Binding sites for human interferon-gamma in protocerebrum and hemolymph of tobacco hornworm (Manduca sexta) larvae differ in sensitivity to polycationic peptides

We have recently characterized specific binding sites for human interferon-gamma on particulates prepared from the protocerebrum and hemolymph of tobacco hornworm larvae, Manduca sexta ?(Parker, M.S., Ourth, D.D., 1999. Comp. Biochem. Physiol. B 122, 155-163). The sensitivity to sulfated polysaccharides indicated an involvement of oligobasic epitopes of hIFN-gamma in the binding. In the present study, we found that polycationic peptides inhibited the binding of [125I]hIFN-gamma to particulates from either the hemolymph or the protocerebrum of Manduca sexta larvae. With amino acid homopolymers, the rank order of potency was poly-L-lysine > poly-L-arginine > poly-L-ornithine, while the acidic side chain polymer poly-L-aspartate was not inhibitory. However, the potency of all polycationic peptides was at least three-fold greater at the hemolymph particulates. Also, acidic polysaccharides such as heparin were much more efficacious in the inhibition of hIFN-gamma binding to hemolymph relative to protocerebral particulates. The peptide polycations inhibited the binding of [125I](Leu31,Pro34)human peptide YY, a ligand selective for the Y1 subtype of the neuropeptide Y receptor, to rabbit kidney or to parietal cortex particulates with the expected rank order of poly-L-arginine > poly-L-lysine > poly-L-ornithine, and with little cross-tissue difference in affinity. The selectivity observed with M. sexta particulates indicates a preferential involvement of oligobasic lysine-rich C-terminal sequences of IFN-gamma, while large insect tissue-related affinity differences point to involvement of diverse oligoacidic sequences in binding to protocerebrum and hemolymph sites. This study provides evidence for the presence of molecules in lepidopteran larvae that are similar in structure to vertebrate co-receptors of IFN-gamma, and adds to the characterization of these binding sites.     

Biological activity of Manduca sexta paralytic and plasmatocyte spreading peptide and primary structure of its hemolymph precursor

A family of hemolymph peptides was previously identified in several lepidopteran insects, which exhibited multiple biological activities including rapid paralysis, blockage of growth and development, or stimulation of plasmatocyte spreading and aggregation. We synthesized Manduca sexta paralytic peptide 1 (PP1) and found that after it was injected into larvae, bleeding from wounds was dramatically reduced. PP1 also stimulated spreading and aggregation behavior of M. sexta plasmatocytes in vitro. Stimulation of plasmatocyte aggregation and adherence to the body wall may explain a decrease observed in the number of circulating plasmatocytes after injection of PP1. Such aggregates might rapidly form plugs in wounds to prevent bleeding. We cloned a cDNA for a Manduca paralytic peptide precursor, using polymerase chain reactions and cDNA library screening. The active 23-residue PP2 peptide encoded by this clone is at the carboxyl-terminal end of a precursor protein predicted to be 107 amino acid residues long after cleavage of a secretion signal peptide. Active PP2 was produced by processing of recombinant proPP2 by bovine factor X_a. A single proPP2 mRNA was present in fat body but not in hemocytes. The level of this mRNA was not affected by injection of bacteria into larvae. We produced recombinant proPP2 in Escherichia coli and used this protein to produce an antiserum. The antiserum detected proPP2 in plasma and was used to observe rapid proteolytic processing of proPP2 after hemolymph collection.     

Structure of a paralytic peptide from an insect, Manduca sexta.

Paralytic peptide 1 (PP1) from a moth, Manduca sexta, is a 23-residue peptide (Glu-Asn-Phe-Ala-Gly-Gly-Cys-Ala-Thr-Gly-Tyr-Leu-Arg-Thr-Ala-Asp-Gly-Arg -Cys-Lys-Pro-Thr-Phe) that was first found to have paralytic activity when injected into M. sexta larvae. Recent studies demonstrated that PP1 also stimulated the spreading and aggregation of a blood cell type called plasmatocytes and inhibited bleeding from wounds. We determined the solution structure of PP1 by two-dimensional 1H NMR spectroscopy to begin to understand structural-functional relationships of this peptide. PP1 has an ordered structure, which is composed of a short antiparallel beta-sheet at residues Tyr11-Thr14 and Arg18-Pro21, three beta turns at residues Phe3-Gly6, Ala8-Tyr11 and Thr14-Gly17, and a half turn at the carboxyl-terminus (residues Lys20-Phe23). The well-defined secondary and tertiary structure was stabilized by hydrogen bonding and side-chain hydrophobic interactions. In comparison with two related insect peptides, whose structures have been solved recently, the amino-terminal region of PP1 is substantially more ordered. The short antiparallel beta-sheet of PP1 has a folding pattern similar to the carboxyl-terminal subdomain of epidermal growth factor (EGF). Therefore, PP1 may interact with EGF receptor-like molecules to trigger its different biological activities.     

Larval and pupal induction and N-terminal amino acid sequence of lysozyme from Heliothis virescens

Fifth instar larvae and prepupae of Heliothis virescens (tobacco budworm) were injected with live Enterobacter cloacae and bled at different times after vaccination. Immune pupal hemolymph showed a 54 times increase in lysozyme activity when compared with normal larval hemolymph, and an 11 times increase of lysozyme activity when compared with immune larval hemolymph. Lysozyme activity of the normal pupal hemolymph increased as greatly as did lysozyme activity of the immune larval hemolymph after metamorphosis. The pupal immune response with regard to lysozyme was much greater than the larval immune response in H. virescens. Lysozyme was purified by heat treatment at 100 degrees C and a chromatography series that included reverse-phase HPLC. The molecular mass of H. virescens lysozyme was approximately 16 kDa by SDS-PAGE which is greater than other insect lysozymes and chicken lysozyme. Amino acid sequence of the N-terminus showed that H. virescens lysozyme is 82% homologous with lysozyme of Manduca sexta and Galleria mellonella. CNBr cleavage of H. virescens lysozyme produced 11 and 6 kDa peptide fragments indicating that one methionine was present, which was also supported by amino acid analysis. However, methionine was located at the carboxyl terminal side rather than the N-terminal side as judged by the N-terminal sequences of each peptide fragment. The residue 22 in most lepidopteran lysozymes is methionine, whereas H. virescens lysozyme had a leucine at residue 22. There was an amino acid deletion near the carboxyl terminal side of H. virescens lysozyme as also found in Trichoplusia ni.     

Identification of neuropeptides from brains of larval Manduca sexta and Lacanobia oleracea using MALDI-TOF mass spectrometry and post-source decay

The occurrence of neuropeptides in the brain of larvae of the tobacco hawkmoth, Manduca sexta, and tomato moth, Lacanobia oleracea, was investigated using matrix-assisted laser desorption ionisation-time of flight (MALDI-TOF) mass spectrometry (MS) and post-source decay (PSD). Methanolic extracts of 100 brains separated by reversed-phase high performance liquid chromatography yielded numerous ion peaks, some of which were common to both species. In M. sexta six [M+H](+) ions were in agreement with peptides previously structurally characterised from M. sexta (FLRF-amides I, II and III, M. sexta allatostatin, CAP(2b) and myoinhibitory peptide VI), whereas a further five corresponded to other known lepidopteran peptides (cydiastatins 3 and 4, helicostatins 1 and 6 and helicokinin II). Of these the identities of FLRF-amide I, cydiastatins 3 and 4 and CAP(2b) were confirmed by PSD analysis. Fourteen [M+H](+) ions corresponding to known lepidopteran peptides (FLRF-amide I, cydiastatins 2, 3 and 4, helicostatins 1, 5, 6, 7 and 9, CCAP, CAP(2b), M. sexta allatostatin and myoinhibitory peptide VI) were measured in L. oleracea brain extracts. From this insect, cydiastatins 3 and 4, helicostatin 5 and FLRF-amide I were identified by PSD. These peptides had not previously been structurally characterised from L. oleracea.     

Functional analysis of two lebocin-related proteins from Manduca sexta

Insects produce a group of antimicrobial peptides (AMPs) in response to microbial infections. Most AMPs are synthesized as inactive precursors/pro-proteins and require proteolytic processing to generate small active peptides. Here we report identification and functional analysis of two lebocin-related proteins (Leb-B and Leb-C) from the tobacco hornworm, Manduca sexta. The mRNA levels of Leb-B and Leb-C increased significantly in larval fat body and hemocytes after injection of Escherichia coli, Micrococcus luteus and Saccharomyces cerevisiae. Western blotting using rabbit polyclonal antibody to Leb-B showed accumulation of large protein(s) and small peptide(s) in larval hemolymph after microbial injection. This result and the presence of RXXR motifs in the deduced amino acid sequences led to our postulation that Leb-B/C may be inactive precursors that are processed in larval hemolymph to generate short active peptides. To test this hypothesis, we expressed and purified full-length and various fragments of Leb-B and Leb-C as thioredoxin (TRX) fusion proteins. We found that fusion proteins could be cleaved by induced larval plasma, and the cleavage sites were determined by protein sequencing. Antibacterial activity of peptide fragments was also verified using synthetic peptides, and active M. sexta lebocin peptides were located at the N-termini of Leb-B/C, which are different from Bombyx mori lebocins 1-4 that are located close to the C-termini. In addition, we found that synthetic Leb-B(22-48) peptide not only had higher antibacterial activity but also caused agglutination of E. coli cells. Our results provide valuable information for studying processing of lebocin precursors in lepidopteran insects.     

A hemolymph major anionic peptide, HemaP, motivates feeding behavior in the sweetpotato hornworm, Agrius convolvuli

We recently identified a novel feeding-modulating peptide, hemolymph major anionic peptide (HemaP), designated Bommo-HemaP (B-HemaP), from hemolymph of the silkworm Bombyx mori. B-HemaP has a unique biological activity in modulating the regular frequency of feeding motivation, which is accompanied by increased foraging behaviors. To confirm the conservation of the HemaP-regulated feeding mechanism in lepidopteran species, we purified and sequenced two candidate peptides from the hemolymph of larvae of the sweet potato hornworm Agrius convolvuli. Unlike B. mori, A. convolvuli had two forms of HemaP, which were designated Agrco-HemaP-1 (A-HemaP-1) and Agrco-HemaP-2 (A-HemaP-2). The amino acid sequence of A-HemaP-2 was identical with that of A-HemaP-1, except for O-glycosylation on the fifth amino acid, threonine, within the N-terminal region. The amino acid sequence of A-HemaP-1/A-HemaP-2 had only 32% identity with B-HemaP. Structural analysis revealed that the carbohydrate moiety of A-HemaP-2 was an α-GalNAc residue. Injection of A-HemaP-1, A-HemaP-2 and recombinant A-HemaP-1 (rA-HemaP-1) individually caused a significant increase in foraging behaviors in A.?convolvuli larvae, and no significant differences were observed among these three A-HemaPs. The CD spectra of these three A-HemaPs were quite similar, and all had α-helix-rich secondary structures. Although A-HemaP-1 and B-HemaP did not exhibit cross-reactivity at any injection doses examined, HemaP might be a conserved molecule among lepidopteran species that can modulate feeding motivation through the fluctuation of peptide levels in hemolymph.     

Isolation and characterization of bacteria-induced protein P4 from hemolymph of Manduca sexta

Insects synthesize several types of hemolymph proteins in response to bacterial infection. The objective of this study was to characterize a 48,000 dalton hemolymph protein induced in larvae of Manduca sexta after injection of bacteria. The protein, isolated by cation exchange and gel filtration chromatography from hemolymph of larvae injected with Micrococcus lysodeikticus, was found to be a glycoprotein with pI = 8.4. The molecular weight, isoelectric point, amino acid composition, and NH2 terminal sequence of the protein are similar to bacteria-induced protein P4 from Hyalophora cecropia, and the M. sexta protein is also designated P4. The hemolymph concentration of M. sexta P4 (35 +/- 7 micrograms/ml in day 3 fifth instar larvae) increases 30- to 45-fold by 48 h after injection of bacteria, but it does not increase in response to injection of distilled water. Lower levels of induction occur after injection of peptidoglycan fragments, zymosan, and lipopolysaccharide. The properties of M. sexta P4 are very similar to those of a previously characterized M. sexta hemolymph protein known as postlarval protein, and antibodies against P4 bind to post-larval protein.     

Isolation and structure determination of a paralytic peptide from the hemolymph of the silkworm, Bombyx mori.

A peptide with paralytic activity in larvae of the silkworm, Bombyx mori, was isolated from its hemolymph. Purification procedures consisted of extraction with 50% acetone, Vydac C4 reversed-phase cartridge elution and 4 steps of reversed-phase HPLC. Injection of the purified peptide into 4th instar B. mori larvae caused rapid and rigid paralysis for 2 min at a dose of 3.4 ng/larva. This paralytic peptide consists of 23 amino acid residues containing 2 cysteines with an intra-disulfide bond. The complete amino acid sequence is: H-Glu-AsnPhe-Val-Gly-Gly-Cys-Ala-Thr-Gly-Phe-Lys-Arg-Thr-Ala-Asp-G ly-Arg-Cys-Lys-Pro-Thr-Phe-OH. The relationship between structure and the biologic activity of synthetic analogs indicated that the entire amino acid sequence and the intra-disulfide bond were necessary for biological activity.     

Bacteria-induced protein P4 (hemolin) from Manduca sexta: a member of the immunoglobulin superfamily which can inhibit hemocyte aggregation.

The synthesis of a number of hemolymph proteins is induced in insects in response to bacterial infections. The major induced hemolymph protein in larvae of Manduca sexta is a glycoprotein of Mr = 48,000 known as P4. We have isolated a clone for P4 from a fat body cDNA library constructed from RNA isolated from larvae injected with bacteria. The cDNA has an open reading frame encoding a 411 residue polypeptide with a hydrophobic NH2-terminal sequence, which appears to be a signal peptide. Analysis of the deduced amino acid sequence shows that P4 is a member of the immunoglobulin (Ig) gene superfamily, and is composed largely of four C2 type Ig domains. The M. sexta P4 amino acid sequence is 60% identical with hemolin (P4) from Hyalophora cecropia. The name "hemolin" has also been adopted for the M. sexta P4 protein. Hemolin mRNA levels in fat body begin to increase within 1 h after injection of bacteria into fifth instar larvae and within 4 h after injection of adults. Hemolin associates with the surface of hemocytes and inhibits hemocyte aggregation responses, suggesting a role for the protein in modulating hemocyte adhesion during recognition and response to bacterial infections in insects.     

Purification and cDNA Cloning of Lysozyme II from Cabbage Butterfly, Artogeia rapae Larvae

ABSTRACT Last instar larvae of cabbage butterfly Artogeia rapae respond to injection of bacteria with a set of inducible antibacterial peptides/proteins. The inducible peptides/proteins are related to the known hinnavins (I and II) and lysozymes (I and II). The lysozyme II has been isolated by heat treatment, cation exchange, and reversed-phase chromatography from immunized hemolymph of last instar larvae. The lysozyme II gene of A. rapae was isolated and its nucleotide sequence was determined by the RACE-PCR from immunized fat body with E. coli. It has an open reading frame of 414 bp nucleotide corresponding to 138 amino acids including an 18 amino acid signal sequence. The molecular weight and the isoelectric point of Artogeia lysozyme II without a signal peptide were 13,649.38 Da and 9.11, respectively. It is great similarity with Manduca lysozyme among other lepidopteran.     

Activation of the silkworm cytokine by bacterial and fungal cell wall components via a reactive oxygen species-triggered mechanism

The insect cytokine paralytic peptide (PP) induces muscle contraction in silkworm larvae. Here we demonstrate that bacterial and fungal cell wall components peptidoglycan and glucan stimulate muscle contraction via activation of PP in the hemolymph. Anti-PP antibody suppressed the muscle contraction induced by PP, peptidoglycan, or glucan. The contraction was also inhibited by free radical scavengers and serine protease inhibitors. Moreover, injecting live silkworms with peptidoglycan or glucan generated the active form of PP. The active form of PP was also produced in vitro when peptidoglycan or glucan was incubated with hemolymph containing the PP precursor. Generation of the active form of PP was suppressed by free radical scavengers and serine protease inhibitors. Furthermore, PP activation in isolated hemolymph was inhibited by potassium cyanide, suggesting that cellular activity is involved. Stimulation by peptidoglycan promoted the generation of reactive oxygen species by silkworm hemocytes. The addition of either the active form of PP or anti-PP antibody to Staphylococcus aureus injected into silkworm larvae delayed or enhanced, respectively, the killing effect of S. aureus, suggesting that activated PP contributes to host resistance to infectious pathogens. These findings suggest that immunologic stimulants such as peptidoglycan or glucan induce reactive oxygen species production from larval hemocytes, followed by the activation of serine protease, which mediates the PP processing reaction and leads to defensive responses.     

Neuropeptides associated with the frontal ganglion of larval Lepidoptera

The occurrence of neuropeptides in the frontal ganglia of larvae of the tobacco hawkmoth, Manduca sexta, the tomato moth, Lacanobia oleracea and the cotton leafworm, Spodoptera littoralis was investigated using reversed-phase high performance liquid chromatography (RP-HPLC), matrix-assisted laser desorption time of flight mass spectrometry (MALDI-TOF MS) and enzyme-linked immunosorbent assay (ELISA). Only three types of peptides could be identified or assigned from frontal ganglion extracts; M. sexta allatostatin (Manse-AS), M. sexta allatotropin (Manse-AT), and F/YXFGL-NH2 allatostatins. The peptide profiles of frontal ganglion of L. oleracea and S. littoralis were similar, with ten identical [M+H]+ ions, seven of which could be assigned to known lepidopteran peptides (Manse-AT, cydiastatin 2, 3, 4 and helicostatin 1, 5, 9). In addition, mass ions corresponding to helicostatin 7 (which was confirmed by MALDI-post source decay analysis) and Manse-AS were present in frontal ganglia of L. oleracea and helicostatin 6 in frontal ganglia of S. littoralis. Only four mass ions from M. sexta frontal ganglia corresponded to known peptides, cydiastatin 3 and 4, helicostatin 1, and Manse-AT. The only difference between the profiles of frontal ganglia from different stages of L. oleracea were mass ions which could not be assigned, and no differences were observed in the allatoregulatory peptides present. In HPLC fractions of M. sexta frontal ganglia, F/YXFGL-NH2 allatostatin-like immunoreactivity was widespread suggesting that more allatostatins were present than were identified.     

Adipokinetic hormones (AKHs) of sphingid Lepidoptera, including the identification of a second M. sexta AKH

The adipokinetic hormones (AKHs) from the corpora cardiaca (CC) of representative species from all three subfamilies of the Sphingidae (hawkmoths) were investigated using matrix-assisted laser desorption-ionization time-of-flight (MALDI-TOF) and liquid chromatography electrospray ion trap mass spectrometry (LC-ESI MS), including a re-examination of the AKH complement of the tobacco hawkmoth, Manduca sexta. In addition to larvae and adults of M. sexta (subfamily: Sphinginae), adults from the following subfamilies were examined: Macroglossinae (large elephant hawkmoth, Deilephila elpenor), Smerinthinae (poplar hawkmoth, Laothoe populi and eyed hawkmoth, Smerinthus ocellata), and Sphinginae (death's head hawkmoth, Acherontia atropos). All moths are shown to have the nonapeptide Manse-AKH (pELTFTSSGWamide) in their CC, together with a second AKH, which, on the basis of mass ions ([M+Na](+), [M+K](+)) and partial sequence analysis is identical in all species examined. The structure of this AKH was elucidated from peptides leached out of the CC of adult M. sexta and shown, by ESI-collision-induced dissociation (CID) tandem mass spectrometry (MS/MS), to be a novel decapeptide AKH with a sequence of pELTFSSGWGQamide. The new peptide has been code named Manse-AKH-II. Sequence confirmation was obtained from identical MS studies with synthetic Manse-AKH-II and with the native peptide. Manse-AKH-II has significant lipid-mobilizing activity when injected at low dose (5pmol) into newly emerged adult M. sexta. The potential implications of a second AKH, in M. sexta in particular, are discussed in relation to putative receptor(s).     

Plasmatocyte spreading peptide (PSP1) and growth blocking peptide (GBP) are multifunctional homologs

Recently, we identified Plasmatocyte spreading peptide (PSP1) from the moth Pseudoplusia includens and reported that it mediates adhesion of hemocytes to foreign surfaces. PSP1 is structurally very similar to three classes of peptides identified earlier from other species of Lepidoptera: growth blocking peptide (GBP) originally identified in Pseudaletia separata, and a series of related peptides from other species designated as paralytic (PP) or cardioactive (CAP) peptides. In this study, we conducted parallel experiments in P. includens and P. separata to determine whether PSP1 and GBP have distinct or multiple biological activities. Both peptides affected the adhesive state of hemocytes from each moth very similarly. PSP1 and GBP exhibited significant growth blocking and paralytic activity in P. separata. Both peptides also had growth blocking activity in P. includens although larvae had to be injected with higher doses of each peptide to reduce weight gain than was observed for P. separata. However, GBP and PSP1 had little paralytic activity in P. includens. Collectively, our results indicate that GBP and PSP1 are multifunctional, but that some interspecific variation also exists in their growth blocking and paralytic activities. We suggest that all PSP1, GBP, PP and CAP family members are homologs that likely have multiple biological activities. Based upon the unique consensus sequence of their N termini, we propose that these molecules be henceforth referred to as members of the "ENF" peptide family.     

Survival and differential development of Entomophaga maimaiga and Entomophaga aulicae (Zygomycetes: Entomophthorales) in Lymantria dispar hemolymph

The closely related entomophthoralean fungi Entomophaga aulicae and E. maimaiga are both host-specific pathogens of lepidopteran larvae. However, these fungi do not have the same host range. The first objective of this study was to compare the fate of E. aulicae in the nonpermissive host Lymantria dispar with the fate of the successful pathogen E. maimaiga over the same time period. In the hemolymph of L. dispar injected with E. maimaiga protoplasts, the number of hemocytes demonstrated a decreasing trend after the first day postinjection and hemocytes completely disappeared by day 5, with the majority of larvae dying in 5.6 +/- 0.1 days. In L. dispar larvae, E. maimaiga infections developed successfully, evidenced by increasing numbers of protoplasts and hyphal bodies prior to host mortality. In contrast, at day 5 hemocytes were readily visible in hemolymph of E. aulicae-injected larvae, but E. aulicae cells did not increase in numbers, although persisting in the hemolymph for at least 16 days postinjection. For both fungal species, when hemolymph samples from injected insects were introduced to culture media viable fungal cultures were always produced. Both E. aulicae and E. maimaiga occurred in hemolymph initially after injection as protoplasts. For E. maimaiga, after day 3, <50% of fungal cells were hyphal bodies until insect death when most cells regenerated cell walls. For E. aulicae, from day 2 equal numbers of fungal cells in the hemolymph occurred as protoplasts and hyphal bodies. To investigate the cause of fungistasis in E. aulicae-injected larvae, E. aulicae cell cultures exposed to partially purified protein fractions from hemolymph of larvae infected with either fungus displayed increased lysis and decreased viability at lower concentrations of protein fractions compared with E. maimaiga cell cultures. These studies demonstrate that E. aulicae does not increase in L. dispar hemolymph, although it persists and results suggest that proteinaceous factors induced within the hemolymph may limit the capacity of E. aulicae to develop successful infections.     

The role of allatostatic and allatotropic neuropeptides in the regulation of juvenile hormone biosynthesis in Lacanobia oleracea (Lepidoptera: Noctuidae)

In the sphinghid moth Manduca sexta, two allatoactive neuropeptides appear to be responsible for regulating juvenile hormone (JH) production by the corpora allata (CA). These peptides (M. sexta allatostatin, Mas-AS, and M. sexta allatotropin, Mas-AT) respectively inhibit and stimulate in vitro JH biosynthesis by CA in this insect. However, although Mas-AS inhibits CA in both larval and adult insects, Mas-AT is active only in adult M. sexta. The situation in other lepidopteran species is less clear-cut and, although both peptides have been detected (usually by immunologic and/or molecular techniques) in several other moths (including noctuids), their function as regulators of JH production remains uncertain. In the tomato moth Lacanobia oleracea (Lepidoptera: Noctuidae), we have previously demonstrated the occurrence of Mas-AS and/or Mas-AT in extracts of CA, brain and other organs, and have shown that both peptides are present in larval and adult forms. However, in L. oleracea, although Mas-AS inhibits larval and adult CA in vitro, it does so only at relatively high concentrations, and to a maximum of only approximately 70%. By contrast, Mas-AT (which is also present in larval and adult L. oleracea) stimulates larval and adult CA, but is substantially more potent ( approximately 100 fold) than the allatostatin. In this paper we present the results of paired, concurrent measurements (using ELISA) of levels of Mas-AS and Mas-AT in brains, CA and hemolymph (plasma and hemocytes) of L. oleracea at times when there are marked changes in JH titers. We also present data on the in vitro rates of JH biosynthesis by isolated CA, and on hemolymph JH esterase activity measured at the same critical developmental times, and discuss all of these data in relation to the putative allatoregulatory roles of the M. sexta allatotropic and allatostatic neuropeptides in L. oleracea.     

Antimicrobial factors of hemolymph and excretion of larvae Lucilia sericata (meigen) (diptera, calliphoridae)

The present study deals with molecular nature and peculiarities of functioning of two main protective systems of larvae Lucilia sericata--the antimicrobial compounds of hemolymph and of the excretion released by feeding larvae into environmental. There are identified a number of inducible antibacterial peptides including defensins (3844, 4062, and 4117 Da), P-peptide (3043 Da), and four new polypeptides (3235, 3702, 3746, and 3768 Da) In hemolymph of the larvae submitted to bacterial infestation, by the chromatomasspectrometry methods. The excretion of larvae Lucilia sericata contains peptides analogous or identical to hemolymph antibacterial peptides (diptericins: 8882 Da and 9025 Da), high molecular compounds of peptide nature (6466 Da, 6633 Da, 5772 Da, 8631 Da, etc.) differing from the known hemolymph components and low molecular compounds (130-700 Da). Spectrum of excretion bactericidal activity includes various groups of bacterial including the most actual pathogen from medical point of view--the meticillin-resistant Staphylococcus aureus, unlike the hemolymph that does not have antistaphylococcal activity. The excretion components suppressing growth and development of this staphylococcus are represented by substances of the low molecular nature (from 160 to 1020 Da). The performed studies characterize the strategies used by "surgical maggots" for protection from pathogens and for suppression of microbial competitors and allow better understanding of molecular mechanisms of larval therapy of purulent infectious diseases. These studies in perspective can serve the basis for creation of the principally new drugs for struggle with usual and antibiotics-resistant bacterial infections.     

Venom peptides from solitary hunting wasps induce feeding disorder in lepidopteran larvae

The cell lytic activity and toxicity against lepidopteran larvae of 13 venom peptides (4 OdVPs and 9 EpVPs) from two solitary hunting wasps, Orancistrocerus drewseni and Eumenes pomiformis, were examined with mastoparan as a reference peptide. Of the 13 peptides, 7 were predicted to have α-helical structures that exhibit the typical character of amphipathic α-helical antimicrobial peptides. The remaining peptides exhibited coil structures; among these, EpVP5 possesses two Cys residues that form an internal disulfide bridge. All the helical peptides including mastoparan showed antimicrobial and insect cell lytic activities, whereas only two of them were hemolytic against human erythrocytes. The helical peptides induced a feeding disorder when injected into the vicinity of the head and thorax of Spodoptera exigua larvae, perhaps because their non-specific neurotoxic or myotoxic action induced cell lysis. At low concentrations, however, these helical peptides increased cell permeability without inducing cell lysis. These findings suggest that the helical venom peptides may function as non-specific neurotoxins or myotoxins and venom-spreading factors at low concentrations, as well as preservatives for long-term storage of the prey via antimicrobial, particularly antifungal, activities.     

Isolation and functional characterization of an allatotropin receptor from Manduca sexta

Manduca sexta allatotropin (Manse-AT) is a multifunctional neuropeptide whose actions include the stimulation of juvenile hormone biosynthesis, myotropic stimulation, cardioacceleratory functions, and inhibition of active ion transport. Manse-AT is a member of a structurally related peptide family that is widely found in insects and also in other invertebrates. Its precise role depends on the insect species and developmental stage. In some lepidopteran insects including M. sexta, structurally-related AT-like (ATL) peptides can be derived from alternatively spliced mRNAs transcribed from the AT gene. We have isolated a cDNA for an AT receptor (ATR) from M. sexta by a PCR-based approach using the sequence of the ATR from Bombyx mori. The sequence of the M. sexta ATR is similar to several G protein-coupled receptors from other insect species and to the mammalian orexin receptor. We demonstrate that the M. sexta ATR expressed in vertebrate cell lines is activated in a dose-responsive manner by Manse-AT and each Manse-ATL peptide in the rank order ATL-I > ATL-II > ATL-III > AT, and functional analysis in multiple cell lines suggest that the receptor is coupled through elevated levels of Ca(2+) and cAMP. In feeding larvae, Manse-ATR mRNA is present at highest levels in the Malpighian tubules, followed by the midgut, hindgut, testes, and corpora allata, consistent with its action on multiple target tissues. In the adult corpora cardiaca--corpora allata complex, Manse-ATR mRNA is present at relatively low levels in both sexes.