The intrinsic peritrophic matrix protein peritrophin-95 from larvae of Lucilia cuprina is synthesised in the cardia and regurgitated or excreted as a highly immunogenic protein

The intrinsic peritrophic matrix glycoprotein, peritrophin-95, from the midgut of larvae of Lucilia cuprina can only be solubilized from the matrix using strong denaturants. This suggests that the protein has a structural role in the matrix. Consistent with this is the finding that immuno-gold and immuno-fluorescence localizations of the protein showed a uniform distribution within the peritrophic matrix. RT-PCR demonstrated that expression of peritrophin-95 mRNA was restricted to the larval cardia, a small organ located in the anterior midgut from which the type 2 peritrophic matrix originates. Immuno-blots and ELISAs demonstrated that the sera from sheep infested naturally or artificially with these larvae recognised peritrophin-95. This indicates that peritrophin-95 stimulates the ovine immune system during larval infestation even though the protein is firmly attached to the peritrophic matrix in the larval midgut and seemingly "concealed" from the ovine immune surveillance system. Analyses of larval regurgitated or excreted material by immuno-blots, immuno-affinity purification and amino-terminal sequencing demonstrated the presence of soluble monomeric peritrophin-95. These results indicate that peritrophin-95, a candidate vaccine antigen for use in sheep is not a "concealed" antigen as previously thought. The presence of soluble peritrophin-95 in the regurgitated/excreted material from larvae suggests that this protein may be involved in a maturation phase of peritrophic matrix production, a by-product of which is the excretion or regurgitation of soluble peritrophin-95.     

Vaccines against blowfly strike: the effect of adjuvant type on vaccine effectiveness.

Vaccination of sheep with a partially purified extract of Lucilia cuprina larvae in some cases resulted in marked reduction of growth in larvae which fed on the sheep. Twelve adjuvants were assessed, in vitro and in vivo, to determine which induced the largest inhibitory effect on larval growth. The Freund's complete adjuvant and Quil A groups produced ELISA antibody levels significantly higher (P less than 0.05) than other groups. Seven adjuvants mediated an immune response which caused significant inhibition of larval growth (P less than 0.05). When the sheep were assessed by in vivo larval culture, only larvae feeding on sheep vaccinated with the antigen presented in Freund's complete adjuvant or dextran sulphate or a dextran sulphate/Freund's incomplete adjuvant mixture weighed significantly less (P less than 0.05) than larvae feeding on control sheep. The effect on larvae was monitored in vitro for 70 days after vaccination, by which time significant reduction in larval weight was no longer observed. The loss of larval growth inhibition was not associated with a corresponding reduction in overall antibody levels.     

Acquired resistance of sheep to larvae of Lucilia cuprina, assessed in vivo and in vitro

The effect on subsequent larval survival of infesting sheep repeatedly with larvae of Lucilia cuprina was assayed in vivo and in vitro. One in vivo assay technique, in which implanted larvae were grown to third instar, indicated a significant reduction in larval survival; another in vivo technique, in which larvae were allowed to develop to second instar in small aluminium rings attached to the sheep, indicated no reduction in larval growth or survival. Larvae of Lucilia cuprina grown in vitro on media containing sera from previously infested sheep were significantly retarded in growth after 20 h compared with controls; no difference was detected when larvae were allowed to develop to pupation on two changes of the same media. No significant differences in survival of larvae either to 20 h or to pupation were obtained between the two treatments. ELISA antibody levels against crude soluble larval material were significantly higher for sera from infested sheep than for control sera, and the regression of antibody level on mean larval weight obtained after 20 h growth in vitro was significant. The immunoglobulin fraction isolated from sera of infested sheep significantly retarded larval growth when incorporated with normal serum in growth media. These results are consistent with an effect of specific anti-larval antibody produced by sheep in response to infestation.     

A novel family of chitin-binding proteins from insect type 2 peritrophic matrix. cDNA sequences, chitin binding activity, and cellular localization

The peritrophic matrix is a prominent feature of the digestive tract of most insects, but its function, formation, and even its composition remain contentious. This matrix is a molecular sieve whose toughness and elasticity are generated by glycoproteins, proteoglycans, and chitin fibrils. We now describe a small, highly conserved protein, peritrophin-15, which is an abundant component of the larval peritrophic matrices of the Old World screwworm fly, Chrysomya bezziana, and sheep blowfly, Lucilia cuprina. Their deduced amino acid sequences code for a 8-kDa secreted protein characterized by a highly conserved and novel register of six cysteines. Two Drosophila homologues have also been identified from unannotated genomic sequences. Recombinant peritrophin-15 binds strongly and specifically to chitin; however, the stoichiometry of binding is low (1:10,000 N-acetyl glucosamine). We propose that peritrophin-15 caps the ends of the chitin polymer. Immunogold studies localized peritrophin-15 to the peritrophic matrix and specific vesicles in cells of the cardia, the small organ of the foregut responsible for peritrophic matrix synthesis. The vesicular contents are disgorged at the base of microvilli underlying the newly formed peritrophic matrix. This is the first time that the process of synthesis and integration of a peritrophic matrix protein into the nascent peritrophic matrix has been observed.     

Retarded growth of Lucilia cuprina larvae on sheep and their sera following production of an immune response.

Attempts were made to immunize sheep against larvae of the sheep blowfly Lucilia cuprina using supernatant and pellet prepared by centrifuging (100,000 g max) homogenates from whole second instar larvae of L. cuprina or their excised guts. Injection of supernatant from whole larvae and from two fractions of this supernatant, prepared by ammonium sulphate precipitation, significantly reduced (by 24-58%) the final weight of larvae grown in vivo (i.e. on immunized sheep) for 20 or 44 h. Serum from animals vaccinated with supernatant from whole larvae reduced larval weights by 12% after growth for 20 h in vitro (i.e. on diet containing serum from treated animals). Pellet material from whole larvae or guts, when injected into sheep, stimulated an immune response which reduced the weight of larvae by 20-23% after 20 or 48 h in vitro. Larvae grown on these animals were not reduced in weight. Immunoglobulin (Ig) isolated from serum of a sheep vaccinated with gut material strongly retarded growth of larvae in vitro, the effect increasing with Ig concentration. These results indicate that an immune response in sheep, induced by injecting extracts of L. cuprina larvae, substantially reduces growth of this parasite.     

Aminopeptidases as potential targets for the control of the Australian sheep blowfly, Lucilia cuprina.

A series of experiments were carried out to investigate the role of proteinase enzymes in the growth of larvae of the sheep blowfly, Lucilia cuprina. First, instar larvae were incubated on an artificial growth media in the presence of various concentrations of inhibitors of all the major proteinase classes. Inhibitors of serine proteinases and aminopeptidases were found to cause significant growth inhibition and in some cases death of the larvae within 24 h, suggesting that these enzymes were the major classes involved in protein digestion in the gut of the insect. A second group of experiments analysed the effects of two inhibitors from the same or different proteinase classes in the growth media. Synergistic inhibition of larval growth was observed with the incorporation of inhibitors of serine proteinases and aminopeptidases. The results suggest that these classes of proteinases are both central to protein digestion in this insect, probably in the gut, and that the inhibition of both types of activity leads to an almost complete blockade of digestion. Testing in vivo gave similar results with infections on sheep skin inhibited by either serine proteinase or aminopeptidase enzyme inhibitors and the combination of both stopped the infection process. The role of aminopeptidases in larval metabolism and as potential targets for blowfly control agents is examined.     

The immune response of the sheep popliteal lymph node to a purified phenoloxidase from larval cuticle of the sheep ectoparasite, Lucilia cuprina

The popliteal lymph node of the sheep can mount a strong immune response to a phenoloxidase, enzyme A, purified from larval cuticle of a major sheep ectoparasite, the sheep blowfly, Lucilia cuprina. Continuous sampling from a cannulated efferent lymphatic allowed monitoring of changes in both cellular output (total cells and large blast cells) and specific antibody production (by ELISA) following primary and secondary challenge with antigen. Anti-enzyme A antibodies in lymph selectively precipitated enzyme A but not a second cuticular phenoloxidase, enzyme B, a finding that will prove useful in immunolocalization of the enzymes and in elucidating their origins. The implications for immunization of sheep against L. cuprina are discussed.     

The humoral immune response of sheep to antigens from larvae of the sheep blowfly (Lucilia cuprina)

The sheep blowfly, Lucilia cuprina, is a myiasis-causing insect whose larvae evoke an immune response in sheep. By means of an immuno-dot blot and Western immuno-blot assays it has been demonstrated that sheep experimentally infected with larvae produce antibodies against a wide array of components from all three larval instars, with each instar displaying a differing set of antigens. The electrophoretic profiles of the proteins in various larval extracts and the patterns of antibody reactivity were very different. Of the extracts tested (1st, 2nd and 3rd instar larval excretions/secretions and visceral homogenates, extracts of 3rd instar salivary glands, mid guts, haemolymph and cuticle) the most intense antibody reaction was detected against the salivary gland extract: preparations of larval excretions/secretions and from the larval mid gut also reacted strongly. In contrast a cuticle extract reacted minimally with infected sheep sera.     

Prospects for the control of sheep blowfly strike by vaccination

Research into vaccination against flystrike is aimed at either controlling the predisposing condition, fleece rot, or direct control of the fly maggots. A vaccine against the major bacterial species found in fleece rot lesions, Pseudomonas aeruginosa, is undergoing field trials and results suggest that this vaccine may reduce fleece rot incidence. Problems to be investigated include the existence of variants of P. aeruginosa in the field and the involvement of other species of bacteria in fleece rot. Strategies for direct vaccination include immunization with larval products involved in wound formation and larval nutrition and immunization against novel antigens usually from the gut of first instar larvae. Both methods have resulted in significant inhibition of larval growth. Analysis of larval products has revealed a number of active proteases which degrade skin proteins such as collagen. Inhibition of these enzymes with plasma enzyme inhibitors also affects larval growth in vitro. Antibodies raised against these enzymes are being tested for inhibitory effects against larvae and used to isolate cDNA clones from Lucilia cuprina libraries. Antigens from the gut are able to induce antibodies inhibitory to larval growth both in vitro and in vivo. Isolation of these antigens is proceeding in a number of laboratories. Problems still to be analysed include whether growth inhibition produces effective protection in the field and whether sufficient antibody will have early access to the larvae to significantly affect them.     

Suppression of populations of Australian sheep blowfly, Lucilia cuprina (Wiedemann) (Diptera: Calliphoridae), with a novel blowfly trap

The Australian sheep blowfly, Lucilia cuprina , initiates more than 85% of fly strikes on sheep in Australia with an estimated average annual cost of A$280 million to the Australian sheep industry. LuciTrap^® is a commercially available, selective trap for L. cuprina consisting of a plastic bucket with multiple fly entry cones and a synthetic attractant. The impact of LuciTrap on populations of L. cuprina on sheep properties in five Australian states was evaluated by comparing L. cuprina populations on paired properties with and without LuciTraps over seasons when significant fly populations could be expected. Twenty-four comparisons (trials) were conducted over 4 years. During times of 'higher fly density' (when the 48 h geometric mean of trap catches on the control property was greater than five L. cuprina ), the overall geometric mean trap catches for control and trapped properties differed significantly ( P  < 0.001) with mean trap catches of 19.4 and 7.74 L. cuprina , respectively. The selectivity of the LuciTrap was confirmed with 59% of all trapped flies being L. cuprina . Chrysomya spp. and Calliphora spp. constituted 9.3% and 1.1% of the catches with a variety of other flies (mainly Sarcophagidae and Muscidae ) providing the remainder (31%). Lucilia sericata was only trapped in Tasmania and made up 7.7% of the Lucilia spp. catch in that state. Seventy-two per cent of the trapped L. cuprina were female. The deployment of LuciTrap on sheep properties at one trap per 100 sheep from the beginning of the anticipated fly season suppressed the populations of L. cuprina by 60% compared with matched control properties. The LuciTrap is a selective and easy to use fly trap and constitutes an effective, non-insecticidal tool for use in integrated management programs for L. cuprina .     

Responses of the sheep blowflies Lucilia sericata and Lcuprina to odour and the development of semiochemical baits

Abstract. The literature relating to the attraction of the sheep blowflies Lucilia sericata and Lucilia cuprina to their ovine hosts is reviewed. The responses of the two species are similar and different components of the behaviour leading to host location and oviposition appear to involve at least two distinct sets of semiochemical cues. Activation, upwind orientation and landing appear to occur in response to putrefactive sulphur-rich volatiles, originating from bacterial decomposition products. Oviposition is elicited primarily by the presence of ammonia-rich compounds; moisture, pheromones and tactile stimuli may also act as oviposition stimuli. There is a pronounced sex difference in the response of Lucilia to semiochemicals with a higher proportion of females attracted than males and a higher proportion of gravid than non-gravid females. While the mechanisms of host location by Lucilia are of intrinsic interest, understanding the responses to semiochemicals is important in the attempt to develop powerful synthetic baits for deployment with the traps or targets used for population sampling or suppression. The literature is discussed with respect to the development of synthetic semiochemical baits.     

Effects of cyromazine on reproduction and offspring development in Lucilia cuprina (Diptera: Calliphoridae).

The effects of cyromazine on reproduction and subsequent hatch and larval developmental in Lucilia cuprina (Wiedemann) were examined by feeding the compound in water to adult flies at concentrations up to 100 ppm. Cyromazine did not interfere with oviposition or hatch; however, subsequent larval development was strongly inhibited in a concentration-dependent manner.     

The sheep antibody response to repeated infection with Lucilia cuprina.

, , and 1992. The sheep antibody response to repeated infection with Lucilia cuprina. International Journal for Parasitology 22: 1169–1174. The specific serum antibody responses of sheep exposed to 10 consecutive infections of L. cuprina have been analysed by enzyme-linked immuno-sorbent assay and immunoblotting using monoclonal antibodies specific for sheep immunoglobulin isotypes. Recognition of a number of larval excretory-secretory products by IgM antibodies appeared to be non-specific. IgG₁ was the major antibody class stimulated by the infection protocol and marked increases in antibody to specific excretory-secretory antigens were observed. Three molecules of 35, 30 and 25 kDa were particularly recognized although the extent of recognition of these molecules varied considerably between individual sheep serum. A pooled serum composed of sera collected after five to seven infections significantly inhibited larval growth in in vitro cultures when compared to a sera pool consisting of sera collected both prior to infection and after infections 1 and 2. The degree of inhibition was greater when serum with high specific antibody titre was used.     

Identification and characterization of proteins from Bacillus thuringiensis with high toxic activity against the sheep blowfly, Lucilia cuprina

Current control of the sheep blowfly (Lucilia cuprina) relies on chemical insecticides, however, with the development of resistance and increasing concerns about human health and environmental residues, alternative strategies to control this economically important pest are required. In this study, we have identified several isolates of Bacillus thuringiensis (Bt), collected from various Australian soil samples, that produce crystals containing 130 and 28 kDa proteins. These isolates were highly toxic to feeding larvae in both in vitro bioassays and in vivo on sheep. By N-terminal amino acid sequencing, we identified the smaller crystal band (28 kDa) as a cytological (Cyt) protein. Upon solubilization and proteolytic processing by trypsin, the 130 kDa crystal protein yielded among others, a truncated 55-60 kDa toxin moiety which exhibited larvicidal activity against sheep blowfly. The amino-terminal sequence of the trypsin-resistant protein band revealed that this Bt endotoxin was encoded by a new cry gene. The novel cry protein was present in all the strains that were highly toxic in the larval assay. We have also identified from one of the isolates, a novel secretory toxin with larvicidal activity.     

Purified glutathione S-transferases from parasites as candidate protective antigens.

Glutathione S-transferase (GST) activity was detected in larvae of the Australian sheep blowfly Lucilia cuprina, and in the nematode Haemonchus contortus. A specific inhibitor of the enzyme was shown to affect survival of both species of parasite in vitro. GST from both parasites has been purified and partially characterized. Antisera raised to the purified enzymes were shown to inhibit the enzyme activity in vitro. However, the antisera had no effect on the survival of either parasite.     

Prasinons A and B: Potent Insecticides from Streptomyces prasinus

Two metabolites which have high activity against sheep blowfly larvae (Lucilia sericata and L. cuprina) were found to be produced by Streptomyces prasinus NCIB 10719. These substances were isolated from culture filtrate by solvent extraction and chromatography and named prasinons A and B. Fermentation factors affecting the formation of these substances are described together with their physical, chemical, and biological properties.     

Secretion of the type 2 peritrophic matrix protein, peritrophin-15, from the cardia

The midgut of most insects is lined with a peritrophic matrix, which is thought to facilitate digestion and protect the midgut digestive epithelial cells from abrasive damage and invasion by ingested micro-organisms. The type 2 peritrophic matrix is synthesised by a complex and highly specialised organ called the cardia typically located at the junction of the cuticle-lined foregut and midgut. Although the complex anatomy of this small organ has been described, virtually nothing is known of the molecular processes that lead to the assembly of the type 2 peritrophic matrix in the cardia. As a step towards understanding the synthesis of the peritrophic matrix, the synthesis and secretion of the intrinsic peritrophic matrix protein, peritrophin-15 has been followed in the cardia of Lucilia cuprina larvae using immuno-gold localisations. The protein is synthesised by cardia epithelial cells, which have abundant rough endoplasmic reticulum, Golgi, and vesicles indicative of a general secretory function. Peritrophin-15 is packaged into secretory vesicles probably produced from Golgi and transported to the cytoplasmic face of the apical plasma membrane. The vesicles fuse with the plasma membrane at the base of the microvilli and release peritrophin-15 into the inter-microvilli spaces. The protein then becomes associated with the nascent peritrophic matrix, which lies along the tips of the epithelial cell microvilli. It is proposed that peritrophin-15 binds to the ends of chitin fibrils present in the nascent peritrophic matrix, thereby protecting the fibril from the action of exochitinases.     

Time resources and population dynamics in insects

An account is given of the way the temperature-mediated processes of development and locomotor activity in insects interact with the availability of essential resources to reduce lifetime fecundity below the potential predicted from laboratory performance. Current work on the sheep blowfly, Lucilia cuprina, is used to illustrate the points made wherever possible. Brief reviews of the ecologically important relationships between rate of development and temperature and level of activity and temperature are presented. The ways in which such laboratory-derived relationships may be applied in the interpretation of field results are described and discussed. The notions of time as a resource and of protein-food, mates and oviposition sites as limiting resources are presented and these provide the basis of a time/resource/fecundity mechanism limiting reproductive performance during the life-time of a female insect. Field and laboratory data are used to show the potentiality of such a mechanism for reducing life-time fecundity in the sheep-blowfly.