that of the proteolytic enzymes. Lipase activity was only minimally present. Early concurrent release of both proteases and chitinases suggested that both may be important in the penetration of the larval integument by germinating conidia ofN. rileyi. Expression of proteases and chitinases, especially aminopeptidase and endochitinase was probably a specific response to cuticle, because little or no activity was expressed on the non-host, cellulose substrate.This article reports the results of research only. Mention of a proprietary product in this paper does not constitute a recommendation for use by the US Department of Agriculture.     

Apical secretion and association of the Drosophila yellow gene product with developing larval cuticle structures during embryogenesis.

Summary The yellow (y) gene of Drosophila melanogaster is required for the pigmentation of larval and adult cuticle structures. The deduced y protein sequence includes two putative N-linked glycosylation sites and a putative signal peptide, suggesting that it might be a secreted molecule. Consistent with the characteristics of a secreted protein, our in vitro translation studies using RNA synthesised from the y cDNA demonstrate that the nascent y polypeptide is a preprotein that cotranslationally translocates into the endoplasmic reticulum (ER) membrane and becomes glycosylated. The N-terminal peptide is cleaved from the preprotein between the two alanine residues at positions 21 and 22, to release the final product into the lumen of the ER. Antibodies raised against the y polypeptide detect the protein starting at 13 h post-fertilization in epidermal cells and in the cuticle structures secreted by them that later become pigmented; in addition, yellow protein is detected in the cuticle structures associated with Keilin's organs. The embryonic -galactosidase staining pattern of a transgene, bearing a construct in which expression of the lacZ gene is driven by the y promoter, is also described and is similar to that of the y protein. Our results indicate that the y gene product is an apically secreted protein which becomes an immobilised structural component of the pigmented cuticle.     

Local motion and conformational changes in the cuticle of Clivia miniata Regel

The temperature dependence of the local diffusion of fluorescent molecular probes of various polarities (alkane, long-chain fatty acid, short-chain alcohol and fatty acid), all labelled with 7-nitrobenz-2-oxa-1,3-diazol-4-yl in the cuticle of Clivia miniata Regel was studied by the technique of fluorescence recovery after photobleaching. The technique yields the coefficient of diffusion, D, in the plane of the cuticle over distances of some 10 m and the fraction, R, of mobile reporter molecules. The inner (more hydrophilic) and the outer (more hydrophobic) faces of the cuticle were studied separately by appropriate incubation. The value of D was found to depend sensitively on the polarity of the probe, the temperature and the position within the cuticle (outer hydrophobic or inner hydrophilic side). Depending on the type of probe, D increased (in the case of the alkane) or decreased (in the case of the alcohol) after removal of the (monomeric) waxes. The electron-spin-resonance (ESR) spectra of incorporated spin-labelled fatty-acid probes measured in the intact cuticle contained a major component similar to the spectrum recorded from the polymerized matrix from which waxes had been extracted, and a second component similar to the spectrum from the monomeric waxes. At low temperatures, the ESR spectra from labels at two different chain positions corresponded to chain motion which was slow on the ESR timescale. At high temperatures, the spectral component from the monomeric waxes indicated chain motions in the motional narrowing regime which were of an essentially isotropic nature.No evidence was found for a liquid-crystalline lipid phase such as found for the polar lipids in cell membranes, nor was there evidence for a sharp, thermotropic, lipid-phase transition either in the cuticle or in the waxes. Experiments with oriented samples did not demonstrate the presence of large domains with a uniform orientation of the lipid chains relative to the cuticular layers. The diffusion measurements and spin-label studies provide evidence for conformational changes of the cuticle extending over the whole temperature range studied (10° C to 70° C). These conformational changes are attributed to phase-separation processes within the cuticle. The phase separation in extracted waxes extended over a similar broad temperature range. This indicates that the transitions in the cuticle are largely determined by these components. At higher temperatures, however, the chain mobility in the regions of monomeric wax was considerably greater than that in the polymerized matrix. The experimental results strongly indicate that all three layers of the Clivia cuticle exhibit a multilamellar structure of alternatingly stacked, highly hydrophobic layers of welldefined thickness (5±0.5 nm) and more disordered layers of variable (4 to 15 nm) thickness. The lamellae are wellordered and extend over the whole leaf in the cuticle proper but are split-up into small domains in the inner and the external cuticular layer. Furthermore, changes of the molecular transport properties caused by the influence of ozone exerted during the growth of the plant were studied. We found that the diffusion coefficient increased both in the outer and the inner layer of the cuticle. A particularly large increase, by about a factor of three, was found for alkane diffusion in the hydrophobic outer face, pointing to defects in the polymerized matrix.Abbreviations MX-membrane polymer matrix membrane (or monomeric wax-depleted cuticle) - ESR electron-spin resonance - n-SASL n-(4,4-dimethyl-N-oxy-2-oxazolidinyl)-stearic acid - NBD 7-nitrobenz-2-oxa-1,3-diazol-4-yl The present work was made possible by a grant from the Bayerische Umweltministerium. Additional support by the Fonds der Chemischen Industrie is gratefully acknowledged. We are most grateful for very helpful discussions with Professor H. Ziegler, Professor J. Schönherr and Dr. M. Riederer from the Institut für Botanik, Technische Universität München, FRG.     

Morphogenesis and cuticular markers during the larval-pupal transformation of the medfly Ceratitis capitata

Changes in morphology during early metamorphosis of the medfly, Ceratitis capitata (Wied.) (Tephritidae) were correlated with biochemical differentiation events. Protein profiles were studied both in the 3rd instar larval cuticle further transformed into puparium and the newly synthesized pupal cuticle. Beta-alanine incorporation into the puparium (0–20 h) correlates with concomitant pigmentation (completed by 16 h) and sclerotization phenomena. This early tannification program seems to be followed by deposition of a layer of substances, probably ecdysial fluid remnants, into the puparium. Their deposition ends approximately at +46 h. Simultaneously, pupal cuticle material starts to be deposited. Synthesis and deposition of the main pupal cuticle protein was detected 48 h after pupariation. At that time, eversion of the pupal head occurs. The definitive profile of pupal cuticle proteins was attained at around +72 h together with the establishment of adult body proportions.     

Effects of cuticle source and concentration on germination of conidia of two isolates of Nomuraea rileyi

The effects of cuticle from larvae of Trichoplusia ni, Heliothis zea and H. virescens on rate and extent of germination of conidia of a Mississippian isolate (MS) and an Ecuadoran (EC) isolate of Nomuraea rileyi were studied. Solid substrates generally stimulated more germination than submerged substrates. There was little or no effect of cuticle source (H. zea or H. virescens) on germination of either the EC isolate or the MS isolate cultured on a solid substrate, however, differences in patterns of germination were obtained in submerged substrates. Addition of cuticle of H. zea or H. virescens generally increased the germination time for the MS isolate. Germination time for the EC isolate was significantly increased when H. virescens cuticle was used.This article reports the results of research only. Mention of a proprietary product in this paper does not constitute a recommendation for use by U.S. Department of Agriculture.     

Mutations affecting the pattern of the larval cuticle inDrosophila melanogaster

Summary The present report describes the recovery and genetic characterization of mutant alleles at zygotic loci on the third chromosome ofDrosophila melanogaster which alter the morphology of the larval cuticle. We derived 12600 single lines from ethyl methane sulfonate (EMS)-treatedst e orrucuca chromosomes and assayed them for embryonic lethal mutations by estimating hatch rates of egg collections. About 7100 of these lines yielded at least a quarter of unhatched eggs and were then scored for embryonic phenotypes. Through microscopic examination of unhatched eggs 1772 lines corresponding to 24% of all lethal hits were classified as embryonic lethal. In 198 lines (2.7% of all lethal hits), mutant embryos showed distinct abnormalities of the larval cuticle. These embryonic visible mutants define 45 loci by complementation analysis. For 32 loci, more than one mutant allele was recovered, with an average of 5.8 alleles per locus. Complementation of all other mutants was shown by 13 mutants. The genes were localized on the genetic map by recombination analysis, as well as cytologically by complementation analysis with deficiencies. They appear to be randomly distributed along the chromosome. Allele frequencies and comparisons with deficiency phenotypes indicate that the 45 loci represent most, if not all, zygotic loci on the third chromosome, where lack of function recognizably affects the morphology of the larval cuticle.     

Calliphorin,a major protein of the blowfly: Correlation between the amount of protein,its biosynthesis,and the titer of translatable calliphorin-mRNA during development

The amount of calliphorin, its biosynthesis, and the levels of translatable calliphorin-mRNA have been determined during the postembryonic development of Calliphora vicina R.-D. The amount of calliphorin increases in early third-instar larvae, reaching maximal levels in 6-day-old animals. It continuously decreases during late larval and pupal development to approximately one-half of the maximal levels and abruptly sinks during eclosion. The biosynthesis of calliphorin takes place only in 3- to 5-day-old larvae. Poly(A)⁺-RNA has been translated into proteins in a wheat germ cell-free system. Calliphorin-mRNA can be detected in 3- to 7-day-old larvae; maximal concentrations are observed in 4- and 5-day-old animals. No calliphorin-mRNA can be detected in prepupae, pupae, or imagos. The biosynthesis of calliphorin in blowfly larvae stops before a decrease of translatable calliphorin-mRNA is observed. This finding raises the question of the mechanism of in vivo inactivation of this specific mRNA.     

Regulation of cuticle-degrading subtilisin proteases from the entomopathogenic fungi, <Emphasis Type="Italic">Lecanicillium</Emphasis> spp: implications for host specificity

The ability to produce cuticle-degrading proteases to facilitate host penetration does not distinguish per se entomopathogenic fungi from saprophytes. However, adapted pathogens may produce host-protein specific enzymes in response to cues. This possibility prompted an investigation of the regulation of isoforms of the subtilisin Pr1-like proteases from five aphid-pathogenic isolates of Lecanicillium spp. Significant differences were found in substrate specificity and regulation of Pr1-like proteases between isoforms of the same isolate and between different isolates. For example, the pI 8.6 isoform from KV71 was considerably more active against aphid than locust cuticle and was induced specifically by N-acetylglucosamine (NAG). Isoform pI 9.1 from the same isolate was only produced on insect cuticle while most other isoforms were more prominent on chitin containing substrates but not induced by NAG. The ability to regulate isoforms independently may allow production at critical points in host penetration. Appearance of proteases (not subtilisins) with pI 4.2 and 4.4 only on aphid cuticle was a possible link with host specificity of KV71. The absence of C or N metabolite repression in subtilisins from KV42 is unusual for pathogen proteases and may help to account for differences in virulence strategy between aphid-pathogenic isolates of Lecanicillium longisporum (unpublished data).     

Penetration of chemicals into the Malus leaf cuticle

The adaxial leaf cuticle of Malus pumila was examined by electron microscopy to determine possible avenues for transcuticular movement of foliarly applied chemicals. Cutin-embedded polysaccharide microfibrils originated at the outer epidermal cell wall and occasionally extended to the cuticle surface. Lamellae, ca. 4 nm wide, usually were oriented parallel to the cuticle surface. When oriented perpendicular to the surface, they extended nearly to the subjacent wall layer from the surface. Aqueous solutions of uranyl acetate, silver nitrate and phenyl mercuric acetate applied to the cuticle surface of leaf segments floated on solutions of phosphate salts or thiocarbohydrazide (TCH) reacted within the cuticle to form insoluble electron-opaque deposits indicative of their avenues of transcuticular movement. Uranyl phosphate deposits were observed only in the polysaccharide microfibrils of chloroform: methanolextracted leaves. Silver-TCH deposits were observed in the microfibrils of both extracted and nonextracted leaf cuticles. Phenyl mercuric acetate-TCH deposits were randomly dispersed throughout the extracted cuticle and not associated with the polysaccharide microfibrils.Abbreviations TCH thiocarbohydrazide - PMA phenyl mercuric acetate     

Cuticular permeability of the black widow spiderLatrodectus hesperus

Summary The water permeability of abdominal cuticle of the black widow spiderLatrodectus hesperus was examined using gravimetric, in situ and in vitro techniques. At 30 °C and 0% RH, water loss rates (WLR) of whole, living spiders were higher than in situ WLR measured with capsules secured to the cuticle surface, while in situ WLR of living spiders were greater than in situ WLR for dead spiders. Although these differences are not statistically significant, these results suggest that there may be important extracuticular water loss pathways in living animals, and that the living epidermis does not provide an active barrier to water efflux. In vitro WLR measured on excised pieces of cuticle, in contrast, were nearly 5 times greater than in situ WLR of dead spiders. Temperature/transpiration curves show that permeability increased exponentially with rising temperature, with rates increasing most rapidly between 45 and 51 °C. The WLR for spiders whose cuticle was scrubbed with chloroform: methanol was consistently and substantially (200x) higher than WLR for control or sham-treated spiders. Discussion focuses on the location and composition of the epicuticular lipid water barrier and the potential use of black widow cuticle for in vitro studies of lipid barrier effectiveness in arthropods in general.     

Fungal adhesion pad formation and penetration of root cuticle in early stage mycorrhizas ofPicea abies andLaccaria amethystea

Summary Primary events during the establishment of the fungus-root symbiosis in ectomycorrhizas are still little understood. No attention has been paid so far to the adhesion of hyphae to the root cuticle and penetration of this barrier, although the importance of the cuticle has been shown for pathogen-plant interactions. Early developmental stages of in vitro mycorrhization ofLaccaria amethystea onPicea abies after short periods of incubation in growth chambers under elevated CO₂ concentrations were studied by light and transmission electron microscopy. No structural changes in mycorrhization related to elevated CO₂ were found, but fine roots and mycorrhizas developed faster. Adhesion pad formation was observed at hyphal tips in contact with the root cuticle. The adhesion pad was connected to the outer cell wall layer of the hypha and reacted positively to the Swift reaction for cysteine rich proteins. Although the reaction cannot be considered as totally specific, findings are discussed in respect to hydrophobins, which have recently been found to be expressed during early steps in ectomycorrhizal development. The root cuticle was dissolved and penetrated by fungal tips of the fingerlike branching mycelium attached to the root surface. The findings are compared with well documented pathogenic fungus-plant interactions at the cuticle. The possibility of restriction of hyphal attack to that part of the cuticle covering cell junctions is discussed.     

Identification and molecular analysis of a multigene family encoding calliphorin, the major larval serum protein of Calliphora vicina

A library of Calliphora vicina genomic DNA was constructed in the λEMBL3 vector and screened for recombinant phages containing chromosomal segments encoding calliphorin, the major larval serum protein (LSP) of Calliphora. A large series of recombinants hybridizing with in vitro labelled poly(A)⁺ RNA from Calliphora larval fat bodies and with specific probes derived from the LSP-1 genes of Drosophila melanogaster was isolated. Five of these phages, chosen at random, were shown by hybrid selection to retain calliphorin mRNA specifically. Eleven calliphorin mRNA-homologous regions were located on restriction maps of these phages by hybridization with 5' end-labelled poly(A)⁺ RNA from Calliphora larval fat bodies. Each phage contains at least two calliphorin genes arranged in direct repeat orientation and seperated by 3.5–5 kb intergenic regions. The genes display similar but not identical restriction patterns. Filter hybridization and heteroduplex analysis indicate that they share a detectable homology with the LSP-1β gene of D. melanogaster. Whole genome Southern analysis showed that these genes belong to a large family of closely related calliphorin genes which were found by in situ hybridization to polytene chromosomes of trichogen cells to be clustered in region 4a of chromosome 2 of Calliphora vicina.     

Ultrastructural studies on the early cuticular metamorphosis of adult female Lernaeocera branchialis (L.) (Copepoda,Pennellidae)

After its final moult and fertilization an adult female of the marine fish-parasitic copepod, Lernaeocera branchialis, begins an extensive metamorphosis. This commences while the parasite is still on the flounder intermediate host and is completed once the female has established itself on the whiting final host. One early component of the metamorphosis is a considerable elongation of the parasite's abdominal region. S.e.m. and t.e.m. studies have revealed that part of the mechanism of the elongation consists of a straightening out of a highly folded abdominal cuticle. Before fertilization, the epicuticle and outer procuticular layers of this integument are thrown into a series of transverse, 4–6 µm deep pleats or folds with a density of 1–1.2 folds/µm of abdominal length. Straightening these folds can generate an approximately 6-fold length increase. The folds are already present beneath the female chalimus IV cuticle when the epidermis of this development stage starts to secrete the adult cuticle. Immediately before the final moult, the adult cuticle is super-folded with the whole cuticle displaying second-order folds, 8–10 µm deep.The capacity of Lernaeocera to engage in extensive cuticular modifications without recourse to a moult is compared with similar abilities shown by some insect species.     

Glycosidase activity in the post-ecdysial cuticle of the blue crab, Callinectes sapidus

We have previously demonstrated a marked change in sugar moieties of glycoproteins of the cuticle of the blue crab, Callinectes sapidus, between 0.5 and 3 h post-ecdysis. The present study has identified a glycosidase that appears in the cuticle during the early post-ecdysial hours. The enzyme has affinities for p-nitrophenyl derivatives of both N-acetylglucosamine and N-acetylgalactosamine. Both activities are competitively inhibited by chitobiose, suggesting that the enzyme could be a N-acetylhexosaminidase (EC 3.2.1.52). Atypical of N-acetylhexosaminidases described to date, this enzyme has a pH optimum of 7.0. The enzyme activity is high during the post-ecdysial period coincident with the changes in glycoprotein profiles observed in vivo. Partial purification of the enzyme has been accomplished by Sephacryl size-exclusion chromatography followed by concanavalin A affinity chromatography.