Catecholamine containing neurons in the cockroach brain

Evolution, Discovery, and Interpretations of Arthropod Mushroom Bodies

Mushroom bodies are prominent neuropils found in annelids and in all arthropod groups except crustaceans. First explicitly identified in 1850, the mushroom bodies differ in size and complexity between taxa, as well as between different castes of a single species of social insect. These differences led some early biologists to suggest that the mushroom bodies endow an arthropod with intelligence or the ability to execute voluntary actions, as opposed to innate behaviors. Recent physiological studies and mutant analyses have led to divergent interpretations. One interpretation is that the mushroom bodies conditionally relay to higher protocerebral centers information about sensory stimuli and the context in which they occur. Another interpretation is that they play a central role in learning and memory. Anatomical studies suggest that arthropod mushroom bodies are predominately associated with olfactory pathways except in phylogenetically basal insects. The prominent olfactory input to the mushroom body calyces in more recent insect orders is an acquired character. An overview of the history of research on the mushroom bodies, as well as comparative and evolutionary considerations, provides a conceptual framework for discussing the roles of these neuropils.

Tyrosine hydroxylase in the cerebral ganglia of the American cockroach (Periplaneta americana L.): an immunohistochemical study

We have investigated the distribution of tyrosine-hydroxylase-like immunoreactivity in the cerebral ganglia of the American cockroach, Periplaneta americana. Groups of tyrosine-hydroxylase-immunoreactive cell bodies occur in various parts of the three regions of the cerebral ganglia. In the protocerebrum, single large neurons or small groups of neurons are located in the lateral neuropil, adjacent to the calyces, and in the dorsal portion of the pars intercerebralis. Small scattered cell bodies are found in the outer layers of the optic lobe, and clusters of larger cell bodies can be found in the deutocerebrum, medial and lateral to the antennal glomeruli. Thick bundles of tyrosine-hydroxylase-positive nerve fibers traverse the neuropil in the proto- and deutocerebrum and innervate the glomerular and the non-glomerular neuropil with fine varicose terminals. Dense terminal patterns are present in the medulla and lobula of the optic lobe, the pars intercerebralis, the medial tritocerebrum, and the area surrounding the antennal glomeruli, the central body and the mushroom bodies. The pattern of tyrosine-hydroxylase-like immunoreactivity is similar to that previously described for catecholaminergic neurons, but it is distinctly different from the distribution of histaminergic and serotonergic neurons.

Alkaline phosphatase activity in the brain of the American cockroach Periplaneta americana L

The supra- and suboesophageal ganglia of the American cockroach contain material which catalyses the alkaline hydrolysis (pH 9.5) of 5-bromo-4-chloro-3-indolyl phosphate in the presence of Nitro blue tetrazolium. Histochemical studies on unfixed cryostat sections indicate that this type of alkaline phosphatase is restricted to discrete regions in the cockroach brain. Highest enzyme activity is encountered in the mushroom bodies, central body, antennal glomeruli and specific parts of some distinct neural connections including the optic nerve, antennal nerve, circumoesophageal connectives and nerves leaving the suboesophageal ganglion. Tissue fixation by use of formaldehyde-type fixatives, as well as routine paraffin-embedding, completely destroy all histochemically detectable enzyme activity. Native polyacrylamide gradient electrophoresis suggests that the alkaline phosphatase activity is present as multiple isozymic forms, which show up in the 120-130 kD range of standard proteins. Enzyme activity becomes undetectable after fixation (trichloroacetic acid, formaldehyde containing fixatives) of electrophoretically separated native proteins, as well as after electrophoresis in denaturing conditions (SDS and beta-mercapto-ethanol, boiling). However, the enzyme activity remains virtually unaffected after storage of the sample for prolonged periods at -20 to -80 degrees C.

Identifiable neurons in the locust central nervous system that react with antibodies to serotonin

A detailed account is given of a number of neurons in the locust central nervous system that react with antibody raised to serotonin-albumin complex. The antibody was applied to a series of frozen sections of locust ganglia and visualized by using the peroxidase immunohistochemical procedure. The neurons described include certain afferents and their related neuropiles, a small number of efferents and several systems of interneurons, some of which are segmentally repeated, some run from the brain through the whole nerve cord, while others are confined to the brain. It has been possible to identify many of the neurons from previous descriptions obtained from cobalt, Golgi, and osmium ethyl gallate methods.

Serotonin immunoreactive neurons in the central nervous system of an insect (Periplaneta americana)

Serotonin-like immunoreactivity was mapped in the central nervous system (CNS) of the cockroach, Periplaneta americana. Immunoreactive staining occurred in every ganglion of the CNS. The largest numbers of immunoreactive somata were detected in the optic lobes and the brain, and lowest numbers in the first and second thoracic ganglia. Dense stained fibers, ramifications, and varicosities were found in all ganglia, and numerous axon like processes occurred in all interganglionic connectives. Immunoreactive processes were not, however, detected in most of the peripherally projecting nerve roots. Processes were found only in roots of the suboesophageal ganglion and the tritocerebral lobes of the brain. A comparison of the map for serotonin immunoreactivity with one generated for the pentapeptide transmitter proctolin suggests that the two systems overlap only in the suboesophageal ganglion and the tritocerebrum. The amine and peptide may co-occur in neurons in these regions. The serotonin immunoreactive system appeared significantly different from the octopaminergic system of the ventral nerve cord. Seventy-two potentially identifiable immunoreactive cells were located in the cockroach CNS. Some of these may be suitable for physiological study of the functional role of serotonin.

Identification and localization of catecholamines in the nervous system of Limulus polyphemus

The concentrations of various catecholamines in the nervous system of the horseshoe crab Limulus polyphemus have been determined by high-performance liquid chromatography with electrochemical detection. Dopamine, norepinephrine, epinephrine, and their precursor L-Dopa were present in appreciable quantities in discrete regions of the central nervous system and cardiac ganglion. The catecholamines were localized more precisely by use of the glyoxylic-acid-histofluorescence technique of de la Torre and Surgeon (1976). Catecholamine fluorescence appeared in protocerebral and tritocerebral neuropile, including regions of the central body and optic medulla. Posterior to these brain areas, tracts extended through the circumesophageal ganglionic ring and laterally out each of the pedal ganglia. Small clusters of large fluorescent somata were present in the protocerebrum. No fluorescence was observed in the corpora pedunculata.

The brain of the horseshoe crab (Limulus polyphemus). III. Cellular and synaptic organization of the corpora pedunculata

The large, hemispherical mass of the Limulus corpora pedunculata consists of two highly branched lobes, each connected to the protocerebrum by a narrow stalk. About 10(4) afferent fibers enter through the stalks and make diverse, profuse, and often reciprocal contacts with several million Kenyon (intrinsic) cells and one another. The Kenyon cell axonal arborizations converge on a few hundred efferent dendrites. The afferent fiber types can be classified into five types. Type A forms the club-shaped core of glomeruli and circumglomerular annuli, and contains small flat vesicles, suggesting an inhibitory function. Type B terminates with bushy endings in glomeruli and is presynaptic to both Kenyon cells and to Type A terminals. It has clear round vesicles and is the presumptive excitatory input. Type C terminates on other afferents, in glomeruli, and rarely on Kenyon cell bodies, contains angular (neurosecretory) granules and is postulated to impart circadian rhythm. Type D terminates on Kenyon cell somata and the initial neurite segment (but not in glomeruli), and contains dense-cored vesicles. Type E terminates in peduncles on other afferents and Kenyon cell telodendria. It contains dense vesicles. The C, D, and E afferents have reciprocal synaptic connections with Kenyon cell axon terminals. Glomeruli thus receive three different inputs of presumptive inhibitory (A), excitatory (B), and neuromodulatory nature (C). Kenyon cells, increasing in number up to about 1 x 10(8) in the adult, show minor variations in their dendritic pattern and have only one rare variant cell type. Interactions between them occur primarily at their axonal boutons as they crowd around efferent fibers. The latter have large receptive fields, some of their large somata are located within the confines of the corpora pedunculata, and they receive input almost only from Kenyon cells. Numerical and directional details of the circuitry in the corpora pedunculata have been extracted by a combination of light and electron microscopy, serial sectioning, silver staining, and stereology. The corpora pedunculata appear to process primarily the voluminous chemosensory input from the appendages, an assumption that is supported by the major connections of the organ.

Brain catecholamines, spontaneous bioelectrical activity and aggressive behavior in ants (Formica rufa)

The effects of dopamine (DA), 1-DOPA, diethyldithiocarbamate (DDTC) and haloperidol on aggressive behavior and spontaneous bioelectrical activity of the ant (Formica rufa) were studied. Drugs such as DA, 1-DOPA and DDTC increased mutual aggressivity in ants while it failed to change aggression directed towards other species of insects (e.g., the beetle Geotrupes sp.). The amplitude of EEG waves and the amplitude of neuronal discharges within the protocerebrum decreased after administration of both DA and 1-DOPA. Both DDTC and 1-DOPA increased the concentration of adrenaline as well as DA in the brain of ants. Haloperidol decreased intrageneric aggressivity but caused no evident changes in both EEG pattern and neuronal discharges. The present study indicates that catecholamines are critically involved in the organization of aggressive behavior in ants.