The stomatogastric nervous system of the house cricket Acheta domesticus L. II. Iontophoretic study of neuron anatomy

The anatomy of neurons of the stomatogastric nervous system of Ascheta domesticus was studied using heavy metal iontophoresis through cut nerve ends followed by silver intensification. Nineteen categories of neuron are described and compared with neurons known from the stomatogastric nervous system of other insects. Possible functions for the neurons are suggested. Motor neuron candidates are suggested for all parts of the gut served by the stomatogastric nervous system, and axons of sensory neurons of the anterior pharynx are located. There are four neuron types that cannot readily be assigned motor, sensory, or interneuron functions: large dorsal cells of the frontal ganglion; the two neurons of the nervus connectivus, and two categories of neurons in the median neurosecretory cell group of the pars intercerebralis, the axons of which are contained in the stomatogastric nerves.     

Pressure sensation by an anterior pagoda neuron population distributed in multiple ganglia in the leech, Whitmania pigra

Sensory processing of pressure signals in the central nervous system of the leech, Whitmania pigra, was studied through the interaction between pressure sensory neurons and anterior pagoda neurons. The responses of anterior pagoda neurons to one pulse or a train of pulses in pressure sensory neurons were characterized by the latency and amplitude of excitatory postsynaptic potentials. Here we show that each pressure sensory neuron is able to activate all the anterior pagoda neurons throughout the leech central nervous system. The response patterns of all anterior pagoda neurons were appropriate to the pressure location: in the longitudinal direction the anterior pagoda neuron further away from the pressure sensory neuron had a smaller response with longer latency; inside each ganglion, the anterior pagoda neuron on the contralateral side had a larger response with shorter latency than that on the ipsilateral side. All anterior pagoda neurons excited by pressure sensory neurons comprised a parallel system in which each anterior pagoda neuron was independent from the others. The location information of pressure stimuli was represented through the response of all 40 anterior pagoda neurons covering the whole leech body with a specific pattern of latency and amplitude.     

美洲大蠊中枢DUM神经元的分离和电压门控Na+电流的记录

【目的】建立美洲大蠊Periplaneta americana中枢神经系统背侧不成对中间神经元（dorsal unpaired median neurons, DUM neurons）的分离方法和DUM神经元电生理实验模型。【方法】IA型胶原酶法消化美洲大蠊末端腹神经节, 机械吹打得到DUM神经元细胞, 运用膜片钳技术记录DUM神经元细胞电压门控Na+电流。【结果】分离得到的DUM神经元细胞状态良好, 具有DUN神经元典型的梨状形态和表面特征。以膜片钳全细胞方式记录到的Na+电流符合钠通道电流特征。【结论】IA型胶原酶消化得到美洲大蠊DUM神经元细胞的方法可靠, 能稳定地记录到Na+电流。本文描述的方法为昆虫神经细胞的电生理机制研究提供一个可用的实验模型。     

The morphology of the central nervous system of the barnacle,Semibalanus cariosus (Pallas)

The central nervous system of the sessile barnacle, Semibalanus cariosus (Pallas), has been studied with the particular aim of determining the locations of neuron somata in relation to peripheral nerves. This was accomplished by tracing peripheral nerves using dissection and methylene blue staining techniques, histological methods, and by permitting cobaltous chloride to diffuse via axons into ganglia (“backfilling”). The neuron maps resulting from the study reveal some well-defined sub-systems, a considerable degree of functional clumping of neuron somata, and some unexpected projections of neurons in the CNS. Neurophysiological studies based on these findings are in progress.     

Effects of death of a single neuron on the functional organization of the neuronal ensemble in the leech

The reaction of leech nervous system after elimination of individual mechanosensory neuron by intracellular Pronase injection were studied. In the motor neurons connected with killed cells at 14-90th days after the operation there were the changes of the resting membrane potential and amplitude of postsynaptic potentials developed by the stimulation of mechanosensory neuron. It is suggested that the leech nervous system serves as the dynamic formation depending on changes of neuronal ensemble structure.     

Non-traditional large neurons in the granular layer of the cerebellar cortex

The granular layer of the cerebellar cortex is composed of two groups of neurons, the granule neurons and the so-called large neurons. These latter include the neuron of Golgi and a number of other, lesser known neuron types, generically indicated as non-traditional large neurons. In the last few years, owing to the development of improved histological and histochemical techniques for studying morphological and chemical features of these neurons, some non-traditional large neurons have been morphologically well characterized, namely the neuron of Lugaro, the synarmotic neuron, the unipolar brush neuron, the candelabrum neuron and the perivascular neuron. Some types of non-traditional large neurons may be involved in the modulation of cortical intrinsic circuits, establishing connections among neurons distributed throughout the cortex, and acting as inhibitory interneurons (i.e., Lugaro and candelabrum neurons) or as excitatory ones (i.e., unipolar brush neuron). On the other hand, the synarmotic neuron could be involved in extrinsic circuits, projecting to deep cerebellar nuclei or to another cortex regions in the same or in a different folium. Finally, the perivascular neuron may intervene in the intrinsic regulation of the cortex microcirculation.     

The formation of synapses in the central nervous system

Interneuronal synapses are specialized contact zones formed between the transmitting pole of one neuron, usually an axon, and the receptive pole of another nerve cell, usually a dendritic process or the soma. The formation of these synaptic contacts is the result of cellular events related to neurite elongation, the establishment of polarity, axon guidance, and target recognition. A series of morphological rearrangements takes place once synaptic targets establish their initial contact. These changes include the clustering of synaptic vesicles in the presynaptic element and the formation of a specialized area capable of signal transduction at the postsynaptic target. The present review discusses the role of different synaptic proteins in the cellular events leading to the formation of synapses among neurons in the central nervous system.     

Decreased Response to Acetylcholine during Aging of Aplysia Neuron R15

How aging affects the communication between neurons is poorly understood. To address this question, we have studied the electrophysiological properties of identified neuron R15 of the marine mollusk Aplysia californica. R15 is a bursting neuron in the abdominal ganglia of the central nervous system and is implicated in reproduction, water balance, and heart function. Exposure to acetylcholine (ACh) causes an increase in R15 burst firing. Whole-cell recordings of R15 in the intact ganglia dissected from mature and old Aplysia showed specific changes in burst firing and properties of action potentials induced by ACh. We found that while there were no significant changes in resting membrane potential and latency in response to ACh, the burst number and burst duration is altered during aging. The action potential waveform analysis showed that unlike mature neurons, the duration of depolarization and the repolarization amplitude and duration did not change in old neurons in response to ACh. Furthermore, single neuron quantitative analysis of acetylcholine receptors (AChRs) suggested alteration of expression of specific AChRs in R15 neurons during aging. These results suggest a defect in cholinergic transmission during aging of the R15 neuron.     

Synchronized dynamics of cortical neurons with time-delay feedback

The dynamics of three mutually coupled cortical neurons with time delays in the coupling are explored numerically and analytically. The neurons are coupled in a line, with the middle neuron sending a somewhat stronger projection to the outer neurons than the feedback it receives, to model for instance the relay of a signal from primary to higher cortical areas. For a given coupling architecture, the delays introduce correlations in the time series at the time-scale of the delay. It was found that the middle neuron leads the outer ones by the delay time, while the outer neurons are synchronized with zero lag times. Synchronization is found to be highly dependent on the synaptic time constant, with faster synapses increasing both the degree of synchronization and the firing rate. Analysis shows that pre-synaptic input during the inter-spike interval stabilizes the synchronous state, even for arbitrarily weak coupling, and independent of the initial phase. The finding may be of significance to synchronization of large groups of cells in the cortex that are spatially distanced from each other.     

Colocalized FMRFamide-related neuropeptides in the nervous system of the colorado potato beetle,Leptinotarsa decemlineata (say) (Coleoptera : Chrysomelidae) demonstrated immunohistochemically with mono- and polyclonal antibodies

The distribution of—still chemically undefined—peptide epitopes in subclasses of peptidergic neurons in the Colorado potato beetle, Leptinotarsa decemlineata (Coleoptera : Chrysomelidae) was studied in preparation for peptide isolation by immunological methods. Two monoclonal antibodies, MAC-13 and MAC-3, were selected for their capacity to reveal selected neuron populations by immunohistochemical methods. They partially mimic the immunostaining pattern of a polyclonal anti-FMRFamide antiserum. Immunoreactive neurons, containing FMRFamide-related antigens, were demonstrated with high specificity in the CNS as well as in the visceral and peripheral nervous system. Their total number is large, compared with other subclasses of peptidergic neurons, approximately 230 (peripheral neurons not included). Axons of these neurons run either to the corpora cardiaca for release of peptides into the bloodstream, or to distant target organs, such as the digestive tract, reproductive organs, and somatic muscles. Large, isolated peripheral neurons occur in the vicinity of the ventral nerve cord and release products through terminals located in or on the sheath of nerves emanating from the thoracic ganglia. Different antigens may be colocalized in neuron subclass-specific combinations and then always in the same secretory granules. These observations make clear that groups of peptidergic neurons, considered earlier as a homogeneous population, are much more diversified than hitherto suspected. We may anticipate the occurrence, in subsequent isolation procedures, of at least 3 classes of FMRFamide-related peptides. Compartments in the central nervous system containing high concentrations of single or mixed antigens have been identified.     

The neural apparatus of the small intestine of piglets after administration of a growth stimulator kormogrisein]

By means of classical neurohistological techniques, phase contrast microscopy and morphometry, a comparative investigation has been performed concerning the development of the intramural nervous apparatus in the small intestine, normal and at application of cormogrisine. The structural peculiarities of morphogenesis are considered together with signs of activation and inhibition of the neurons growth in tissue culture. A number of morphological criteria, demonstrating an increased extrusive activity and enhancing potensity of the neurons growth have been revealed. The number of nervous processes becomes greater; degree of their ramification increases; a part of neurons of Dogiel II type turns into multiprocessive neurons with some signs of Dogiel I type cells; growth cones and arcadian structures are present; giant processes appear; thick nervous fasciculi are formed; volume of the neuron bodies increases more intensively. After application of cormogrisine for 2 months a definite neurostimulatory effect is revealed; it demonstrates a more intensive morphogenesis of the small intestine nervous of Physiology, USSR, Academy of Medical Sciences, Leningrad.     

Systemic control of the molecular,cell, and epigenetic mechanisms of long-lasting consequences of stress

Based on M.E. Lobashev’s views of the systemic control of genetic and cytogeneitc processes and a substantial effect of excitability on plastic changes in the central nervous system (CNS), the effect of prolonged emotional and pain stress (PEPS) on the molecular, cell, and epigenetic mechanisms of injury memory was studied in rat strains bred for a certain excitability of the nervous system. PEPS was for the first time found to cause long-lasting (2 months) morphological alterations of the CA3 region of the hippocampus and to modify the genome activity of its pyramidal neurons. The two phenomena were potentiated by a genetically determined low functional state of the CNS. The post-stress regulation of the genome function in hippocampal neurons was mediated by changes in heterochromatin conformation, activation of methyl-CpG-binding protein (MeCP2) synthesis, and subsequent changes in acetylation of histone H4. Genetically determined high excitability of the nervous system proved to be a risk factor that affects the specifics and time course of the observed molecular, cell, and genetic transformations of neurons. The results provide for a better understanding of the epigenetic mechanisms of injury memory, which forms a pathogenetic basis for posttraumatic stress disorder and other human psychogenic conditions characterized by a prolonged duration.     

The effects of transplantation and regeneration of sensory neurons on a somatotopic map in the cricket central nervous system

The restoration of the cercal afferent projection of crickets was examined after severing the cercal nerve or amputating the cercus and reimplanting it. After either maneuver the sensory neurons regenerated arborizations in the central nervous system (CNS) within about 1 month. In order to assess the role of the pathway taken to the CNS in controlling the growth of the terminal arborization, we transplantated left cerci to the right side of the host. The operation mismatched the mediolateral axes of host and graft tissues. In one-third of the neurons examined, the axon trajectories of the regenerated neurons were altered. The terminal arborizations in these cases were unusual; for example, one neuron arborized in an abnormal area as well as in its normal area. In rare instances this neuron arborized only in incorrect areas of the CNS. Thus, it appears that axon pathway can have an effect on the central structure of sensory neurons. However, in most cases after the surgery, the neurons were able to reach their proper target areas even by circuitous routes. The proximodistal coordinate of the map is isomorphic with sensory neuron age, because the most distal receptors are produced early in postembryonic development and new ones are added proximally at each molt. We tested the possibility that the order of differentiation was critical for generating the afferent projection with two experiments. First, the distal cercus including the distal members of the clavate array was amputated. The specimen regenerated an entire distal cercus including distal clavate receptors. When newly generated, distal neurons were stained, the terminal arbors were identical to the amputated neurons they replaced. In this case, both age and order of arrival were reversed from normal yet the topographic projection pattern was not altered. Second, we transplanted young cerci onto older specimens and then examined the regenerated arbors of the transplanted sensory neuron. The immature neuron arborized in the adult nervous system exactly as the mature homolog. Thus the age of a sensory neuron did not appear to be a controlling variable in the elaboration of a terminal arborization. The significance of these results is discussed in the context of two models for development of orderly neuronal connections.     

Target-dependent morphological segregation of Aplysia sensory outgrowth in vitro.

The adult nervous system is characterized by partial or complete morphological segregation of terminals from different afferent neurons innervating the same postsynaptic target. This segregation is thought to result, in part, from competition between the afferent terminals. To explore the role of the target cell in the spatial distribution of presynaptic inputs, the sensory neurons of Aplysia were cultured either with or without a common target motor neuron. In the presence of a common target, the outgrowth from two different sensory neurons tends to occupy separate postsynaptic regions. When cultured without a target motor neuron, processes from different sensory neurons do not segregate, but rather grow freely along one another. Thus, morphological segregation of sensory outgrowth requires interaction with a target neuron and may reflect competition between presynaptic terminals for a limited number of synaptic sites on the motor neuron, or for a postsynaptic trophic factor.     

Dynamics of behaviour during neuronal morphogenesis in culture

We report a developmental sequence in the type and frequency of behaviours of neurons differentiating in vitro. We characterised these changes with extensive analysis of time-lapse sequences from both the continuing cell line pheochromocytoma PC12 and primary mixed cell culture of cat and mouse central nervous system. PC12 cells activated by nerve growth factor (NGF) differentiate in a uniform and synchronous manner. This allowed the first quantification of changes in different neuron behaviours during morphogenesis. Shortly after NGF activation, PC12 cells are highly labile in morphology and exhibit a large variety of morphological behaviours. During the first week of differentiation, the frequency of these behaviours declines, and gross morphology becomes more stable. The frequency of neurite initiation after 1 week in NGF is one-seventh what it was after 2 days in NGF. Over the same period, neurite retraction declines to one-third, and somal migration ceases altogether. Growth-cone activity does not decline during development. These behaviour changes correlate with published data on the differentiation of the neurite cytoskeleton. A qualitatively similar ontogeny was noted in the differentiation of CNS neurons in mixed cell culture. Major differences occur in the relative timing of changes in behaviours. Mature, stable morphology is not detected in these cultures until 7 weeks in vitro.     

Nervous network in larvae of the ascidian Ciona intestinalis

 With the use of the monoclonal antibody UA301, which specifically recognizes the nervous system in ascidian larvae, the neuronal connections of the peripheral and central nervous systems in the ascidian Ciona intestinalis were observed. Three types of peripheral nervous system neurons were found: two located in the larval trunk and the other in the larval tail. These neurons were epidermal and their axons extended to the central nervous system and connected with the visceral ganglion directly or indirectly. The most rostral system (rostral trunk epidermal neurons, RTEN) was distributed bilateral-symmetrically. In addition, presumptive papillar neurons in palps were found which might be related to the RTEN. Another neuron group (apical trunk epidermal neurons, ATEN) was located in the apical part of the trunk. The caudal peripheral nervous system (caudal epidermal neurons, CEN) was located at the dorsal and ventral midline of the caudal epidermis. In the larval central nervous system, two major axon bundles were observed: one was of a photoreceptor complex and the other was connected with RTEN. These axon bundles joined in the posterior sensory vesicle, ran posteriorly through the visceral ganglion and branched into two caudal nerves which ran along the lateral walls of the caudal nerve tube. In addition, some immunopositive cells existed in the most proximal part of the caudal nerve tube and may be motoneurons. Received: 8 September 1997 / Accepted: 14 December 1997     

Development of the enteric nervous system

The mature enteric nervous system (ENS) is characterized by a degree of neuronal phenotypic diversity and independence of central nervous system control unequaled by any other region of the peripheral nervous system. Studies that have utilized the immunocytochemical demonstration of neurofilament protein and explanation of primordial gut with subsequent growth in culture have indicated that the neural crest precursors of enteric neurons are already committed to the neuronal lineage when they colonize the bowel; however, neuronal phenotypic expression occurs within the gut itself. It is likely that precursors able to give rise to each type of neuron found in the mature ENS are present among the earliest neural crest émigrés to reach the bowel. In mice a proximodistal wave of neuronal phenotypic expression occurs that does not appear to reflect the descent of neuronal precursors. This observation, the known plasticity of developing neural crest-derived neurons, and the demonstration of a persistent population of proliferating neuroblasts in the gut raise the possibility that enteric neuronal phenotypic expression is influenced by the enteric microenvironment.     

Neuron death in the developing avian isthmo-optic nucleus, and its relation to the establishment of functional circuitry.

The present review covers all the published data on neuron death in the developing avian isthmo-optic nucleus (ION), which provides a particularly convenient situation for studying the causes and consequences of neuron death in the development of the vertebrate central nervous system. The main conclusions are as follows: The naturally occurring neuron death in the ION is related both temporally and causally to the ION's formation of afferent and efferent connections. The ION neurons need to obtain both anterograde and retrograde survival signals in order to survive during a critical period in embryogenesis. They may compete, at least for the retrograde signals, but the nature of the competition is still unclear. The retrograde signals are modified by action potentials. Neurons dying from a lack of anterograde survival signals can be distinguished morphologically from ones dying from a lack of retrograde signals. The neuron death refines circuitry by selectively eliminating neurons with "aberrant" axons projecting to the "wrong" (i.e., ipsilateral) retina or to the "wrong" (topographically inappropriate) part of the contralateral retina.     

Morphological phenotyping of enteric neurons using neurofilament immunohistochemistry renders chemical phenotyping more precise in porcine ileum

The aim of the study was: (1) to test the suitability of neurofilament (NF) immunohistochemistry for representing the shapes of morphologically defined neuron types in the pig ileum myenteric plexus, (2) to estimate the proportions of these neuron types as related to the whole myenteric neuron population and (3) to demonstrate the usefulness of a refined morphological classification of enteric neurons on the paradigm of calcitonin gene-related peptide (CGRP)-immunoreactive neurons. So far, immunoreactivity for this peptide was supposed to be present in the pig enteric nervous system only in type II neurons. Ileal whole mounts of two pigs were stained with the cuprolinic blue (CB) method and, thereafter, incubated with an antibody pool against NF proteins (70, 160 and 210 kDa), visualised with a fluorochrome-tagged secondary antibody. The structural representation of morphologically defined myenteric neuron types typical for pig ileum (Stach I, II, IV, V and VI) was equivalent to their silver impregnated image, as demonstrated in previous studies. Counts of CB-stained neurons revealed between 2,526 and 2,662 neurons per square centimetre in one pig and between 2,027 and 2,763 in the other. As related to these total neuron numbers, the proportions of type I neurons were 1.7% and 1.5%, of type II neurons 7.2% and 7.9%, of type IV neurons 1.9% and 2.4%, of type V neurons 1.1% and 1.5%, and of type VI neurons 1.3% each. These values are generally comparable with those estimated earlier on silver impregnated material. Double labelling for NF and CGRP indicated that CGRP-immunoreactive smooth contoured neurons with long processes could be subdivided into two distinct morphological neuron types, i.e. type II and type V. We conclude that NF immunohistochemistry is an appropriate tool for representation of morphologically defined enteric neuron types in the pig. Combination of this technique with immunohistochemistry for neuroactive substances may be useful for making both morphological and chemical classification schemes mutually more precise.