Leucokinins, a new family of ion transport stimulators and inhibitors in insect Malpighian tubules

Isolation of NEB-LFamide, a novel myotropic neuropeptide from the grey fleshfly

A methanolic extract of 350,000 adult grey fleshflies Neobellieria bullata, was prepared and screened for myotropic activity. After fractionation on the first column, all fractions were screened in two heterologous (Locusta oviduct and Leucophaea hindgut) and one homologous (Neobellieria hindgut) myotropic bioassay. We here report the purification of one fraction, which stimulates the contractions of the Locusta oviduct. Electrospray Mass Spectrometry of the peptide revealed a molecular mass of 1395.82. The primary structure has been determined as AYRKPPFNGSLF-amide. This novel peptide was designated Neb-LF-amide. This sequence is different from the other known myotropic peptides in insects. The threshold concentration of the synthetic peptide is 1 x 10(-7) M on the Locusta oviduct. On the hindgut of Neobellieria or Leucophaea, the synthetic peptide is not active. By use of a polyclonal antiserum raised against the synthetic peptide, immunoreactivity was localized in median neurosecretory cells in the pars intercerebralis of the fly brain, indicating that Neb-LF-amide is a neuropeptide.

Neuropeptides implicated in the control of diuresis in insects

Primary urine production in insect Malpighian tubules is stimulated by two classes of neuropeptides, CRF-related diuretic peptides and insect kinins. The CRF-related peptide of the locust, Locusta migratoria, has a hormonal role in the control of postfeeding diuresis, but the functional role of the kinins has yet to be defined. The two classes of peptide act synergistically to stimulate tubule secretion, and the kinins may therefore have a modulatory action in the control of diuresis. The peptides differ in their effects on Malpighian tubule ion transport, and this could be important for the regulation of hemolymph volume and composition.

Isolation and identification of a diuretic hormone from the mealworm Tenebrio molitor

A diuretic hormone of unusual structure was isolated from extracts of whole heads of the mealworm Tenebrio molitor. The hormone is a 37-aa peptide of 4371 Da, with the sequence SPTISITAPIDVLRKTWEQERARKQMVKNREFLNSLN. This peptide increases cAMP production in Malpighian tubules of T. molitor. The amino acid sequence reveals that this peptide is a member of the family of sauvagine/corticotropin-releasing factor/urotensin I-related insect diuretic hormones. The C-terminal sequence of this peptide is quite different from other members of this family, which have a hydrophobic C terminus (isoleucinamide or valinamide). When aligned comparably, T. molitor diuretic hormone has a more hydrophilic C terminus, leucylasparagine (free acid). In contrast to all other known diuretic hormones of this family, this peptide has exceptionally low stimulatory activity on cAMP production in Malpighian tubules of Manduca sexta. However, at nanomolar concentrations it stimulates cAMP production in Malpighian tubules of T. molitor. Diuretic hormones of this family have been isolated previously from Lepidoptera, Orthoptera, Dictyoptera, and Diptera. This appears to be the first diuretic hormone isolated from a coleopteran insect.

Separation of oviposition-stimulating peptides and myotropic factors from head extracts of Galleria mellonella L.: comparative effects of myotropic and non-myotropic factors on egg laying

Methanolic extracts from heads of the wax moth, Galleria mellonella L. contain several factors that stimulate oviposition of virgin females in vivo and spontaneous contractions of the oviduct in vitro of the cricket, Gryllus bimaculatus. The myotropic and egg-laying activities behaved distinctly during all steps of purification, including fractionation on reverse-phase high-performance liquid chromatography. A novel neuropeptide was isolated from Galleria mellonella. The peptide does not increase the motility of isolated cricket oviducts. Among 13 other myotropic or non-myotropic factors studied, none were found to be as potent as the new peptide in stimulating egg-laying activity. The dose-response curves of myotropic and non-myotropic factors indicate that (i) proctolin, L-glutamate, octopamine, leucokinin-VI, leucopyrokinin, ecdysone and 20-hydroxy-ecdysone, or equivalent structures, might be involved in Galleria mellonella oviposition control, and (ii) that only the novel wax moth neuropeptide has the ability to trigger egg laying in that insect. The significance of these findings is discussed.

Properties of achetakinin binding sites on malpighian tubule membranes from the house cricket, Acheta domesticus

A biologically active 125I-labeled analogue of AK-II (3'-hydroxyphenyl propionic-Gly-Gly-Gly-Phe-Ser-Pro-Trp-Gly-NH2) was used to investigate the properties of achetakinin binding sites on plasma membranes from Malpighian tubules of Acheta domesticus. With optimized conditions, binding was rapid, reversible, and specific, and saturation studies revealed a single class of binding sites with Kd 0.55 nM and Bmax 39.9 fmol/mg membrane protein. The affinities of achetakinins for binding sites on tubule membranes ranked AK-V > AK III > AK-II > AK-I > or = AK-IV, in general agreement with their potencies in functional assays. However, IC50 values were several orders of magnitude higher than corresponding values for EC50, which suggests a considerable receptor reserve.

Diuretic activity of C-terminal group analogues of the insect kinins in Acheta domesticus

A series of insect kinin analogues, AFFPWG-X, modified at the C-terminal group, were evaluated in a cricket Malpighian tubule secretion bioassay. The results were compared with activity profiles observed in a cockroach hindgut myotropic bioassay for these analogues. Although the replacement of the C-terminal amide group with a negatively charged acid leads to a precipitious drop in diuretic activity, it can be partially restored with the introduction of ester groups such as methyl or benzyl. The presence of branched chain character in the C-terminal group or a C-terminal alpha-carbon-amide distance spanning five methylene group spacers is incompatible with the receptor interaction required for biological activity. Significant diuretic activity is retained with four or fewer methylene groups in this region. C-terminal group analogues containing -SCH3, -NHCH2CH2OCH3, or -OCH2(C6H5) offered the greatest retention of diuretic activity while providing increased hydrophobicity and/or steric bulk. The data are of potential value in the development of mimetic analogues of this insect neuropeptide family. Mimetic analogues are potentially valuable tools to insect neuroendocrinologists studying diuresis and/or engaged in the development of future pest management strategies.

Leucokinin and diuretic hormone immunoreactivity of neurons in the tobacco hornworm, Manduca sexta, and co-localization of this immunoreactivity in lateral neurosecretory cells of abdominal ganglia

Because leucokinins stimulate diuresis in some insects, we wished to identify the neurosecretory cells in Manduca sexta that might be a source of leucokinin-like neurohormones. Immunostaining was done at various stages of development, using an antiserum to leucokinin IV. Bilateral pairs of neurosecretory cells in abdominal ganglia 3-7 of larvae and adults are immunoreactive; these cells project via the ipsilateral ventral nerves to the neurohemal transverse nerves. The immunoreactivity and size of these lateral cells greatly increases in the pharate adult, and this change appears to be related to a period of intensive diuresis occurring a few days before adult eclosion. Relationships of these neurons to cells that are immunoreactive to a M. sexta diuretic hormone were also investigated. Diuretic hormone and leucokinin immunoreactivity are co-localized in the lateral neurosecretory cells and their neurohemal projections. A median pair of leucokinin-immunoreactive, and a lateral pair of diuretic hormone-immunoreactive neurons in the larval terminal abdominal ganglion project to neurohemal release sites within the cryptonephridium. The immunoreactivity of these cells is lost as the cryptonephridium is eliminated during metamorphosis. This loss appears to be related to the change from the larval to adult pattern of diuresis.

Culekinin depolarizing peptide: a mosquito leucokinin-like peptide that influences insect Malpighian tubule ion transport

A peptide termed culekinin depolarizing peptide (CDP) was isolated from approximately 1.2 million mosquitos (94% Culex salinarius). The peptide was isolated on the basis of a rapid myotropic assay that utilized a hindgut preparation from Leucophaea maderae and a transepithelial voltage assay that used mosquito Malpighian tubules from Aedes aegypti. A 15% trifluoroacetic acid extraction from the mosquitos, two solid phase extraction steps, and six HPLC steps resulted in the isolation of 9.7 nmol of CDP. This value corresponds to approximately 8 fmol/mosquito. Edman degradation indicated the following sequence for CDP: Asn-Pro-Phe-His-Ser-Trp-Gly-NH2. The sequence was confirmed as the suspected C-terminal amide form of the peptide, since native and synthetic CDP had identical chemical and biological properties. CDP is a member of the leucokinin family of neuropeptides. The leucokinins have been found in three other insect species (Leucophaea maderae, Acheta domesticus and Locusta migratoria) where these peptides were isolated by their myotropic properties alone. CDP shares a C-terminal sequence homology (i.e., Phe-X-Ser-Trp-Gly-NH2) with the rest of the leucokinins. CDP corresponds to the strongest tubule depolarizing activity in the C. salinarius extract. These findings agree with previous structure-activity studies that suggest that mosquitos would contain a leucokinin-like factor that had Phe-His-Ser-Trp-Gly-NH2 as the C-terminal pentapeptide. This is the first leucokinin isolated from blood feeding or holometabolous insects.

Partial identification, synthesis and immunolocalization of locustamyoinhibin, the third myoinhibiting neuropeptide isolated from Locusta migratoria

A blocked neuropeptide that suppresses the motility of the cockroach hindgut has been isolated from an extract of 9000 brain-corpora cardiaca-corpora allata-suboesophageal ganglion complexes of Locusta migratoria. Biological activity was monitored during HPLC purification by observing the myoinhibiting activity of column fractions on the isolated hindgut of Leucophaea maderae. Due to the low amount of material left after deblocking, this myoinhibiting peptide--designated as locustamyoinhibin or Lom-MIH--could only be partially sequenced: pGlu-X-Tyr-X'-Lys-Gln-Ser-Ala-Phe-Asn-Ala-Val-Ser-NH2. Nevertheless, the carboxy-terminal nonamer sequence (Lom-MIH5-13) was synthesized and also displayed myoinhibiting activity, indicating that the biologically active core lies in the carboxy-terminal sequence. Lom-MIH shows no sequence similarities with other peptides from vertebrate or invertebrate sources and is the third myoinhibiting peptide identified in Locusta migratoria. A polyclonal antiserum was raised against Lom-MIH5-13 and used to investigate the distribution of immunoreactive peptide in the central nervous system and its associated neurohaemal structures. Two groups of neurons with somata in the optic lobes show locustamyoinhibin (Lom-MIH)-like immunoreactivity. These groups have somata at the dorsal and ventral edge of the lamina ganglionaris. The neurons have dense ramifications in the lamina, with processes extending into the first optic chiasma and into the accessory medulla. Four cell bodies were detected in the protocerebrum, and two cells were found at the externo-lateral edge of the tritocerebrum. No immunoreactive perikarya could be observed in the suboesophageal ganglion nor in the ganglia of the ventral nerve cord. Neither the corpora cardiaca nor the neurohaemal organs of the ventral nerve cord showed immunolabelling. Therefore, our findings provide anatomical evidence for a central neurotransmitter role of Lom-MIH.

Localization of leucokinin VIII in the cockroach, Leucophaea maderae, using an antiserum directed against an achetakinin-I analog

An antiserum against an achetakinin analog selectively localized leucokinin VIII (LKVIII) in the CNS of Leucophaea maderae. Preabsorption studies of the achetakinin antiserum with either preimmune serum or LKVIII prevented a positive reaction in both ELISA and immunocytochemical procedures. LKVIII immunoreactive neurons were found in the brain, frontal, and subesophageal ganglion, all 3 thoracic ganglia and the terminal ganglion. Nerves originating from the thoracic and terminal abdominal ganglia contain LKVIII material. Lateral and medial neurosecretory cells synthesizing LKVIII-like products contribute axons to the nervi corporis cardiaci that terminate in neurohemal sites in the corpora cardiaca and nervi corporis allati. Thus, leucokinin VIII, like leucokinin I (LKI) and leucomyosuppressin (LMS), appears to have both a neurohemal and neurotransmitter mode of regulating target cells in L. maderae.

A comparative study of leucokinin-immunoreactive neurons in insects

Antisera were raised against leucokinin IV, a member of the leucokinin peptide family. Immunohistochemical localization of leucokinin immunoreactivity in the brain of the cockroach Nauphoeta cinerea revealed neurosecretory cells in the pars intercerebralis and pars lateralis, several bilateral pairs of interneurons in the protocerebrum, and a group of interneurons in the optic lobe. Several immunoreactive interneurons were found in the thoracic ganglia, while the abdominal ganglia contained prominent immunoreactive neurosecretory cells, which projected to the lateral cardiac nerve. The presence of leucokinins in the abdominal nerve cord was confirmed by HPLC combined with ELISA. Leucokinin-immunoreactive neurosecretory cells were also found in the pars intercerebralis of the cricket Acheta domesticus and the mosquito Aedes aegypti, but not in the locust Schistocerca americana or the honey bee Apis mellifera. However, all these species have leucokinin-immunoreactive neurosecretory cells in the abdominal ganglia. The neurohemal organs innervated by abdominal leucokinin-immunoreactive cells were different in each species.

Peptidergic neurons in the snail Helix pomatia: distribution of neurons in the central and peripheral nervous systems that react with an antibody raised to the insect neuropeptide, leucokinin I

In this study, an antiserum raised against an insect myotropic peptide, leucokinin I (DPAFNSWGamide), was used for mapping leucokinin-like immunoreactive (LK-LI) neurons in the gastropod mollusc, Helix pomatia. Immunocytochemistry performed on both whole-mounts and cryostat sections demonstrated LK-LI neurons in all ganglia of the central nervous system (CNS), except the visceral ganglion. Altogether about 700 immunolabelled neurons have been found, with nearly one-half (46%) in the cerebral ganglia. A large proportion of the LK-LI neurons have small cell bodies and are likely to be interneurons. The most prominent LK-LI cell group is represented by the entire neuron population of the mesocerebri, which is the major source of a thick fiber bundle system, encircling and innervating the whole CNS. One single LK-LI giant neuron was found, which is located in the left pedal ganglion and is termed GLPdLKC (giant left pedal leucokinin immunoreactive cell). This cell has not been identified previously. The ganglion neuropils are heavily innervated by varicose LK-LI fiber arborizations. Some integrative centers, such as the medullary neuropil of the procerebri, reveal an extreme density of LK-LI innervation. All major peripheral nerves contain a large number of LK-LI axons, and LK-LI innervation is found in the musculature of different peripheral organs (buccal mass, lip, tentacles, oviduct, intestine). Among the peripheral organs investigated, the intestine contains a rich varicose LK-LI network, composed of both intrinsic and extrinsic elements. Radioimmunoassay (RIA) demonstrates a very high content of LK-LI material in Helix ganglion extracts (about 50 pmol/CNS). This is the first report on the occurrence of a substance resembling the myotropic neuropeptide leucokinin I in a phylum outside arthropods. Based on our immunocytochemical observations, a role for leucokinin-like peptides in both central and peripheral regulatory processes in Helix is suggested. According to double-labelling experiments, only a small number of the LK-LI neurons are labelled with an antibody to the vertebrate tachykinin substance P.

Isolation and characterization of a diuretic peptide common to the house fly and stable fly

An identical CRF-related diuretic peptide (Musca-DP) was isolated and characterized from whole-body extracts of the house fly, Musca domestica, and stable fly, Stomoxys calcitrans. The peptide stimulates cyclic AMP production in Manduca sexta Malpighian tubules and increases the rate of fluid secretion by isolated Musca domestica tubules. The 44-residue peptide, with a mol.wt. of 5180, is amidated, and has the primary structure: NKPSLSIVNPLDVLRQRLLLEIARRQMKENTRQVELNRAILKNV-NH2. Musca-DP has a high percentage of sequence identity with other characterized CRF-related insect diuretic peptides.

Localization of Locusta-DP in locust CNS and hemolymph satisfies initial hormonal criteria

Locusta-diuretic peptide (Locusta-DP) is a potent stimulant of fluid secretion and cyclic AMP production by locust Malpighian tubules. In this study, a polyclonal antiserum raised to the C-terminus of Locusta-DP reveals a wide distribution of immunoreactive cell bodies and processes throughout the CNS, and endings in two important neurohemal release sites: the corpora cardiaca and the perivisceral organs. HPLC fractionation of CNS, neurohemal structures, and hemolymph reveals immunoreactive material that coelutes with synthetic Locusta-DP and stimulates cyclic AMP production by locust tubules. The identity of the immunoreactive and biologically active material is confirmed as authentic Locusta-DP by mass spectrometry.

Characterization of an antiserum against an achetakinin I-analog and its use for the localization of Culekinin Depolarizing Peptide II in the mosquito, Culex salinarius

ELISA experiments revealed that an antiserum raised against an achetakinin-analog could specifically detect the recently isolated Culekinin Depolarizing Peptide (CDP)-II from the mosquito, Culex salinarius. The characterization indicated that two different epitopes in the C-terminal region of achetakinin I and CDP-II are recognized. One epitope is the -F-Y-region, the other is the -P-W-region. Among the peptides isolated from C. salinarius, the antiserum reacts only with CDP-II. Pre-absorption tests of the antiserum with CDP-II in immunohistological stainings abolished the reaction, while tests with pre-immune sera did not cause any immunopositive reactions. In the mosquito head ganglia, immunoreactive neurons were detected in the pars lateralis, the optic lobe and the suboesophageal ganglion. Although some immunopositive axons extended into the nervi corporis cardiacii II, no immunoreactivity was observed in the retrocerebral complex. In the thoracic ganglia, immunoreactive neurons were found in the pro-, meso- and metathoracic neuromeres. No immunoreactivity was found elsewhere. With this study we demonstrate that CDP-II, isolated from a whole body extract, is truly a neuropeptide, and the data suggest that its function is neuromodulating or neurotransmitting rather than neurohormonal.

The myotropic peptides of Locusta migratoria: structures, distribution, functions and receptors

The search for myotropic peptide molecules in the brain, corpora cardiaca, corpora allata suboesophageal ganglion complex of Locusta migratoria using a heterologous bioassay (the isolated hindgut of the cockroach, Leucophaea maderae) has been very rewarding. It has lead to the discovery of 21 novel biologically active neuropeptides. Six of the identified Locusta peptides show sequence homologies to vertebrate neuropeptides, such as gastrin/cholecystokinin and tachykinins. Some peptides, especially the ones belonging to the FXPRL amide family display pleiotropic effects. Many more myotropic peptides remain to be isolated and sequenced. Locusta migratoria has G-protein coupled receptors, which show homology to known mammalian receptors for amine and peptide neurotransmitters and/or hormones. Myotropic peptides are a diverse and widely distributed group of regulatory molecules in the animal kingdom. They are found in neuroendocrine systems of all animal groups investigated and can be recognized as important neurotransmitters and neuromodulators in the animal nervous system. Insects seem to make use of a large variety of peptides as neurotransmitters/neuromodulators in the central nervous system, in addition to the aminergic neurotransmitters. Furthermore quite a few of the myotropic peptides seem to have a function in peripheral neuromuscular synapses. The era in which insects were considered to be "lower animals" with a simple neuroendocrine system is definitely over. Neural tissues of insects contain a large number of biologically active peptides and these peptides may provide the specificity and complexity of intercellular communications in the nervous system.

Acyl, pseudotetra-, tri- and dipeptide active-core analogs of insect neuropeptides

Pseudopeptides of the achetakinin insect neuropeptide family were synthesized by replacing the amino acid blocks Phe-, Phe-Tyr-, and Phe-Tyr-Pro- of the active-core pentapeptide Phe-Tyr-Pro-Trp-Gly-NH2 with hydrocinnamic acid, 6-phenylhexanoic acid, and both 9-phenylnonanoic and 6-phenylhexanoic acid, respectively. All four of these analogs retained myotropic activity, demonstrating that the active core could be reduced from a pentapeptide to a modified dipeptide. Most notable of these was the pseudotetrapeptide hydrocinnamyl-Tyr-Pro-Trp-Gly-NH2, which retained 70% of the potency and over 85% of the maximal activity of the parent pentapeptide. The N-terminal amino group, the phenol ring of the Tyr residue, the sulfate moiety and the Gly residue of the insect sulfakinin active core Tyr(SO3H)-Gly-His-Met-Arg-Phe-NH2 were all replaced by dodecanedioic acid. The resulting pseudotetrapeptide, dodecandioyl-His-Nle-Arg-Phe-NH2, elicited myostimulatory activity. Conversely, the related acyl pseudopentapeptide azelayl-Gly-His-Nle-Arg-Phe-NH2 proved myoinhibitory. A possible explanation for these disparate biological responses is discussed. These acyl pseudopeptides are important advances towards the eventual development of stable, potent mimetic agonists and antagonists of insect neuropeptides.

Use of specific antisera for the localisation and quantitation of leucokinin immunoreactivity in the nematode, Ascaris suum

1. The leucokinins (LKs) are a group of eight related peptides isolated from the cockroach, Leucophaea maderae. 2. Antisera raised against LK-V, which were specific for the conserved mid to C-terminal region of the LKs, were used to immunostain the parasitic nematode Ascaris suum. 3. LK-IR was observed in neurons in the anterior nerve ring, retrovesicular ganglion, and ventral and dorsal nerve cords of the parasite. Immunostaining was specific in that it was abolished by preabsorption of the antiserum with different leucokinins. Some of the LK-immunoreactive neurons were identified on the basis of their morphological similarity with identified neurons in the free-living nematode Caenorhabditis elegans. 4. Immunoreactivity towards a number of other peptides, notably neuropeptide F, FMRF-amide, KGQELE and KELTAE, has previously been demonstrated in all LK-immunoreactive neurons, thus confirming the multiple-peptidergic nature of certain nematode nerves. 5. LK-IR was demonstrated and quantified in a number of tissues using RIA. Highest amounts were found in extracts of gut; LK-IR was also demonstrated in extracts of body wall, heads and tails, testes, ovaries and pseudocoelomic fluid. 6. The distribution of tissue LK-IR did not correlate with the amount of neuronal tissue in the samples. 7. Dilution experiments suggested that the LK-IR in the parasite is heterogeneous and that the peptide(s) in some tissues may not be analogous to the insect LKs. 8. The LK-IR in the parasite remains to be characterized; however, the results suggest that peptides related to the leucokinins may have a far wider phylogenetic distribution than has hitherto been thought.

Tachykinin- and leucokinin-related peptides in the nervous system of the blowfly: immunocytochemical and chromatographical diversity

We are interested in the presence and function in insects of neuropeptides related to the vertebrate tachykinins. Hence, we have used antisera raised against the tachykinins substance P and kassinin, and against the insect neuropeptide leucokinin I, for localization studies and immunochemical analysis of related peptides in the nervous system of the blowfly Phormia terraenovae. In radioimmunoassays (with antisera against kassinin and leucokinin I) used in combination with reverse-phase HPLC, it was shown that the antisera recognize immunoreactive material with distinctly hydrophobic properties and each antiserum appear to detect several forms of immunochemically related peptides. With immunocytochemistry it was shown that the kassinin and leucokinin antisera each reacted with material in a distinct set of neurons. The leucokinin-immunoreactive material is present both in interneurons and in neurosecretory cells, suggesting roles of native leucokinin-like peptides as neuromodulators in the nervous system and as neurohormones acting on peripheral targets. The kassinin immunoreactivity was seen in interneurons, but could not be conclusively localized in neurosecretory cells, possibly indicating a role only within the nervous system.

Discussion paper: towards a systematic classification for regulatory peptides

Advances in microsequencing technology have led to the elucidation of primary structures of peptidic messengers from many eukaryotic and prokaryotic life forms. Existing peptide nomenclature is based upon such factors as bioactivity, source of isolation (tissue or species), chemical attributes, acronyms derived from a combination of these factors, or by other arbitrary means. In order to overcome many of the problems arising from current nomenclature, a standardised classification scheme for peptidic messengers is proposed which utilises an alphanumeric code string analogous to EC enzyme classification to convey information on origin, chemistry and relatedness to other similar molecules. It is anticipated that the scheme outlined will provide the basis for the rational classification of new peptides.

Leads for insect neuropeptide mimetic development

Insect neuropeptides mediate a number of physiological processes critical for insect survival. The numerous neuropeptide sequences that have been reported present an opportunity to decipher the chemical and conformational requirements for neuropeptide-receptor interactions. Chemical and conformational requirements for activity represent a "template" from which agonist/antagonist peptide mimetics, with the potential to disrupt critical insect processes, can be developed. Information on structural requirements is presented for three neuropeptide families: the sulfakinins, pyrokinins, and leucokinin/achetakinins, including active core size, important side chains, peptide superagonists, and new data on pseudopeptide modification of the N- and C-terminal regions. Members of these peptide families have been associated with a variety of physiological activities such as myotropism, pheromonotropism, diapause induction, and diuresis in a number of insects. Spectroscopic data coupled with computer molecular dynamics/graphics studies on conformationally restricted analogs of insect neuropeptides reveal information on the active conformation adopted at the receptor site. Routes to development of peptide-mimetics from neuropeptide templates are discussed.

Isolation, characterization and biological activity of a CRF-related diuretic peptide from Periplaneta americana L

A diuretic peptide (Periplaneta-DP) has been isolated from extracts of whole heads of the cockroach, Periplaneta americana. The purified peptide increases cyclic AMP production and the rate of fluid secretion by isolated Malpighian tubules in vitro. In the fluid secretion assay, the response to native Periplaneta-DP is comparable to that obtained with crude extracts of cockroach corpora cardiaca, and the EC50 lies between 10(-8) and 10(-9) M. The primary structure of Periplaneta-DP was established as a 46-residue amidated peptide: T G S G P S L S I V N P L D V L R Q R L L L E I A R R R M R Q S Q D Q I Q A N R E I L Q T I-NH2. Periplaneta-DP is a further member of the recently established family of CRF-related insect diuretic peptides.

A bifunctional heterodimeric insect neuropeptide analog

The synthesis and biological activity of a bifunctional, heterodimeric insect neuropeptide analog are described. The heterodimer is composed of the C-terminal pentapeptide active core regions of the leucokinin/achetakinin and pyrokinin neuropeptide families linked via their N-terminal amino groups with a succinyl diacid moiety. Members of the leucokinin/achetakinin family can induce fluid secretion in malpighian tubules of the house cricket, Acheta domesticus, whereas the pyrokinins demonstrate activity in a cricket oviduct myotropic bioassay. No cross-activity is observed for the two neuropeptide families in these bioassays. However, the heterodimer elicits responses in both Acheta bioassays. Such a bifunctional analog may in future serve as a template for the design of stable, bifunctional pest insect control agents of greater efficiency.

Segmental peptidergic innervation of abdominal targets in larval and adult dipteran insects revealed with an antiserum against leucokinin I

An antiserum against the cockroach neuropeptide leucokinin I (LKI) was used to study peptidergic neurons and their innervation patterns in larvae and adults of three species of higher dipteran insects, the flies Drosophila melanogaster, Calliphora vomitoria, and Phormia terraenovae, as well as larvae of a primitive dipteran insect, the crane fly Phalacrocera replicata. In the larvae of the higher dipteran flies, the antiserum revealed three pairs of cells in the brain, three pairs of ventro-medial cells in the subesophageal ganglion, and seven pairs of ventro-lateral cells in the abdominal ganglia. Each of these 14 abdominal leucokinin-immunoreactive (LKIR) neurons innervates a single muscle of the abdominal body wall (muscle 8), which is known to degenerate shortly after adult emergence. Conventional electron microscopy demonstrates that this muscle is innervated by at least one axon containing clear vesicles and two axons containing dense-cored vesicles. Electron-microscopical immunocytochemistry shows that the LKIR axon is one of these two axons with dense-cored vesicles and that it forms terminals on the sarcolemma of its target muscle. The abdominal LKIR neurons appear to survive metamorphosis. In the adult fly, the efferent abdominal LKIR neurons innervate the spiracles, the heart, and neurohemal regions of the abdominal wall. In the crane fly larva, dorso-medial and ventrolateral LKIR cell bodies are located in both thoracic and abdominal ganglia of the ventral nerve cord. As in the larvae of the other flies, the abdominal ventrolateral LKIR neurons form efferent axons. However, in the crane fly larva there are two pairs of efferent LKIR neurons in each of the abdominal ganglia and their peripheral targets include neurohemal regions of the dorsal transverse nerves. An additional difference is that in the crane fly, a caudal pair of LKIR axons originating from the penultimate pair of dorso-median LKIR cells in the terminal ganglion innervate the hind-gut.

Neurons in the cockroach nervous system reacting with antisera to the neuropeptide leucokinin I

Antisera were raised against the myotropic neuropeptide leucokinin I, originally isolated from head extracts of the cockroach Leucophaea maderae. Processes of leucokinin I immunoreactive (LKIR) neurons were distributed throughout the nervous system, but immunoreactive cell bodies were not found in all neuromeres. In the brain, about 160 LKIR cell bodies were distributed in the protocerebrum and optic lobes (no LKIR cell bodies were found in the deuto- and tritocerebrum). In the ventral ganglia, LKIR cell bodies were seen distributed as follows: eight (weakly immunoreactive) in the subesophageal ganglion; about six larger and bilateral clusters of 5 smaller in each of the three thoracic ganglia, and in each of the abdominal ganglia, two pairs of strongly immunoreactive cell bodies were resolved. Many of the LKIR neurons could be described in detail. In the optic lobes, immunoreactive neurons innervate the medulla and accessory medulla. In the brain, three pairs of bilateral LKIR neurons supply branches to distinct sets of nonglomerular neuropil, and two pairs of descending neurons connect the posterior protocerebrum to the antennal lobes and all the ventral ganglia. Other brain neurons innervate the central body, tritocerebrum, and nonglomerular neuropil in protocerebrum. LKIR neurons of the median and lateral neurosecretory cell groups send axons to the corpora cardiaca, frontal ganglion, and tritocerebrum. In the muscle layer of the foregut (crop), bi- and multipolar LKIR neurons with axons running to the retrocerebral complex were resolved. The LKIR neurons in the abdominal ganglia form efferent axons supplying the lateral cardiac nerves, spiracles, and the segmental perivisceral organs. The distribution of immunoreactivity indicates roles for leucokinins as neuromodulators or neurotransmitters in central interneurons arborizing in different portions of the brain, visual system, and ventral ganglia. Also, a function in circuits regulating feeding can be presumed. Furthermore, a role in regulation of heart and possibly respiration can be suggested, and probably leucokinins are released from corpora cardiaca as neurohormones. Leucokinins were isolated by their myotropic action on the Leucophaea hindgut, but no innervation of this portion of the gut could be demonstrated. The distribution of leucokinin immunoreactivity was compared to immunolabeling with antisera against vertebrate tachykinins and lysine vasopressin.

Locustakinin, a novel myotropic peptide from Locusta migratoria, isolation, primary structure and synthesis

The isolated hindgut of the cockroach, Leucophaea maderae is a very efficient bioassay tool for the monitoring of certain structural types of insect myotropic peptides during HPLC purification. Using this detection system, a six residue peptide has been isolated from an extract of 9000 brain corpora cardiaca-corpora allata suboesophageal ganglion complexes of Locusta migratoria. Amino acid composition and sequence analysis combined with enzymatic digestion data established the structure of the novel peptide as Ala-Phe-Ser-Ser-Trp-Gly-amide. The chromatographic and biological properties of the synthetic peptide were the same as those of the native peptide, thus confirming structural analysis. The carboxy-terminal pentamer sequence is the active core of leucokinins II, V and VII and of achetakinin III (myotropic neuropeptides isolated from Leucophaea m. and from Acheta domesticus; Holman et al., 1990). Furthermore, the octapeptide leucokinin VII contains the novel sequence as its carboxy-terminal hexamer and Achetakinin V (AFHSWGamide) differs from it by one residue. This new peptide designated as locustakinin I (locusts) may therefore represent an evolutionary molecular link between leucokinin VII (cockroaches) and achetakinin V (crickets). Using synthetic locustakinin, physiological studies will be performed in the locust. In view of the known effects of leucokinins, locustakinin may be important in the stimulation of ion transport and inhibition of diuretic activity in Malpighian tubules. This study indicates that the AFXSWGamide sequence appears to have been well conserved and that members of this peptide family may be widely distributed among insects and posses a number of functions.

Isolation and identification of a new diuretic peptide from the tobacco hornworm, Manduca sexta

A 30-amino acid diuretic peptide was isolated from the corpora cardiaca-corpora allata complexes and, separately, from medial neurosecretory cells of the Sphingid moth, Manduca sexta. The peptide was found to have the following sequence, determined by automated Edman degradation and mass spectrometry: SFSVNPAVDILQHRYMEKV AQNNRNFLNRV-NH2. We have named the peptide Mas-DP II. The peptide was synthesized and shown to possess diuretic activity in decapitated moths. Mas-DP II is related by sequence homology to a 41-amino acid diuretic peptide identified previously from M. sexta, and it belongs to the family of corticotropin releasing factor-like peptides.

An active pseudopeptide analog of the leucokinin insect neuropeptide family

A pseudopeptide analog of the active core of the leucokinin insect neuropeptide family was synthesized and found to retain myotropic activity. No reports of active pseudopeptide analogs of an insect or other invertebrate neuropeptide have previously appeared in the literature. The pseudopeptide (Phe psi [CH2-NH] Phe-Ser-Trp-Gly-NH2) contains a reduced-amide linkage between the two N-terminal Phe residues. Unlike its amide-bond containing counterpart, the activity of the pseudopeptide was not destroyed upon exposure to aminopeptidase M.

Comparative effects of leucomyosuppressin on the visceral muscle systems of the cockroach Leucophaea maderae

1. Leucomyosuppressin (LMS) did not inhibit the spontaneous contractions of visceral muscles of the cockroach Leucophaea maderae uniformly as a group but rather showed a selective suppression of activity in the foregut and hindgut. The threshold of LMS inhibition for these organs was 10(-11) M for the foregut and 3 x 10(-11) M for the hindgut. The maximum response for each organ was generally recorded at 2.4 x 10(-8) M. 2. Both the heart and the oviduct were 100-1000 times less sensitive to LMS than either the foregut or the hindgut. Although the responses of the heart to LMS (10(-9) to 10(-8) M) were somewhat inconsistent, the myocardium showed a reduction in either the amplitude or frequency of contractions in 75% of the preparations tested. The oviduct showed the lowest level of responsiveness of all the muscles tested. Even at a concentration of 10(-7) M LMS, the amplitude and frequency of contractions showed no more than a 58% inhibition. 3. Desensitization to LMS was observed in three of the four muscle types tested. The phenomenon occurred in 37% of the foreguts, 34% of the hindguts and 54% of the heart preparations tested. The results of this study show that each visceral muscle type has its own unique response profile to LMS and support the idea that peptides may be multifunctional regulators.