Several isoforms of locustatachykinins may be involved in cyclic AMP-mediated release of adipokinetic hormones from the locust Corpora cardiaca.

Four locustatachykinins (LomTK I-IV) were identified in about equal amounts in extracts of corpora cardiaca of locusts, using reverse-phase high-performance liquid chromatography and radioimmunoassay with synthetic LomTK I-IV as standards. Brain extracts also contained the four isoforms in roughly equimolar concentrations. Retrograde tracing of the nervi corporis cardiaci II (NCC II) in vitro with Lucifer yellow in combination with LomTK immunocytochemistry revealed that about half of the secretomotor neurons in the lateral part of the protocerebrum projecting into the glandular lobe of the corpora cardiaca (CCG) contain LomTK-immunoreactive material. Since the four LomTKs are present in the CCG, these four or five neurons in each hemisphere are likely to contain colocalized LomTK I-IV. The role of two of the LomTKs in the regulation of the release of adipokinetic hormones (AKHs) from the adipokinetic cells in the CCG in the locust was investigated. Experiments performed in vitro showed that LomTK I and II induced release of AKH in a dose-dependent manner. These peptides also rapidly and transiently elevated the cyclic AMP-content of the CCG. The peak level of cyclic AMP occurred about 45 seconds after stimulation with LomTK. These results support the proposal that LomTKs are involved in controlling the release of the adipokinetic hormones and suggest that all LomTK isoforms may participate in this cyclic AMP-mediated event.

An aminoisobutyric acid-containing analogue of the cockroach tachykinin-related peptide, LemTRP-1, with potent bioactivity and resistance to an insect angiotensin-converting enzyme.

Nine tachykinin-related peptides (TRPs), designated LemTRP-1-9, were recently isolated from the cockroach, Leucopheae maderae. To obtain a LemTRP resistant to endo- and exoprotease-mediated hydrolysis, we synthesized a peptide with one of the carboxy terminus residues substituted for a sterically hindered aminoisobutyric acid (Aib) and with the amino terminus blocked with a pyroglutamate. The Aib-containing analogue of the nonapeptide LemTRP-1 (Aib-LemTRP-1) thus has the sequence pGlu-Ala-Pro-Ser-Gly-Phe-Leu-Aib-Val-Arg-NH2. This analogue was shown to be resistant to hydrolysis by recombinant angiotensin-converting enzyme (ACE), from Drosophila melanogaster. Endogenous LemTRP-1 on the other hand was rapidly hydrolysed by ACE at the Gly7-Val8 bond, resulting in a single heptapeptide. The Aib-LemTRP-1 has about the same potency as LemTRP-I in inducing contractions of the L. maderae hindgut muscle. It was also tested in intracellular recordings for ability to induce firing of action potentials in dorsal unpaired median (DUM) neurons in the metathoracic ganglion of the locust Locusta migratoria. The Aib-containing analogue was nearly as active as LemTRP-1 and the natural ligand locustatachykinin I. LemTRP-1 and Aib-LemTRP-1 had the same transient time course of action on the cockroach hindgut. This suggests that peptide degradation is not likely to be the cause of the transient action of TRPs.

Characterization of actions of Leucophaea tachykinin-related peptides (LemTRPs) and proctolin on cockroach hindgut contractions.

The nine Leucophaea Tachykinin-Related Peptides (LemTRP 1-9) isolated from the midgut and brain of the cockroach, Leucophaea maderae, all induced increases in spontaneous contractions of the L. maderae hindgut. Synthetic LemTRP 1 and 3-9, were equally potent in inducing contractions of the hindgut. More than seven of the nine C-terminal residues of the closely related locust peptide locustatachykinin I (LomTK I) are required for full activity of the peptide on the L. maderae hindgut. Proctolin, a well characterized myostimulatory neuropeptide, was shown to be more potent than LemTRPs. LemTRP 1 and proctolin did not have synergistic actions in potentiating the amplitude and tonus of contractions of the L. maderae hindgut. Several differences could be seen in actions of LemTRP 1 and proctolin. In contrast to proctolin, LemTRP 1 could not override the inhibitory action of 10(-9) M of the myoinhibitory peptide leucomyosuppressin. Spantide I, an antagonist of the mammalian tachykinin receptors, at a concentration of 5 microM, blocked the response to LemTRP 1, but not to proctolin. The competitive proctolin receptor antagonist [alpha-methyl-L-tyrosine2]-proctolin blocked the action of both proctolin and LemTRP 1 when applied at 1 microM, whereas cycloproctolin had no antagonist action on either peptide. Verapamil, a blocker of voltage gated Ca2+-channels, and the less specific Ca2+-channel blocker Mn2+, abolished the action of LemTRP 1, but not of proctolin. The results obtained indicate that LemTRPs act on receptors distinct from those of proctolin. Double label immunocytochemistry revealed that all LomTK-like immunoreactive fibers impinge on the proctolinergic fibers in the hindgut. This finding and the inhibitory actions of Ca2+-channel blockers on TRP responses and of the proctolin receptor antagonist on both peptides, may suggest that the LemTRP receptors are not on the hindgut muscle fibers but on the terminals of the proctolinergic neurons. Thus, LemTRPs may induce release of proctolin on the hindgut. An alternative is that LemTRPs act by mechanisms clearly distinct from those of proctolin.

Two novel tachykinin-related peptides from the nervous system of the crab Cancer borealis.

Immunocytochemical and biochemical studies have indicated the presence of many neuroactive substances in the stomatogastric nervous system (STNS) of the crab Cancer borealis. In electrophysiological studies, many of these substances modulate the motor output of neural networks contained within this system. Previous work in the STNS suggested the presence of neuropeptides related to the invertebrate tachykinin-related peptide (TRP) family. Here we isolate and characterize two novel peptides from the C. borealis nervous system that show strong amino acid sequence identity to the invertebrate TRPs. The central nervous systems of 160 crabs were extracted in an acidified solvent, after which four reversed-phase HPLC column systems were used to obtain pure peptides. A cockroach hindgut muscle contraction bioassay and a radioimmunoassay (RIA) employing an antiserum to locustatachykinin I (Lom TK I) were used to monitor all collected fractions. The amino acid sequences of the isolated peptides were determined by Edman degradation. Mass spectrometry and chemical synthesis confirmed the sequences to be APSGFLGMR-NH2 and SGFLGMR-NH2. APSGFLGMR-NH2 is approximately 20-fold more abundant in the crab central nervous system than is SGFLGMR-NH2. We have named these peptides Cancer borealis tachykinin-related peptide Ia and Ib (CabTRP Ia and Ib), respectively. Both peptides are myoactive in the cockroach hindgut muscle contraction bioassay, with CabTRP Ia being approximately 500 times more potent than CabTRP Ib. RIA performed on HPLC-separated C. borealis stomatogastric ganglion (STG) extract revealed that CabTRP Ia is the only detectable TRP-like moiety in this ganglion. Incubation of synthetic CabTRP Ia with the isolated STG excited the pyloric motor pattern. These effects were suppressed by the broad-spectrum tachykinin receptor antagonist Spantide I. Spantide I had no effect on the actions of the unrelated endogenous peptide proctolin in the STG. There was no consistent influence of CabTRP Ib on the pyloric rhythm. Given its amino acid sequence and minimal biological activity in the crab, CabTRP Ib may be a breakdown product of CabTRP Ia.

Peptidergic activation of locust dorsal unpaired median neurons: depolarization induced by locustatachykinins may be mediated by cyclic AMP.

Four tachykinin-related peptides, locustatachykinin 1-4 (LomTK 1-4) are distributed in interneurons throughout the central nervous system of the locust Locusta migratoria and may have important roles as neurotransmitters or neuromodulators. In search of the central actions of LomTKs, we analyzed the response of the efferent dorsal unpaired median (DUM) neurons in the locust metathoracic ganglion. Immunocytochemistry, using an antiserum against LomTK 1, combined with intracellular filling of efferent DUM neurons with Lucifer yellow, revealed that LomTK-immunoreactive fibers are in close proximity to dendritic arborizations of the DUM neurons. Hence, LomTKs may act on DUM neurons by releasing locally in the metathoracic ganglion. Intracellular recordings were made from somata of DUM neurons, and LomTKs were either bath-applied to an isolated metathoracic ganglion or pressure-ejected onto the DUM neuron soma. LomTK 1 at concentrations of 0.1 mM-0.1 microM caused a relatively slow, reversible depolarization with a subsequent increase in the frequency of action potential firing. Amino-terminally truncated forms of LomTK 1 were applied to DUM neurons. The heptapeptide [3-9]-LomTK 1 had a substantially reduced activity, and bioactivity was lost after further truncation. Spantide 1, an antagonist of mammalian tachykinin receptors, reversibly blocked the effect of LomTK 1. The effect of LomTK 1 was clearly reduced in the presence of GDP-beta-S, a stable analog of GDP that inactivates G-proteins. The action of LomTK 1 was potentiated by both IBMX and theophylline, two cyclic AMP (cAMP) phosphodiesterase inhibitors. The action of LomTK 1 was mimicked by pressure-ejecting 8-bromo-cAMP, a membrane permeable analog of cAMP, and by forskolin, an adenylate cyclase activator. Furthermore, cAMPS, a blocker of protein kinase A activity, reduced the effect of LomTK 1. These findings indicate that cAMP is involved in mediating DUM neuron depolarization.

Multiple members of the leucokinin neuropeptide family are present in cerebral and abdominal neurohemal organs in the cockroach Leucophaea maderae.

Two neurohemal organs of the cockroach Leucophaea maderae, the corpora cardiaca and the lateral heart nerve are known to contain leucokinin immunoreactive material. We examined the corpora cardiaca and the lateral heart nerve to establish whether these neurohemal organs store all 8 known leucokinin isoforms or if the leucokinins have a differential distribution. Extracts of corpora cardiaca and abdominal hearts with attached lateral heart nerve were separated on reversed phase high performance liquid chromatography (rpHPLC), then tested for leucokinin immunoreactivity by a radioimmunoassay (RIA) able to detect all 8 leucokinin isoforms. Extracts from brain and optic lobes were also separated and assayed in the RIA. Synthetic leucokinin 1-8 were subjected to rpHPLC and their different retention times established by RIA for reference. Leucokinin immunoreactive material originating from the corpora cardiaca and lateral heart nerves eluted in fractions corresponding to those of the synthetic leucokinin 1-8. In this study we have thus demonstrated that probably all 8 leucokinin isoforms are stored in the corpora cardiaca and the lateral heart nerve. These observations suggest that all 8 leucokinins are likely to be released as neurohormones into the circulation.

Several forms of callitachykinins are distributed in the central nervous system and intestine of the blowfly Calliphora vomitoria.

We have examined the distribution of two tachykinin-related neuropeptides, callitachykinin I and II (CavTK-I and CavTK-II), isolated from whole-animal extracts of the blowfly Calliphora vomitoria. Extracts of dissected brains, thoracic-abdominal ganglia and midguts of adult blowflies and the entire central nervous system of larval flies were analysed by high performance liquid chromatography (HPLC) combined with enzyme-linked immunosorbent assay (ELISA) for the presence of CavTKs. To identify the two neuropeptides by HPLC, we used the retention times of synthetic CavTK-I and II as reference and detection with an antiserum raised to locustatachykinin II (shown here to recognise both CavTK-I and II). The brain contains only two immunoreactive components, and these have exactly the same retention times as CavTK-I and II. The thoracic-abdominal ganglia and midgut contain immunoreactive material eluting like CavTK-I and II as well as additional material eluting later. The larval central nervous system (CNS) contains material eluting like CavTK-I and II as well as a component that elutes earlier. We conclude that CavTK-I and II are present in all assayed tissues and that additional, hitherto uncharacterised, forms of tachykinin-immunoreactive material may be present in the body ganglia and midgut as well as in the larval CNS. An antiserum was raised to CavTK-II for immunocytochemistry. This antiserum, which was found to be specific for CavTK-II in ELISA, labelled all the neurones and midgut endocrine cells previously shown to react with the less selective locustatachykinin antisera. It is not clear, however, whether CavTK-I and II are colocalised in all LomTK-immunoreactive cells since there is no unambiguous probe for CavTK-I.

Abundant distribution of locustatachykinin-like peptide in the nervous system and intestine of the cockroach Leucophaea maderae.

An antiserum raised to the locust neuropeptide locustatachykinin I (LomTK I) was used for analysis of the distribution of tachykinin-related peptide in the cockroach Leucophaea maderae. Extracts of dissected brains, suboesophageal ganglia, thoracic ganglia and midguts were separated by high performance liquid chromatography and the fractions analysed in enzyme-linked immunosorbent assay with use of the LomTK antiserum. Each of the tissues was found to contain LomTK-like immunoreactive (LomTK-LI) components with retention times corresponding approximately to synthetic LomTK I and II and callitachykinins I and II. The LomTK antiserum was also used for immunocytochemical mapping of peptide in the nervous system and intestine of L. maderae. A large number of LomTK-LI interneurons were detected in the proto-, deuto- and tritocerebrum of the brain and in the suboesophaegeal ganglion. The immunoreactive neurons supply processes to most parts of the brain: the central body, protocerebral bridge, mushroom body calyces, antennal lobes, optic lobe and most regions of the non-glomerular neuropil. A few protocerebral neurons send LomTK-LI processes to the glandular lobe of the corpora cardiaca. In each of the thoracic ganglia there are six LomTK-LI interneurons and in each of the unfused abdominal ones there are two interneurons. The fused terminal ganglion contains some additional cell bodies in the posterior neuromers. LomTK-LI cell bodies were detected in the frontal ganglion and fibres were seen in this ganglion as well as in the hypocerebral ganglion. The frontal ganglion supplies LomTK-LI processes to the muscle layer of the pharynx. The muscle layer of the midgut is innervated by LomTK-LI fibres from the stomatogastric system (oesophageal nerve and associated ganglia). Additionally the midgut contains numerous LomTK-LI endocrine cells. A number of the pharyngeal dilator muscles were also found to be innervated by LomTK-LI fibres, probably derived from cell bodies in the suboesophageal ganglion. All the LomTK-LI neurons of the central nervous system appear to be interneurons, suggesting a neuromodulatory role of the endogenous tachykinins. The tachykinin-like peptides from peripheral ganglia may be involved in the control of foregut and midgut contractility and possibly the peptide of the endocrine cells in the midgut has additional actions related to intestinal function.

Locustatachykinin immunoreactivity in the blowfly central nervous system and intestine.

An antiserum raised against locustatachykinin I, one of four myotropic peptides that have been isolated from the locust brain and corpora cardiaca, was characterized by enzyme-linked immunosorbent assay (ELISA) and used for immunocytochemical detection of neurons and endocrine cells in the nervous system and intestine of the blowfly Calliphora vomitoria. The ELISA characterization indicated that the antiserum recognizes the common C-terminus sequence of the locustatachykinins I-III. Hence, the cross reaction with locustatachykinin IV is less, and in competitive ELISAs no cross reaction was detected with a series of vertebrate tachykinins tested. It was also shown that the antiserum recognized material in extracts of blowfly heads, as measured in ELISA. In high-performance liquid chromatography the extracted locustatachykinin-like immunoreactive (LomTK-LI) material eluted in two different ranges. A fairly large number of LomTK-LI neurons was detected in the blowfly brain and thoracicoabdominal ganglion. A total of about 160 LomTK-LI neurons was seen in the proto-, deuto-, and tritocerebrum and subesophageal ganglion. Immunoreactive processes from these neurons could be traced in many neuropil regions of the brain: superior and dorsomedian protocerebrum, optic tubercle, fan-shaped body and ventral bodies of the central complex, all the glomeruli of the antennal lobes, and tritocerebral and subesophageal neuropil. No immunoreactivity was seen in the mushroom bodies or the optic lobes. In the fused thoracicoabdominal ganglion, 46 LomTK-LI neurons could be resolved. The less evolved larval nervous system was also investigated to obtain additional information on the morphology and projections of immunoreactive neurons. In neither the larval nor the adult nervous systems could we identify any efferent or afferent immunoreactive axons or neurosecretory cells. The widespread distribution of LomTK-LI material in interneurons suggests an important role of the native peptide(s) as a neurotransmitter or neuromodulator within the central nervous system. Additionally a regulatory function in the intestine is indicated by the presence of immunoreactivity in endocrine cells of the midgut.

Callitachykinin I and II, two novel myotropic peptides isolated from the blowfly, Calliphora vomitoria, that have resemblances to tachykinins.

Two peptides, related to the locust myotropic peptides locustatachykinin I-IV, were isolated from the blowfly Calliphora vomitoria. Whole, frozen flies were used for extraction with acidified methanol. A cockroach hindgut muscle contraction bioassay was used for monitoring fractions during subsequent purification steps. A series of eight different high performance liquid chromatography column systems was required to obtain optically pure peptides. Two peptides were isolated and their sequences determined by Edman degradation and confirmed by mass spectrometry and chemical synthesis as APTAFYGVR-NH2 and GLGNNAFVGVR-NH2. They were named callitachykinin I and II. The peptides have sequence similarities to the locustatachykinins and vertebrate tachykinins. Both callitachykinins were recognized by an antiserum to locustatachykinin I in enzyme-linked immunosorbent assay (ELISA) tests and callitachykinin II was additionally recognized by an antiserum to the vertebrate tachykinin kassinin, suggesting that immunolabeling of blowfly neurons with these antisera is due to neuronal callitachykinins.

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.

Galanin immunoreactivity and 125I-galanin binding sites in the blowfly brain.

We have used immunocytochemical, immunochemical (RIA) and chromatographic methods (HPLC, gel filtration) to provide evidence for presence of GAL-like peptide(s) in the blowfly Phormia terraenovae. HPLC indicates the presence of several forms of GAL-like peptides. Immunocytochemistry showed that there are about 160 GAL-IR neurons in the brain and subesophageal ganglia supplying the central body, superior protocerebrum, the optic lobe and tritocerebral neuropil. Autoradiography of binding with 125I-labelled porcine GAL on brain sections revealed GAL binding sites in the central body complex and deutocerebrum. The presence of galanin-like peptide(s) and putative receptor sites in the fly brain suggest a role in neuromodulation in specific circuits.

Autoradiographic localization of 125I-galanin binding sites in the blowfly brain.

The localization of porcine galanin (pGAL) binding sites in the brain of the blowfly Phormia terraenovae was investigated by autoradiography using the following radioiodinated ligands: pGAL 1-29 (two isoforms), pGAL 15-29 and rat (r) GAL 1-29. The different porcine radioligands bound specifically with the following intensity: 125I-[Tyr26]-pGAL15-29 > > 125I-[Tyr26]-pGAL1-29 > > 125I-[Tyr9]-pGAL1-29. With rat galanin 125I-[Tyr9]-rGAL1-29 no specific binding could be shown. In addition, displacement of 125I-[Tyr26]-pGAL1-29 was tested with pGAL 1-29, pGAL 1-22 and pGAL 15-29 (at 0.1 nM-1 microM). A gradual displacement was achieved with increasing concentrations of pGAL 1-29 and pGAL15-29, whereas no displacement with pGAL 1-22 was detected. The results indicate that the C-terminal portion of pGAL is important for binding in the blowfly. The pGAL binding sites were localized in synaptic neuropils of the central body, the antennal lobes, the optic lobes, the pars intercerebralis and the subesophageal ganglion, all of which contain GAL-like immunoreactive neural processes.

Diversity in tachykinin-like peptides in the insect brain.

When testing a large number of antisera against tachykinins of various vertebrates and one insect (the cockroach Leucophaea maderae) we found three distinct populations of tachykinin-immunoreactive neurons in the blowfly: (1) one recognized by antisera against substance P, (2) another by antisera against the frog peptide kassinin and (3) a third with antisera raised against the cockroach peptide Leucokinin I. As a comparison tests on the cockroach Leucophaea showed that only antisera against neurokinin A (NKA) and leucokinin I gave immunostaining, RIA and immunocytochemical displacement tests demonstrated that the each of the three listed types of antisera was specific for the corresponding antigenic peptide and showed virtually no cross reactivity with the other tachykinin peptides. By immunocytochemistry we have mapped the three populations of tachykinin-immunoreactive neurons in the blowfly CNS. Two constitute unique sets of interneurons that were previously not detected with other antisera, the third, recognized by antisera against substance P, is a subpopulation of the FMRFamide immunoreactive neurons. The leucokinin immunoreactive material in the blowfly seems to be chemically different from that in Leucophaea and also the sets of neurons immunolabeled in the two insect species are to some extent different. The preliminary results presented here indicate the presence of multiple forms of tachykinin-like peptides in the blowfly and that these are distinct from those in the cockroach. From the immunocytochemistry it appears that the insect tachykinins may be involved in a variety of regulatory functions in the CNS and in some cases possibly act as neurohormones.

Galanin message-associated Peptide-like immunoreactivity in the nervous system of the blowfly: distribution and chromatographic characterization.

Galanin message-associated peptide (GMAP) is a flanking peptide in mammalian preprogalanin located C-terminally of galanin (GAL). GMAP-like immunoreactive (LI) material in the brain of the blowfly Phormia terraenovae was analysed by radioimmunoassay combined with reversed-phase high-performance liquid chromatography and immunocytochemistry and compared to GAL-LI material. A sensitive radioimmunoassay, developed against a species-conserved portion of mammalian GMAP (synthetic porcine GMAP(19-41)amide), was applied to serially diluted blowfly head extracts. High-performance liquid chromatography combined with radioimmunoassay showed that the GMAP-LI material eluted as several different components with one major component coeluting with the synthetic GMAP fragment. One GMAP-LI peak co-eluted with a GAL-LI component of the extract. By immunocytochemistry it was shown that a distinct set of GMAP-LI neurons and neurosecretory cells is present in the blowfly brain and thoracico-abdominal ganglion. About 150 GMAP-LI cell bodies were found in the brain, distributed in the protocerebrum, tritocerebrum and suboesophageal ganglion. Several hundred GMAP-LI cell bodies were detected in the medulla of the optic lobe. In the fused thoracico-abdominal ganglion there are about 70 GMAP-LI cell bodies distributed in a segmental fashion. Several of the GMAP-LI neurons also contain GAL-LI material whereas some do not. In addition, there are GAL-LI neurons that do not react with the GMAP antiserum. Some of the GMAP-LI interneurons and neurosecretory cells could be traced in detail enabling a resolution of putative sites of action of the peptide.

Galanin immunoreactivity in the blowfly nervous system: localization and chromatographic analysis.

In this study chromatographic, immunochemical, and immunocytochemical methods provide evidence of a galanin-like peptide(s) in an invertebrate, the blowfly Phormia terraenovae. The major portion of the galanin-like immunoreactivity (GAL-LI) in fly heads was extractable in acetic acid but not in boiling water, which suggests that the peptide(s) may be highly basic in nature. GAL-LI was present both in the head and body portion of the blowfly in roughly the same amounts. Initial gel filtration data, using a G-50 Sephadex column and a weak phosphate-buffer (pH 6.5) as eluent, suggested that a fly GAL-LI peptide(s) from fly heads, eluting as an apparent single peak, was smaller than porcine GAL(1-29) and GAL(1-15). However, concomitant analysis using a G-25 Sephadex column and acetic acid (0.2 M) as eluent, spread the immunoreactive material over a great portion of the chromatogram, although the main portion of the material eluted in the same size range as porcine GAL(1-29). Taken together, the gel filtration data thus suggest that fly GAL-LI peptide(s) may be highly basic but presumably similar in size to vertebrate GAL(1-29). However, the hydrophobic properties of the fly GAL-LI peptide(s) differ from that of porcine GAL as demonstrated by the presence of several immunoreactive components eluting both early as well as late in the chromatogram when using reverse-phase high performance liquid chromatography (HPLC); early peaks may represent highly basic and/or possibly smaller GAL-immunoreactive peptide(s), whereas later peaks may represent less basic and possibly elongated forms. Immunocytochemistry indicated that GAL-LI was present in the nervous system of the blowfly. About 160 GAL-immunoreactive neurons were found in the brain and subesophageal ganglion, 26 in the fused thoracic ganglion and 30 in the fused abdominal ganglion. In the brain, GAL-immunoreactive fibers supply specific subdivisions of the central body, optic lobe, superior protocerebrum, and tritocerebrum as well as neuropil in the subesophageal ganglia. In the thoracico-abdominal ganglia, GAL-immunoreactive neuron processes are found inside synaptic neuropil as well as in the neural sheath of the ganglia and several of the dorsal nerve roots. Many of the GAL-immunoreactive neurons react also with an antiserum against porcine galanin message associated peptide, a peptide present in the preprogalanin protein. Immunocytochemical double-labeling indicated that some GAL-immunoreactive neurons also reacted with antisera against the molluscan peptides FMRFamide and SCPB, whereas no evidence could be found for colabeling with antisera against tyrosine hydroxylase, substance P and physalaemin.(ABSTRACT TRUNCATED AT 400 WORDS)

Insect tachykinin-like peptide: distribution of leucokinin immunoreactive neurons in the cockroach and blowfly brains.

Antisera were raised against leucokinin I, a cockroach myotropic neuropeptide with some resemblance to vertebrate tachykinins. These antisera were used for immunocytochemical mapping of neurons and neurosecretory cells in the brains of a cockroach and a blowfly species. The leucokinin immunoreactive cells are distinct from neurons that can be labeled with antisera against vertebrate type tachykinins. It is suggested that leucokinin-like peptides may have roles as neurohormones and neuromodulators in the insect nervous system.