Anatomy of neurons crossing the tritocerebral commissures of the cockroach Periplaneta americana (Blattaria)

The neuronal connections of the tritocerebral commissures of Periplaneta americana were studied in the brain-suboesophageal ganglion complex and the stomatogastric nervous system by means of heavy metal iontophoresis through cut nerve ends followed by silver intensification. The tritocerebral commissure 1 (Tc1) contains mainly the processes of the subpharyngeal nerve (Spn) whose neurons are located in both tritocerebral lobes and in the frontal ganglion. Some neurons of the frontal ganglion project through the Tc1 to the contralateral tritocerebrum. A few fibers in this commissure were observed projecting to the protocerebrum and the suboesophageal ganglion. There are tritocerebral neurons which pass through the Tc1 or the tritocerebral commissure 2 (Tc2) and extend on into the stomatogastric nervous system. One axon of a descending gaint neuron appears in the Tc2. This neuron lies in the tritocerebrum and connects the brain to the contralateral side of the ventral nerve cord. In addition, sensory fibers of the labral nerve (Ln) traverse both commissures to the opposite tritocerebrum. The anatomical and physiological relevance of the identified neuronal pathways is discussed. © 1995 Wiley-Liss, Inc.     

Diffuse serotoninergic neurohemal systems associated with cerebral and suboesophageal nerves in the head of the Colorado potato beetle Leptinotarsa decemlineata

We analyzed the anatomy of two diffuse neurohemal systems for serotonin in the head of the Colorado potato beetle Leptinotarsa decemlineata by means of immunohistochemistry. One system is formed by axons from two bilateral pairs of neurons in the frontal margin of the suboesophageal ganglion that enter the ipsilateral mandibular nerve, emerge from this nerve at some distance from the suboesophageal ganglion, and cover all branches of the mandibular nerve with a dense plexus of immunoreactive axon swellings. The other system is formed by axons from two large neurons in the frontal ganglion that enter the ipsilateral frontal connectives, emerge from these connectives, and form a network of axon swellings on the labroforntal, pharyngeal, and antennal nerves and on the surface of the frontal ganglion. Immunohistochemical electron microscopy demonstrated that the axon swellings are located outside the neural sheaths of the nerves and hence in close contact with the hemolymph. We therefore suggest that these plexuses represent extensive neurohemal systems for serotonin. Most immunoreactive terminals are in direct contact with the hemolymph, and other terminals are closely associated with the muscles of the mandibles, labrum, and anterior pharynx, as well as with the salivary glands, indicating that these organs are under serotoninergic control.     

Anatomical and functional characterisation of the stomatogastric nervous system of blowfly (Calliphora vicina) larvae

The anatomy and functionality of the stomatogastric nervous system (SNS) of third-instar larvae of Calliphora vicina was characterised. As in other insects, the Calliphora SNS consists of several peripheral ganglia involved in foregut movement regulation. The frontal ganglion gives rise to the frontal nerve and is connected to the brain via the frontal connectives and antennal nerves (ANs). The recurrent nerve connects the frontal- to the hypocerebral ganglion from which the proventricular nerve runs to the proventricular ganglion. Foregut movements include rhythmic contractions of the cibarial dilator muscles (CDM), wavelike movements of crop and oesophagus and contractions of the proventriculus. Transections of SNS nerves indicate mostly myogenic crop and oesophagus movements and suggest modulatory function of the associated nerves. Neural activity in the ANs, correlating with postsynaptic potentials on the CDM, demonstrates a motor pathway from the brain to CDM. Crop volume is monitored by putative stretch receptors. The respective sensory pathway includes the recurrent nerve and the proventricular nerve. The dorsal organs (DOs) are directly connected to the SNS. Mechanical stimulation of the DOs evokes sensory activity in the AN. This suggests the DOs can provide sensory input for temporal coordination of feeding behaviour.     

The myth of intercalary segment in insect head

Embryonic development of the head of Oxyrhachis tarandus (Membracidae) has been investigated in detail to settle the controversy of head segmentation and to refute the occurrence of an intercalary segment. The head is formed from six distinct elements: the prostominal lobe, the paired cephalic lobes, the antennal segment and the three noncontroversial gnathal segments. The prostomial lobe, which possesses a neuromere and a pair of coelomic cavities, represents the first body segment, called the prostomial segment. The tritocerebral lobes of the brain and the stomatogastric nervous system, consisting of a frontal ganglion, clypeolabral nerves, and the recurrent nerve etc., develop from the neuromere of the prostomial lobe. The tritocerebrum thus belongs to the prostomial segment rather than to an imaginary intercalary segment and mainly represents the ganglionic center of the stomatogastric nervous system in the brain. Frons, clypeus, and labrum develop from the outer wall of the prostomial lobulate plate, whereas the epipharyngeal wall, including the cibarial pump, develops from its inner wall. The presence of three coelomic cavities and of three distinct neural masses in the cephalic lobes during the initial stages of development shows that they have developed by the fusion of three distinct segments during the long phylogenetic history of insects. The portion of the germ band presently considered as the intercalary segment is actually the sternal part of the antennal segment. The neural cells located in this region give rise to the deutocerebrum by shifting forward, around the stomodaeum, and always leaving a commissure behind. The intercalary segment is thus a complete illusion. The antennal segment is postoral in the beginning and bears a pair of coelomic cavities, but later on it shifts forward and its sternal part invaginates into the stomodaeum.     

Serotonin-immunoreactive neurons in the antennal lobes and suboesophageal ganglion of the honeybee

Summary We have used immunohistochemical methods to investigate the morphology of identified, presumptive serotonergic neurons in the antennal lobes and suboesophageal ganglion of the worker honeybee. A large interneuron (deutocerebral giant, DCG) is described that interconnects the deutocerebral antennal and dorsal lobes with the suboesophageal ganglion and descends into the ventral nerve chord. This neuron is accompanied by a second serotonin-immunoreactive interneuron with projections into the protocerebrum. Two pairs of bilateral immunoreactive serial homologues were identified in each of the three suboesophageal neuromeres and were also found in the thoracic ganglia. With the exception of the frontal commissure, no immunoreactive processes could be found in the peripheral nerves of the brain and the suboesophageal ganglion. The morphological studies on the serial homologues were extended by intracellular injections of Lucifer Yellow combined with immunofluorescence.     

Fine Structural Analysis of the Central Nervous System in the Spider, Achaearanea tepidariorum (Theridiidae: Araneae)

ABSTRACT Central nervous system (CNS) of arachnids is still mysterious and has a rich unexplored field compare to what is known in insects or crustaceans. The CNS of the spider, Achaearanea tepidariorum, consists of a dorsal brain or supraesophageal ganglion and circumesophageal connectives joining it to the subesophageal mass. As the segmentation of the arachnid brain is still under discussion, we classify the brain as a protocerebral and tritocerebral ganglion depending on the evidences which generally accepted. The subesophageal nerve mass underneath the brain is the foremost part of the ventral nerve cord. All of this nerve mass is totally fused together, and forming subesophageal ganglia in this spider. In the brain, the nerve cells are packed in the frontal, dorsal and lateral areas, but are not absent from the posterior and ventral regions. In addition, the nerve cells of the subesophageal and abdominal ganglia are only restricted to the ventral and ventolateral regions. The CNS of the spider, Achaearanea tepidariorum is similar in feature to the Family Araneidae.     

Anatomy of the stomatogastric nervous system associated with the foregut in Drosophila melanogaster and Calliphora vicina third instar larvae

The stomatogastric nervous system (SNS) associated with the foregut was studied in 3rd instar larvae of Drosophila melanogaster and Calliphora vicina (blowfly). In both species, the foregut comprises pharynx, esophagus, and proventriculus. Only in Calliphora does the esophagus form a crop. The position of nerves and neurons was investigated with neuronal tracers in both species and GFP expression in Drosophila. The SNS is nearly identical in both species. Neurons are located in the proventricular and the hypocerebral ganglion (HCG), which are connected to each other by the proventricular nerve. Motor neurons for pharyngeal muscles are located in the brain not, as in other insect groups, in the frontal ganglion. The position of the frontal ganglion is taken by a nerve junction devoid of neurons. The junction is composed of four nerves: the frontal connectives that fuse with the antennal nerves (ANs), the frontal nerve innervating the cibarial dilator muscles and the recurrent nerve that innervates the esophagus and projects to the HCG. Differences in the SNS are restricted to a crop nerve only present in Calliphora and an esophageal ganglion that only exists in Drosophila. The ganglia of the dorsal organs give rise to the ANs, which project to the brain. The extensive conformity of the SNS of both species suggests functional parallels. Future electrophysiological studies of the motor circuits in the SNS of Drosophila will profit from parallel studies of the homologous but more accessible structures in Calliphora.     

The stomatogastric nervous system of the house cricket Acheta domesticus L. I. The anatomy of the system and the innervation of the gut

The distribution of the ganglia and nerves of the stomatogastric nervous system and the innervation of the extrinsic and intrinsic muscles are described. Median unpaired frontal and hypocerebral ganglia and paired ingluvial ganglia are present. The anterior pharynx is innervated by branches of the frontal nerve and by the anterior and posterior pharyngeal nerves, originating from the frontal ganglion. The posterior pharyngeal nerves are linked to nerves innervating the posterior part of the pharynx which have their origin in the hypocerebral ganglion, the anterior portion of which has previously been regarded as part of the recurrent nerve. Paired esophageal nerves run the length of the esophagus and crop between the hypocerebral and and ingluvial ganglia, innervating the muscularis by serial side branches. From each ingluvial ganglion runs an ingluvial nerve which innervates the gizzard and a cecal nerve which innervates the midgut and its ceca. At the posterior end of the midgut there is a poorly developed nerve ring. Nerves running posteriorly from this nerve ring link the stomatogastric nervous system with the proctodeal innervation from the terminal abdominal ganglion. Multipolar peripheral neurons are present on the muscularis of the whole of the foregut, rather randomly distributed on the crop and gizzard but forming fairly definite groupings at some points on the pharynx. Though of varied appearance, these cells could not be divided into discrete morphological categories. Peripheral neurons on the midgut are of different and characteristic morphology, though a few cells of the same appearance as those of the foregut occur at the midgut-hindgut boundary. Nerve fibers on the gut almost invariably terminate on the fibers of the muscularis.     

蟋蟀脑的解剖结构与生理机能

蟋蟀脑由前脑、中脑和后脑三部分组成。前脑由1对蕈形体、中央复合体和视叶构成;每个蕈形体由2个冠、柄及与柄相连的α叶和β叶组成,是信息联络整合部位;中央复合体由中央体和脑桥组成,主要参与感觉信息的加工过程;视叶由神经节层、外髓和内髓组成,是视觉系统的中心。中脑由主要组成成分为嗅觉纤维球的嗅叶组成,是嗅觉系统的中心。后脑向后与食道下神经节相连。     

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.     

Induction of body distension by operations on the nervous system in larvae of the swallowtall, Papilio xuthus

Removal of the ganglion or severance of the nerve cords at the thorax in mature larvae of the swallowtail, Papilio xuthus, induced systemic distension of the body by swallowing excess air. Such a distension, however, was never induced by simultaneous extirpation of the brain, suboesophageal ganglion, or frontal ganglion, or by severance of the recurrent nerve. Removal of an abdominal ganglion induced distension of the posterior part of the body accompanied by shrinkage of the anterior part. The latter phenomenon appears to be induced by a different mechanism from that of systemic distension.     

Suboesophageal neurons involved in head movements and feeding in locusts.

The projections of nerves 6 and 7 of the locust suboesophageal ganglion (SOG) were stained by axonal filling with cobalt chloride. Nerve 6 contains two motoneurons which innervate neck muscles 50 and 51. Sensory neurons innervating hairs on the dorso-occipital region of the head also enter the ganglion through nerve 6 and terminate in a small bilateral plexus. The projections of the head hairs in nerve 6 do not overlap the arborizations of the motoneurons or the neurons of nerve 7, but lie in the same area as descending sensory neurons from wind-sensitive hairs of the front of the head. One branch of nerve 7 (7B) contains two fibres which innervate the salivary gland. These 'salivary' neurons (labelled SN1 and SN2) have their cell bodies in the ganglion. The second branch, 7A, contains sensory neurons from the submentum of the labium, which form four sensory plexuses, two dorsal and two ventral. The sensory plexuses from the submentum have specific regions of overlap with the salivary neurons and with the neck muscle motoneurons. We interpret these as indicating a flow of information from labial receptors signalling head and mouthpart movement to neurons involved in salivation and head movement. We further postulate that the anatomical separation of the various sensory plexuses is indicative of functional localization within the ganglion.     

A study of the cerebral region of the visual system in the pulmonata

The distribution of central axons of receptor cells of the eyes and the locations of neurons sending axons into the optic nerves were studied in the cerebral ganglia of the pulmonate mollusksLymnaea stagnalis andHelix sp. by the method of axonal transport of cobalt chloride injected via the optic nerves. Afferent fibers of these nerves form terminal ramifications (chiefly dorsally) in the middle part of the cerebral ganglion. Some of them pass through the commissure to the symmetrical region of the opposite cerebral ganglion. Neurons innervating the eyes are located in several regions of both cerebral ganglia. InLymnaea they are distributed near the point of entry of the optic nerve, in the region of the commissure, the mesocerebrum, and the posterior part of the ganglion. InHelix these neurons are found in the same regions except in the posterior part of the ganglion. In electrophysiological experiments responses of neurons in these parts of the cerebral ganglion to adequate stimulation of the eye were recorded. Differences in the character of responses and also the presence of neurons indifferent to stimulation of the eye are evidence of the functional heterogeneity of these areas. This suggests that morphologically separate visual centers do not exist in the cerebral ganglion of the Pulmonata. Neurons giving specific responses to stimulation of the eye and evidently belonging to different levels of the visual system (afferent or efferent divisions) are closely connected both with each other and with cells of other functional systems.A. A. Ukhtomskii Physiological Research Institute, A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 14, No. 2, pp. 179–184, March–April, 1982.     

Neurons with ‘secretory end-feet’-A probable neuroendocrine complex in Nereis

A neuronal complex of unusual cytological character and probable glandular function is located within the cerebral ganglion in Nereidae (Polychaeta). The perikarya form a pair of ganglionic nuclei situated above the optic commissure. Each nucleus gives rise to a tract of stout axons that passes between the anterior and posterior optic nerves and down through the neuropile. Beneath the neuropile the axons separate from each other and branch extensively before terminating on the brain floor as ‘secretory end-feet’. These endings are scattered over a wide area of the inner surface of the brain capsule and exhibit a topographical relationship with the infracerebral gland.     

Musculature and nervous system of<Emphasis Type="Italic"> Gnathostomula peregrina</Emphasis> (Gnathostomulida) shown by phalloidin labeling,immunohistochemistry, and cLSM,and their phylogenetic significance

Musculature and nervous system of Gnathostomula peregrina (Gnathostomulida, Scleroperalia) were reconstructed from whole animals by immunohistochemistry and confocal laser scanning microscopy. The F-actin muscular subset, stained with FITC-labeled phalloidin, consists of: (1) eleven pairs (four ventral, one ventrolateral, one dorsolateral, five dorsal) of longitudinal muscles; (2) two types of diagonal muscles (thin fibers throughout the body, and slightly thicker fibers of which seven pairs occur ventrally and two pairs dorsally); (3) evenly spaced thin circular fibers that gird the posterior half of the body, continuing less prominently into the anterior half; and (4) a complex pharyngeal and genital musculature. Dorsoventral muscles are absent. The organization of the FMRFamidergic nervous system shows: (1) a central nervous system with a frontal ganglion and one pair of longitudinal nerves ending in a terminal commissure, and one median ventral nerve; (2) eight to ten unipolar perikarya above, and up to ten bipolar perikarya in front of the brain; (3) a total of five (one unpaired, two paired) longitudinal nerves of the peripheral nervous system with two to four accompanying perikarya; and (4) a buccal ganglion of the stomatogastric nervous system with six to eight perikarya above the pharyngeal bulbus. Our results reveal the musculature and nervous system of Gnathostomula to be more complex than hitherto reported.     

Avesicular intercellular contacts in the neuropil of the ganglia of the subpharyngeal complex and in the nerves of the edible snail

Intercellular interconnections in neuropil of dorsal ganglia in the subpharyngeal complex and nerves have been studied in a mature snail (Helix pomatia), dimensions of the shell--3.0 X 3.5 sm, after double fixation (glutaraldehyde and osmium tetraoxide) and treatment with phosphoric tungsten acid. Zones of the neuropil in the left pleural and parietal ganglia have been investigated--where the nerves leave ganglia and in the area of giant cells; neuropil of the central part of both parietal ganglia; central part of the visceral ganglion and nerves--left palial, intestinal and left pleural commissure. The most spread forms of avesicular intercellular contacts in the neuropil are symmetrical. Besides the latter, processes of the neuropil form fissural and desmosomal junctions. Localization of the avesicular contacts supposes presence of dendro-dendritic junctions of desmosomal and fissural types and axo-axonal ones--of desmosomal type. Various types of the contacts differ from each other by their ultrastructural organization.     

Monoaminhaltige Strukturen im Zentralnervensystem der Trichoptera (Insecta)

Zusammenfassung Mit der fluoreszenzmikroskopischen Methode nach Falck und Hillarp wurden biogene Monoamine im Ganglion cerebrale und -suboesophageale bei adulten Trichopteren lokalisiert. Es konnten nur spezifisch grün fluoreszierende Strukturen festgestellt werden. Den überwiegenden Teil dieser Strukturen bilden terminale Varikositäten. Bestimmte Zentren, darunter die primären Assoziationszentren, weisen eine besonders hohe Konzentration und regelmäßige Anordnung fluoreszierender Bereiche auf. Hierzu gehören die Medulla externa und-interna, das Corpus centrale mit seinen Knollen, der -Lobus und -Lobus, das Corpus ventrale und das Neuropil des Unterschlundganglions. Im Deutocerebrum nimmt die Anzahl der fluoreszierenden Fasern stark ab, im Tritocerebrum sind sie kaum noch vorhanden. Die Lamina ganglionaris, der Pedunculus und die Glomeruli fluoreszieren nicht. Fluorophorhaltige Zellkörper lassen sich nur vereinzelt darstellen. Die meisten dieser Zellen (im Lobus opticus, Protocerebrum lateral der -Loben, in der caudalen Pars intercerebralis, im Suboesophageal-ganglion) konnten unter konstanten technischen Bedingungen regelmäßig nachgewiesen werden. Selten waren dagegen Zellen in der Ganglienzellschicht zwischen Proto- und Deutocerebrum sowie eine Zelle im Tritocerebrum darstellbar.

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Monoamine-containing structures in the central nervous system in Trichoptera (Insecta), part I

Summary The distribution of biogenic monoamines in the cerebral ganglion and suboesophageal ganglion of adult Trichoptera (Insecta) was studied by means of the histochemical fluorescence method of Falck and Hillarp. All structures that showed a specific fluorescence emitted a green light. Most of these structures were varicose fibres, spread over almost all the neuropile of the ganglia. In many areas (Medulla externa and interna, -lobe, -lobe, Corpora ventralia, Corpus centrale, and in the Ganglion suboesophageale) the catecholamine-containing varicosities appeared densely packed. In the deutocerebrum, the fluorescent structures were less numerous, the lowest amount of adrenergic neurons being found in the tritocerebrum. No specific fluorescence could be detected in the lamina ganglionaris, the pedunculus, and the glomeruli of the mushroom bodies.Perykarya displaying a specific fluorescence could be divided into two groups: those that could be constantly seen under standardized technical conditions and those found only occasionally. The former were situated in the cell layer of the optical lobe, the protocerebrum, close to the tops of the -lobes, in the caudal pars intercerebralis, and in the suboesophageal ganglion. In the last-mentioned ganglion, there appeared dorsally and ventrally in the caudal part two pairs of cell bodies which exhibited a green fluorescence also in their processes. Only occasionally catecholamine-containing cell bodies could be demonstrated in the cell layer between protocerebrum and deutocerebrum as well as in the tritocerebrum.

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Die vorliegende Arbeit wurde am Histologischen Institut der Universität Lund/Schweden durchgeführt. Ich danke Herrn Prof. K. Gösswald (Institut für Angewandte Zoologie, Würzburg), Herrn Prof. B. Falck, Herrn cand. med. A. Björklund, Herrn Dr. B. Ehinger (Histologisches Institut, Lund) sowie Herrn Dr. R. Elofsson und Herrn Dr. B. Tjeder (Zoologisches Institut, Lund) für die fachliche und technische Hilfe.Die Untersuchung wurde unterstützt durch The Swedish Natural Science Research Council, no. 99-35.