Inhibition of PK/PBAN-mediated functions in insects: discovery of selective and non-selective inhibitors

The antagonistic properties of a few linear and backbone cyclic (BBC) conformationally constraint peptide libraries and their analogs, were tested for the ability to inhibit pyrokinin/pheromone biosynthesis activating neuropeptide (PK/PBAN) mediated functions: sex pheromone biosynthesis in Heliothis peltigera female moths, cuticular melanization in Spodoptera littoralis larvae, pupariation in the fleshfly Neobellieria bullata and hindgut contraction in Leucophaea maderae, elicited by exogenously injected PBAN, pheromonotropin (PT), leucopyrokinin (LPK), myotropin (MT) or by the endogenous peptides. The data revealed differential inhibitory patterns within the same assay with different elicitors (in both the pheromonotropic and melanotropic assays) and among the different functions and disclosed selective antagonists, hinting at the possibility that the receptors that mediate those functions may differ from one another structurally.     

Potent activity of a PK/PBAN analog with an (E)-alkene,trans-Pro mimic identifies the Pro orientation and core conformation during interaction with HevPBANR-C receptor

The pyrokinin/pheromone biosynthesis activating neuropeptide (PK/PBAN) family plays a multifunctional role in an array of important physiological processes in insects, including regulation of sex pheromone biosynthesis in moths. A cyclic PK/PBAN analog (cyclo[NTSFTPRL]) retains significant activity on the pheromonotropic HevPBANR receptor from the tobacco budworm Heliothis virescens expressed in CHO-K1 cells. Previous studies indicate that this rigid, cyclic analog adopts a type I β-turn with a transPro over residues TPRL within the core PK/PBAN region. An analog containing an (E)-alkene, trans-Pro mimetic motif was synthesized, and upon evaluation on the HevPBANR receptor found to have an EC₅₀ value that is not statistically different from a parent C-terminal PK/PBAN hexapeptide sequence. The results, in aggregate, provide strong evidence for the orientation of Pro and the core conformation of PK/PBAN neuropeptides during interaction with the expressed PBAN receptor. The work further identifies a novel scaffold with which to design mimetic PBAN analogs as potential leads in the development of environmentally favorable pest management agents capable of disrupting PK/PBAN-regulated pheromone signaling systems.     

Discovery of a linear lead antagonist to the insect pheromone biosynthesis activating neuropeptide (PBAN)

We report the discovery of a linear lead antagonist for the insect pheromone biosynthesis activating neuropeptide (PBAN) which inhibits sex pheromone biosynthesis in the female moth Heliothis peltigera. Two approaches have been used in attempting to convert PBAN agonists into antagonists. The first involved omission of the C-terminal amide and reduction of the sequence from the N-terminus in a linear library based on PBAN 1-33NH(2.) The second involved replacement of L amino-acids by the D hydrophobic amino acid D-Phe in a linear library based on PBAN28-33NH(2.) Screening of the two libraries for pheromonotropic antagonists resulted in the disclosure of one compound out of the D-Phe library (Arg-Tyr-Phe-D-Phe-Pro-Arg-Leu-NH(2)) which inhibited sex pheromone production by 79 and 64% at 100 pmol in two moth colonies and exhibited low agonistic activity. Omission of the C-terminal amide in PBAN 1-33NH(2) and its shorter analogs did not lead to the discovery of an antagonistic compound.     

Role of neuropeptides in sex pheromone production in moths

Sex pheromone biosynthesis in many moth species is controlled by a cerebral neuropeptide, termed pheromone biosynthesis activating neuropeptide (PBAN). PBAN is a 33 amino acid C-terminally amidated neuropeptide that is produced by neuroendocrine cells of the subesophageal ganglion (SEG). Studies of the regulation of sex pheromone biosynthesis in moths have revealed that this function can be elicited by additional neuropeptides all of which share the common C-terminal pentapeptide FXPRL-amide (X = S, T, G, V). In the past two decades extensive studies were carried out on the chemical, cellular and molecular aspects of PBAN and the other peptides (termed the pyrokinin (PK)/PBAN family) aiming to understand the mode of their action on sex pheromone biosynthesis. In the present review we focus on a few of these aspects, specifically on the: (i) structure-activity relationship (SAR) of the PK/PBAN family, (ii) characterization of the PK/PBAN receptor and (iii) development of a novel strategy for the generation of PK/PBAN antagonists and their employment in studying the mode of action of the PK/PBAN peptides.     

Histochemical localization of the PBAN receptor in the pheromone gland of Heliothis peltigera

The presence of the pyrokinin (PK)/ Pheromone biosynthesis activating neuropeptide (PBAN) receptor in pheromone gland cells of Heliothis peltigera females was demonstrated, and its spatial distribution in the ovipositor was visualized with two photo-affinity biotinilated ligands: BpaPBAN1-33NH(2) and BpaArg(27)-PBAN28-33NH(2). Light microscopy histological studies revealed that the gland is contained within the inter-segmental membrane (ISM) between the 8th and 9th abdominal segments. The gland was found to be composed of a single layer of columnar epithelial cells positioned under the inter-segmental cuticle. Similar epithelial cells were also found in the dorsal and ventral regions of the 9th abdominal segment. All regions containing the glandular cells bound both ligands, indicating presence of the PK/PBAN receptor. The patterns obtained with both ligands were similar, hinting at the possibility that either both ligands bind to the same receptor, or, that if there are two distinct receptors, their spatial distribution throughout the gland is very similar.     

Rationally designed neuropeptide antagonists: A novel approach for generation of environmentally friendly insecticides

We report our approach for the generation of a novel type of putative insecticides based on backbone cyclic peptidomimetic antagonists of insect neuropeptides using pheromone biosynthesis activating neuropeptide (PBAN) as a model. This approach, called the backbone cyclic neuropeptide based antagonist (BBC-NBA), includes the following steps: (i) elucidation of the active sequence of the chosen insect neuropeptide; (ii) disclosure of a lead antagonist based on the sequence found in step (i); (iii) design and synthesis of backbone cyclic peptide libraries (cycloscan) based on the sequence of the lead antagonist; and (iv) design and synthesis of a peptidomimetic prototype insecticide. The BBC-NBA approach was applied to PBAN and led to the discovery of a potent linear lead antagonist and a potent backbone cyclic antagonist devoid of agnoistic activity which inhibited sex pheromone biosynthesis inHeliothis peltigera female moths.     

烟实夜蛾性信息素合成激活肽基因的分子克隆

根据家蚕Bombyx mori和玉米夜蛾Helicoverpa zea的性信息素合成激活肽基因序列,设计若干套引物, 以烟实夜蛾Heliothis assulta基因组DNA为模板进行PCR扩增, 得到0.63 kb的特异性DNA片段。该片段克隆进适当载体,序列测定和同源比较, 查明烟实夜蛾的基因组中存在性信息素合成激活肽基因。烟实夜蛾的性信息素合成激活肽由33个氨基酸组成, C末端是FXPRL结构,是目前发现的第4种昆虫性信息素合成激活肽。在该神经肽第14和第15个氨基酸之间, 插入一个0.42 kb的内含子。 进一步的分析证明了烟实夜蛾的性信息素合成激活肽基因在潜成虫期的食道下神经节中表达。     

Structural and functional differences between pheromonotropic and melanotropic PK/PBAN receptors

Background

The pyrokinin/pheromone biosynthesis-activating neuropeptide (PK/PBAN) plays a major role in regulating a wide range of physiological processes in insects. The ubiquitous and multifunctional nature of the PK/PBAN peptide family raises many questions regarding the mechanisms by which these neuropeptides elicit their effects and the nature of the receptors that mediate their functions.

Methods

A sex pheromone gland receptor of the PK/PBAN family from Heliothis peltigera female moth and a Spodoptera littoralis larval receptor were cloned and stably expressed, and their structural models, electrostatic potentials and cellular functional properties were evaluated.

Results

Homology modeling indicated highly conserved amino-acid residues in appropriate structural positions as experimentally shown for class A G-protein coupled receptors. Structural differences could be proposed and electrostatic potentials of the two receptor models revealed net charge differences. Calcium mobilization assays demonstrated that both receptors were fully functional and could initiate extracellular calcium influx to start PK/PBAN signal transduction. Evaluation of the signaling response of both receptors to PBAN and diapause hormone (DH) revealed a highly sensitive, though differential response. Both receptors responded to PBAN whereas only Spl-PK/PBAN-R exhibited a high response toward DH.

Conclusions

The structural, electrostatic and cellular functional differences indicate that different PK/PBAN in vivo functions may be mediated by different PK/PBAN receptors and elicited by different peptide(s).

General significance

The results advance our understanding of the mode of action of the PK/PBAN family, and might help in exploring novel high-affinity receptor-specific antagonists that can serve as a basis for the development of new families of insect-control agents.     

Insect neuropeptide antagonists

The development of a new integrated approach to the generation of a novel type of insect neuropeptide (Np) antagonists and putative insect control agents based on backbone cyclic compounds is described. The approach, termed the backbone cyclic neuropeptide-based antagonist (BBC-NBA), was applied to the insect pyrokinin (PK)/pheromone biosynthesis activating neuropeptide (PBAN) family as a model, and led to the discovery of a potent linear lead antagonist and several highly potent, metabolically stable BBC antagonists, devoid of agonistic activity, which inhibited PBAN-mediated activities in moths in vivo. This review briefly summarizes our knowledge of insect Nps, describes the PK/PBAN Np family, presents the basic concepts behind the BBC-NBA approach, and introduces the advantages of this method for generation of Np agonists, antagonists and insecticide prototype molecules.     

Pheromonotropic stimulation of moth pheromone gland cultures in vitro

The direct neurohormonal control of pheromone biosynthesis by pheromone biosynthesis activating neuropeptide (PBAN) was demonstrated in Helicoverpa (Heliothis) spp. using pheromone gland cultures in vitro. Pheromone gland activation involved the de novo production of the main pheromone component (Z)-11-hexadecenal as revealed by radio-TLC, radio-HPLC, and radio-GC. Activation was found to be a specific response attributed to pheromone gland cultures alone. Specificity of pheromonotropic activation was demonstrated to be limited to nervous tissue extracts. A sensitive and specific radioimmunoassay was developed using [³H]-PBAN, and the spatial and temporal distribution of PBAN-immunore-activity was studied. PBAN-immunoreactivity in brain complexes was found throughout the photoperiod and in all ages. From the distribution of PBAN-immunoreactivity it appears that PBAN release is affected by photoperiod. Pheromone gland cultures were found to be competent to pheromone production irrespective of age and photoperiod. Therefore, the neuroendocrine control of pheromone production operates at the level of neuropeptide synthesis and/or release and not at the level of the target tissue itself. The involvement of cyclic-AMP as a second messenger system was demonstrated. Brain extracts and PBAN were shown to stimulate dose- and time-dependent changes in intracellular cyclic-AMP levels. The role of cyclic-AMP in this mechanism was further verified by the ability of cyclic-AMP mimetics to mimic the pheromonotropic effect of brain extracts and PBAN. However, dose-response studies using PBAN and a hexapeptide C-terminal fragment of PBAN suggested that PBAN induces a two mechanism response, one occurring at low PBAN concentrations (high affinity receptor) and another at higher PBAN concentrations (low affinity receptor). Further evidence indicating a dual receptor system was obtained with the observation that the active phorbol ester (phorbol-12-myristate 13-acetate), the diacyl-glycerol analog (1,2-dioleolyl-sn-glycerol), and the intracellular calcium ionophore (ionomycin) mimicked the physiological action of PBAN and that lithium chloride had a pheromonostatic effect. The results indicate that pheromone glands also possess receptors that are linked to inositol phosphate hydolysis. © 1994 Wiley-Liss, Inc.     

Immunochemical and biological analysis of pheromone biosynthesis activating neuropeptide in Heliothis peltigera.

This study describes the preparation and characterization of a highly specific antiserum to Helicoverpa zea pheromone biosynthesis activating neuropeptide (Hez-PBAN), and the use of this antiserum, in an enzyme linked immunosorbent assay (ELISA), to determine: a) the content of endogenous PBAN in head extracts of male and female Heliothis peltigera; b) the level of PBAN at different developmental stages; and c) the content of PBAN in four different moth species. Cross-reactivity studies revealed that the antiserum is directed mainly toward the N-terminal region of the neuropeptide, and that it exhibits similar binding affinities toward the oxidized and reduced forms of PBAN. Analysis of PBAN content in head extracts of male and female H. peltigera, at scotophase, revealed the presence of 4.97 and 4.58 pmol, respectively, in 3-day-old moths, and 5.33 and 4.78 pmol, respectively, in 7-day-old moths. The similarity in the content of PBAN at both ages and sexes was in accordance with the amount of pheromonotropic activity in these extracts which stimulated pheromone biosynthesis to a similar level. Analysis of PBAN-like immunoreactivity (IR) in head extracts of H. peltigera larvae and pupae demonstrated the existence of the neuropeptide in the 4th larval instar and continued to increase as a function of development. No IR could be detected in the first three larval instars. The larval and pupal extracts also exerted pheromonotropic activity which followed a similar pattern. The activity in these extracts, however, was considerably lower than that found in adult male and female heads. IR was also detected in head extracts of three other Noctuidae moths: Helicoverpa armigera, Cornutiplusia circumflexa and Spodoptera littoralis, indicating a high degree of chemical and structural similarity of PBAN in these moths.     

Effect of synthetic pban and derived peptides on sex pheromone biosynthesis in Heliothis peltigera (Lepidoptera: Noctuidae)

The activity of synthetic Heliothis zea PBAN (Hez-PBAN) and four shorter peptides on the sex pheromone biosynthesis in Heliothis peltigera was investigated in order to characterize their biological potency, and to determine the structure-activity relationship. Hez-PBAN (PBAN 1–33) is very potent and stimulates sex pheromone biosynthesis at the picomolar range both in photophase and scotophase. Removal of eight amino acids from the N-terminal region of the peptide Hez-PBAN had only a minor effect on the biological activity. A shorter fragment of Hez-PBAN, lacking 18 amino acids from the N-terminus, was less active. Two short peptides, consisting of eight and six amino acids, derived from the C-terminal region of Hez-PBAN had very little biological activity. In addition, it was found that PBAN 1–33 undergoes oxidation during storage. The oxidation of the peptide resulted in a loss of its biological activity, which could be restored by reduction with N-methylmercaptoacetamide. Unlike PBAN 1–33, PBAN 9–33 did not lose activity as a function of time, and its activity was fully preserved after prolonged storage. The results indicate that PBAN 1–33 and PBAN 9–33 have similar activities, and that the sequence containing the eight N-terminal amino acids is not essential for the biological activity of Hez-PBAN on the biosynthesis of H. peltigera sex pheromone.     

Hormonal control of female sex pheromone biosynthesis in the redbanded leafroller moth,Argyrotaenia velutinana

Pheromone biosynthesis in female redbanded leafroller moths (RBLR) is under control of a neuropeptide produced in the brain. A bioassay consisting of isolated abdomens was developed to test the mode of action of the pheromone biosynthesis activating neuropetide (PBAN). Pheromone titer and incorporation of radiolabeled acetate into pheromone could be monitored with this bioassay. Synthetic PBAN with sequences identical to PBAN isolated from Heliothis zea and Bombyx mori were active in inducing synthesis of pheromone in RBLR. Removal of the ventral nerve cord in isolated abdomens did not inhibit the action of PBAN. Small amounts of PBAN-like activity was found in hemolymph collected from normal females but not from decapitated females. Severing the VNC in vivo in normal females did not lower the pheromone titer. These data indicate that PBAN is released into the hemolymph and then travels to its site of action. A two-fold increase in both pheromone titer and radiolabeled acetate incorporation upon incubation with PBAN was shown with isolated pheromone glands. However, the differences between control and PBAN-induced values were smaller than those obtained with the isolated abdomen culture bioassay where a seven-fold increase was observed. A decrease in pheromone titer was seen upon the in vivo removal of the corpus bursae from normal females. Removal of the corpus bursae in the isolated abdomen cultures also abolished the activity of PBAN. However, cutting the cervix bursae and leaving the corpus bursae in the abdomen culture increased both titer and radiolabeled acetate incorporation into pheromone without the presence of PBAN. An aqueous extract made from the corpus bursae of 5-day-old females was also active by itself in inducing pheromone biosynthesis in the isolated abdomen cultures. Experiments performed using newly emerged females confirmed that the corpus bursae extracts will induce pheromone biosynthesis. These results indicate that both PBAN and the corpus bursae are involved in controlling pheromone biosynthesis in RBLR.     

A brominated-fluorene insect neuropeptide analog exhibits pyrokinin/PBAN-specific toxicity for adult females of the tobacco budworm moth

An analog of the insect pyrokinin/PBAN class of neuropeptides, which features a 2-amino7-bromofluorene attached to the carboxy-terminal bioactive core of the insect pyrokinin/PBAN class of neuropeptides (Phe-Thr-Pro-Arg-Leu-NH(2)), via a succinnic acid linker, was tested in adult H. virescens moths. This analog was found to induce pheromone production when injected into or applied topically to moths. Topical application of as much as 1 nmol of the analog to moths induced production of significant amounts of pheromone for only 1-2 h, whereas injection of 500 pmol induced pheromone production for up to 20 h. All insects died within 24 h after injection of 500 pmol of the analog. Mortality studies indicated that the LD(50) for the analog was 0.7 pmol when injected. A non-pyrokinin/PBAN peptide analog formed by attachment of 2-amino-7-bromofluorene to Ala-Ala-Arg-Ala-Ala-NH(2) (via the succinnic acid linker) did not induce mortality when injected at 1 nmol. Similarly no mortality was found when up to 2 nmol of an analog containing a non-brominated fluorene ring, formed by attachment of 9-fluoreneacetic acid to Phe-Thr-Pro-Arg-Leu-NH(2,) was injected into moths. The data indicated that both the bromine and active core of the pyrokinin neuropeptides (Phe-Thr-Pro-Arg-Leu-NH(2)) were critical for a specific toxic action and suggested that the brominated analog poisoned the moths by interacting with pyrokinin receptors.     

A pentapeptide of the C-terminal sequence of PBAN with pheromonotropic activity

Peptides ranging in length from 4 to 18 amino acid residues representing various sequence fragments of Helicoverpa (Heliothis)zea-pheromone biosynthesis activating neuropeptide (Hez-PBAN) were synthesized and tested for pheromonotropic activity. Biological activity resides in the C-terminus and the C-terminal pentapeptide (Phe-Ser-Pro-Arg-Leu-NH₂) represents the minimum sequence essential for induction of pheromone production. The C-terminal hexapeptide (Tyr-Phe-Ser-Pro-Arg-Leu-NH₂) had significantly higher activity at the lower doses of 100 and 10 pmol and may represent a tryptic cleavage product of PBAN.     

Backbone cyclic peptide antagonists, derived from the insect pheromone biosynthesis activating neuropeptide, inhibit sex pheromone biosynthesis in moths.

We describe an application of the backbone cyclization and cycloscan concept for the design and synthesis of pheromone biosynthesis activating neuropeptide (PBAN) antagonists capable of inhibiting sex pheromone biosynthesis in Heliothis peltigera female moths. Two backbone cyclic (BBC) sub-libraries were designed and synthesized. The structure of the first sub-library ([Arg27]PBAN27-33NH2, termed the Ser sub-library) was based on the active C-terminal hexapeptide sequence (Tyr-Phe-Ser-Pro-Arg-Leu-NH2) of PBAN1-33NH2, which was found to comprise its active core. The second sub-library ([Arg27, D-Phe30]PBAN27-33NH2, termed the D-Phe sub-library) was based on the sequence of the lead antagonist Arg-Tyr-Phe-(D)Phe-Pro-Arg-Leu-NH2. In both sub-libraries the Pro residue was replaced by an Nalpha(omega-amino-alkyl)Gly building unit having various lengths of the alkyl chain. All the cyclic peptides in each sub-library had the same primary sequence and the same location of the ring. The members of each library differed from each other by the bridge size and bridge chemistry. Screening of the two libraries for pheromonotropic antagonists resulted in the disclosure of four compounds that fully inhibited sex pheromone biosynthesis at 1 nmol and were devoid of agonistic activity. All antagonistic peptides originated from the D-Phe sub-library. Substitution of the D-Phe30 amino acid with a Ser resulted in a loss of antagonistic activity. Agonistic activities were exhibited by peptides from both sub-libraries.     

Evidence for two-step regulation of pheromone biosynthesis by the pheromone biosynthesis-activating neuropeptide in the moth Heliothis virescens

The control of pheromone biosynthesis by the neuropeptide PBAN was investigated in the moth Heliothis virescens. When decapitated females were injected with [2-(14)C] acetate, females co-injected with PBAN produced significantly greater quantities of radiolabeled fatty acids in their pheromone gland than females co-injected with saline. This indicates that PBAN controls an enzyme involved in the synthesis of fatty acids, probably acetyl CoA carboxylase. Decapitated females injected with PBAN showed a rapid increase in native pheromone, and a slower increase in the pheromone precursor, (Z)-11-hexadecenoate. Total native palmitate and stearate (both pheromone intermediates) showed a significant decrease after PBAN injection, before their titers were later restored to initial levels. In contrast, the acyl-CoA thioesters of these two saturated fatty acids increased during the period when their total titers decreased. When a mixture of labeled palmitic and heptadecanoic (an acid that cannot be converted to pheromone) acids was applied to the gland, PBAN-injected females produced greater quantities of labeled pheromone and precursor than did saline-injected ones. The two acids showed similar time-course patterns, with no difference in total titers of each of the respective acids between saline- and PBAN-injected females. When labeled heptadecanoic acid was applied to the gland alone, there was no difference in titers of either total heptadecanoate or of heptadecanoyl-CoA between PBAN- and saline-injected females, suggesting that PBAN does not directly control the storage or liberation of fatty acids in the gland, at least for this fatty acid. Overall, these data indicate that PBAN also controls a later step involved in pheromone biosynthesis, perhaps the reduction of acyl-CoA moieties. The control by PBAN of two enzymes, near the beginning and end of the pheromone biosynthetic process, would seem to allow for more efficient utilization of fatty acids and pheromone than control of only one enzyme.     

The identification of an age- and female-specific putative PBAN membrane-receptor protein in pheromone glands of Helicoverpa armigera: possible up-regulation by Juvenile Hormone

The present study was designed to determine the age and female specificity of a membrane protein that binds to a pheromone biosynthesis activating neuropeptide (PBAN) ligand and to elucidate the effect of Juvenile Hormone (JH) on binding as well as pheromone activation. The precise age at which developing adult females of Helicoverpa armigera begin to respond to PBAN was determined. PBAN activates in vitro pheromone biosynthesis as well as its intracellular second messenger, cAMP, only in intersegments of newly emerged adult female pheromone glands (i.e. 1-day-old females). An increase in response was observed in 2-day-old females. Intersegments of female pupae and the homologous tissues of adult males do not respond to PBAN. However, in the presence of Juvenile Hormone II (JH II) PBAN induced a response in females, 1 day before emergence (pharate females), but not in younger female pupae. This phenomenon was also observed after topical applications of the JH analog fenoxycarb (FX). In addition the response to PBAN by intersegments of FX-treated emerged adults increased significantly to the level of 2-day-old females. JH II also stimulated the level of incorporation of (35)S-labelled amino acids in female pupae into membrane proteins that are typical in adult intersegments. Using a photoaffinity-biotin labelled PBAN analog we demonstrate specific binding of a membrane protein (estimated MW: 50 kD) in adult females. This binding was not detected in female pupae 3 days before emergence. However, in such female pupae specific binding of the 50 kD protein by the photoaffinity-biotin labelled PBAN analog was induced after JH II or FX treatments thereby providing evidence that JH may up-regulate this putative receptor protein.     

Ant Trail Pheromone Biosynthesis Is Triggered by a Neuropeptide Hormone

Our understanding of insect chemical communication including pheromone identification, synthesis, and their role in behavior has advanced tremendously over the last half-century. However, endocrine regulation of pheromone biosynthesis has progressed slowly due to the complexity of direct and/or indirect hormonal activation of the biosynthetic cascades resulting in insect pheromones. Over 20 years ago, a neurohormone, pheromone biosynthesis activating neuropeptide (PBAN) was identified that stimulated sex pheromone biosynthesis in a lepidopteran moth. Since then, the physiological role, target site, and signal transduction of PBAN has become well understood for sex pheromone biosynthesis in moths. Despite that PBAN-like peptides (∼200) have been identified from various insect Orders, their role in pheromone regulation had not expanded to the other insect groups except for Lepidoptera. Here, we report that trail pheromone biosynthesis in the Dufour''s gland (DG) of the fire ant, Solenopsis invicta, is regulated by PBAN. RNAi knock down of PBAN gene (in subesophageal ganglia) or PBAN receptor gene (in DG) expression inhibited trail pheromone biosynthesis. Reduced trail pheromone was documented analytically and through a behavioral bioassay. Extension of PBAN''s role in pheromone biosynthesis to a new target insect, mode of action, and behavioral function will renew research efforts on the involvement of PBAN in pheromone biosynthesis in Insecta.     

Pheromonotropic and pheromonostatic activity in moths

Pheromone biosynthesis in many species of moths requires a pheromonotropic neurosecretion, the pheromone biosynthesis activating neuropeptide (PBAN), from the brain-subesophageal ganglion-corpora cardiaca complex. Some investigators suggest that PBAN is released into the hemolymph and acts directly on sex pheromone glands (SPG) via a Ca⁺⁺/calmodulin-dependent adenylate cyclase. Others suggest, however, that PBAN acts via octopamine that is released by nerves from the terminal abdominal ganglion innervating the SPG. These findings suggest that there are controversies on the mode of action of PBAN and other pheromonotropic factors, sometimes even within the same species. Mating in many insects results in temporary or permanent suppression of pheromone production and/or receptivity. Such a suppression may result from physical blockage of the gonopore or deposition of pheromonostatic factor(s) by the male during copulation that result in suppressed pheromone production and/or receptivity in females either directly or by a primer effect. In several species of insects, including moths, a pheromonostatic factor is transferred in the seminal fluid of males. Similar to the controversies associated with the pheromonotropic activity of PBAN, sometimes even within the same species, there appear to be controversies in pheromonostasis in heliothines as well. This paper reviews these conflicting findings and presents some data on pheromonostatic and pheromonotropic activity in Heliothis virescens that support and conflict with current information, raising further questions. Answers to some of the questions are partly available; however, they remain to be answered unequivocally. © 1994 Wiley-Liss, Inc.