Parasitoid wasp uses a venom cocktail injected into the brain to manipulate the behavior and metabolism of its cockroach prey

Unlike other venomous predators, the parasitoid wasp Ampulex compressa incapacitates its prey, the cockroach Periplaneta americana, to provide a fresh food supply for its offspring. We first established that the wasp larval development, from egg laying to pupation, lasts about 8 days during which the cockroach must remain alive but immobile. To this end, the wasp injects a cocktail of neurotoxins to manipulate the behavior of the cockroach. The cocktail is injected directly into the head ganglia using biosensors located on the stinger. The head sting induces first 30 min of intense grooming followed by hypokinesia during which the cockroach is unable to generate an escape response. In addition, stung cockroaches survive longer, lose less water, and consume less oxygen. Dopamine contained in the venom appears to be responsible for inducing grooming behavior. For the hypokinesia, our hypothesis is that the injected venom affects neurons located in the head ganglia, which send descending tonic input to bioaminergic neurons. These, in turn, control the thoracic premotor circuitry for locomotion. We show that the activity of identified octopaminergic neurons from the thoracic ganglia is altered in stung animals. The alteration in the octopaminergic neurons' activity could be one of the mechanisms by which the venom modulates the escape circuit in the cockroach's central nervous system and metabolism in the peripheral system.     

Wasp manipulates cockroach behavior by injecting venom cocktail into prey central nervous system

The parasitoid wasp Ampulex compressa induces behavioral changes in the cockroach prey by injecting venom into its central nervous system. In contrast to most other venomous predators, the wasp's sting does not induce paralysis. Rather, the two consecutive stings in the thoracic and head ganglia induce three stereotypic behavioral effects. The prey behavior is manipulated in a way beneficial to the wasp and its offspring by providing a living meal for its newborn larva. The first sting in the thorax causes a transient front leg paralysis lasting a few minutes. This paralysis prevents the cockroach from fighting with its front legs, thereby facilitating the second sting in the head. A postsynaptic block of central synaptic transmission mediates this leg paralysis. Following the head sting, dopamine identified in the venom induces 30 minutes of intense grooming that appears to prevent the cockroach from straying until the last and third behavioral effect of hypokinesia commences. In this lethargic state that lasts about three weeks, the cockroach does not respond to various stimuli nor does it initiates movement. However, other specific behaviors of the prey are unaffected. We propose that the venom represses the activity of head ganglia neurons thereby removing the descending excitatory drive to specific thoracic neurons.     

Interaction of wasp venom mastoparan with biomembranes

Mastoparan-induced changes in the K+ permeability of rat peritoneal mast cells, human erythrocytes, Staphylococcus aureus and Escherichia coli were examined. Mastoparan did not efficiently increase the K+ permeability of cells except for S. aureus. The release of membrane phospholipids was also observed from S. aureus cells in the concentration range of the permeability enhancement. Mastoparan stimulated histamine release from mast cells, independently of a small efflux of K+. Mastoparan became markedly effective to E. coli cells whose outer membrane structure was chemically disrupted beforehand, showing that the peptide can enhance the permeability of the cytoplasmic membranes of both Gram-positive and -negative bacteria. In experiments using liposomes, mastoparan increased the permeability of the liposomes composed of egg phosphatidylethanolamine and egg phosphatidylglycerol, which are the lipid constituents of the cytoplasmic membrane of E. coli cells, while it showed a weak activity to the liposomes composed of egg phosphatidylcholine and cholesterol. The latter result related closely to the fact that this peptide acted weakly on erythrocytes and mast cells in which acidic lipids constitute a minor portion. Mastoparan decreased the phase transition temperature of dipalmitoylphosphatidylglycerol liposomes, but it did not affect that of dipalmitoylphosphatidylcholine liposomes. These results indicate that mastoparan penetrated into membranes mainly containing acidic phospholipids and disrupted the membrane structure to increase the permeability. The action of the wasp venom mastoparan was compared with that of a bee venom melittin.     

Early destruction of cockroach respiratory system and heart by emerald jewel wasp larvae

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Effects of the wasp venom peptide, mastoparan, on a phosphoinositide-specific phospholipase C purified from rabbit brain membranes

The wasp venom peptide, mastoparan (Ile-Asn-Leu-Lys-Ala-Leu-Ala-Ala-Leu-Ala-Lys-Lys-Ile-LeuNH2), activated phosphatidylinositol 4,5-bisphosphate (PIP2) hydrolysis as catalyzed by a phosphoinositide-specific phospholipase C (PLC-Im) purified from rabbit brain membranes. This activation was found when the molar ratio of mastoparan to PIP2 was less than 1 and when the concentration of PIP2 exceeded 10 microM. PIP2 breakdown was inhibited at both high and low substrate concentrations if the molar ratio of mastoparan to PIP2 was greater than 1. The stimulatory effect of mastoparan correlated with its ability to restrict aggregation of PIP2 into higher order structures (liposomes or mixed deoxycholate/phospholipid micelles) as the concentration of PIP2 was increased to 10 microM or greater. Mastoparan stimulation of PIP2 breakdown required the presence of a higher calcium concentration than was necessary for detection of enzyme activity. Both the stimulatory and inhibitory effects of mastoparan on PIP2 hydrolysis were lost if 2.5 mM deoxycholate was present in the assays. Hydrolysis of phosphatidylinositol (PI) by PLC-Im was inhibited at all concentrations of mastoparan tested. These results show that both PIP2 and PI are suitable substrates for PLC-Im, depending on the physical characteristics of their aggregates in aqueous suspension. An amphiphilic alpha-helix-forming peptide such as mastoparan may modulate phospholipase C activity due to the peptide's interaction with phospholipid substrates.     

Analysis of venom constituents from the parasitoid wasp Pimpla hypochondriaca and cloning of a cDNA encoding a venom protein

Venom from Pimpla hypochondriaca, an endoparasitoid of pupae, was size-fractionated using gel filtration chromatography and analysed by SDS-PAGE in the presence and absence of reducing agent. A complex mixture of more than 20 venom constituents was identified which ranged in M(r) between approximately 5 and 100 kDa. Venom from a wide range of size fractions inhibited the motility of larval haemocytes and prevented the formation of cell aggregates when analysed in vitro, indicating that anti-haemocytic activity is mediated by multiple venom components. Sephadex A25 beads injected into the haemocoel of pupae were encapsulated within 24h. This reaction was abolished when the pupae were injected with 30 microg of venom protein, equivalent to one-fifth of a venom sac, 1h prior to implantation of the beads, confirming that venom suppresses encapsulation in pupae. Using random 5' end sequencing of a P. hypochondriaca venom gland cDNA library, we have isolated a cDNA encoding a 25.3 kDa protein containing a signal peptide and having sequence similarity to serine proteases. The N-terminal sequence of six residues from two venom proteins of 28 and 30 kDa was the same and identical to amino acids encoded by the cDNA, confirming that two mass forms of the protein are secreted into the venom sac. The N-terminal sequence of both venom proteins began nine residues towards the C terminus following the predicted signal sequence cleavage site, suggesting that the proteins are proteolytically processed before or during storage in the venom sac. The general applicability of using random 5' sequencing to identify cDNAs encoding secretory products is discussed.     

Characterization of a venom gland-associated rhabdovirus in the parasitoid wasp Diachasmimorpha longicaudata

Parasitoid wasps reproduce by laying their eggs on or inside of a host insect, which triggers a defense response in the host insect that kills the developing wasp. To counteract the host’s lethal response, some parasitoid wasps are associated with symbiotic viruses that alter host metabolism and development to promote successful development of the wasp embryo. These symbiotic viruses display a number of characteristics that differ from those of pathogenic viruses, but are poorly understood with the exception of one group, the polydnaviruses. Here, we characterize the genome of a non-polydnavirus associated with parasitoid wasps, Diachasmimorpha longicaudata rhabdovirus (DlRhV), and assess its role as a potential mutualistic virus. Our results show that the DlRhV genome contains six open reading frames (ORFs). Three ORFs show sequence homology to known viral genes and one ORF encodes a previously identified protein, called parasitism-specific protein 24 (PSP24), that has been hypothesized to play a role in promoting successful parasitism by D. longicaudata. We constructed a phylogeny that shows that DlRhV is most closely related to other insect-infecting rhabdoviruses. Finally, we report that DlRhV infection does not occur in all populations of D. longicaudata, and is not required for successful parasitism.     

Insensitivity of the spider heart to solitary wasp venom

• 1.1. The heart and associated tissues of spiders that had been stung by a mud-dauber wasp were examined for responses to the toxin. Microelectrode recordings of myocardial cell membrane depolarizations were obtained from spontaneously beating hearts in situ. Transmission electron microscopic examination was made of the cardiac ganglion, myocardium and hemocytes.
• 2.2. The myocardial cell depolarizations in paralyzed and unparalyzed spiders were 20–40 mV in amplitude and 300–500 msec in duration. The depolarizations did not display an overshoot, and individual excitatory synaptic potentials were seen in the responses. Therefore, the normal electrical events in the heartbeat, which is neurogenic, were not interrupted by the toxin.
• 3.3. No alteration in the ultrastructure of the cardiac ganglion, neuromuscular synapses, myocardial cells or hemocytes was apparent in the material obtained from paralyzed spiders.

     

A parasitoid wasp manipulates the drive for walking of its cockroach prey

The parasitoid wasp A. compressa hunts cockroaches as a live food supply for its offspring. The wasp selectively injects venom into the cerebral ganglia of the prey to induce long-term hypokinesia [1-5], during which the stung cockroach, although not paralyzed, does not initiate spontaneous walking and fails to escape aversive stimuli. This allows the wasp to grab the cockroach by the antenna and walk it to a nest much like a dog on a leash. There, the wasp lays an egg on the prey, seals the nest, and leaves. The stung cockroach, however, does not fight to escape its tomb but rather awaits its fate, being consumed alive by the hatching larva over several days. We investigated whether the venom-induced hypokinesia is a result of an overall decrease in arousal or, alternatively, a specific decrease in the drive to initiate or maintain walking. We found that the venom specifically affects both the threshold for the initiation and the maintenance of walking-related behaviors. Nevertheless, the walking pattern generator itself appears to be intact. We thus report that the venom, rather than decreasing overall arousal, manipulates neuronal centers within the cerebral ganglia that are specifically involved in the initiation and maintenance of walking.     

Effect of black widow spider venom on the cockroach heart

The effect of black widow spider venom [crude gland extract (CGE), gland lumen venom (GLV), or from direct bite] on the cardiac activity of Periplaneta americana was assayed both in vivo and in vitro. It was shown that these different forms of venom in all cases blocked the cockroach heart-beat. Both CGE and GLV showed a selective activity on the heart function compared with their effect on the CNS. It is suggested that cardiac block is due to impairment of either the cardiac nerve ganglia function or the myocardial neuromuscular junctions, or of both of them. The mode of action of the toxic effects on the heart is discussed. Experiments with antiserum from CGE indicate that the antigenic fractions of CGE and GLV affecting the heart function, as well as those affecting the insect motor functions, are common to both toxic materials.     

Mastoparan, a wasp venom, activates platelets via pertussis toxin-sensitive GTP-binding proteins

Mastoparan induced limited release of serotonin from intact human platelets, while neither intracellular calcium ion elevation nor arachidonic acid mobilization was observed. Cytolysis induced by mastoparan was negligible in the concentration range that induced serotonin release. In digitonin-permeabilized cells, mastoparan induced Ca(++)-independent release of serotonin and Ca(++)-dependent arachidonic acid release. Both serotonin release and arachidonic acid release were reduced by pertussis toxin, suggesting that platelet activation induced by mastoparan is mediated by GTP-binding proteins.     

Ion channel block in rat diaphragm by the venom of the digger wasp Philanthus triangulum

In the rat phrenic nerve-diaphragm preparation the twitch tension and tetanic contractions, already reduced by d-tubocurarine, succinylchloride or neostigmine, are further reduced by the venom of the digger wasp Philanthus triangulum F. The venom reduces the temperature- and voltage-sensitivity of the acetylcholine-receptor-activated ion channels, at the motor end-plate, and shortens the decay time of the miniature end-plate currents, analogous to a block described for the purified toxin, delta-PTX, on insect glutamate-activated channels. Preliminary results show that delta-PTX has an effect similar to that of the total venom on the decay phase of miniature end-plate currents.     

Suppression of the stored-product pest Sitophilus zeamais (Coleoptera: Curculionidae) by simultaneous release of a predatory bug and a parasitoid wasp

The control of the maize weevil, Sitophilus zeamais in brown rice was estimated by using a reduviid bug, Amphibolus venator, and a pteromalid wasp, Theocolax elegans. Results showed that the simultaneous release of both species of natural enemies could enhance biological control compared with the release of either species alone.     

Mastoparan, a wasp venom, stimulates insulin release by pancreatic islets through pertussis toxin sensitive GTP-binding protein

A wasp venom, mastoparan, rapidly stimulated insulin release by rat pancreatic islets in a dose-related manner. The amount of insulin released in response to 58 microM mastoparan far exceeded that induced by 27.8 mM glucose. Mastoparan stimulated insulin release to similar degrees at ambient glucose concentrations of 1.7 mM and 5.6 mM. The islets obtained from pertussis toxin-treated rats showed unequivocally less response to mastoparan. Pretreatment of islets with bromophenacyl bromide, a phospholipase A2 inhibitor, abolished their responsiveness to mastoparan. Pretreatment of islets with nifedipine, a Ca2+ channel blocker, was without effect. Mastoparan is a unique stimulator of insulin release by the pancreatic islets, which acts through GTP-binding protein(s) and phospholipase A2.     

Localization of the site of effect of a wasp's venom in the cockroach escape circuitry

The parasitic wasp Ampulex compressa stings a cockroach Periplaneta americana in the neck, toward the head ganglia (the brain and subesophageal ganglion). In the present study, our aim was to identify the head ganglion that is the target of the venom and the mechanisms by which the venom blocks the thoracic portion of the escape neuronal circuitry. Because the escape responses elicited by a wind stimulus in brainless and sham-operated animals were similar, we propose that the venom effect is on the subesophageal ganglion. Apparently, the subesophageal ganglion modulates the thoracic portion of the escape circuit. Recordings of thoracic interneuron responses to the input from the abdominal giant interneurons showed that the thoracic interneurons receive synaptic drive from these interneurons in control and in stung animals. Unlike normal cockroaches, which use both fast and slow motoneurons for producing rapid escape movements, stung animals activate only the slow motoneuron. However, we show that in stung animals, the fast motoneuron still can be recruited with bath application of pilocarpine, a muscarinic agonist. These results indicate that the descending control from the subesophageal ganglion is presumably exerted on the premotor thoracic interneurons to motoneurons connection of the thoracic escape circuitry. Accepted: 19 December 1998     

Kinetics of plasma cytokine levels in children hyposensitized with wasp venom

Specific immunotherapy shifts immune responses towards a Th0/Th1 response. Production of chemokines is also decreased early after the initiation of rush venom immunotherapy. We aimed to investigate in vivo whether cytokine plasma levels reflect the shift towards a Th0-Th1 pattern of immune response as seen in vitro in lymphocytes from patients undergoing venom immunotherapy. Therefore, we studied plasma levels of various cytokines before (day 1), during (day 2), and after (day 4) rush immunotherapy in nine wasp-allergic children. The levels of interleukin-5 and IFN-gamma were below the detection threshold. No variations were observed in levels of interleukin-4, interleukin-10, and TNF-alpha. In contrast, mean levels of RANTES transiently increased at day 2, and decreased below the pretreatment levels at day 4. Those alterations were significant in five children with high levels of RANTES at day 1, and reporting severe anaphylaxis. In the four other children, the levels of RANTES were not significantly increased at day 4. These results suggest that RANTES plasma levels are positively correlated with the severity of the reaction to hymenoptera venom, and that a significant decrease in the levels of RANTES occurs only in children with high pretreatment levels. However, the kinetics of RANTES plasma levels correlated neither with the results of allergological tests, nor with the outcome of venom immunotherapy.