Evidence for brain-derived neurotrophic factor-like neuropeptide in brain of the silk moth Bombyx mori during postembryonic periods

Brain-derived neurotrophic factor-like neuropeptide is produced in the brain of the silk moth, Bombyx mori. Immunocytochemical studies of brain and retrocerebral complex of larvae, prepupae, pupae and adults showed that four pairs of median neurosecretory cells and six pairs of lateral neurosecretory cells which had different immunoreactivities to BDNF peptide. Day-1 adult brains showed no evidence of neurons stained by anti-BDNF antibodies. Those reactivities, which were much stronger in median cells than in lateral cells, were the weakest in an earliest larval stage and a latest pupal stage but the strongest in late larval stage. Median neurosecretory cells projected their axons into the contralateral corpora allata by decussation in the median region, nerve corpora cardiaca (NCC) I, and nerve corpora allata (NCA) I, whereas lateral neurosecretory cells extended their axons to the ipsilateral corpora allata via NCC II and NCA I.     

Neuroendocrine organs of the lemon-butterfly, Papilio demoleus L. II. The corpora cardiaca-allata complex of the adult.

The retrocerebral endocrine organs of the adult lemon-butterfly; Papilio demoleus have been described. The organs are subaortic lying closely behind the brain. While the nervi corporis cardiaci I (NCCI) originate from the protocerebrum of the brain, the NCCII seem to take their origin in the tritocerebrum in common with another nerve named earlier as the tegumentary nerve. The corpora cardiaca (CC) and corpora allata (CA) are closely approximated to each other obliterating the nervi corporis allati (NCA) which are conspicuous in the larva of the same species. An intercardiacal bridge (ICB) connects the CC of the two sides and acts as a possible centre of distribution for the neurosecretory material (NSM) to the gut. Histological evidence suggests that the NSM inside the CC remains intraaxonal without being primarily unloaded in the organs for storage. The intrinsic secretory cell of the CC are intimately associated with the neurosecretory fibres from the brain and bear fairly thick axons. No NSM could be detected in the CA of this insect.     

Neurosecretory system of the earwig Labedura riparia, and the rôle of the aorta as a neurohaemal organ

The neurosecretory system of Labedura riparia has been described from sections and whole mounts using a variety of techniques. The pars intercerebralis contains two clusters of medial neurosecretory cells (MNC), each cluster consisting of 8 to 10 A-cells and occasional B-cells. The lateral sides of the brain have a few B-cells. The axons of the median neurosecretory cells terminate in the cephalic aorta (AO), whereas the axons of the lateral neurosecretory cells (LNC) terminate in the corpora cardiaca (CC). It appears that the neurosecretory material (NSM) elaborated in the MNC is stored in the cephalic aorta and that elaborated in the LNC is stored in the corpora cardiaca, which are two oval or elongate bodies composed of large chromophobe and small chromophil cells. Posteriorly there is the oval or elongate corpus allatum (CA) attached to the CC by thick nerves. The CA consists of one cell type only. Both CC and CA contain no A-cell neurosecretory material. It has been suggested that the neurosecretory system of L. riparia is composed of two complexes. One is formed by the medial neurosecretory cells for which the aorta functions as a neurohaemal organ, and the other is formed by lateral neurosecretory cells-lateral neurosecretory pathways-nervi corporis cardiaci-II in which the corpora cardiaca function as a neurohaemal organ.     

New features of the brain-retrocerebral neuroendocrine complex of the locust Schistocerca vaga (scudder)

Summary The techniques of axonal iontophoresis and cobalt sulfide precipitation were used to elucidate the relationships of the brain's neurosecretory cell groups and the retrocerebral complex of the locust Schistocerca vaga. The axons of the nervi corporis cardiaci I (NCC I) arise (1) from the medial neurosecretory cells of the protocerebrum, showing only limited branching, looping or spiraling; and (2) from a cell group previously undescribed for this species, located in the tritocerebrum. The axons project into the neurohemal and the glandular portions of the corpora cardiaca and into the hypocerebral ganglion, but not into the corpora allata. Axons of the NCC II arise from the lateral neurosecretory cells of the protocerebrum and project into the center of the corpora allata via the nervi corporis allati I (NCA I), as well as into the neurohemal and glandular portions of the corpora cardiaca. Axons of the NCC III arise from another newly described cell group in the tritocerebrum and end in both the corpora cardiaca and corpora allata. Axons of the NCA II arise from cells in the subesophageal ganglion and also end in the corpora allata.Supported by NIH Predoctoral Fellowship No. 5 F 01 GM 43816-03, NSF Grant GB-23033 and NIH Grant CA-05045 to H. A. Bern and USPHS Grant 1 R 01 NS09404 to C.H.F. Rowell.I wish to express my gratitude to Professors H.A. Bern and C.H.F. Rowell for unending encouragement and advice. I am indebted to Dr. Mick O'Shea for instruction in the cobalt/axonal iontophoresis method, and to Ms. Bea Bacher for excellent technical assistance.     

Developmental Changes in the Bombyxin-and Insulin-like Immunoreactive Neurosecretory System in the Wax Moth, Galleria mellonella

Four medial neurosecretory cells (MNC) and 4 lateral neurosecretory cells (LNC) in each brain hemisphere, and one pair of cells in each thoracic ganglion (TG) of Galleria larva react with antibodies against bombyxin and insulin. Material secreted from the MNC and LNC is released mainly in the corpora allata, and that from the TG through the ventral median nerves. Intrinsic secretory cells of the corpora cardiaca (CC) also contain bombyxin-like, but not insulin-like material. The immunoreactivities all disappear during molts and reappear with resumption of feeding. In the MNC and TG they reappear for less than a day, but in cells of the CC immunoreactivity reappears for the whole feeding period. Before pupation, the LNC become temporarily immunopositive towards the end of feeding period, and the MNC and TG during the wandering period, i.e. at the time of prothoracic gland stimulation. Immunoreactivity disappears during the pupal molt. In pupae it is present in the 4 pairs of MNC and 1–2 pairs of LNC 12–48 hr after ecdysis, and in cells of the CC from 12 hr after ecdysis until the end of the pupal instar. In adult, immunoreactivity is restricted to 2 pairs of the LNC and to CC cells.     

Neurons projecting from the brain to the corpora allata in orthopteroid insects: anatomy and physiology

Retrograde and orthograde labeling of neurons projecting to the corpus allatum was performed in locust, grasshopper, cricket, and cockroach species in order to identify brain neurons that may be involved in the regulation of juvenile hormone production. In the acridid grasshopper Gomphocerus rufus L., and the locusts Locusta migratoria (R.&F.) and Schistocerca gregaria Forskal, the corpora allata are innervated by two morphologically distinguishable types of brain neurons. One group of 9–13 neurons (depending on species) with somata in the pars lateralis extend axons via the nervus corporis cardiaci 2 and nervus corporis allati 1 to the ipsilateral corpus allatum, whereas two cells in each pars lateralis have bilateral projections and innervate both glands. No direct connection between the pars intercerebralis and corpus allatum has been found. In contrast, neurons with paired axons innervating both glands are not present in Periplaneta americana (L.) and Gryllus bimaculatus de Geer. Instead, two cells in each pars lateralis project only to the gland contralateral to their somata. Electrophysiological experiments on acridid grasshoppers have confirmed the existence of a direct conduction pathway between the two glands via the paired axons of four cells that have been identified by neuroanatomy. These cells are not spontaneously active under experimental conditions. Ongoing discharges in the left and right nerves are unrelated, suggesting that the corpora allata receive independent neuronal inputs from the brain.     

Immunological evidence for an allatostatin-like neuropeptide in the central nervous system of Schistocerca gregaria,Locusta migratoria and Neobellieria bullata

Methanolic brain extracts of Locusta migratoria inhibit in vitro juvenile hormone biosynthesis in both the locust L. migratoria and the cockroach Diploptera punctata. A polyclonal antibody against allatostatin-5 (AST-5) (dipstatin-2) of this cockroach was used to immunolocalize allatostatin-5-like peptides in the central nervous system of the locusts Schistocerca gregaria and L. migratoria and of the fleshfly Neobellieria bullata. In both locust species, immunoreactivity was found in many cells and axons of the brain-retrocerebral complex, the thoracic and the abdominal ganglia. Strongly immunoreactive cells were stained in the pars lateralis of the brain with axons (NCC II and NCA I) extending to and arborizing in the corpus cardiacum and the corpora allata. Although many neurosecretory cells of the pars intercerebralis project into the corpus cardiacum, only 12 of them were immunoreactive and the nervi corporis cardiaci I (NCC I) and fibers in the nervi corporis allati II (NCA II) connecting the corpora allata to the suboesophageal ganglion remained unstained. S. gregaria and L. migratoria seem to have an allatostatin-like neuropeptide present in axons of the NCC II and the NCA I leading to the corpus cardiacum and the corpora allata. All these data suggest that in locusts allatostatin-like neuropeptides might be involved in controlling the production of juvenile hormone by the corpora allata and, perhaps, some aspects of the functioning of the corpus cardiacum as well. However, when tested in a L. migratoria in-vitro juvenile hormone-biosynthesis assay, allatostatin-5 did not yield an inhibitory or stimulatory effect. There is abundant AST-5 immunoreactivity in cell bodies of the fleshfly N. bullata, but none in the CA-CC complexes. Apparently, factors that are immunologically related to AST-5 do occur in locusts and fleshflies but, the active protion of the peptide required to inhibit JH biosynthesis in locusts is probably different from that of AST-5.     

An active principle from the corpora cardiaca,corpora allata and suboesophageal ganglion of the locust,inducing egg diapause in Bombyx mori

The activity of the substance(s) which are contained in the cephalic endocrine organs of the locust which induce egg diapause in Bombyx mori was examined by implantation and injection of saline extracts of these organs. Extracts from the median and lateral neurosecretory parts of the locust brain were not effective in inducing egg diapause. Extracts of the corpora cardiaca, corpora allata, and suboesophageal ganglion of the locust induced diapause eggs in Bombyx pharate adults from which the suboesophageal ganglion had been removed. The first two extracts could induce egg diapause even in isolated abdomens of pharate adults of Bombyx. In the locust corpora cardiaca, the activity was present only in the glandular lobe and not in the nervous region. This activity decreased when the nervi corporis cardiaci I and II and of nervi corporis allati I were cut. Allatectomy also brought about a decrease in the activity in the glandular lobe which could not be restored by the injection of juvenile hormone. The activity in the corpora allata was enhanced slightly by the disconnection though not significantly.From these results, it is assumed that the corpora cardiaca, corpora allata and suboesophageal ganglion of the locust contain and active principle(s) capable of inducing egg diapause in Bombyx mori. The nervous connections between the brain, corpora cardiaca, and corpora allata are essential for the accumulation of the active substance(s) in the glandular lobes of the corpora cardiaca.     

Three-dimensional architecture of identified cerebral neurosecretory cells in an insect

The organization of identified neurosecretory cell groups in the larval brain of the tobacco hornworm, Manduca sexta, was investigated immunocytologically. Computer-assisted three-dimensional reconstruction was used to examine the architecture of the neurosecretory cell groups. The group III lateral neurosecretory cells (L-NSC-III) which produce the prothoracicotropic hormone are located dorsolaterally in the protocerebrum and extend axons medially that decussate to the contralateral lobe prior to exiting the brain through the nervi corporis cardiaci I + II. The group IIa2 medial neurosecretory cells (M-NSC IIa2) are located anteriorly in the medial dorsal protocerebrum. The axons of these cells also exit the brain via the contralateral nervi corporis cardiaci I + II. However, their axons traverse a different pathway through the brain from that of the L-NSC III axons. Each of the cell groups possesses elaborate dendrites with terminal varicosities. The dendrites can be classified into specific fields based upon their location and projection pattern within the brain. The dendrites for these two neurosecretory cell groups overlap in specific regions of the protocerebral neuropil. After the axons of these neurosecretory cells exit the brain through the retrocerebral nerve, they innervate the corpus allatum where they arborize to form neurohemal terminals in strikingly different patterns. The L-NSC III penetrate throughout the glandular structure and the M-NSC IIa2 terminals are restricted to the external sheath. A third group of cerebral neurosecretory cells, the ventromedial neurons (VM) which stain with the monoclonal antibody to prothoracicotropic hormone in Manduca, are located anteriorly in the medial region of the brain. The axons of these cells do not exit the brain to the retrocerebral complex, but rather pass through the circumesophageal connectives and ventral nerve cord. These neurons appear to be the same VM neurons that produce eclosion hormone. One dendritic field of the L-NSC III terminates in close apposition to the VM neurons. The distinct morphologies of these neurosecretory cell groups in relation to other cell groups and the distribution of neuropeptides within the neurons suggest that insect neurosecretory cells, like their vertebrate counterparts, may have multiple regulatory roles.     

The innervation of the corpus cardiacum of Locusta migratoria: A neuroanatomical study with the use of Lucifer yellow

Summary Neural connections of the corpus cardiacum (CC) in the African locust, Locusta migratoria, were labelled with the fluorescent tracer Lucifer yellow. (1) Unilateral anterograde labelling of the nervus corporis cardiaci I revealed fluorescent fibres in the storage lobe of the CC (CCS). Some fluorescent fibres in the CCS closely approached the ipsilateral border of the glandular lobes of the CC (CCG). Fluorescent fibres also projected into the neuropile of the hypocerebral ganglion via the ipsilateral nervi cardiostomatogastrici I and II, and from there into the oesophageal nerves. (2) Unilateral anterograde labelling of the nervus corporis cardiaci II revealed fluorescent fibres in the CCS and in the ipsilateral CCG. Fluorescent fibres also projected via the ipsilateral nervus corporis allati I into the corpus allatum. (3) Unilateral retrograde labelling of the nervus corporis allati I revealed a distinct fluorescent nerve tract that runs through the CCS and into the nervus corporis cardiaci II. The tract arises from about eight cell bodies in the brain at the rostroventral side of the ipsilateral calyx of the mushroom body. (4) Labelling of the recurrent nerve revealed fluorescent fibres and some fluorescent cell bodies in the hypocerebral ganglion and, via the nervi cardiostomatogastrici I and II, also in the CCS. Fluorescent fibres were also present in the oesophageal nerves.     

Proctolin-like immunoreactivity in the central and peripheral nervous systems of the locust, Locusta migratoria

Proctolin-like immunoreactivity (PLI) was widely distributed in the locust, Locusta migratoria, within the central, peripheral and stomatogastric nervous systems, as well as the digestive system and retrocerebral complex. Proctolin-like immunoreactivity was observed in cells and processes of the brain and all ganglia of the ventral nerve cord. Of interest, PLI was found in the lateral neurosecretory cells, which send axons within the paired nervi corporis cardiaci II (NCC II) to the corpus cardiacum (CC). The CC contained extensive processes displaying PLI, which continued on within the paired nervi corporis allata (NCA) to the paired corpora allata (CA) where the axons entered and branched therein. The frontal and hypocerebral ganglia of the stomatogastric nervous system contained PLI within processes, resulting in a brightly staining neuropile. Each region of the gut contained PLI in axons and processes of varying patterns and densities. The paired ingluvial ganglia contained PLI, including an extensively stained neuropile and immunoreactive axons projecting through the nerves to the foregut. The hindgut contained PLI within longitudinal tracts, with lateral projections originating from the 8th abdominal ganglion via the proctodeal nerve. The midgut contained PLI in a regular latticework pattern with many varicosities and blebs. No difference in PLI in cells and processes of the central nervous system (CNS) was found between males and females.     

THE NEUROENDOCRINE SYSTEM AND STOMATOGASTRIC NERVOUS SYSTEM OF THE ADULT TSETSE FLY GLOSSINA MORSITANS

The brain of Glossina morsitans Westwood contains four groups of neurosecretory cells which are stainable with chrome haematozylin and phloxin. The axons of these cells form a pair of nervi corporis cardiaci which pass posteriorly from the brain and innervate the corpora cardiaca and corpus allatum before uniting with a small ganglion posterior to the corpora cardiaca. This ganglion is considered to represent the fusion of the fusion of the hypocerebral and ventricular ganglia which remain separate in other insects.
There is no frontal ganglion in the adult Glossina and the recurrent nerve fuses with one of the nervi corporis cardiaci immediately behind the brain. The oesophageal nerves arising from the fused hypocerebral and ventricular ganglia innervate the oesophagus in the anterior part of the thorax, the proventriculus and the posterior extension of the oesophagus close to the crop. These nerves possess both sensory and motor nerve endings. The differences which exist between Glossina and other cyclorrhaphous Diptera with respect to their neuroendocrine/stomatogastric system are noted and considered in terms of the control of neuroendocrine function.     

The Morphology of the Stomodeal Nervous System in the Adult Dragon Flies Bradinopyga geminata and Orthetrum chrysis (Libellulidae)

The morphology of the stomodeal nervous system of the adult dragon flies Bradinopyga geminata and Orthetrum chrysis is described. No gastric ganglion or ganglion ingluviale has been found. Instead the oesophageal nerve forks near the junction of the proventriculus and the midgut. The two nerves run on either side of the midline as ingluvial nerves and enter the proventricular ganglionic masses. These ganglionic masses are connected by a transverse nerve, which has been called as the nervus transversus proventriculare. Both bipolar and multipolar types of sensory cells have been found over the surface of the crop. These cell bodies appear to be interconnected by connective tissue. Dendrites of these cells terminate on the longitudinal muscle fibres, surrounding the proventriculus and the midgut. The proximal processes of these cells enter the proventricular ganglionic mass. In methylene blue whole mounts they resemble the stretch receptors, hence it is quite probable that they play some role in the peristaltic movement of the gut. The corpora cardiaca lie dorsal to the pharynx and are connected to the brain by two pairs of nerves, the nervi corporis cardiaci (NCC I, NCC II). Unlike in other insects, the nerve connecting the corpora cardiaca with the corpora allata is slender and arises as a branch of the nerve, nervus corporis allati II. The corpora alata are spherical to ovoid in shape and lie ventral to the nerve cord. Anteriorly they are attached to the inner wall of the hypopharynx and posteriorly to the subesophageal ganglion by a pair of nerves, the nervi corporis allati II.     

ACTIVATION OF THE CORPORA ALLATA IN RELATION TO OVARIAN MATURATION IN THE SEASONAL FORMS OF THE BUTTERFLY, POLYGONIA C-AUREUM L.

In Polygonia c-aureum , there are two seasonal forms, viz. , the summer form and the autumn form. Previous experiments (E ndo , 1970) showed that the corpora allata of the summer form accelerate the maturation of ovarian follicles soon after imaginal ecdysis. On the other hand, the corpora allata of the autumn form do not stimulate ovarian maturation during a period of 2 to 3 weeks after the emergence.
In the summer form (S) as well as in the autumn form (A), the corpora allata remained in an inactive state for about 15 days after emergence when they had been isolated microsurgically from the brain and the corpora cardiaca during the larval period. Further, when separation of the brain into the right and left hemispheres or ablation of the medial neurosecretory group cells of the pars intercerebralis had been carried out on S-pupae of 28 hr after pupation or of earlier ages, they developed into autumn form in respect to wing pattern and their corpora allata did not stimulate ovarian maturation until 2 to 3 weeks after emergence. On the other hand, when the above operations had been performed 34 hr after the pupation or of later ages, they developed into summer form in respect to wing pattern and ovarian maturation was evident soon after the emergence. In these cases, stimulation of the corpora allata is closely connected with the development of seasonal-forms of wing pattern.
From these experiments, it is clear that the medial neurosecretory group cells of the pars intercerebralis in S-insects stimulate the corpora allata about 30 hr after pupation by way of the nervi corporis cardiaci and the activated corpora allata promote ovarian maturation throughout adult life. In A-insects, on the other hand, the medial neurosecretory group cells of the brain are inactive and fail to activate the corpora allata which in turn have no influence on ovarian maturation.     

Immunohistochemical Localization of Prothoracicotropic Hormone-Producing Neurosecretory Cells in the Brain of Bombyx mori

A monoclonal antibody that recognized the Bombyx prothoracicotropic hormone (PTTH) was produced by immunizing mice with a synthetic pentadecapeptide corresponding to the amino-terminal portion of Bombyx PTTH. The antibody recognized both intact and reduced forms of PTTH. Immunohistochemistry with this antibody has demonstrated that PTTH is produced by two pairs of dorso-lateral neurosecretory cells of the brain and transported to the corpora allata by axons running through the contralateral hemisphere of the brain. Immunoreactive axon terminals in the corpora allata were localized between the glandular cells, suggesting that PTTH is released at the inner part of this organ.     

The neurosecretory cells of the brain and suboesophageal ganglion of Chironomus riparius

The neurosecretory cells of the supra- and suboesophageal ganglia of young, unmated, adult male midges, Chironomus riparius, have been examined by both light and electron microscopy. The 5 cell types recognized have been placed in three major categories on the basis of their ultrastructural characteristics:—α₁ cells, of which there are 8 in each medial neurosecretory cell (MNC) group and 3 in each group of ventral neurosecretory cells (VNC), contain electron-dense granules, 150 to 200 nm in diameter; α₂ cells containing irregular, electron-dense granules, 70 to 120 nm in diameter comprise the remaining 3 cells in each VNC group and the 2 or 3 cells in each outer neurosecretory cell (ONC) group; α₃ cells, of which there are 1 or 2 on each side of the midline in the ventral cortex of the sub-oesophageal ganglion (SNC₂), contain electron-lucent, spherical granules, 70 to 120 nm in diameter. The β cells contain spherical or ellipsoidal, electron-lucent granules, 80 to 100 nm in diameter, and make up the lateral neurosecretory cell (LNC) groups, each of three or four cells. The γ cells contain both spherical and flattened, electron-dense granules, 130 to 160 nm in diameter and 150 to 250 by 70 to 150 nm in size respectively, only 1 cell of this category being found in each half of the suboesophageal ganglion in the dorsal cortex (SNC₁). Axons from the MNC and VNC form the nervi corporis cardiaci I (NCCI) and those of the LNC and ONC, the nervi corporis cardiaci II (NCCII). Those of the SNC₁ appear to enter the wall of the stomodaeum but axons of the SNC₂ could not be traced.     

The development of identified neurosecretory cells in the tobacco hornworm, Manduca sexta

The prothoracicotropic hormone (PTTH) is a principal neuropeptide regulator of insect postembryonic molting and metamorphosis. In the tobacco hornworm, Manduca sexta, PTTH is produced by two neurosecretory cells (NSC) located in each protocerebral lobe of the brain. The development of these neurons, the L-NSC III, has been investigated immunocytologically to establish the time course of their morphological differentiation. PTTH may be one of the earliest neuropeptides expressed in insect embryos. PTTH-immunoreactivity was initially detected in the somata at 24 to 30% of embryonic development. Neurites sprouted shortly thereafter and began to grow medially through the brain anlage. By 42% embryonic development, the neurites had decussated to the contralateral brain lobe. As development progressed, the L-NSC III neurites grew along specific tracts through the contralateral brain lobe reaching the ventrolateral regions of the brain by approximately 60% development. The axons exited the brain through a retrocerebral nerve, the nervi corporis cardiaci I + II. At approximately 63% development, the axons innervated the corpus allatum and began branching to form neurohemal terminals for PTTH release. At 60% development, short collaterals began extending in the protocerebral neuropil. During the remainder of embryogenesis, both the dendritic collaterals and the terminal neurohemal varicosities continued to elongate and arborize. By 85% embryonic development, the basic architecture of the L-NSC III was established.     

The development of identified neurosecretory cells in the tobacco hornworm, Manduca sexta

The prothoracicotropic hormone (PTTH) is a principal neuropeptide regulator of insect postembryonic molting and metamorphosis. In the tobacco hornworm, Manduca sexta, PTTH is produced by two neurosecretory cells (NSC) located in each protocerebral lobe of the brain. The development of these neurons, the L-NSC III, has been investigated immunocytologically to establish the time course of their morphological differentiation. PTTH may be one of the earliest neuropeptides expressed in insect embryos. PTTH-immunoreactivity was initially detected in the somata at 24 to 30% of embryonic development. Neurites sprouted shortly thereafter and began to grow medially through the brain anlage. By 42% embryonic development, the neurites had decussated to the contralateral brain lobe. As development progressed, the L-NSC III neurites grew along specific tracts through the contralateral brain lobe reaching the ventrolateral regions of the brain by approximately 60% development. The axons exited the brain through a retrocerebral nerve, the nervi corporis cardiaci I + II. At approximately 63% development, the axons innervated the corpus allatum and began branching to form neurohemal terminals for PTTH release. At 60% development, short collaterals began extending in the protocerebral neuropil. During the remainder of embryogenesis, both the dendritic collaterals and the terminal neurohemal varicosities continued to elongate and arborize. By 85% embryonic development, the basic architecture of the L-NSC III was established.     

Morphology of neurones associated with the antennal heart of Periplaneta americana (Blattodea,Insecta)

Summary Innervation of the antennal heart, an independent accessory circulatory motor in the head of insects, was investigated in the cockroach Periplaneta americana by use of axonal cobalt filling and transmission electron microscopy. The muscles associated with this organ are innervated by neurones located in a part of the suboesophageal ganglion, generally considered to be formed by the mandibular neuromere. Dorsal unpaired median (DUM) and paired contralateral neurones were stained. The axons of all these neurones run along the circumoesophageal connectives and through the paired nervus corporis cardiaci III into the corpora cardiaca. They pass through these organs forming fine arborizations there and exit anteriorly as a small pair of nerves which terminate at the antennal heart-dilator muscles. Numerous branches of these nerves extend beyond the lateral borders of the large transverse dilator muscle and terminate in the ampullar walls of the antennal heart. These neurosecretory fibres form neurohaemal areas which obviously release their products into the haemolymph, which is pumped into the antennae. The possible functions of the neurones associated with the antennal heart are discussed with respect to both, their role as a modulatory input for the circulatory motor and as a neurohormonal release site.     

Development of blood-cerebrospinal fluid barrier to horseradish peroxidase in the avian choroidal epithelium

Summary Four neurons in the brain of the migratory locust were immunohistologically identified with an anti-met-enkephalin antiserum. The perikarya of two of these cells are located in the center of each of the two groups of lateral protocerebral neurosecretory cells. The fibres coming from these perikarya terminate in numerous immunoreactive ramifications visible at the periphery of both tractus I to the corpora cardiaca, through which pass the neurosecretory products of the pars intercerebralis. The other two cell bodies are located at the bases of the two optic lobes; their fibres enter the posterior part of the protocerebrum and ramify around the root of the nervus corporis cardiaci II, another area through which neurosecretory products pass. The topographic distribution of these met-enkephalin arborizations suggests that these four neurons may act as neuromodulators of the acitivity of the major neurosecretory cells in the brain of this insect.