Analysis of the cuticular proteins of Hyalophora cecropia with polyclonal antibodies

The cuticular proteins from different anatomical regions and metamorphic stages of Hyalophora cecropia were analyzed with polyclonal antibodies raised against cuticular protein extracts from each stage. Western blots of 2D gels coupled with detection of antibody-antigen binding with avidin-biotinylated-horseradish peroxidase complexes (ABC method) proved to be extremely sensitive. Reactions of polyclonal antisera with blots of extracts of different cuticular regions revealed the following: (1) glycosylated cuticular proteins were highly antigenic; (2) there was less cross-reaction between rigid and flexible cuticles from the same metamorphic stage than among cuticles with similar mechanical properties from different stages; (3) proteins with identical molecular weights and isoelectric points were antigenically indistinguishable.     

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.     

Post-translational modifications of the cuticular proteins of Hyalophora cecropia from different anatomical regions and metamorphic stages

Post-translational modifications are a conspicuous feature of the proteins of vertebrate extracellular matrices such as cartilage. Yet this feature remains virtually unexplored with insect cuticle, a situation this paper begins to remedy. Cuticular proteins were extracted from cuticles of Hyalophora cecropia and separated on isoelectrofocusing and 2D gels. Periodic acid-Schiff reagent stained several proteins from flexible cuticles and a few proteins from rigid cuticles, indicating that some proteins were glycosylated. Elucidation of the specific nature of this glycosylation came from probing electrophoretically separated cuticular proteins blotted onto nitrocellulose with biotinylated lectins. Most major cuticular proteins did not react; minor cuticular proteins and molecules which do not stain with Coomassie blue were found to bind lectins specific for mannose and N-acetylgalactosamine. Limited binding was also detected with lectins specific for N-acetylglucosamine, galactose and fucose. No sialic acid was detected using either lectins or neuraminidase digestion. The amount of glycosylation was greatest in proteins extracted from flexible cuticles. Although several proteins stained with Alcian blue indicating presence of sulfation, ³⁵S which had been incorporated at low levels in cuticular proteins corresponded to [³⁵S]methionine. No indication of the presence of mammalian-type glycosaminoglycans in insect cuticles was obtained after treatment with chondroitinase or nitrous acid. The functional significance of the modifications detected remains unknown. No evidence for phosphorylated proteins or lipoproteins was found.     

The CPCFC cuticular protein family: Anatomical and cuticular locations in Anopheles gambiae and distribution throughout Pancrustacea

Arthropod cuticles have, in addition to chitin, many structural proteins belonging to diverse families. Information is sparse about how these different cuticular proteins contribute to the cuticle. Most cuticular proteins lack cysteine with the exception of two families (CPAP1 and CPAP3), recently described, and the one other that we now report on that has a motif of 16 amino acids first identified in a protein, Bc-NCP1, from the cuticle of nymphs of the cockroach, Blaberus craniifer (Jensen et al., 1997). This motif turns out to be present as two or three copies in one or two proteins in species from many orders of Hexapoda. We have named the family of cuticular proteins with this motif CPCFC, based on its unique feature of having two cysteines interrupted by five amino acids (C-X(5)-C). Analysis of the single member of the family in Anopheles gambiae (AgamCPCFC1) revealed that its mRNA is most abundant immediately following ecdysis in larvae, pupae and adults. The mRNA is localized primarily in epidermis that secretes hard cuticle, sclerites, setae, head capsules, appendages and spermatheca. EM immunolocalization revealed the presence of the protein, generally in endocuticle of legs and antennae. A phylogenetic analysis found proteins bearing this motif in 14 orders of Hexapoda, but not in some species for which there are complete genomic data. Proteins were much longer in Coleoptera and Diptera than in other orders. In contrast to the 1 and occasionally 2 copies in other species, a dragonfly, Ladona fulva, has at least 14 genes coding for family members. CPCFC proteins were present in four classes of Crustacea with 5 repeats in one species, and motifs that ended C-X(7)-C in Malacostraca. They were not detected, except as obvious contaminants, in any other arthropod subphyla or in any other phylum.The conservation of CPCFC proteins throughout the Pancrustacea and the small number of copies in individual species indicate that, when present, these proteins are serving important functions worthy of further study.     

Analysis of the cuticular proteins of Hyalophora cecropia with two dimensional electrophoresis

The soluble cuticular proteins of defined anatomical regions from different metamorphic stages of the giant silkmoth, Hyalophora cecropia, were characterized by two dimensional electrophoresis. As urea concentrations in 2D gels were increased, some of the cuticular proteins from the larval dorsal abdomen decreased in mobility relative to the molecular weight standards. This decrease was also influenced by the pH and ionic strength of the resolving gel. Clustering of proteins into groups, whose members showed similar behavior under different electrophoretic conditions, was indicative of membership in multigene families. By such criteria, common families were found in cuticles with similar mechanical properties from different metamorphic stages, yet there was evidence that different members of a single family were independently regulated.     

Studies on proteins in post-ecdysial nymphal cuticle of locust, Locusta migratoria, and cockroach, Blaberus craniifer

Proteins were extracted from the cuticle of mid-instar nymphs of locusts, Locusta migratoria, and cockroaches, Blaberus craniifer. Seven proteins were purified from the locust extract and five from the cockroach extract, and their amino acid sequences were determined. Polyacrylamide gel electrophoresis indicates that the proteins are present only in the post-ecdysially deposited layer of the nymphal cuticles. One of the locust and one of the cockroach nymphal proteins contain a 68-residue motif, the RR-2 sequence, which has been reported for several proteins from the solid cuticles of other insect species. Two of the cockroach proteins contain a 75-residue motif, which is also present in a protein from the larval/pupal cuticle of a beetle, Tenebrio molitor, and in proteins from the exoskeletons of a lobster, Homarus americanus, and a spider, Araneus diadematus. The motif contains a variant of the Rebers-Riddiford consensus sequence, and is called the RR-3 motif. One of the locust and three of the cockroach post-ecdysial proteins contain one or more copies of an 18-residue motif, previously reported in a protein from Bombyx mori pupal cuticle. The nymphal post-ecdysial proteins from both species have features in common with pre-ecdysial proteins (pharate proteins) in cuticles destined to be sclerotised; they show little similarity to the post-ecdysial cuticular proteins from adult locusts or to proteins from soft, pliable cuticles. Possible roles for post-ecdysial cuticular proteins are discussed in relation to the reported structures.     

Comprehensive sequence analysis of horseshoe crab cuticular proteins and their involvement in transglutaminase-dependent cross-linking

Arthropod cuticles play an important role as the first barrier against invading pathogens. We extensively determined the sequences of horseshoe crab cuticular proteins. Proteins extracted from a part of the ventral side of the cuticle were purified by chitin-affinity chromatography, and separated by two-dimensional SDS/PAGE. Proteins appearing on the gel were designated high molecular mass chitin-binding proteins, and these proteins were then grouped into classes based on their approximate isoelectric points and predominant amino acid compositions. Members of groups designated basic G, basic Y, and acidic S groups contained a so-called Rebers and Riddiford consensus found in arthropod cuticular proteins. Proteins designated acidic DE25 and DE29 each contained a Cys-rich domain with sequences similar to those of insect peritrophic matrix proteins and chitinases. In contrast, basic QH4 and QH10 contained no consensus sequences found in known chitin-binding proteins. Alternatively, a low molecular mass chitin-binding fraction was prepared by size exclusion chromatography, and 15 low molecular mass chitin-binding proteins, named P1 through P15, were isolated. With the exception of P9 and P15, all were found to be identical to known antimicrobial peptides. P9 consisted of a Kunitz-type chymotrypsin inhibitor sequence, and P15 contained a Cys-rich motif found in insulin-like growth factor-binding proteins. Interestingly, we observed transglutaminase-dependent polymerization of nearly all high molecular mass chitin-binding proteins, a finding suggests that transglutaminase-dependent cross-linking plays an important role in host defense in the arthropod cuticle, analogous to that observed in the epidermal cornified cell envelope in mammals.     

Larval cuticle proteins of Lucilia cuprina: Electrophoretic separation,quantification and developmental changes

Proteins from isolated cuticles of third instar larvae of the sheep blowfly, Lucilia cuprina, have been solubilized with water or 7 M urea or 2% SDS. While 7 M urea or 2% SDS extract significantly more protein than water, the same major proteins, in the same relative proportions, are extracted by all three solutions. More than 80% of the cuticular protein is extracted by 7 M urea or 2% SDS. Extracted proteins resolve into nine major bands when analysed by gradient polyacrylamide gel electrophoresis. These proteins are anionic, relatively low in molecular weight (13–28 kd) and are essentially free of carbohydrate. Only minor differences exist between the proteins of two morphologically distinct cuticular regions. Cuticle proteins, extracted from larvae at different developmental stages (first, second and third instars) display quantitatively and qualitatively unique electrophoretic profiles. A number of proteins are common to all stages however. The electrophoretic profiles of proteins extracted from larval cuticles at various times within an instar also differ although the differences are largely quantitative. This is particularly evident during the transition from the feeding to the wandering stages of the third instar; the weight of the cuticle relative to that of the larva increases and this is accompanied by marked changes in the electrophoretic profile of the cuticle proteins.     

Cuticular Proteins in Insects and Crustaceans

Comparisons between crustacean and insect cuticles are hamperedby the paucity of cuticular protein sequences for the former.Sufficient complete sequences are available for insect cuticularproteins to allow recognition of conserved motifs and relationshipsamong proteins that reflect the type of cuticle from which theyhave been extracted. All five sequences from an arachnid andtwo of 14 from crustaceans have a motif found in the largestgroup of insect cuticular proteins. Numerous insights have beengained from studying insect cuticular proteins and their genes.These insights have been summarized in hopes of encouraginginterest in building on the foundations laid by Dorothy Skinnerwith the exoskeleton of Gecarcinus.     

Sequence determination of three cuticular proteins and isoforms from the migratory locust,Locusta migratoria,using a combination of Edman degradation and mass spectrometric techniques

The cuticle (exoskeleton) is a characteristic structure of insects and other arthropods. It is an extracellular layer which surrounds and protects the insect, and it is composed of proteins, lipids, water molecules, phenolic materials and chitin. Four proteins isolated from the thorax and femur cuticle of pharate adult migratory locust, Locusta migratoria, have been purified by ion-exchange chromatography and reversed-phase high performance liquid chromatography (RP-HPLC). Their amino acid sequences were determined by combined use of mass spectrometry and automated Edman degradation. The cuticular extract was also separated by two-dimensional gel electrophoresis. In order to localize and identify the position of the proteins in the gel, a number of gel spots were excised and the proteins electroeluted. The molecular mass of some of the electroeluted proteins was determined by means of matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) as well as by electrospray mass spectrometry (ESI-MS). Two of the sequenced proteins exist as pairs of closely related isoforms; one of the pairs contains the conserved 68-residue RR-2 motif, common for proteins from solid cuticles, and the other proteins contain the short motif Ala-Ala-Pro-Ala/Val repeatedly throughout the sequence.     

The cuticular proteins of Tenebrio molitor: II. Patterns of synthesis during postembryonic development

The program of synthesis for the soluble cuticular proteins of Tenebrio molitor was determined by following the incorporation of labeled leucine after a 4-hr pulse in vivo. Soluble proteins were extracted from labeled cuticles and separated on SDS-polyacrylamide slab gels; individual gel slices were counted. The synthetic patterns of larvae and pupae were similar to one another but distinct from the adult pattern. At each stage, the preecdysial pattern was unlike that of postecdysial animals. Distinct periods of synthesis were detected for different proteins. One protein was synthesized and deposited throughout cuticle formation in all three metamorphic stages. One group was synthesized only after ecdysis, while synthesis and secretion of other proteins were restricted to the preecdysial period. Some cuticular proteins never acquired detectable label.     

The primary structure of an endocuticular protein from two locust species,Locusta migratoria and Schistocerca gregaria,determined by a combination of mass spectrometry and automatic Edman degradation

The complete primary structures of two variants of a protein, Abd-5, isolated from the endocuticles of the migratory locust Locusta migratoria and the desert locust Schistocerca gregaria, have been determined. The proteins from the two species are N-terminally blocked with pyroglutamic acid. Their sequences differed only in two positions. Comparison of the sequences to those of other cuticular proteins shows that moderate homologies exist to 11 other cuticular proteins from insects representing four different orders. Amino acid residues in certain positions appear to be strictly conserved.     

The cuticular proteins of Tenebrio molitor: I. Electrophoretic banding patterns during postembryonic development

Buffer-soluble cuticular proteins of the abdomen of the yellow mealworm, Tenebrio molitor, were analyzed by SDS-polyacrylamide gel electrophoresis. Since the abdominal epidermis of Tenebrio persists throughout the insect's life, these cuticular proteins reflect the secretory history of a continuous line of cells during its entire metamorphic developmental program. Twenty-two to thirty-eight bands were detected in extracts of larval cuticle, 11 to 35 in pupal cuticular extracts, and 30 to 41 in extracts from adults. No population polymorphism was apparent, nor was there any sexual dimorphism, in these cuticular proteins. At each metamorphic stage, the cuticular proteins formed a unique banding pattern. Bands unique to the larval and to the adult exocuticular extracts were observed. Extracts from cuticles of freshly ecdysed animals (exocuticle) differed from extracts from animals in which sclerotization and postecdysial (endocuticle) deposition had occurred, both in number of hands and in their molecular weight distributions. Some proteins became less soluble during sclerotization. The majority of the exocuticular bands from all three stages had molecular weights below 25,000; higher-molecular-weight proteins were extracted from postecdysial animals of each stage.     

The AVIT protein family. Secreted cysteine-rich vertebrate proteins with diverse functions

Homologues of a protein originally isolated from snake venom and frog skin secretions are present in many vertebrate species. They contain 80–90 amino acids, 10 of which are cysteines with identical spacing. Various names have been given to these proteins, such as mamba intestinal protein 1 (MIT1), Bv8 (Bombina variegata molecular mass ~8 kDa), prokineticins and endocrine-gland vascular endothelial growth factor (EG-VEGF). Their amino-terminal sequences are identical, and so we propose that the sequence of their first four residues, AVIT, is used as a name for this family. From a comparison of the sequences, two types of AVIT proteins can be discerned. These proteins seem to be distributed widely in mammalian tissues and are known to bind to G-protein-coupled receptors. Members of this family have been shown to stimulate contraction of the guinea pig ileum, to cause hyperalgesia after injection into rats and to be active as specific growth factors. Moreover, the messenger RNA level of one of these AVIT proteins changes rhythmically in the region of the brain known as the suprachiasmatic nucleus. This shows that members of this new family of small proteins are involved in diverse biological processes.     

Expression and hormonal control of a new larval cuticular multigene family at the onset of metamorphosis of the tobacco hornworm

The pattern of cuticular protein synthesis by the epidermis of the tobacco hornworm larva changes during the final day of feeding, leading to an alteration in cuticular structure and a stiffening of the cuticle. We have isolated a small multigene family which codes for at least three of the new cuticular proteins made at this time. The five genes which were isolated from this family map to two different genomic regions. Sequencing shows that one of the genes is 1.9 kb and consists of three exons coding for a 12.2-kDa acidic (pI = 5.26) protein that is predominantly hydrophilic. The deduced amino acid sequence shows regions of similarity to proteins from flexible lepidopteran cuticles and from Drosophila larval and pupal cuticles, but not to proteins found in highly sclerotized cuticles. This gene family is first expressed late on the penultimate day (Day 2) of feeding in the final larval instar and ceases expression 2 days later when metamorphosis begins. In situ hybridization shows that this gene family is expressed in all the epidermal cells of Day 3 larvae except the bristle cells and those at the muscle attachment site. Expression can be induced in Day 1 epidermis by exposure to 50 ng/ml 20-hydroxyecdysone in vitro, but only if juvenile hormone is absent. Its developmental expression, tissue specificity, and hormonal regulation strongly suggest that this multigene family is involved in the structural changes that occur in the larval cuticle just prior to the onset of metamorphosis.     

Cuticular Collagenous Proteins of Second-stage Juveniles and Adult Females of Meloidogyne incognita: Isolation and Partial Characterization

Cuticles isolated from second-stage juveniles and adult females of Meloidogyne incognita were purified by treatment with 1% sodium dodecyl sulfate (SDS). The juvenile cuticle was composed of three zones differing in their solubility in β-mercaptoethanol (BME). Proteins in the cortical and median zones were partially soluble in BME, whereas the basal zone was the least soluble. The BME-soluble proteins from the juvenile cuticle were separated into 12 bands by SDS-polyacrylamide gel electrophoresis and characterized as collagenous proteins based on their sensitivity to collagenase and amino acid composition. The adult cuticle consisted of two zones which were dissolved extensively by BME. The basal zone was completely solubilized, leaving behind a network of fibers corresponding to the cortical zone. The BME-soluble proteins from the adult cuticle were separated by electrophoresis into nine bands one of which constituted > 55% of the total BME-soluble proteins. All bands were characterized as collagenous proteins. Collagenous proteins from juvenile cuticles also contained glycoproteins which were absent from the adult cuticles.     

Plant Cuticles Are Polyelectrolytes with Isoelectric Points around Three

The isoelectric points of isolated cuticles from Citrus aurantium L. (3.15), Prunus armeniaca L. (3.45), and Pyrus communis L. (2.90) leaves were determined from membrane potentials. At pH values below the isoelectric point, cuticular membranes carry a net positive charge and are permselective to anions (determined using ⁸²Br⁻). Above the isoelectric point, they carry a net negative charge and are permselective to cations (determined using ²⁴Na⁺). There are no gradients of fixed charges across the cuticular membranes as indicated by the absence of asymmetry potentials. Positive charges in the membranes originate from residues of basic amino acids of proteins or polypeptides contained in a nonextractable form within the cuticle. The exchange capacity of basic fixed groups in the cuticles of six species (Lycopersicon esculentum Mill., Capsicum annuum L. fruit cuticles, and Brassaia spec. leaf cuticles in addition to the above species) varied between 0.010 and 0.025 meq g⁻¹ cuticle. Fixed acidic groups were donated by residues of acidic amino acids, polygalacturonic acid, and nonesterified -COOH groups of the cutin polymer. At pH 8, total cation exchange capacity as determined using ⁴⁵Ca²⁺ varied between 0.26 (Citrus) and 0.30 (apricot) meq g⁻¹.     

The cuticle proteins of Drosophila melanogaster: stage specificity

Five stage-specific cuticles are produced during the development of Drosophila. Urea-soluble proteins were extracted from each developmental stage and compared by gel electrophoresis. Proteins from first and second instar cuticle are identical except for minor differences in two proteins. Each subsequent stage, third instar, pupa, and adult, has a unique set of cuticle proteins. Qualitative changes within stages are seen in proteins from third instar and adult cuticle. Third instar cuticle proteins can be divided into “early” [proteins 2a, 3, 4, 5, 7, and 8] and “late” [proteins 2 and 1] groups. Adult cuticle proteins change in relative amounts during pharate adult development and change mobility at eclosion. The lower abdominal pupal cuticle lacks a protein found in the pupal cuticle covering the head and thorax. Cuticle proteins from each stage are immunologically related. Nonetheless, electrophoretic variants of three larval proteins do not affect any major changes in the electrophoretic mobility of proteins from other stages. We propose that each stage (except first and second instar) has proteins encoded by discrete genes.     

Comparative Proteomics Studies of Insect Cuticle by Tandem Mass Spectrometry: Application of a Novel Proteomics Approach to the Pea Aphid Cuticular Proteins

The cuticle is a biological composite material consisting principally of N‐acetylglucosamine polymer embedded in cuticular proteins (CPs). CPs have been studied and characterized by mass spectrometry in several cuticular structures and in many arthropods. Such analyses were carried out by protein extraction using SDS followed by electrophoresis, allowing detection and identification of numerous CPs. To build a repertoire of cuticular structures from Bombyx mori, Apis mellifera and Anopheles gambiae the use of SDS and electrophoresis was avoided. Using the combination of hexafluoroisopropanol and of a surfactant compatible with MS, a high number of CPs was identified in An. gambiae wings, legs and antennae, and in the thoracic integument cuticle of Ap. mellifera pupae. The exoskeleton analysis of B. mori larvae allowed to identify 85 CPs from a single larva. Finally, the novel proteomics approach was tested on cuticles left behind after the molt from the fourth instar of Acyrthosiphon pisum. Analysis of these cast cuticles allowed to identify 100 Ac. pisum CPs as authentic cuticle constituents. These correspond to 68% of the total putative CPs previously annotated for this pea aphid. While this paper analyzes only the recovered cuticular proteins, peptides from many other proteins were also detected.