Formation of functional synaptic connections between cultured cortical neurons from agrin-deficient mice.

Numerous studies suggest that the extracellular matrix protein agrin directs the formation of the postsynaptic apparatus at the neuromuscular junction (NMJ). Strong support for this hypothesis comes from the observation that the high density of acetylcholine receptors (AChR) normally present at the neuromuscular junction fails to form in muscle of embryonic agrin mutant mice. Agrin is expressed by many populations of neurons in the central nervous system (CNS), suggesting that this molecule may also play a role in neuron-neuron synapse formation. To test this hypothesis, we examined synapse formation between cultured cortical neurons isolated from agrin-deficient mouse embryos. Our data show that glutamate receptors accumulate at synaptic sites on agrin-deficient neurons. Moreover, electrophysiological analysis demonstrates that functional glutamatergic and gamma-aminobutyric acid (GABA)ergic synapses form between mutant neurons. The frequency and amplitude of miniature postsynaptic glutamatergic and GABAergic currents are similar in mutant and age-matched wild-type neurons during the first 3 weeks in culture. These results demonstrate that neuron-specific agrin is not required for formation and early development of functional synaptic contacts between CNS neurons, and suggest that mechanisms of interneuronal synaptogenesis are distinct from those regulating synapse formation at the neuromuscular junction.     

Laminin promotes neuritic regeneration from cultured peripheral and central neurons

The ability of axons to grow through tissue in vivo during development or regeneration may be regulated by the availability of specific neurite-promoting macromolecules located within the extracellular matrix. We have used tissue culture methods to examine the relative ability of various extracellular matrix components to elicit neurite outgrowth from dissociated chick embryo parasympathetic (ciliary ganglion) neurons in serum-free monolayer culture. Purified laminin from both mouse and rat sources, as well as a partially purified polyornithine-binding neurite promoting factor (PNPF-1) from rat Schwannoma cells all stimulate neurite production from these neurons. Laminin and PNPF-1 are also potent stimulators of neurite growth from cultured neurons obtained from other peripheral as well as central neural tissues, specifically avian sympathetic and sensory ganglia and spinal cord, optic tectum, neural retina, and telencephalon, as well as from sensory ganglia of the neonatal mouse and hippocampal, septal, and striatal tissues of the fetal rat. A quantitative in vitro bioassay method using ciliary neurons was used to (a) measure and compare the specific neurite-promoting activities of these agents, (b) confirm that during the purification of laminin, the neurite-promoting activity co- purifies with the laminin protein, and (c) compare the influences of antilaminin antibodies on the neurite-promoting activity of laminin and PNPF-1. We conclude that laminin and PNPF-1 are distinct macromolecules capable of expressing their neurite-promoting activities even when presented in nanogram amounts. This neurite-promoting bioassay currently represents the most sensitive test for the biological activity of laminin.     

Reaction of sensory neurons of the spinal ganglia to sectioning of their peripheral and central processes

Transversal ++semi-sectioning of the spinal ganglion (SG) is a good model for studying the reaction of the ganglional sensory neurons to sectioning of their peripheral and central processes. At sectioning the peripheral and central processes of the SG neurons degeneration of the neurons and their death take place. The degenerative processes are more pronounced in the neurons with the peripheral processes sectioned, and the restorative ones-with the central processes sectioned. The dynamics of the posttraumatic changes in absolute number of the neurons, profile areas of the body fields and neuronal nuclei, amount of neurons with certain signs of axonal reactions in the SG demonstrate a maximally pronounced reaction on the 7th day and beginning of restorative processes on the 15th day. They are not completed by the 180th day.     

Formation, maintenance, and functional uncoupling of connections between identified Helisoma neurons in situ

Previous work with identified Helisoma neurons has characterized an array of neuroplastic responses to axotomy that include the generation of new neuritic outgrowth, the reinnervation of target organs, and the formation of new electrical synapses. These responses are not random, but rather occur in a precise, predictable manner under a variety of culture conditions. The present investigation demonstrates that specific identified neurons display similar neuroplastic "behavior" within the living animal. In response to in situ nerve crushes, neurons B4 and B5 generate new neuritic outgrowth, neuron B4 functionally reinnervates the salivary glands, and new electrical synapses form between the left and right neurons B5. The in situ paradigm employed in the present experiments made it possible to examine responses to axotomy over longer periods than in earlier studies with organ cultures. New B5R-B5L connections, previously found to be stable over the short term in culture, gradually decreased in strength in situ, and the cells effectively uncoupled by 8 weeks after axotomy. This uncoupling did not depend upon target reinnervation and occurred in the continued presence of neurites in the buccal commissure. It is suggested that the stability of new connections is related to whether the connection previously existed in the unperturbed nervous system. The similarities between the ability of identified neurons to grow and to form synaptic connections in situ and in culture suggests that neurons are endowed with a specific program of regenerative responses that can be expressed reliably in a wide variety of environmental conditions.     

Interaction between central and peripheral temperature signals on temperature-sensitive hypothalamic neurons

Changes in the mean firing rate of posterior hypothalamic neurons were studied in experiments on unanesthetized cats in response to elevation of the brain temperature by 0.7–1.5°C and the skin temperature by 3–5°C separately or simultaneously. Altogether 85 neurons were studied in 14 animals: 11 responded to only one form of temperature stimulation, whereas in 16 neurons changes in the firing pattern (in most cases in the same direction) were observed in response to both forms of temperature stimulation. Different types of responses of these neurons were established. Sensitivity to the central temperature stimulus was increased in some neurons of this group when skin temperature stimulation was intensified.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 8, No. 6, pp. 613–619, November–December, 1976.     

Impedance profiles of peripheral and central neurons

The electrical impedance of trigeminal ganglion cells (in vivo) and hippocampal CA1 neurons (in vitro) of guinea pigs was measured in the frequency range of 5-1250 Hz using intracellular recording techniques with single microelectrodes and computerized methodology. The transfer functions of the electrode and the electrode-neuron system were computed from the ratio of fast Fourier transforms of the output voltage response from the neuron and input current composed of sine waves with rapidly increasing frequency which displaced membrane potential by 2-5 mV. We believe these to be the first measurements of complex impedance and transfer functions in peripheral and central neurons of vertebrates and the first use of such input current functions. The majority of trigeminal ganglion cells did not exhibit electrical behaviour ascribable to a simple resistance-capacitance (RC) circuit but showed a hump at low frequencies (5-250 Hz) in the computed transfer function, probably attributable to resonance. The transfer function in less than 20% of the trigeminal neurons could be fitted approximately to a theoretical transfer function (resistance in series with a parallel RC circuit model) providing values for electrode resistance, effective input resistance, and effective input capacitance. The transfer functions measured in hippocampal CA1 neurons were characterized by a rapid fall-off in the low frequency range (less than 200 Hz). Impedance locus plots approximate the locus corresponding to a series RC circuit in parallel with a parallel RC circuit.     

Mechanisms of heterosynaptic facilitation in molluscan neurons

This review is focused on the analysis of research data obtained in one of the models of conditioned reflex, heterosynaptic facilitation (HSF), in the molluscan nervous system. Our experiments were performed on identified giant command neurons LS1 and PS1 of the freshwater snail Planorbarius corneus. HSF was elicited during the electrical stimulation of two nerves: pallial (the analog of unconditioned stimulation — US) and one of the cerebral nerves (the analog of the conditioned stimulation — CS). The degree of HSF manifestation depended not on the intensity of the synaptic response of the giant neuron to US, but the efficacy of the connection between the pallial nerve and neurosecretory neurons surrounding the command neuron of the mesocerebrum. It is demonstrated that HSF develops due to the diffuse neurohumoral action of serotonin (5-hydroxytryptamine — 5-HT) on the postsynaptic structures, but not as a result of local synaptic action on the presynaptic mechanism. Approximately 70% of US cases of 5-HT application induced a four- to six-fold increase in amplitude of the excitatory postsynaptic potential (EPSP) and acetylcholine (ACh) response. Both responses are N-cholinergic and depend on the membrane permeability to Na⁺ and K⁺. In 30% of the cases, ACh response diminished simultaneously with EPSP increase. The 5-HT effect on EPSP and ACh responses were mimicked by the action of phosphodiersterase blockers and adenylate cyclase activators. Thus, the activation of the adenylate cyclase system following 5-HT action facilitates the postsynaptic mechanism underlying HSF formation in command neurons of Planorbarius corneus. Dopamine (DA) and noradrenaline (NA) blocked EPSP and simultaneously increased the amplitude of ACh response. These monoamines were also blocked HSF. The wash-out of catecholamines following HSF blockade enhanced the restoration and subsequent prolongation of synaptic facilitation. It is thus concluded that DA or NA may control the HSF intensity and duration under natural conditions of the nervous system in the molluscs.Neirofiziologiya/Neurophysiology, Vol. 25, No. 3, pp. 224–232, May–June, 1993.     

Morphology and central synaptic connections of the efferent neurons innervating the crayfish hindgut

Summary The distribution, morphology and synaptic connections of the hindgut efferent neurons in the last (sixth) abdominal ganglion of the crayfish, Orconectes limosus, have been investigated using light and electron microscopy in conjunction with retrograde cobalt/nickel and HRP labeling through the intestinal nerve. The hindgut efferent neurons occur singly and in clusters, and are unipolar. Their axonal projections are uniform and consist of a thick primary neurite with typical lateral projections and limited arborization of varicose fibers in the ganglionic neuropil. They also send lower order axon processes to the ganglionic neural sheath, where they arborize profusely, forming a network of varicose fibers. The majority of the efferent neurons project to the anterior part of the hindgut. HRP-labeled axon profiles are found in both pre- and postsynaptic position in the neuropil of the ganglion. HRP-labeled axon profiles also establish pre- and postsynaptic contacts in the intestinal nerve root. All hindgut efferent terminals contain similar synaptic vesicle populations: ovoid agranular vesicles (50–60 nm) and a few large granular vesicles (100–200 nm). It is suggested that the hindgut efferent neurons in the last abdominal ganglion are involved in: (1) innervation of the hindgut; (2) central integrative processes; (3) en route synaptic modification of efferent and afferent signals in the intestinal nerve; (4) neurohumoral modulation of peripheral physiological processes.Fellow of the Alexander von Humboldt Stiftung